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Review: Nutritional regulation of intestinal starch and protein assimilation in ruminants

Published online by Cambridge University Press:  06 February 2020

D. L. Harmon*
Affiliation:
Department of Animal and Food Science, University of Kentucky, Lexington, KY40546, USA
K. C. Swanson
Affiliation:
Department of Animal Sciences, North Dakota State University, Fargo, ND58102, USA
*

Abstract

Pregastric fermentation along with production practices that are dependent on high-energy diets means ruminants rely heavily on starch and protein assimilation for a substantial portion of their nutrient needs. While the majority of dietary starch may be fermented in the rumen, significant portions can flow to the small intestine. The initial phase of small intestinal digestion requires pancreatic α-amylase. Numerous nutritional factors have been shown to influence pancreatic α-amylase secretion with starch producing negative effects and casein, certain amino acids and dietary energy having positive effects. To date, manipulation of α-amylase secretion has not resulted in substantial changes in digestibility. The second phase of digestion involves the actions of the brush border enzymes sucrase-isomaltase and maltase-glucoamylase. Genetically, ruminants appear to possess these enzymes; however, the absence of measurable sucrase activity and limited adaptation with changes in diet suggests a reduced capacity for this phase of digestion. The final phase of carbohydrate assimilation is glucose transport. Ruminants possess Na+-dependent glucose transport that has been shown to be inducible. Because of the nature of pregastric fermentation, ruminants see a near constant flow of microbial protein to the small intestine. This results in a nutrient supply, which places a high priority on protein digestion and utilization. Comparatively, little research has been conducted describing protein assimilation. Enzymes and processes appear consistent with non-ruminants and are likely not limiting for efficient digestion of most feedstuffs. The mechanisms regulating the nutritional modulation of digestive function in the small intestine are complex and coordinated via the substrate, neural and hormonal effects in the small intestine, pancreas, peripheral tissues and the pituitary—hypothalamic axis. More research is needed in ruminants to help unravel the complexities by which small intestinal digestion is regulated with the aim of developing approaches to enhance and improve the efficiency of small intestinal digestion.

Type
Review Article
Copyright
© The Animal Consortium 2020

Implications

Feed digestion represents a critical process of the utilization of nutrients for productive purposes such as meat or milk production. In high-producing ruminants, starch represents the major component of dietary energy, whereas protein represents a high cost and dietary, environmental concern; thus, it is critical that the utilization of both be optimal. Evolution has dictated that ruminants use protein derived from microbial fermentation, and this tends to be a critical driver for nutrient assimilation. In contrast, starch does not result in signalling to increase starch assimilation, and evolutionary constraints may exist for maximal use in the small intestine of ruminants.

Introduction

In ruminants, the composition of digesta flowing to the small intestine differs substantially from what is consumed in the diet because ruminants have a complex stomach with four compartments allowing for pregastric fermentation (Merchen, Reference Merchen and Church1988; Swanson, Reference Swanson, Smithers and Knoerzer2019). This differing digesta composition is because of fermentation in portions of the stomach (rumen, reticulum and omasum) resulting in the production of volatile fatty acids (VFAs) and microbial biomass. The VFA provides a large proportion (approximately 50% to 85%) of the total metabolizable energy to the animal. A portion of the feed carbohydrates and proteins are degraded in the forestomachs, and a portion escapes fermentation in the forestomachs and flows to the small intestine along with microbial biomass containing microbial protein and is utilized by the animal. Microbial protein supplies a substantial portion (approximately 50% or more) of the protein digested and utilized by the animal.

The small intestine is the primary site of digestion and absorption of the macronutrients, escape starch, protein (microbial and escape) and lipids, aside from VFA absorption in the forestomachs. Because of the microbial influence on the nutrient profile, a complete description of these processes remains elusive. The objectives of this review are to describe: (1) the processes and potential limitations of small intestinal starch and protein assimilation and (2) the mechanisms regulating the nutritional modulation of digestive function in the small intestine in ruminants.

Small intestinal starch digestion

The feeding of large amounts of grain to ruminants is still a relatively new practice encompassing approximately the past 70 years. The continued availability of comparatively inexpensive cereal grains has insured that the practice will continue for the foreseeable future as modern production practices continually expand in scale with ever-decreasing profit margins. Research into these practices is also relatively recent with the earliest work characterizing the adaptive responses in ruminants fed high-starch ingredients (Clary et al., Reference Clary, Mitchell, Little and Bradley1969).

In forage-based diets, fibre and microbial polysaccharides are the primary carbohydrates flowing to the small intestine (Swanson, Reference Swanson, Smithers and Knoerzer2019). Limited fibre is digested in the small intestine because there are no fibre-digesting enzymes produced by the animal and there is a much smaller population of microbes in the small intestine than in the forestomach. When forage-based diets are fed, limited amounts of soluble carbohydrates such as starches flow to the small intestine as the small amounts in forages are fermented by the microbes in the forestomach, and any α-glucosides present may arise from microbial sources (Branco et al., Reference Branco, Harmon, Bohnert, Larson and Bauer1999). However, from 4% to 60% of dietary starch passes to the small intestine, depending on grain source and processing methods, when high-concentrate diets based on cereal grains are fed (Theurer, Reference Theurer1986). A recent summary for dairy cows (Moharrery et al., Reference Moharrery, Larsen and Weisbjerg2014) reported that ruminal digestion averaged 68% with a range of 22% to 94%.

Pancreatic α-amylase

Most species readily adapt their complement of digestive enzymes to match their diet (Brannon, Reference Brannon1990), ensuring maximum digestion of major dietary components. Early work suggested that ruminants fed high-grain diets had increased pancreatic concentrations of α-amylase (Clary et al., Reference Clary, Mitchell, Little and Bradley1969; Russell et al., Reference Russell, Young and Jorgensen1981; Janes et al., Reference Janes, Weekes and Armstrong1985). Kreikemeier et al. (Reference Kreikemeier, Harmon, Peters, Gross, Armendariz and Krehbiel1990) were the first to demonstrate that pancreatic α-amylase was linked to dietary energy intake and that earlier studies suggesting that pancreatic α-amylase was up-regulated with increased starch intake were confounded by dietary energy. This study (Kreikemeier et al., Reference Kreikemeier, Harmon, Peters, Gross, Armendariz and Krehbiel1990) demonstrated that cattle do respond to increased dietary energy, whether it is from forage or concentrate, by increasing pancreatic α-amylase content. When starch intake was increased while controlling energy, the content of pancreatic α-amylase decreased.

This adaptive response is unique and unexpected. Follow-up experiments using steers with pancreatic cannula confirmed that starch infused directly into the abomasum would decrease pancreatic α-amylase secretion compared with water or starch infused into the rumen (Walker and Harmon, Reference Walker and Harmon1995).

The nature of ruminant digestion insures that increased dietary energy increases the intestinal supply of microbial protein. Thus, the interpretation of experiments reporting that increased dietary energy intake increases pancreatic α-amylase is inherently confounded with energy and protein. Experiments have shown that increasing the small intestinal protein supply by infusing casein abomasally increases small intestinal starch disappearance (Richards et al., Reference Richards, Branco, Bohnert, Huntington, Macari and Harmon2002) and abomasal casein infusion increases pancreatic α-amylase secretion (Richards et al., Reference Richards, Swanson, Paton, Harmon and Huntington2003). These results could indicate that the increased pancreatic α-amylase responses to increased dietary energy resulted from the increased supply of small intestinal protein.

To directly examine the relationship between the small intestinal supply of protein and energy, calves were infused abomasally for 10 days with casein and starch in a 2 × 2 factorial arrangement (Swanson et al., Reference Swanson, Matthews, Woods and Harmon2002a). Compared with control (water infusion), calves receiving starch had reduced pancreatic α-amylase, whereas calves receiving casein had increased pancreatic α-amylase. However, calves receiving both starch and casein had reduced pancreatic α-amylase, similar to starch alone. These results suggest that the positive effects of casein to increase pancreatic α-amylase are suppressed by increased small intestinal starch.

The regulation of pancreatic α-amylase is obviously complex and involves translational events. In the casein and starch infusion study (Swanson et al., Reference Swanson, Matthews, Woods and Harmon2002a), casein infusion increased both pancreatic α-amylase mRNA expression and α-amylase protein, whereas starch + casein decreased both.

The ability of starch, or a partially hydrolysed starch solution (Walker and Harmon, Reference Walker and Harmon1995; Swanson et al., Reference Swanson, Matthews, Woods and Harmon2002a), to down-regulate pancreatic α-amylase questions the capacity of the ruminant to hydrolyse starch and how starch influences the regulation of pancreatic α-amylase. However, a comparison of glucose infused abomasally compared with starch demonstrated that glucose also down-regulates pancreatic α-amylase (Swanson et al., Reference Swanson, Richards and Harmon2002b) indicating that the hydrolysis of α-glucosides is not limiting the adaptive response.

The downregulation of pancreatic α-amylase in cattle remains an intriguing and unexplained adaptive response. The concept has been studied and repeated across multiple experiments and experimental models. Several experiments have sought to characterize factors that affect pancreatic α-amylase, particularly factors that appear to stimulate increases in pancreatic α-amylase. The most notable of these is increasing casein supply to the small intestine. Research infusing starch and casein either ruminally or abomasally into steers (Taniguchi et al., Reference Taniguchi, Huntington and Glenn1995) reported that starch and casein infused abomasally increased the net portal and total splanchnic fluxes of glucose suggesting greater small intestinal starch hydrolysis and glucose absorption. Casein infused into the abomasum of lambs has been reported to increased glucose transporter activity in the small intestine (Mabjeesh et al., Reference Mabjeesh, Guy and Sklan2003).

The observation that casein could enhance small intestinal starch assimilation was followed by experiments showing that small intestinal starch disappearance (Richards et al., Reference Richards, Branco, Bohnert, Huntington, Macari and Harmon2002; Brake et al., Reference Brake, Titgemeyer, Bailey and Anderson2014b) and pancreatic α-amylase secretion (Richards et al., Reference Richards, Swanson, Paton, Harmon and Huntington2003) increased with casein infusion. Subsequent work comparing the feeding of intact and acid-hydrolysed casein demonstrated that intact casein stimulated pancreatic α-amylase secretion in steers as well as increasing cholecystokinin (CCK) secretion (Lee et al., Reference Lee, Choi, Jin, Wang, Lee, Ku, Hwang, Kim, Vega and Lee2013).

The exact mechanism for stimulation of pancreatic α-amylase and increasing starch digestion remains unclear but attempts to refine the response to individual amino acids have been made. Brake et al. (Reference Brake, Titgemeyer and Anderson2014a) infused duodenally and ileally cannulated steers with starch and compared additions of casein, crystalline amino acids similar to casein and essential or non-essential amino acids similar to casein. The small intestinal starch digestion was highest for the casein and crystalline amino acids similar to casein treatments. These authors then followed with a second experiment comparing casein, glutamate equivalent to casein, phenylalanine plus tryptophan plus methionine equivalent to casein or both. Small intestinal starch digestibility was highest in the casein and glutamate treatments, and based on differences in the ileal flows of small-chain α-glycosides the authors suggested that casein and non-essential amino acids may increase starch digestion by different mechanisms with casein favouring increased pancreatic α-amylase. The differential response suggesting a greater pancreatic α-amylase response was not present in a follow-up study where glutamate infusion from 30 to 120 g/day linearly increased small intestinal starch digestibility (Blom et al., Reference Blom, Anderson and Brake2016).

