Hostname: page-component-586b7cd67f-r5fsc Total loading time: 0 Render date: 2024-11-24T08:29:25.215Z Has data issue: false hasContentIssue false

Thyroid hormones in small ruminants: effects of endogenous, environmental and nutritional factors

Published online by Cambridge University Press:  01 August 2007

L. Todini*
Affiliation:
Dipartimento di Scienze Ambientali – Sezione di Produzioni Animali, Università di Camerino, Via della Circonvallazione 93/95, 62024 Matelica (MC), Italy

Abstract

Appropriate thyroid gland function and thyroid hormone activity are considered crucial to sustain the productive performance in domestic animals (growth, milk or hair fibre production). Changes of blood thyroid hormone concentrations are an indirect measure of the changes in thyroid gland activity and circulating thyroid hormones can be considered as indicators of the metabolic and nutritional status of the animals. Thyroid hormones play a pivotal role in the mechanisms permitting the animals to live and breed in the surrounding environment. Variations in hormone bioactivity allow the animals to adapt their metabolic balance to different environmental conditions, changes in nutrient requirements and availability, and to homeorhetic changes during different physiological stages. This is particularly important in the free-ranging and grazing animals, such as traditionally reared small ruminants, whose main physiological functions (feed intake, reproduction, hair growth) are markedly seasonal. Many investigations dealt with the involvement of thyroid hormones in the expression of endogenous seasonal rhythms, such as reproduction and hair growth cycles in fibre-producing (wool, mohair, cashmere) sheep and goats. Important knowledge about the pattern of thyroid hormone metabolism and their role in ontogenetic development has been obtained from studies in the ovine foetus and in the newborn. Many endogenous (breed, age, gender, physiological state) and environmental factors (climate, season, with a primary role of nutrition) are able to affect thyroid activity and hormone concentrations in blood, acting at the level of hypothalamus, pituitary and/or thyroid gland, as well as on peripheral monodeiodination. Knowledge on such topics mirror physiological changes and possibly allows the monitoring and manipulation of thyroid physiology, in order to improve animal health, welfare and production.

Type
Full Paper
Copyright
Copyright © The Animal Consortium 2007

Introduction

Appropriate thyroid gland function and activity of thyroid hormones (TH) are considered crucial to sustain the productive performance in domestic animals (growth, milk, hair fibre production) and circulating TH can be considered as indicators of the metabolic and nutritional status of the animals (Riis and Madsen, Reference Riis and Madsen1985; Todini et al., Reference Todini, Malfatti, Valbonesi, Trabalza-Marinucci and Debenedetti2007). Changes of blood TH concentrations are an indirect measure of the changes in thyroid gland activity. Many papers report marked seasonal variation in thyroid activity and in blood TH concentration. These hormone variations are particularly important in the free-ranging and grazing animals, whose main physiological functions (feed intake, reproduction, hair growth) are markedly seasonal. This is the case of small ruminants traditionally reared. Such variations in hormone concentration, in fact, allow the animals to adapt their metabolic balance to different environmental conditions, variations in nutrient requirements and availability, and to homeoretic changes during different physiological stages.

The present paper aims to review and summarise literature data about actions specifically described in domestic small ruminants and the effects that several factors may exert on thyroid activity and circulating TH. Endogenous factors (breed, age, gender, physiological state), environmental factors (climate, season) and nutrition are considered. Many other particular conditions are well known to alter thyroid functions in small ruminants, but they are not discussed in the present paper as they are not physiological: illness, iodine excess or deficiency, ingestion of goitrogenic substances, phytoestrogens and other endocrine-disrupting compounds, exogenous hormones or drugs intake. The values of blood hormone concentrations are characterised by an extreme variability, which is of course very meaningful in each particular study. On the other hand, values reported in different papers are not comparable due to the very large differences of the experimental animals and conditions, as well as assay methods. For this reason, the author’s choice was not to report the absolute numerics of hormone values in the text.