Numerous mechanisms may contribute to what is measured as increased small intestinal disappearance. Research on milk-fed calves reported that 89% of starch intake might have been fermented prior to the terminal ileum (Gilbert et al., Reference Gilbert, Pantophlet, Berends, Pluschke, van den Borne, Hendriks, Schols and Gerrits2015) suggesting that microbial activity may contribute substantially to the small intestinal carbohydrate disappearance. The infusion of casein into the small intestine causes dramatic increases in large intestinal digestion suggesting that stimulation of microbial activity in the small intestine is undoubtedly a contributor to the increased disappearances observed with casein and may explain some of the differential responses attributed to casein and amino acids (Brake et al., Reference Brake, Titgemeyer and Anderson2014a and Reference Brake, Titgemeyer, Bailey and Anderson2014b; Blom et al., Reference Blom, Anderson and Brake2016), albeit 89% disappearance from fermentation may be unique to the milk-fed calf. However, the increases in intestinal starch disappearance observed with individual amino acids are less attributable to increased microbial activity and have been associated with increased pancreatic α-amylase.

Other amino acids have been evaluated for their effect on small intestinal starch digestion. Goats were infused duodenally with phenylalanine at 0, 2, 4 and 8 g/day for 2 weeks and pancreatic secretion was measured (Yu et al., Reference Yu, Xu, Yao, Liu, Li, Liu, Wang, Sun and Liu2013). Pancreatic α-amylase secretion responded quadratically with a small increase at 2 g/day. A follow-up experiment using short-term, 10 h infusions showed that pancreatic α-amylase secretion responded cubically with increases in secretion at 2 and 10 g/day of phenylalanine. A similar experiment using goats reported that both short- and long-term infusions of leucine at 0, 3, 6 or 9 g/day increased pancreatic α-amylase secretion (Yu et al., Reference Yu, Xu, Liu, Yao, Yu and Wang2014a).

The inconsistent responses may result from the difficulty in assessing pancreatic α-amylase secretion with few animals and because of the pulsatile and variable secretion from the pancreas. However, these studies (Yu et al., Reference Yu, Xu, Yao, Liu, Li, Liu, Wang, Sun and Liu2013 and Reference Yu, Xu, Liu, Yao, Yu and Wang2014a) indicate that phenylalanine and leucine have the ability to up-regulate pancreatic α-amylase secretion, whereas the combination of phenylalanine plus tryptophan plus methionine did not increase small intestinal starch digestion in steers (Brake et al., Reference Brake, Titgemeyer and Anderson2014a). These observations were confirmed in goats receiving duodenal infusions of leucine (3 and 9 g/day) and phenylalanine (2 g/day) that were slaughtered and enzyme activity in the small intestine measured (Yu et al., Reference Yu, Xu, Wang, Liu, Yao, Wu, Qin and Sun2014b). The infusion of leucine and phenylalanine caused large increases in pancreatic α-amylase activity in the proximal small intestine and tended to increase small intestinal starch digestibilty.

The effects of leucine on pancreatic secretion have also been studied in cattle. Heifers fitted with pancreatic cannula also received duodenal infusions of 10, 20 and 30 g/day of leucine (Liu et al., Reference Liu, Liu, Liu, Xu, Yu, Wang, Cao and Yao2015). They reported that leucine infused at 10 g/day increased pancreatic α-amylase secretion. However, supplementing additional phenylalanine and leucine in milk-fed calves did not increase pancreatic α-amylase (Cao et al., Reference Cao, Yang, Guo, Zheng, Wang, Cai, Liu and Yao2018).

The milk-fed calf may have differing mechanisms of regulation compared with the previous studies in mature ruminants. However, leucine has been shown to up-regulate pancreatic α-amylase in pancreatic acinar cells isolated from new-born calves and maintained in culture (Guo et al., Reference Guo, Liang, Zheng, Liu, Yin, Cao and Yao2018a). They demonstrated an upregulation of the m-TOR signalling pathway that may have resulted in increased α-amylase synthesis. This response contrasted with the influence of phenylalanine that was studied using pancreatic acinar cells and tissue segments isolated from 2-month-old calves (Guo et al., Reference Guo, Tian, Shen, Zheng, Liu, Cao, Cai and Yao2018b). Phenylalanine stimulates α-amylase secretion and mRNA expression as well as the phosphorylation of S6K1 and 4EBP1 indicating that phenylalanine could regulate the synthesis of α-amylase through the mRNA translation initiation factors, S6K1 and 4EBP1. Thus, these studies report that phenylalanine and leucine both stimulate pancreatic enzyme synthesis but through different mechanisms.

Mucosal carbohydrases

Research on the deficiencies of mucosal carbohydrases in infants has dramatically increased our understanding of the processes involved in mucosal carbohydrase function (Nichols et al., Reference Nichols, Baker and Quezada-Calvillo2018). The major starch hydrolysis activities within the small intestine function through two proteins that contribute four hydrolytic activities, sucrase-isomaltase and maltase-glucoamylase (Galand, Reference Galand1989). These proteins have a high degree of homology (Figure 1), and sucrase-isomaltase is generally present in much higher quantities. These four activities are better described as α-glucosidases because they digest multiple linear starch oligosaccharides to glucose, not just maltose. An excellent chronology of the study of intestinal disaccharidases is available (Lentze, Reference Lentze2018).

Figure 1 Maltase-glucoamylase and sucrose-isomaltase protein structures. Percentages represent sequence identity. Size differences represent greater relative protein abundances for sucrose-isomaltase. Adapted with permission from Lee et al. (Reference Lee, Rose, Lin, Quezada-Calvillo, Nichols and Hamaker2016) Copyright ©2016 American Chemical Society.

The process of starch assimilation in humans has been described in detail by numerous authors. The process involves six carbohydrase activities: salivary and pancreatic α-amylase, n-terminal and c-terminal activities of sucrase-isomaltase and maltase-glucoamylase (Lin et al., Reference Lin, Nichols, Quezada-Calvillo, Avery, Sim, Rose, Naim and Hamaker2012b). Ruminants lack salivary α-amylase, and they possess no sucrase activity (Huber et al., Reference Huber, Jacobson and Allen1961). Thus, of the six required enzyme activities ruminants possess perhaps four, pancreatic α-amylase, mucosal isomaltase activity and mucosal maltase(s) activities (Coombe and Siddons, Reference Coombe and Siddons1973). The enzyme profile of ruminants resembles humans exhibiting congenital sucrase-isomaltase deficiency where patients have genetic mutations resulting in the absense of one or both subunits of sucrase-isomaltase resulting in limitations in carbohydrate digestion.

A complete understanding of starch assimilation may also be limited by terminology. The textbook description has been that pancreatic α-amylase α-1,4 endoglucosidase hydrolysis in the intestinal lumen produces maltose and a collection of limit dextrins, so named because of the presence of α-1,6-bonds ‘limits’ the activity of α-amylase in these regions. These products of pancreatic α-amylase are then exposed to mucosal carbohydrases that hydrolyse this collection of starch fragments at the brush border membrane prior to glucose transport. While this description is not inaccurate, it is simplistic. For example, studies characterizing the substrate preferences of the n- and c-terminal subunits of recombinant mammalian maltase-glucoamylase and sucrase-isomaltase reported that the c-terminal subunit of maltase-glucoamylase provided rapid and high digestion of cooked starch, nearly 80%, while other subunits showed 20% to 30% digestion (Lin et al., Reference Lin, Nichols, Quezada-Calvillo, Avery, Sim, Rose, Naim and Hamaker2012b). Thus, multiple proteins may contribute to the hydrolysis of starch molecules.

Referring to maltase as a specific enzyme is also misleading, but rather there are multiple proteins possessing maltase activity, or more specifically, each subunit possessing carbohydrase activity has activity on multiple substrates (Lin et al., Reference Lin, Hamaker and Nichols2012a). Characterization of the substrate preferences of the intestinal carbohydrases for various α-linked substrates demonstrated that c-terminal and n-terminal maltase-glucoamylase and c-terminal and n-terminal sucrase-isomaltase all possessed some hydrolytic capacity for isomaltose, whereas both c-terminal sucrase-isomaltase and c-terminal maltase-glucoamylase hydrolysed sucrose (Table 1). This would suggest that since ruminants possess no measurable sucrase activity there are differences in the structure and function of the mucosal carbohydrases.

Table 1 Hydrolysis of different substrates by c-terminal (ct) and n-terminal (nt) mouse recombinant α-glucosidases

One unit of enzyme activity was arbitrarily defined as the amount of enzyme that released 1 μg of glucose from 1% maltose per 10 min at 37°C.; Mean value ± SD of measurement of experiments performed in triplicate. Adapted from Lee et al. (Reference Lee, Rose, Lin, Quezada-Calvillo, Nichols and Hamaker2016).

The process of multiple entities acting on multiple substrates increases the complexity of carbohydrate assimilation exponentially. However, strides have been made in understanding this process. The roles of maltase-glucoamylase and sucrase-isomaltase have been characterized using a maltodextrin substrate chosen to emulate a pancreatic α-amylase end-product (Quezada-Calvillo et al., Reference Quezada-Calvillo, Robayo-Torres, Ao, Hamaker, Quaroni, Brayer, Sterchi, Baker and Nichols2007). They reported that at low-substrate concentrations maltase-glucoamylase was more active than sucrase-isomaltase; however, at higher substrate concentrations, maltase-glucoamylase was inhibited, whereas sucrase-isomaltase was not. Thus, maltase-glucoamylase contributed only 20% of the hydrolytic activity, and pancreatic α-amylase was stimulatory to both the hydrolytic activities of sucrase-isomaltase and maltase-glucoamylase. This inhibitory activity was later localized to the C-terminal ‘glucoamylase’ subunit (Quezada-Calvillo et al., Reference Quezada-Calvillo, Sim, Ao, Hamaker, Quaroni, Brayer, Sterchi, Robayo-Torres, Rose and Nichols2008). It has been proposed that maltase-glucoamylase is responsible for the rapid hydrolysis at low-starch intakes, whereas sucrase-isomaltase provides sustained hydrolysis at high-starch intakes (Diaz-Sotomayor et al., Reference Diaz-Sotomayor, Quezada-Calvillo, Avery, Chacko, Yan, Lin, Ao, Hamaker and Nichols2013). This greater overall activity of sucrase-isomaltase is consistent with the relative abundances of the proteins in that sucrase-isomaltase is approximately 3-fold greater than maltase-glucoamylase (Amiri and Naim, Reference Amiri and Naim2017).

While our knowledge of the brush border carbohydrases has increased dramatically for non-ruminants, much less is known in regard to their function in ruminants. The expression of sucrase-isomaltase and maltase-glucoamylase has been shown to be highly responsive to diet changes in mice, increasing in response to increased digestible starch and regressing when fed resistant starch (Goda and Honma, Reference Goda and Honma2018). This response is thought to be elicited by available hexose as corresponding increases in glucose transporter (SGLT1) accompany increases in sucrase-isomaltase with both glucose and fructose feeding, with the reponse being more significant for fructose (Kishi et al., Reference Kishi, Takase and Goda1999).

The structural similarities of sucrase-isomaltase and maltase-glucoamylase (59% homologous) suggest a common route for post-translational processing in that both are type II membrane glycoproteins (Nichols et al., Reference Nichols, Eldering, Avery, Hahn, Quaroni and Sterchi1998; Amiri and Naim, Reference Amiri and Naim2017). A similar path of post-translational processing could result in a common alteration in c-terminal processing affecting both proteins. However, differences in processing do exist (Amiri and Naim, Reference Amiri and Naim2018). Particularly, sucrase-isomaltase is cleaved at the luminal membrane by trypsin into the two subunits (Naim et al., Reference Naim, Sterchi and Lentze1988) whereas maltase-glucoamylase is not.

Generally, ruminant mucosal carbohydrase activities are non-responsive to changes in diet (Siddons, Reference Siddons1968; Russell et al., Reference Russell, Young and Jorgensen1981; Janes et al., Reference Janes, Weekes and Armstrong1985; Kreikemeier et al., Reference Kreikemeier, Harmon, Peters, Gross, Armendariz and Krehbiel1990; Bauer et al., Reference Bauer, Harmon, McLeod and Huntington1995; Gorka et al., Reference Gorka, Schurmann, Walpole, Blonska, Li, Plaizier, Kowalski and Penner2017). Ruminants possess measurable activities for maltase (Siddons, Reference Siddons1968), isomaltase (Coombe and Siddons, Reference Coombe and Siddons1973), trehalase (Coombe and Siddons, Reference Coombe and Siddons1973; Kreikemeier et al., Reference Kreikemeier, Harmon, Peters, Gross, Armendariz and Krehbiel1990) and lactase (Siddons, Reference Siddons1968).

Heat inactivation suggested that activities of trehalase, isomaltase and lactase were single entities, whereas maltase represented multiple activities (Coombe and Siddons, Reference Coombe and Siddons1973). Based on the Lee et al. (Reference Lee, Rose, Lin, Quezada-Calvillo, Nichols and Hamaker2016) study (Table 1), the n-terminal activities of both proteins would represent multiple enzymes with no sucrase activity. Whether both proteins differ in ruminants remains to be determined.

The apparent absence of changes in mucosal carbohydrase activities in ruminants suggests that ruminants do not adapt to increased intake of carbohydrate. However, increased intestinal length (Kreikemeier et al., Reference Kreikemeier, Harmon, Peters, Gross, Armendariz and Krehbiel1990) and increased mucosal mass (Kreikemeier et al., Reference Kreikemeier, Harmon, Peters, Gross, Armendariz and Krehbiel1990; Gorka et al., Reference Gorka, Schurmann, Walpole, Blonska, Li, Plaizier, Kowalski and Penner2017) led to increases in total hydrolytic capacity of the intestine and in the jejunum with increases in energy intake (Kreikemeier et al., Reference Kreikemeier, Harmon, Peters, Gross, Armendariz and Krehbiel1990; Gorka et al., Reference Gorka, Schurmann, Walpole, Blonska, Li, Plaizier, Kowalski and Penner2017).

These studies suggest that, as ruminants consume increased amounts of high-concentrate diets, there is a greater ability to assimilate the starch in the small intestine. However, that capacity when compared with the ability of the non-ruminant to adapt, and perhaps with a more efficient complement of enzymes, may explain the inefficiencies of ruminant small intestinal digestion. We have calculated that starch digestibility in the small intestine must be maintained to at least 70% (Huntington et al., Reference Huntington, Harmon and Richards2006) to maintain the energetic efficiency advantages of small intestinal digestion. These limitations may explain some of the challenges of meeting that requirement.

Glucose transport

Early research suggested limited amounts of glucose are absorbed into the portal blood of functioning ruminants (Schambye, Reference Schambye1951). However, studies directly evaluating glucose transport by measuring disappearance of sugars from isolated loops of the small intestine filled with sugar solutions determined that absorptive capacity decreased along the length of the small intestine as measurements proceeded distally and that the capacity decreased following weaning (White et al., Reference White, Williams and Morris1971). These workers also suggested that the capacity for glucose absorption was less than the rat, mainly as a function of intestinal length per kg BW.

The presence of active transport of sugars was reported (Scharrer, Reference Scharrer1976) and a decrease in transport capacity associated with weaning was described (Scharrer et al., Reference Scharrer, Peter and Raab1979). These authors (Scharrer et al., Reference Scharrer, Peter and Raab1979) also demonstrated that the declining transport of glucose associated with weaning could be delayed by prolonged milk feeding.

These early studies, which contributed significantly to our understanding of sugar transport in ruminants, were all conducted using anaesthetized sheep, with measurements made using intestinal perfusions and measurement of glucose disappearance. These observations were later confirmed using brush border membrane vesicles prepared from sheep small intestine (Shirazi-Beechey et al., Reference Shirazi-Beechey, Kemp, Dyer and Beechey1989). These authors reported that Na+-dependent glucose transport (SGLT1) was present throughout the small intestine of pre-ruminant lambs but absent in ruminants. These observations were later extended (Shirazi-Beechey et al., Reference Shirazi-Beechey, Hirayama, Wang, Scott, Smith and Wright1991a) to show that SGLT1 was maximum 2 weeks following birth then declined to negligible amounts following weaning and that increased transport activity could be maintained by maintaining lambs on milk replacer. This study was also the first to report SGLT1 could be induced in the small intestine of 2- to 3-year-old sheep infused for 4 days with 30 mM glucose or α-methyl-D-glucopyranoside (a non-metabolizable analogue).

Subsequent work (Lescale-Matys et al., Reference Lescale-Matys, Dyer, Scott, Freeman, Wright and Shirazi-Beechey1993) showed that maintaining lambs on milk maintained tissue SGLT1 mRNA levels, whereas infusion of glucose into functional ruminant sheep increased mRNA only 2-fold compared with a 60- to 90-fold increase in transporter activity. Changes in SGLT1 activity in sheep were associated with changes in SGLT1 protein abundance (Shirazi-Beechey et al., Reference Shirazi-Beechey, Dyer, Allison and Wood1996) whereas the regulation of SGLT1 synthesis was thought to occur post-translationally.

The presence of SGLT1 in cattle jejunum has been established (Kaunitz and Wright, Reference Kaunitz and Wright1984) and one of the first to address SGLT1 expression throughout the gastrointestinal tract was conducted in lactating cows (Zhao et al., Reference Zhao, Okine, Cheeseman, Shirazi-Beechey and Kennelly1998). They reported that SGLT1 was expressed throughout the gastrointestinal tract of cattle and that SGLT1 was active in the small intestine, being greater in the proximal small intestine. Bauer et al. (Reference Bauer, Harmon, McLeod and Huntington2001b) infused both cattle and sheep abomasally or ruminally with a partially hydrolysed starch solution for 7 days before slaughtering and measuring transport activity in small intestinal tissues. They reported that SGLT1 increased 2.1-fold in the proximal jejunum of animals receiving the abomasal compared with the ruminal infusion. However, a subsequent study (Bauer et al., Reference Bauer, Harmon, Bohnert, Branco and Huntington2001a) was unable to demonstrate changes in SGLT1 activity throughout the small intestine in response to abomasal v. ruminal infusion of partially hydrolysed starch. Obviously, a limitation of this model could be the conversion of starch hydrolysate to glucose or that mechanisms other than SGLT1 contribute to small intestinal glucose disappearance in cattle.

To determine if increased glucose in the small intestine upregulates glucose transport, glucose was abomassaly infused into steers and compared with steers receiving either ruminal or abomasal partially hydrolysed starch (Rodriguez et al., Reference Rodriguez, Guimaraes, Matthews, McLeod, Baldwin and Harmon2004). Sodium-dependent glucose uptake was not affected by treatment, but uptake decreased distally along the intestine. This work is supported by results from dairy cows (Lohrenz et al., Reference Lohrenz, Duske, Schönhusen, Losand, Seyfert, Metges and Hammon2011) fed high- (24%) and low-starch diets (12%). These workers reported no differences in expression of SGLT1 or GLUT2 mRNA or protein in brush border membrane vesicles prepared from mid-duodenum and mid-jejunum. Thus, it appears SGLT1 is functional in cattle, activities are highest in the proximal intestine, but activity does not appear to respond to higher intakes of starch-based diets.

The contribution of diffusion was assessed in cattle (Krehbiel et al., Reference Krehbiel, Britton, Harmon, Peters, Stock and Grotjan1996) by infusing glucose along with 2-deoxyglucose, a non-metabolizable, non-SGLT1 transportable analogue, into the proximal and mid-intestine of steers. They reported that glucose disappearance was much higher in the proximal small intestine and that passive diffusion was a minor contributor to portal glucose appearance. These results would suggest that SGLT1 is the major pathway for glucose transport from the intestinal lumen.

Dyer et al. (Reference Dyer, Vayro, King and Shirazi-Beechey2003) using glucose molecules bound to polyethylene glycol to make them non-absorbable showed that glucose stimulates increased SGLT1 protein by interacting luminally with a glucose sensor. An alternative mechanism for enhancing luminal sugar removal was proposed using mice (Gouyon et al., Reference Gouyon, Caillaud, Carriere, Klein, Dalet, Citadelle, Kellett, Thorens, Leturque and Brot-Laroche2003) where the presence of sugars stimulated the recruitment of basolateral GLUT2 into the brush border membrane and the presence of this facilitated transporter contributed to the upregulation of glucose removal. This mechanism, however, remains controversial (Daniel and Zietek, Reference Daniel and Zietek2015) or may be species dependent (Moran et al., Reference Moran, Al-Rammahi, Arora, Batchelor, Coulter, Ionescu, Bravo and Shirazi-Beechey2010). The latter work using piglets (Moran et al., Reference Moran, Al-Rammahi, Arora, Batchelor, Coulter, Ionescu, Bravo and Shirazi-Beechey2010) demonstrated that GLUT2 was expressed only in the basolateral membrane and that there was no uptake of substrate specific for SGLT1. Similarly, work using SGLT1 and GLUT2 knockout mice (Roder et al., Reference Roder, Geillinger, Zietek, Thorens, Koepsell and Daniel2014) reported that SGLT1 was the major intestinal apical glucose transporter. At this writing, there is no information on whether GLUT2 plays a role in apical glucose transport in ruminants.