Overview of thyroid hormone physiology

TH, tetra-iodothyronine or thyroxine (T4) and 3-5-3′-tri-iodothyronine (T3), are iodinated derivatives from the amino acid tyrosine. T4 can be deiodinated to the biologically active hormone T3 by a 5′-deiodinase enzyme (outer-ring deiodination), and to the inactive reverse T3 (rT3) by the enzyme 5-deiodinase (inner-ring deiodination) (Utiger, Reference Utiger1995). Thyroid gland of adult sheep contains about 90.4%, 8.8% and 0.7% of T4, T3 and rT3, respectively, and T4 is the main secretory product (about 77%) (Chopra et al., Reference Chopra, Sack and Fisher1975). In adult sheep more than 99.9% of T4 and 99.5% of T3 circulate in blood bound to plasma proteins (Chopra et al., Reference Chopra, Sack and Fisher1975). Only the free hormone is responsible for the biological activity and protein-bound hormones function as a promptly utilisable storage, delaying the effects of decreased thyroid secretion, as well as buffer against sudden increases in thyroid’s secretory activity (Bartalena, Reference Bartalena1990; Utiger, Reference Utiger1995).

Small amounts of the active hormone T3 come from the thyroid, but in adult sheep at least 50% of serum T3 and 97% of serum rT3 derive from monodeiodination of T4 in peripheral tissues (Fisher et al., Reference Fisher, Chopra and Dussault1972; Chopra et al., Reference Chopra, Sack and Fisher1975). Deiodination can occur in most if not all tissues, but the liver and the kidney show the highest deiodinating activity. Iodothyronine deiodinase enzymes are selenoproteins and show structural differences and different tissue distribution between various species (Santini et al., Reference Santini, Chopra, Hurd and Teco1992; Nicol et al., Reference Nicol, Lefranc, Arthur and Trayhurn1994; Chadio et al., Reference Chadio, Kotsampasi, Menegatos, Zervas and Kalogiannis2006). Type I is predominantly expressed in the liver and kidney; it is inhibited by propylthiouracil (PTU) and stimulated by T3. The type II enzyme is predominant in the brain, pituitary, skin, skeletal muscle, brown adipose tissue; it is not sensitive to PTU, but it is inhibited by rT3 and T4 (Kohrle, Reference Kohrle1999). Type III monodeiodinase is a 5-deiodinase, which catalyses the transformation of T3 to 3-3′-diiodothyronine (T2) and of T4 to rT3. The latter does not bind to the nuclear receptor and is considered biologically inactive, but it is a powerful inhibitor of type II deiodinase (Kaiser et al., Reference Kaiser, Goumaz and Burger1986) and decreases oxygen consumption and ATP/ADP ratio (Okamoto and Leibfritz, Reference Okamoto and Leibfritz1997). Type III is widely distributed throughout the body, playing an important role in regulating TH homeostasis and bioavailability (Bianco et al., Reference Bianco, Salvatore, Gereben, Berry and Larsen2002; Bianco and Kim, Reference Bianco and Kim2006). It is particularly expressed in the placenta, in the pregnant uterus and in foetal tissues, limiting TH bioactivity and playing a critical role in the development and maturation of the thyroid axis of the foetus and newborn animal (Galton, Reference Galton2005; Hernandez et al., Reference Hernandez, Martinez, Fiering, Galton and St Germain2006). The functions and regulation of the different deiodinase activities are also a mean for allowing the organism to adapt to changing states such as iodine deficiency or chronic illness (Wartofsky and Burman, Reference Wartofsky and Burman1982; Chopra et al., Reference Chopra, Huang, Beredo, Solomon, Chua, Teco and Mead1985). Earlier, diiodothyronines also were considered inactive metabolites, but recently their thermogenic actions have been highlighted (Moreno et al., Reference Moreno, Lombardi, Beneduce, Silvestri, Pinna, Goglia and Lanni2002).

TH are mostly inactivated by glucuronidation in the liver and secretion into bile, or by sulphation and deiodination in the liver or kidney (Chopra et al., Reference Chopra, Solomon, Chopra, Wu, Fisher and Nakamura1978). Oxidative deamination and decarboxylation occurring in the kidney, liver and muscle, form acid metabolites, which maintain a certain biological activity, but do not contribute to the hormone action in euthyroid subjects because they are produced in very small amounts (Greenspan, Reference Greenspan2001). Decarboxylated derivatives of iodothyronines, such as monoiodothyronamine and thyronamine, actually represent a very interesting field of investigation, because they may have some biological actions, even different from those of TH (Wu et al., Reference Wu, Green, Huang, Hays and Chopra2005).