Sheep v. cattle

Evidence would suggest that perhaps sheep are more able to adapt to increasing small intestinal starch. When starch is infused into the abomasum, pancreatic α-amylase secretion decreases as it does in cattle (Wang and Taniguchi, Reference Wang and Taniguchi1998); however, when casein is infused with the starch pancreatic α-amylase secretion is restored, unlike cattle (Swanson et al., Reference Swanson, Matthews, Woods and Harmon2002a). While the early work was confounded by dietary energy (Janes et al., Reference Janes, Weekes and Armstrong1985) there were increases in carbohydrases with increased intake and when dietary energy was balanced using moderate starch diets (Swanson et al., Reference Swanson, Matthews, Matthews, Howell, Richards and Harmon2000), pancreatic α-amylase protein and activity tended to increase despite the trend for reduced pancreatic α-amylase mRNA.

Adaptive responses in glucose transport to carbohydrate in the small intestine have been demonstrated in sheep (Shirazi-Beechey et al., Reference Shirazi-Beechey, Kemp, Dyer and Beechey1989; Shirazi-Beechey et al., Reference Shirazi-Beechey, Hirayama, Wang, Scott, Smith and Wright1991a and Reference Shirazi-Beechey, Smith, Wang and James1991b; Mabjeesh et al., Reference Mabjeesh, Guy and Sklan2003) but changes have been more difficult to demonstrate in cattle (Bauer et al., Reference Bauer, Harmon, Bohnert, Branco and Huntington2001a; Klinger et al., Reference Klinger, Zurich, Schröder and Breves2013). Collectively, these data suggest that sheep may be better able to adapt to high-starch diets, but at present, there is no definitive comparison of starch utilization in sheep and cattle.

Limitations to post-ruminal starch digestion

Many researchers have suggested that the ruminant small intestine has a limited capacity for starch digestion (Orskov, Reference Orskov1986; Owens et al., Reference Owens, Zinn and Kim1986; Swanson and Harmon, Reference Swanson, Harmon, Zabielski, Gregory and Westrom2002; Swanson, Reference Swanson, Smithers and Knoerzer2019). Owens et al. (Reference Owens, Zinn and Kim1986) summarized several studies and reported that only 55% of starch entering the small intestine disappears in the small intestine of cattle fed high-concentrate diets. A recent summary for dairy cows reported that small intestinal disappearance ranged from 11% to 90% with a mean of 60% (Moharrery et al., Reference Moharrery, Larsen and Weisbjerg2014). Similar conclusions have been drawn from studies with dairy cattle (Nocek and Tamminga, Reference Nocek and Tamminga1991) and studies with both beef and dairy cattle (Harmon et al., Reference Harmon, Yamka and Elam2004). Aside from inefficiencies of undigested starch exiting the small intestine, large quantities of starch flowing to the large intestine can result in excess fermentation which can result in diarrhoea and acidosis.

Specific factors limiting starch digestion, proposed by Owens et al. (Reference Owens, Zinn and Kim1986), include limited carbohydrase activity, insufficient time for complete starch hydrolysis, inadequate access of enzymes to starch granules and limited glucose absorption.

Pancreatic α-amylase has been suggested as a possibility by numerous authors; however, attempts to increase small intestinal α-amylase have not enhanced starch assimilation (Remillard et al., Reference Remillard, Johnson, Lewis and Nockels1990; Westreicher-Kristen et al., Reference Westreicher-Kristen, Robbers, Blank, Troescher, Dickhoefer, Wolffram and Susenbeth2018).

The downregulation of pancreatic α-amylase by starch has been overcome by casein infusion (Richards et al., Reference Richards, Swanson, Paton, Harmon and Huntington2003; Brake et al., Reference Brake, Titgemeyer and Anderson2014a) and this has been associated with increased small intestinal starch disappearance (Richards et al., Reference Richards, Branco, Bohnert, Huntington, Macari and Harmon2002) and similar responses have been shown with amino acids mimicking casein (Brake et al., Reference Brake, Titgemeyer and Anderson2014a; Blom et al., Reference Blom, Anderson and Brake2016). Whether these treatments achieve this increased intestinal disappearance through increased pancreatic α-amylase or some other means is unknown. It has been suggested that luminal pH in the proximal small intestine limits pancreatic α-amylase resulting in a shift in carbohydrate hydrolysis to the distal intestine where glucose transport is more limiting (Mills et al., Reference Mills, France, Ellis, Crompton, Bannink, Hanigan and Dijkstra2017); however, attempts to increase intestinal pH have not been shown to increase starch assimilation (Remillard et al., Reference Remillard, Johnson, Lewis and Nockels1990).

The apparently striking differences in mucosal carbohydrases in ruminants may pose another limitation. Knockout mice without maltase-glucoamylase had a 40% reduction in their ability to generate blood glucose from starch (Nichols et al., Reference Nichols, Quezada-Calvillo, Robayo-Torres, Ao, Hamaker, Butte, Marini, Jahoor and Sterchi2009). This essential role plus the recent demonstration of the role of mucosal enzymes in hydrolysing starch (Quezada-Calvillo et al., Reference Quezada-Calvillo, Robayo-Torres, Ao, Hamaker, Quaroni, Brayer, Sterchi, Baker and Nichols2007) suggests that the ruminants evolutionary limits to starch hydrolysis may be greater than previously thought.

While glucose transport has been shown to be inducible in the small intestine of ruminants (Moran et al., Reference Moran, Al-Rammahi, Zhang, Bravo, Calsamiglia and Shirazi-Beechey2014) benefits of this increase for increased small intestinal starch assimilation are lacking.

Combined data suggest that ruminants are limited users of small intestinal starch and that the low digestibilities in the small intestinal are likely the outcome of multiple factors that are only overcome by supplying small amounts of highly digestible substrate.

Limitations in post-ruminal protein assimilation

Compared with carbohydrates, research on the processes of protein assimilation has received little attention. Excellent reviews covering many of the processes are available (Beck, Reference Beck1973; Snook, Reference Snook1973; Hooton et al., Reference Hooton, Lentle, Monro, Wickham, Simpson, Nilius, Gudermann, Jahn, Lill, Petersen and DeTombe2015). However, scant information is available describing the processes in ruminants. The fact that ruminant digestion produces a relatively continual flow of microbial protein to the small intestine places a high priority on protein assimilation suggesting a highly efficient system is in place. Estimates used for small intestinal assimilation of protein are usually 80% (NASEM, 2016) based on N measurements; however, this is an apparent measure and values for true digestibility in the small intestine may be substantially higher. Estimates of small intestinal digestibility of feedstuffs made using the mobile nylon bag technique (Hvelplund et al., Reference Hvelplund, Weisbjerg and Andersen1992) suggest that a single value for small intestinal digestion is inadequate or more importantly, the digestibility of protein sources does vary in the small intestine. Previous research in ruminats showing that protein assimilation has not been exceeded when protein was infused at very high levels suggests that the small intestine has a high digestive and absorptive capacity for protein (Owens et al., Reference Owens, Zinn and Kim1986). Apparent small intestinal digestion of N compounds in ruminants has been reported to be between 65% and 75% of duodenal N flow (Santos et al., Reference Santos, Satter and Stern1984).

Pancreatic proteases

The major endopeptidases, trypsin, chymotrypsin and elastase are all present in the ruminant pancreas, and bovine sources have been well characterized (Walsh et al., Reference Walsh, Kauffman, Kumar and Neurath1964). The exopeptidases, carboxypeptidases A and B are also present, but there are limited data on their nutritional characterization.

The adaptation of protease activity in the small intestine of rats has been known for many years (Snook, Reference Snook1965 and Reference Snook1973). These adaptations to changes in diet involved increases in the synthesis and content of proteases in the pancreas and increased secretion of enzymes (Brannon, Reference Brannon1990). The complexity of ruminant digestion, that is, the pregastric fermentation necessitates that the majority of these studies infused proteins or amino acids into the abomasum or small intestine. Most of these studies reported steady amounts of trypsin or chymotrypsin activities in concert with the steady flows of microbial protein in the ruminant small intestine. However, adaptation did occur with changes in activity up to 1.5-fold common with the highest being 2.0- (Swanson et al., Reference Swanson, Benson, Matthews and Harmon2004) to 2.85-fold increases (Yu et al., Reference Yu, Xu, Wang, Liu, Yao, Wu, Qin and Sun2014b). Contrast this with changes up to 6-fold reported in rats (Brannon, Reference Brannon1990) and it appears ruminant pancreatic protease activity is less responsive to changes in diet. Some of the apparent differences in relative changes may occur because much lower activities occur in the fasting and protein deficient non-ruminant models making relative changes much greater. In the fed ruminant, fermentation produces a nearly continuous flow of microbial protein to the small intestine, and changes in diet produce much more subtle changes in protein flow and changes in pancreatic proteases may be more subtle as well. However, adaptation or stimulation of synthesis and secretion does occur.

Mucosal peptidases

A complete accounting of mucosal peptidases in ruminants is not available at the present time. A summary of current information is available (Hooton et al., Reference Hooton, Lentle, Monro, Wickham, Simpson, Nilius, Gudermann, Jahn, Lill, Petersen and DeTombe2015) and a partial summary of the most common brush border peptidases is in Table 2. The majority have been identified in bovine tissues (Uniprot, 2017) and characterized. Nomenclature for many peptidases has changed, and the identity of all present in any species remains elusive.

Table 2 Common peptidases in the mammalian small intestine brush border

Peptidases are ubiquitous and multifunctional in that the same peptidase may be anchored in the brush border membrane, present in the cytosol of the enterocytes and present in the intestinal lumen. Peptidases have broad specificities allowing them to act on a variety of substrates generated from the hydrolysis of proteins by pancreatic enzymes. In general, peptidases are complementary to pancreatic enzymes in that multiple peptidases target proline containing residues where pancreatic enzymes have little or no activity (Erickson and Kim, Reference Erickson and Kim1990), others may act on intact proteins producing small peptides and amino acids eliminating the need for pancreatic proteases (Guan et al., Reference Guan, Yoshioka, Erickson, Heizer and Kim1988). Brush border peptidases are highest in the proximal to the mid-gut region (Yoshioka et al., Reference Yoshioka, Erickson and Kim1988) in concert with their role in protein assimilation.

Peptide and amino acid transporters

The process of moving the products of digestion from the intestinal lumen across the brush border membrane is multi-faceted involving numerous amino acid and peptide transporters. A thorough description of these processes is beyond the scope of this paper. However, numerous excellent reviews are available describing both amino acid (Bröer, Reference Bröer2008) and peptide transporters (Daniel, Reference Daniel2004; Gilbert et al., Reference Gilbert, Wong and Webb2008; Daniel and Zietek, Reference Daniel and Zietek2015).

Multiple systems have been described for both amino acid (Matthews et al., Reference Matthews, Wong, Bender and Webb1996b; Knapp, Reference Knapp2004; Liao et al., Reference Liao, Vanzant, Harmon, McLeod, Boling and Matthews2009) and peptide (Matthews and Webb, Reference Matthews and Webb1995; Matthews et al., Reference Matthews, Wong, Bender, Bloomquist and Webb1996a) transport in ruminants similar to other species. To date, aspects of amino acid or peptide transport in ruminants have not been reported limiting to protein assimilation.

Mechanisms regulating the nutritional modulation of digestive function in the small intestine

The mechanisms regulating the nutritional modulation of digestive function in the small intestine are complex and coordinated via the substrate, neural and hormonal effects in the small intestine, pancreas, peripheral tissues and the pituitary–hypothalamic axis (Figure 2). The overall regulation is also closely linked with factors regulating feed intake, glucose and amino acid metabolism, and energy balance.

Figure 2 Proposed interrelationships of factors controlling digestion and absorption in ruminants. Blue lines represent nutrient flow, green lines represent hormonal and neural signalling, brown line represents secretion through the pancreatic duct, red lines represent digestive enzyme activity, dashed boxes indicate brush border. Enzymes = pancreatic and brush border carbohydrases and proteases; TR = taste receptor; transport = glucose or amino acid/peptide transporter.

The small intestine plays a vital role in the sensing, digestion and absorption of nutrients. Nutrients are an essential signal for the release of gut peptides (Bauer et al., Reference Bauer, Hamr and Duca2016) within the small intestine and absorbed nutrients can have intestinal, pancreatic or other peripheral effects in mediating dietary effects on pancreatic exocrine function (Call et al., Reference Call, Mitchell and Little1975; Blouet and Schwartz, Reference Blouet and Schwartz2010).

The importance of taste receptors on nutrient sensing in the digestive tract and other tissues in animals and humans is becoming more apparent (Moran et al., Reference Moran, Al-Rammahi, Zhang, Bravo, Calsamiglia and Shirazi-Beechey2014; Lushchak et al., Reference Lushchak, Strilbytska, Yurkevych, Vaiserman and Storey2019). Taste receptors for sweet and umami (T1R), bitter (T2R) and salty (ENaC) have been described in vertebrate animals (Bachmanov et al., Reference Bachmanov, Bosak, Lin, Matsumoto, Ohmoto, Reed and Nelson2014) with much of the research conducted using laboratory animals. Initially, the taste receptors were identified not only in the oral cavity but also in many metabolically active tissues in the body including the small intestine (Kochem, Reference Kochem2017). In the small intestine, the taste receptors are primarily concentrated in the enteroendocrine cells (Herzig et al., Reference Herzig, Louie and Owyang1994; Lee and Owyang, Reference Lee and Owyang2017). The gastrointestinal hormones that are secreted from the neuroendocrine cells containing taste receptors in response to stimulation of the taste receptors include secretin (S-cells), CCK (I-cells), ghrelin (X/A-like cells), GIP (K-cells), and peptide YY, glucagon peptide 1 and glucagon peptide 2 (GLP-2; L-cells) (Calvo and Egan, Reference Calvo and Egan2015). There is also a recent evidence suggesting that multiple gastrointestinal regulatory proteins can be co-localized within the enteroendocrine cells of the small intestine (Fothergill and Furness, Reference Fothergill and Furness2018). The primary functions of the gastrointestinal hormones are to regulate feed intake, feed digestion and whole animal metabolism (Gribble and Reimann, Reference Gribble and Reimann2017; Fothergill and Furness, Reference Fothergill and Furness2018).

Cholecystokinin and secretin have long thought to be key regulators of pancreatic exocrine function (Miyasaka and Funakoshi, Reference Miyasaka and Funakoshi1998; Chey and Chang, Reference Chey and Chang2014) with CCK thought to have primary effects on enzyme secretion and secretin on the buffer and fluid secretion. These effects may be mediated by stimulating neural effects in the small intestine that regulate pancreatic exocrine function or directly on the pancreas via CCK receptors (Bourassa et al., Reference Bourassa, Laine, Kruse, Gagnon, Calvo and Morisset1999). In pigs, this effect is likely mediated at the intestinal level via CCK receptors located in the duodenum which activate neural signals to increase pancreatic enzyme secretion (Evilevitch et al., Reference Evilevitch, Westrom and Pierzynowski2004). Less is known in ruminants. However, incubation of pancreatic tissue explants with caerulein, a CCK mimic, was shown to increase α-amylase release in bovine pancreas from steers previously abomasally infused with casein or when incubated with amino acids (Swanson et al., Reference Swanson, Matthews, Woods and Harmon2003). The role of other gut peptides on pancreatic function is less well defined, especially in ruminants.

The primary nutrients that activate taste receptors in the small intestine are likely amino acids (Bachmanov et al., Reference Bachmanov, Bosak, Glendinning, Inoue, Li, Manita, McCaughey, Murata, Reed, Tordoff and Beauchamp2016) and monosaccharides (Moran et al., Reference Moran, Al-Rammahi, Zhang, Bravo, Calsamiglia and Shirazi-Beechey2014). For example, recent research suggests that the positive effect of increased luminal glucose has on SGLT1 expression is mediated through neuroendocrine cells producing GLP-2 (Moran et al., Reference Moran, Al-Rammahi, Batchelor, Bravo and Shirazi-Beechey2018). Similarly, amino acids have been shown to elicit CCK secretion via taste receptor activation in mice (Daly et al., Reference Daly, Al-Rammahi, Moran, Marcello, Ninomiya and Shirazi-Beechey2013). The physiological effects of taste receptors in the gastrointestinal tract are less well understood in ruminants. However, it has been shown that ruminants do express taste receptors in the small intestine and the artificial sweetener, Sucram, increases SGLT1 mRNA abundance, Na+-dependent glucose uptake, maltase activity, and villus height and crypt depth in the small intestine in lambs and calves (Moran et al., Reference Moran, Al-Rammahi, Zhang, Bravo, Calsamiglia and Shirazi-Beechey2014). Although it seems that the small intestine in ruminants responds to increased glucose supply by increasing mass and carbohydrase activity, in past research from our laboratory, post-ruminal infusion of glucose decreased α-amylase secretion in steers (Swanson et al., Reference Swanson, Richards and Harmon2002b) suggesting a complex and perhaps uncoordinated regulation between intestinal and pancreatic responses related to the adaptation of post-ruminal starch digestive function.

Insulin also has long been implicated as an important regulator of pancreatic exocrine function (Brannon, Reference Brannon1990). Diabetic sheep have decreased α-amylase and lipase secretion (Pierzynowski and Barej, Reference Pierzynowski and Barej1984) suggesting a role for insulin in regulating exocrine pancreatic function in ruminants. Also, an insulin-dependent element has been identified in the α-amylase gene in mice (Keller et al., Reference Keller, Rosenberg, Johnson, Howard and Meisler1990) suggesting a direct role for insulin in regulating pancreatic exocrine function.

The hypothalamus is critical in sensing whole body signals (substrate, hormonal and neural) related to nutrient and energy balance and coordinating whole body responses to stimuli (Blouet and Schwartz, Reference Blouet and Schwartz2010) including factors related to feed intake, digestion and glucose homeostasis. There is also a strong evidence suggesting the importance of the brain–gut axis in regulating pancreatic secretion (Konturek et al., Reference Konturek, Pepera, Zabielski, Konturek, Pawlik, Szlachcic and Hahn2003; Jaworek et al., Reference Jaworek, Nawrot-Porabka, Leja-Szpak and Konturek2010). Interestingly, sweet/amino acid receptors also are located in the hypothalamus (Heeley and Blouet, Reference Heeley and Blouet2016; Kohno, Reference Kohno2017) which likely are important in sensing systemic glucose and amino acid concentrations and along with neural and hormonal signals are sensed by the hypothalamus which allows for coordinated central control of metabolism, including intestinal and pancreatic function. Other hormones thought to influence pancreatic exocrine and intestinal function either directly or through neural signals include melatonin, C-natriuretic peptide, endocannabinoids and leptin to name a few (Chandra and Liddle, Reference Chandra and Liddle2009). More research is needed in ruminants to help unravel the complexities by which small intestinal digestion is regulated with the aim of developing approaches to enhance and improve the efficiency of small intestinal digestion in ruminants.

Acknowledgements

The authors thank Luiz Brito and Pablo Fanseca for helping with data search.

D. L. Harmon 0000-0001-5187-1920

Declaration of interest

Both authors declare no conflict of interest and nor competing interest.

Ethics statement

None.

Software and data repository resources

None of the data were deposited in an official repository.

References

Amiri, M and Naim, HY 2017. Characterization of mucosal disaccharidases from human intestine. Nutrients 9, 1106.CrossRefGoogle ScholarPubMed
Amiri, M and Naim, HY 2018. Posttranslational processing and function of mucosal maltases. Journal of Pediatric Gastroenterology and Nutrition 66 (suppl. 3), S18S23.CrossRefGoogle ScholarPubMed
Bachmanov, AA, Bosak, NP, Glendinning, JI, Inoue, M, Li, X, Manita, S, McCaughey, SA, Murata, Y, Reed, DR, Tordoff, MG and Beauchamp, GK 2016. Genetics of amino acid taste and appetite. Advances in Nutrition 7, 806S822S.CrossRefGoogle ScholarPubMed
Bachmanov, AA, Bosak, NP, Lin, C, Matsumoto, I, Ohmoto, M, Reed, DR and Nelson, TM 2014. Genetics of taste receptors. Current Pharmaceutical Design 20, 26692683.CrossRefGoogle ScholarPubMed
Bauer, PV, Hamr, SC and Duca, FA 2016. Regulation of energy balance by a gut-brain axis and involvement of the gut microbiota. Cellular and Molecular Life Sciences 73, 737755.CrossRefGoogle ScholarPubMed
Bauer, ML, Harmon, DL, McLeod, KR and Huntington, GB 1995. Adaptation to small intestinal starch assimilation and glucose transport in ruminants. Journal of Animal Science 73, 18281838.CrossRefGoogle ScholarPubMed
Bauer, ML, Harmon, DL, Bohnert, DW, Branco, AF and Huntington, GB 2001a. Influence of alpha-linked glucose on sodium-glucose cotransport activity along the small intestine in cattle. Journal of Animal Science 79, 19171924.CrossRefGoogle ScholarPubMed
Bauer, ML, Harmon, DL, McLeod, KR and Huntington, GB 2001b. Influence of alpha-linked glucose on jejunal sodium-glucose co-transport activity in ruminants. Comparative Biochemistry and Physiology A 129, 577583.CrossRefGoogle ScholarPubMed
Beck, IT 1973. The role of pancreatic enzymes in digestion. The American Journal of Clinical Nutrition 26, 311325.CrossRefGoogle ScholarPubMed
Blom, EJ, Anderson, DE and Brake, DW 2016. Increases in duodenal glutamic acid supply linearly increase small intestinal starch digestion but not nitrogen balance in cattle. Journal of Animal Science 94, 53325340.CrossRefGoogle Scholar
Blouet, C and Schwartz, GJ 2010. Hypothalamic nutrient sensing in the control of energy homeostasis. Behavioural Brain Research 209, 112.CrossRefGoogle ScholarPubMed
Bourassa, J, Laine, J, Kruse, ML, Gagnon, MC, Calvo, E and Morisset, J 1999. Ontogeny and species differences in the pancreatic expression and localization of the CCK(A) receptors. Biochemical and Biophysical Research Communications 260, 820828.CrossRefGoogle ScholarPubMed
Brake, DW, Titgemeyer, EC and Anderson, DE 2014a. Duodenal supply of glutamate and casein both improve intestinal starch digestion in cattle but by apparently different mechanisms. Journal of Animal Science 92, 40574067.CrossRefGoogle ScholarPubMed
Brake, DW, Titgemeyer, EC, Bailey, EA and Anderson, DE 2014b. Small intestinal digestion of raw cornstarch in cattle consuming a soybean hull-based diet is improved by duodenal casein infusion. Journal of Animal Science 92, 40474056.CrossRefGoogle ScholarPubMed
Branco, AF, Harmon, DL, Bohnert, DW, Larson, BT and Bauer, ML 1999. Estimating true digestibility of nonstructural carbohydrates in the small intestine of steers. Journal of Animal Science 77, 18891895.CrossRefGoogle ScholarPubMed
Brannon, PM 1990. Adaptation of the exocrine pancreas to diet. Annual Review of Nutrition 10, 85105.CrossRefGoogle Scholar
Bröer, S 2008. Amino acid transport across mammalian intestinal and renal epithelia. Physiological Reviews 88, 249286.CrossRefGoogle ScholarPubMed
Call, JL, Mitchell, GE Jr. and Little, CO 1975. Response of ovine pancreatic amylase to elevated blood glucose. Journal of Animal Science 41, 17171721.CrossRefGoogle ScholarPubMed
Calvo, SS and Egan, JM 2015. The endocrinology of taste receptors. Nature Reviews: Endocrinology 11, 213227.Google ScholarPubMed
Cao, YC, Yang, XJ, Guo, L, Zheng, C, Wang, DD, Cai, CJ, Liu, SM and Yao, JH 2018. Effects of dietary leucine and phenylalanine on pancreas development, enzyme activity, and relative gene expression in milk-fed Holstein dairy calves. Journal of Dairy Science 101, 42354244.CrossRefGoogle ScholarPubMed
Chandra, R and Liddle, RA 2009. Neural and hormonal regulation of pancreatic secretion. Current Opinion in Gastroenterology 25, 441446.CrossRefGoogle ScholarPubMed
Chey, WY and Chang, TM 2014. Secretin: historical perspective and current status. Pancreas 43, 162182.CrossRefGoogle ScholarPubMed
Clary, JJ, Mitchell, GE Jr., Little, CO and Bradley, NW 1969. Pancreatic amylase activity from ruminants fed different rations. Canadian Journal of Physiology and Pharmacology 47, 161164.CrossRefGoogle ScholarPubMed
Coombe, NB and Siddons, RC 1973. Carbohydrases of the bovine small intestine. British Journal of Nutrition 30, 269276.CrossRefGoogle Scholar
Daly, K, Al-Rammahi, M, Moran, A, Marcello, M, Ninomiya, Y and Shirazi-Beechey, SP 2013. Sensing of amino acids by the gut-expressed taste receptor T1R1-T1R3 stimulates CCK secretion. American Journal of Physiology-Gastrointestinal and Liver Physiology 304, G271G282.CrossRefGoogle ScholarPubMed
Daniel, H 2004. Molecular and integrative physiology of intestinal peptide transport. Annual Review of Physiology 66, 361384.CrossRefGoogle ScholarPubMed
Daniel, H and Zietek, T 2015. Taste and move: glucose and peptide transporters in the gastrointestinal tract. Experimental Physiology 100, 14411450.CrossRefGoogle ScholarPubMed
Diaz-Sotomayor, M, Quezada-Calvillo, R, Avery, SE, Chacko, SK, Yan, LK, Lin, AH, Ao, ZH, Hamaker, BR and Nichols, BL 2013. Maltase-glucoamylase modulates gluconeogenesis and sucrase-isomaltase dominates starch digestion glucogenesis. Journal of Pediatric Gastroenterology and Nutrition 57, 704712.CrossRefGoogle ScholarPubMed
Dyer, J, Vayro, S, King, TP and Shirazi-Beechey, SP 2003. Glucose sensing in the intestinal epithelium. European Journal of Biochemistry 270, 33773388.CrossRefGoogle ScholarPubMed
Erickson, RH and Kim, YS 1990. Digestion and absorption of dietary protein. Annual Review of Medicine 41, 133139.CrossRefGoogle ScholarPubMed
Evilevitch, L, Westrom, BR and Pierzynowski, SG 2004. CCK-B receptor antagonist YF476 inhibits pancreatic enzyme secretion at a duodenal level in pigs. Scandinavian Journal of Gastroenterology 39, 886890.CrossRefGoogle Scholar
Fothergill, LJ and Furness, JB 2018. Diversity of enteroendocrine cells investigated at cellular and subcellular levels: the need for a new classification scheme. Histochemistry and Cell Biology 150, 693702.CrossRefGoogle ScholarPubMed
Galand, G 1989. Brush-border membrane sucrase-isomaltase, maltase-glucoamylase and trehalase in mammals – comparative development, effects of glucocorticoids, molecular mechanisms, and phylogenetic implications. Comparative Biochemistry and Physiology B-Biochemistry & Molecular Biology 94, 111.CrossRefGoogle ScholarPubMed
Gilbert, ER, Wong, EA and Webb, JKE 2008. Board-Invited Review: Peptide absorption and utilization: implications for animal nutrition and health. Journal of Animal Science 86, 21352155.CrossRefGoogle ScholarPubMed
Gilbert, MS, Pantophlet, AJ, Berends, H, Pluschke, AM, van den Borne, JJGC, Hendriks, WH, Schols, HA and Gerrits, WJJ 2015. Fermentation in the small intestine contributes substantially to intestinal starch disappearance in calves. Journal of Nutrition 145, 11471155.CrossRefGoogle ScholarPubMed
Goda, T and Honma, K 2018. Molecular regulations of mucosal maltase expressions. Journal of Pediatric Gastroenterology and Nutrition 66 (suppl.), S14S17.CrossRefGoogle ScholarPubMed
Gorka, P, Schurmann, BL, Walpole, ME, Blonska, A, Li, S, Plaizier, JC, Kowalski, ZM and Penner, GB 2017. Effect of increasing the proportion of dietary concentrate on gastrointestinal tract measurements and brush border enzyme activity in Holstein steers. Journal of Dairy Science 100, 45394551.CrossRefGoogle ScholarPubMed
Gouyon, F, Caillaud, L, Carriere, V, Klein, C, Dalet, V, Citadelle, D, Kellett, GL, Thorens, B, Leturque, A and Brot-Laroche, E 2003. Simple-sugar meals target GLUT2 at enterocyte apical membranes to improve sugar absorption: a study in GLUT2-null mice. Journal of Physiology 552, 823832.CrossRefGoogle ScholarPubMed
Gribble, FM and Reimann, F 2017. Signalling in the gut endocrine axis. Physiology & Behavior 176, 183188.CrossRefGoogle ScholarPubMed
Guan, D, Yoshioka, M, Erickson, RH, Heizer, W and Kim, YS 1988. Protein digestion in human and rat small intestine: role of new neutral endopeptidases. American Journal of Physiology-Gastrointestinal and Liver Physiology 255, G212G220.CrossRefGoogle ScholarPubMed
Guo, L, Liang, ZQ, Zheng, C, Liu, BL, Yin, QY, Cao, YC and Yao, JH 2018a. Leucine affects alpha-amylase synthesis through PI3K/Akt-mTOR signaling pathways in pancreatic acinar cells of dairy calves. Journal of Agricultural and Food Chemistry 66, 51495156.CrossRefGoogle ScholarPubMed
Guo, L, Tian, H, Shen, J, Zheng, C, Liu, S, Cao, Y, Cai, C and Yao, J 2018b. Phenylalanine regulates initiation of digestive enzyme mRNA translation in pancreatic acinar cells and tissue segments in dairy calves. Bioscience Reports 38, https://doi.org/10.1042/BSR20171189CrossRefGoogle ScholarPubMed
Harmon, DL, Yamka, RM and Elam, NA 2004. Factors affecting intestinal starch digestion in ruminants: a review. Canadian Journal of Animal Science 84, 309318.CrossRefGoogle Scholar
Heeley, N and Blouet, C 2016. Central amino acid sensing in the control of feeding behavior. Frontiers in Endocrinology 7, 148.CrossRefGoogle ScholarPubMed
Herzig, KH, Louie, DS and Owyang, C 1994. Somatostatin inhibits CCK release by inhibiting secretion and action of CCK-releasing peptide. American Journal of Physiology 266, G1156G1161.Google ScholarPubMed
Hooton, D, Lentle, R, Monro, J, Wickham, M and Simpson, R 2015. The secretion and action of brush border enzymes in the mammalian small intestine. In Reviews of physiology, biochemistry and pharmacology (ed. Nilius, B, Gudermann, T, Jahn, R, Lill, R, Petersen, OH and DeTombe, PP), pp. 59118. Springer International Publishing, Switzerland.CrossRefGoogle Scholar
Huber, JT, Jacobson, NL and Allen, RS 1961. Digestive enzyme activities in the young calf. Journal of Dairy Science 44, 14941501.CrossRefGoogle Scholar
Huntington, GB, Harmon, DL and Richards, CJ 2006. Sites, rates, and limits of starch digestion and glucose metabolism in growing cattle. Journal of Animal Science 84 (suppl.), E14E24.CrossRefGoogle ScholarPubMed
Hvelplund, T, Weisbjerg, MR and Andersen, LS 1992. Estimation of the true digestibility of rumen undegraded dietary protein in the small intestine of ruminants by the mobile bag technique. Acta Agriculturae Scandinavica, Section A – Animal Science 42, 3439.CrossRefGoogle Scholar
Janes, AN, Weekes, TEC and Armstrong, DG 1985. Carbohydrase activity in the pancreatic tissue and small intestine mucosa of sheep fed dried-grass or ground maize-based diets. The Journal of Agricultural Science 104, 435443.CrossRefGoogle Scholar
Jaworek, J, Nawrot-Porabka, K, Leja-Szpak, A and Konturek, SJ 2010. Brain-gut axis in the modulation of pancreatic enzyme secretion. Journal of Physiology and Pharmacology 61, 523531.Google ScholarPubMed
Kaunitz, JD and Wright, EM 1984. Kinetics of sodium D-glucose cotransport in bovine intestinal brush border vesicles. Journal of Membrane Biology 79, 4151.CrossRefGoogle ScholarPubMed
Keller, SA, Rosenberg, MP, Johnson, TM, Howard, G and Meisler, MH 1990. Regulation of amylase gene expression in diabetic mice is mediated by a cis-acting upstream element close to the pancreas-specific enhancer. Genes & Development 4, 13161321.CrossRefGoogle ScholarPubMed
Kishi, K, Takase, S and Goda, T 1999. Enhancement of sucrase-isomaltase gene expression induced by luminally administered fructose in rat jejunum. Journal of Nutritional Biochemistry 10, 812.CrossRefGoogle ScholarPubMed
Klinger, S, Zurich, M, Schröder, B and Breves, G 2013. Effects of dietary starch source on electrophysiological intestinal epithelial properties and intestinal glucose uptake in growing goats. Archives of Animal Nutrition 67, 289300.CrossRefGoogle ScholarPubMed
Knapp, J 2004. Basolateral transport of neutral amino acids in enterocytes is mediated via Systems A, ASC, L, asc, and y(+L). Journal of Dairy Science 87, 220220.Google Scholar
Kochem, M 2017. Type 1 taste receptors in taste and metabolism. Annals of Nutrition and Metabolism 70 (suppl. 3), 2736.CrossRefGoogle ScholarPubMed
Kohno, D 2017. Sweet taste receptor in the hypothalamus: a potential new player in glucose sensing in the hypothalamus. Journal of Physiological Sciences 67, 459465.CrossRefGoogle ScholarPubMed
Konturek, SJ, Pepera, J, Zabielski, K, Konturek, PC, Pawlik, T, Szlachcic, A and Hahn, EG 2003. Brain-gut axis in pancreatic secretion and appetite control. Journal of Physiology and Pharmacology 54, 293317.Google ScholarPubMed
Krehbiel, CR, Britton, RA, Harmon, DL, Peters, JP, Stock, RA and Grotjan, HE 1996. Effects of varying levels of duodenal or midjejunal glucose and 2-deoxyglucose infusion on small intestinal disappearance and net portal glucose flux in steers. Journal of Animal Science 74, 693700.CrossRefGoogle ScholarPubMed
Kreikemeier, KK, Harmon, DL, Peters, JP, Gross, KL, Armendariz, CK and Krehbiel, CR 1990. Influence of dietary forage and feed intake on carbohydrase activities and small intestinal morphology of calves. Journal of Animal Science 68, 29162929.CrossRefGoogle ScholarPubMed
Lee, AA and Owyang, C 2017. Sugars, sweet taste receptors, and brain responses. Nutrients 9, 653665.CrossRefGoogle ScholarPubMed
Lee, BH, Rose, DR, Lin, AH, Quezada-Calvillo, R, Nichols, BL and Hamaker, BR 2016. Contribution of the individual small intestinal alpha-glucosidases to digestion of unusual alpha-linked glycemic disaccharides. Journal of Agricultural and Food Chemistry 64, 64876494.CrossRefGoogle ScholarPubMed
Lee, SB, Choi, CW, Jin, YC, Wang, T, Lee, KH, Ku, MB, Hwang, JH, Kim, KH, Vega, RSA and Lee, HG 2013. Effect of oral administration of intact casein on gastrointestinal hormone secretion and pancreatic alpha-amylase activity in Korean native steer. Asian-Australasian Journal of Animal Sciences 26, 654660.CrossRefGoogle ScholarPubMed
Lentze, MJ 2018. The history of maltose-active disaccharidases. Journal of Pediatric Gastroenterology and Nutrition 66 (suppl.), S4S6.CrossRefGoogle ScholarPubMed
Lescale-Matys, L, Dyer, J, Scott, D, Freeman, TC, Wright, EM and Shirazi-Beechey, SP 1993. Regulation of the ovine intestinal Na+/glucose co-transporter (SGLT1) is dissociated from mRNA abundance. Biochemical Journal 291 (pt 2), 435440.CrossRefGoogle ScholarPubMed
Liao, SF, Vanzant, ES, Harmon, DL, McLeod, KR, Boling, JA and Matthews, JC 2009. Ruminal and abomasal starch hydrolysate infusions selectively decrease the expression of cationic amino acid transporter mRNA by small intestinal epithelia of forage-fed beef steers. Journal of Dairy Science 92, 11241135.CrossRefGoogle ScholarPubMed
Lin, AH-M, Hamaker, BR and Nichols, BLJ 2012a. Direct starch digestion by sucrase-isomaltase and maltase-glucoamylase. Journal of Pediatric Gastroenterology and Nutrition 55, S43S45.CrossRefGoogle ScholarPubMed
Lin, AH-M, Nichols, BL, Quezada-Calvillo, R, Avery, SE, Sim, L, Rose, DR, Naim, HY and Hamaker, BR 2012b. Unexpected high digestion rate of cooked starch by the Ct-maltase-glucoamylase small intestine mucosal alpha-glucosidase subunit. PLoS ONE 7, e35473.CrossRefGoogle ScholarPubMed
Liu, K, Liu, Y, Liu, SM, Xu, M, Yu, ZP, Wang, X, Cao, YC and Yao, JH 2015. Relationships between leucine and the pancreatic exocrine function for improving starch digestibility in ruminants. Journal of Dairy Science 98, 25762582.CrossRefGoogle ScholarPubMed
Lohrenz, AK, Duske, K, Schönhusen, U, Losand, B, Seyfert, HM, Metges, CC and Hammon, HM 2011. Glucose transporters and enzymes related to glucose synthesis in small intestinal mucosa of mid-lactation dairy cows fed 2 levels of starch. Journal of Dairy Science 94, 45464555.CrossRefGoogle ScholarPubMed
Lushchak, O, Strilbytska, OM, Yurkevych, I, Vaiserman, AM and Storey, KB 2019. Implications of amino acid sensing and dietary protein to the aging process. Experimental Gerontology 115, 6978.CrossRefGoogle ScholarPubMed
Mabjeesh, SJ, Guy, D and Sklan, D 2003. Na+/glucose co-transporter abundance and activity in the small intestine of lambs: enhancement by abomasal infusion of casein. British Journal of Nutrition 89, 573580.CrossRefGoogle ScholarPubMed
Matthews, JC and Webb, KE Jr. 1995. Absorption of L-carnosine, L-methionine, and L-methionylglycine by isolated sheep ruminal and omasal epithelial tissue. Journal of Animal Science 73, 34643475.CrossRefGoogle ScholarPubMed
Matthews, JC, Wong, EA, Bender, PK, Bloomquist, JR and Webb, KE Jr. 1996a. Demonstration and characterization of dipeptide transport system activity in sheep omasal epithelium by expression of mRNA in Xenopus laevis oocytes. Journal of Animal Science 74, 17201727.CrossRefGoogle ScholarPubMed
Matthews, JC, Wong, EA, Bender, PK and Webb, KE Jr. 1996b. Demonstration and characterization of a transport system capable of lysine and leucine absorption that is encoded for in porcine jejunal epithelium by expression of mRNA in Xenopus laevis oocytes. Journal of Animal Science 74, 127137.CrossRefGoogle ScholarPubMed
Merchen, NR 1988. Digestion, absorption and excretion in ruminants. In The ruminant animal – digestive physiology and nutrition (ed. Church, DC), p. 172, Prentice-Hall, Englewood Cliffs, NJ.Google Scholar
Mills, JAN, France, J, Ellis, JL, Crompton, LA, Bannink, A, Hanigan, MD and Dijkstra, J 2017. A mechanistic model of small intestinal starch digestion and glucose uptake in the cow. Journal of Dairy Science 100, 46504670.CrossRefGoogle ScholarPubMed
Miyasaka, K and Funakoshi, A 1998. Luminal feedback regulation, monitor peptide, CCK-releasing peptide, and CCK receptors. Pancreas 16, 277283.CrossRefGoogle ScholarPubMed
Moharrery, A, Larsen, M and Weisbjerg, MR 2014. Starch digestion in the rumen, small intestine, and hind gut of dairy cows – a meta-analysis. Animal Feed Science and Technology 192, 114.CrossRefGoogle Scholar
Moran, AW, Al-Rammahi, MA, Arora, DK, Batchelor, DJ, Coulter, EA, Ionescu, C, Bravo, D and Shirazi-Beechey, SP 2010. Expression of Na+/glucose co-transporter 1 (SGLT1) in the intestine of piglets weaned to different concentrations of dietary carbohydrate. British Journal of Nutrition 104, 647655.CrossRefGoogle ScholarPubMed
Moran, AW, Al-Rammahi, MA, Batchelor, DJ, Bravo, DM and Shirazi-Beechey, SP 2018. Glucagon-like peptide-2 and the enteric nervous system are components of cell-cell communication pathway regulating intestinal na(+)/glucose co-transport. Frontiers in Nutrition 5, 101.CrossRefGoogle ScholarPubMed
Moran, AW, Al-Rammahi, M, Zhang, C, Bravo, D, Calsamiglia, S and Shirazi-Beechey, SP 2014. Sweet taste receptor expression in ruminant intestine and its activation by artificial sweeteners to regulate glucose absorption. Journal of Dairy Science 97, 49554972.CrossRefGoogle ScholarPubMed
Naim, HY, Sterchi, EE and Lentze, MJ 1988. Structure, biosynthesis, and glycosylation of human small intestinal maltase-glucoamylase. Journal of Biological Chemistry 263, 1970919717.Google ScholarPubMed
NASEM 2016. Nutrient requirements of beef cattle. National Academy Press, Washington, DC.Google Scholar
Nichols, BL, Baker, SS and Quezada-Calvillo, R 2018. Metabolic impacts of maltase deficiencies. Journal of Pediatric Gastroenterology and Nutrition 66 (suppl. 3), S24S29.CrossRefGoogle ScholarPubMed
Nichols, BL, Eldering, J, Avery, S, Hahn, D, Quaroni, A and Sterchi, E 1998. Human small intestinal maltase-glucoamylase cDNA cloning: homology to sucrase-isomaltase. Journal of Biological Chemistry 273, 30763081.CrossRefGoogle ScholarPubMed
Nichols, BL, Quezada-Calvillo, R, Robayo-Torres, CC, Ao, Z, Hamaker, BR, Butte, NF, Marini, J, Jahoor, F and Sterchi, EE 2009. Mucosal maltase-glucoamylase plays a crucial role in starch digestion and prandial glucose homeostasis of mice. Journal of Nutrition 139, 684690.CrossRefGoogle Scholar
Nocek, JE and Tamminga, S 1991. Site of digestion of starch in the gastrointestinal tract of dairy cows and its effect on milk yield and composition. Journal of Dairy Science 74, 35983629.CrossRefGoogle ScholarPubMed
Orskov, ER 1986. Starch digestion and utilization in ruminants. Journal of Animal Science 63, 16241633.CrossRefGoogle ScholarPubMed
Owens, FN, Zinn, RA and Kim, YK 1986. Limits to starch digestion in the ruminant small intestine. Journal of Animal Science 63, 16341648.CrossRefGoogle ScholarPubMed
Pierzynowski, S and Barej, W 1984. The dependence of exocrine pancreatic secretion on insulin in sheep. Quarterly Journal of Experimental Physiology 69, 3539.CrossRefGoogle Scholar
Quezada-Calvillo, R, Robayo-Torres, CC, Ao, Z, Hamaker, BR, Quaroni, A, Brayer, GD, Sterchi, EE, Baker, SS and Nichols, BL 2007. Luminal substrate “brake” on mucosal maltase-glucoamylase activity regulates total rate of starch digestion to glucose. Journal of Pediatric Gastroenterology and Nutrition 45, 3243.CrossRefGoogle ScholarPubMed
Quezada-Calvillo, R, Sim, L, Ao, Z, Hamaker, BR, Quaroni, A, Brayer, GD, Sterchi, EE, Robayo-Torres, CC, Rose, DR and Nichols, BL 2008. Luminal starch substrate “brake” on maltase-glucoamylase activity is located within the glucoamylase subunit. Journal of Nutrition 138, 685692.CrossRefGoogle ScholarPubMed
Remillard, RL, Johnson, DE, Lewis, LD and Nockels, CF 1990. Starch digestion and digesta kinetics in the small intestine of steers fed on a maize grain and maize silage mixture. Animal Feed Science and Technology 30, 7989.CrossRefGoogle Scholar
Richards, CJ, Branco, AF, Bohnert, DW, Huntington, GB, Macari, M and Harmon, DL 2002. Intestinal starch disappearance increased in steers abomasally infused with starch and protein. Journal of Animal Science 80, 33613368.CrossRefGoogle Scholar
Richards, CJ, Swanson, KC, Paton, SJ, Harmon, DL and Huntington, GB 2003. Pancreatic exocrine secretion in steers infused postruminally with casein and cornstarch. Journal of Animal Science 81, 10511056.CrossRefGoogle ScholarPubMed
Roder, PV, Geillinger, KE, Zietek, TS, Thorens, B, Koepsell, H and Daniel, H 2014. The role of SGLT1 and GLUT2 in intestinal glucose transport and sensing. PLoS ONE 9, e89977.CrossRefGoogle Scholar
Rodriguez, SM, Guimaraes, KC, Matthews, JC, McLeod, KR, Baldwin, RL and Harmon, DL 2004. Influence of abomasal carbohydrates on small intestinal sodium-dependent glucose cotransporter activity and abundance in steers. Journal of Animal Science 82, 30153023.CrossRefGoogle ScholarPubMed
Russell, JR, Young, AW and Jorgensen, NA 1981. Effect dietary corn starch intake on pancreatic amylase and intestinal maltase and pH in cattle. Journal of Animal Science 52, 11771182.CrossRefGoogle ScholarPubMed
Santos, KA, Satter, LD and Stern, MD 1984. Protein degradation in the rumen and amino acid absorption in the small intestine of lactating dairy cattle fed various protein sources. Journal of Animal Science 58, 244255.CrossRefGoogle ScholarPubMed
Schambye, P 1951. Volatile acids and glucose in portal blood of sheep. 2. Sheep fed hay and hay plus crushed oats. Nordisk Veterinaermedicin 3, 748762.Google Scholar
Scharrer, E 1976. Developmental changes of sugar transport in the ovine small intestine. Pflugers Archiv: European Journal of Physiology 366, 147151.CrossRefGoogle ScholarPubMed
Scharrer, E, Peter, W and Raab, W 1979. Reciprocal relationship between rumen development and intestinal sugar transport capacity in sheep. Zentralblatt fur Veterinarmedizin. Reihe A 26, 513520.CrossRefGoogle Scholar
Shirazi-Beechey, SP, Dyer, J, Allison, G and Wood, IS 1996. Nutrient regulation of intestinal sugar-transporter expression. Biochemical Society Transactions 24, 389392.CrossRefGoogle ScholarPubMed
Shirazi-Beechey, SP, Hirayama, BA, Wang, Y, Scott, D, Smith, MW and Wright, EM 1991a. Ontogenic development of lamb intestinal sodium-glucose co-transporter is regulated by diet. Journal of Physiology 437, 699708.CrossRefGoogle Scholar
Shirazi-Beechey, SP, Kemp, RB, Dyer, J and Beechey, RB 1989. Changes in the functions of the intestinal brush border membrane during the development of the ruminant habit in lambs. Comparative Biochemistry and Physiology 94B, 801806.Google Scholar
Shirazi-Beechey, SP, Smith, MW, Wang, Y and James, PS 1991b. Postnatal development of lamb intestinal digestive enzymes is not regulated by diet. Journal of Physiology 437, 691698.CrossRefGoogle ScholarPubMed
Siddons, RC 1968. Carbohydrase activities in the bovine digestive tract. Biochemical Journal 108, 839844.CrossRefGoogle ScholarPubMed
Snook, JT 1965. Dietary regulation of pancreatic enzymes synthesis, secretion and inactivation in the rat. Journal of Nutrition 87, 297305.CrossRefGoogle ScholarPubMed
Snook, JT 1973. Protein digestion. Nutritional and metabolic considerations. World Review of Nutrition and Dietetics 18, 121176.CrossRefGoogle ScholarPubMed
Swanson, KC 2019. Small intestinal anatomy, physiology, and digestion in ruminants. In Reference module in food science (ed. Smithers, G and Knoerzer, K), pp. 17, Elsevier, Amsterdam, NL.Google Scholar
Swanson, KC, Benson, JA, Matthews, JC and Harmon, DL 2004. Pancreatic exocrine secretion and plasma concentration of some gastrointestinal hormones in response to abomasal infusion of starch hydrolyzate and/or casein. Journal of Animal Science 82, 17811787.CrossRefGoogle ScholarPubMed
Swanson, KC and Harmon, DL 2002. Dietary influences on pancreatic alpha-amylase expression and secretion in ruminants. In Biology of the intestine in growing animals (ed. Zabielski, R, Gregory, PC and Westrom, B), pp. 515537. Elsevier Science, Amsterdam, The Netherlands.CrossRefGoogle Scholar
Swanson, KC, Matthews, JC, Matthews, AD, Howell, JA, Richards, CJ and Harmon, DL 2000. Dietary carbohydrate source and energy intake influence the expression of pancreatic alpha-amylase in lambs. Journal of Nutrition 130, 21572165.CrossRefGoogle ScholarPubMed
Swanson, KC, Matthews, JC, Woods, CA and Harmon, DL 2002a. Postruminal administration of partially hydrolyzed starch and casein influences pancreatic alpha-amylase expression in calves. Journal of Nutrition 132, 376381.CrossRefGoogle ScholarPubMed
Swanson, KC, Matthews, JC, Woods, CA and Harmon, DL 2003. Influence of substrate and/or neurohormonal mimic on in vitro pancreatic enzyme release from calves postruminally infused with partially hydrolyzed starch and/or casein. Journal of Animal Science 81, 13231331.CrossRefGoogle ScholarPubMed
Swanson, KC, Richards, CJ and Harmon, DL 2002b. Influence of abomasal infusion of glucose or partially hydrolyzed starch on pancreatic exocrine secretion in beef steers. Journal of Animal Science 80, 11121116.CrossRefGoogle ScholarPubMed
Taniguchi, K, Huntington, GB and Glenn, BP 1995. Net nutrient flux by visceral tissues of beef steers given abomasal and ruminal infusions of casein and starch. Journal of Animal Science 73, 236249.CrossRefGoogle ScholarPubMed
Theurer, CB 1986. Grain processing effects on starch utilization by ruminants. Journal of Animal Science 63, 16491662.CrossRefGoogle ScholarPubMed
Uniprot 2017. UniProt: the universal protein knowledgebase. Nucleic Acids Research 45, D158D169.CrossRefGoogle Scholar
Walker, JA and Harmon, DL 1995. Influence of ruminal or abomasal starch hydrolysate infusion on pancreatic exocrine secretion and blood glucose and insulin concentrations in steers. Journal of Animal Science 73, 37663774.CrossRefGoogle ScholarPubMed
Walsh, KA, Kauffman, DL, Kumar, KSVS and Neurath, H 1964. On the structure and function of bovine trypsinogen and trypsin. Proceedings of the National Academy of Sciences 51, 301.CrossRefGoogle ScholarPubMed
Wang, X and Taniguchi, K 1998. Activity of pancreatic digestive enzymes in sheep given abomasal infusion of starch and casein. Animal Science and Technology (Japan) 69, 870874.Google Scholar
Westreicher-Kristen, E, Robbers, K, Blank, R, Troescher, A, Dickhoefer, U, Wolffram, S and Susenbeth, A 2018. Postruminal digestion of starch infused into the abomasum of heifers with or without exogenous amylase administration. Journal of Animal Science 96, 19391951.CrossRefGoogle ScholarPubMed
White, RG, Williams, VJ and Morris, RJH 1971. Acute in vivo studies on glucose absorption from the small intestine of lambs, sheep and rats. British Journal of Nutrition 25, 5776.CrossRefGoogle ScholarPubMed
Yoshioka, M, Erickson, RH and Kim, YS 1988. Digestion and assimilation of proline-containing peptides by rat intestinal brush border membrane carboxypeptidases. Role of the combined action of angiotensin-converting enzyme and carboxypeptidase P. Journal of Clinical Investigation 81, 10901095.CrossRefGoogle ScholarPubMed
Yu, ZP, Xu, M, Liu, K, Yao, JH, Yu, HX and Wang, F 2014a. Leucine markedly regulates pancreatic exocrine secretion in goats. Journal of Animal Physiology and Animal Nutrition 98, 169177.CrossRefGoogle ScholarPubMed
Yu, ZP, Xu, M, Wang, F, Liu, K, Yao, JH, Wu, Z, Qin, DK and Sun, FF 2014b. Effect of duodenal infusion of leucine and phenylalanine on intestinal enzyme activities and starch digestibility in goats. Livestock Science 162, 134140.CrossRefGoogle Scholar
Yu, ZP, Xu, M, Yao, JH, Liu, K, Li, F, Liu, Y, Wang, F, Sun, FF and Liu, NN 2013. Regulation of pancreatic exocrine secretion in goats: differential effects of short- and long-term duodenal phenylalanine treatment. Journal of Animal Physiology and Animal Nutrition 97, 431438.CrossRefGoogle Scholar
Zhao, FQ, Okine, EK, Cheeseman, CI, Shirazi-Beechey, SP and Kennelly, JJ 1998. Glucose transporter gene expression in lactating bovine gastrointestinal tract. Journal of Animal Science 76, 29212929.CrossRefGoogle ScholarPubMed
Figure 0

Figure 1 Maltase-glucoamylase and sucrose-isomaltase protein structures. Percentages represent sequence identity. Size differences represent greater relative protein abundances for sucrose-isomaltase. Adapted with permission from Lee et al. (2016) Copyright ©2016 American Chemical Society.

Figure 1

Table 1 Hydrolysis of different substrates by c-terminal (ct) and n-terminal (nt) mouse recombinant α-glucosidases

Figure 2

Table 2 Common peptidases in the mammalian small intestine brush border

Figure 3

Figure 2 Proposed interrelationships of factors controlling digestion and absorption in ruminants. Blue lines represent nutrient flow, green lines represent hormonal and neural signalling, brown line represents secretion through the pancreatic duct, red lines represent digestive enzyme activity, dashed boxes indicate brush border. Enzymes = pancreatic and brush border carbohydrases and proteases; TR = taste receptor; transport = glucose or amino acid/peptide transporter.