Thyroid cell growth and all the steps in the synthesis and secretion of TH are stimulated by the pituitary glycoprotein thyrotropin (TSH). TSH synthesis and release are in turn stimulated by the hypothalamic tripeptide TSH-releasing hormone (TRH). The hypothalamus controls the pituitary thyrotrophs also by inhibiting factors (somatostatin, dopamine). Increased plasma levels of TH exert a negative feedback control on both the pituitary and the hypothalamus (Utiger, Reference Utiger1995). Many factors are able to affect thyroid activity and hormone concentrations in blood, acting at the level of hypothalamus, pituitary and/or thyroid gland, as well as on peripheral monodeiodination (Figure 1). In addition, growth factors, prostaglandins, cytokines, by means of paracrine and/or autocrine actions, may modify thyroid cell growth and activity (Greenspan, Reference Greenspan2001).

Figure 1 Schematic representation of the regulation of thyroid gland and thyroid hormones activity.

TH acts on many different target tissues, stimulating oxygen utilisation and heat production in every cell of the body. The overall effects are to increase the basal metabolic rate, to make more glucose available to cells, to stimulate protein synthesis, to increase lipid metabolism and to stimulate cardiac and neural functions (Capen and Martin, Reference Capen and Martin1989). Peculiar actions consist in cell and tissue differentiation. TH are the primary endocrine stimulators of non-shivering (‘facultative’ or ‘adaptive’) thermogenesis, thus regulating body temperature (Silva, Reference Silva2005). One main mechanism of this function should be the stimulation of expression and activity of uncoupling proteins (UCPs), which uncouple re-oxidation of reduced coenymes to ADP phosphorylation, hence producing heat (Collin et al., Reference Collin, Cassy, Buyse, Decuypere and Damon2005). UCPs have been found in various tissues, also in ovine species (Darby et al., Reference Darby, Clarke, Lomax and Symonds1996; Mostyn et al., Reference Mostyn, Wilson, Dandrea, Yakubu, Budge, Alves-Guerra, Pecqueur, Miroux, Symonds and Stephenson2003). Most of the physiological actions of TH are mediated by the binding to nuclear receptors. Recently, several membrane transporters for cellular entry have been identified and they are now considered among the factors on which TH biological activity could depend (Hennemann et al., Reference Hennemann, Docter, Friesema, de Jong, Krenning and Visser2001; Friesema et al., Reference Friesema, Jansen, Milici and Visser2005). As it is the case of steroid hormones some actions of TH are rapid and non-genomic (Davis et al., Reference Davis, Tillman, Davis and Wehling2002; Hiroi et al., Reference Hiroi, Kim, Ying, Furuya, Huang, Simoncini, Noma, Ueki, Nguyen, Scanlan, Moskowitz, Cheng and Liao2006) due to actions on mitochondria and cell membranes on which binding proteins have been identified (Wrutniak-Cabello et al., Reference Wrutniak-Cabello, Casas and Cabello2001; Davis et al., Reference Davis, Davis and Cody2005).

Seasonality of reproduction

In ovine species, a notable interest has been excited by the involvement of TH in seasonal reproduction (Karsch et al., Reference Karsch, Dahl, Hachigian and Thrun1995). In fact, TH play an important function in the expression of endogenous seasonal rhythms of neuroendocrine reproductive activity in sheep, as in many species of birds (Nicholls et al., Reference Nicholls, Follett, Goldsmith and Pearson1988b). Thyroidectomised ewes began their sexual season at the same time as intact animals, but continued to cycle when the intact ewes enter seasonal anoestrus (Nicholls et al., Reference Nicholls, Goldsmith and Dawson1988a; Maurenbrecher and Barrell, Reference Maurenbrecher and Barrell2003). Similar but less-pronounced effects have been obtained in sheep rendered hypothyroid, in which the end of the reproductive season occurred later than in controls (Follett and Potts, Reference Follett and Potts1990; Hernandez et al., Reference Hernandez, Hallford and Wells2003). TH are necessary during a limited period late in the breeding season to permit transition to seasonal anoestrus (Thrun et al., Reference Thrun, Dahl, Evans and Karsch1996 and Reference Thrun, Dahl, Evans and Karsch1997a), acting primarily within the brain to promote inhibition of neuroendocrine reproductive function (Viguié et al., Reference Viguié, Battaglia, Krasa, Thrun and Karsch1999). TH permit the increase of the responsiveness to the oestradiol negative feeback, but are also required for steroid-independent seasonal cycles in luteinising hormone pulse frequency (Anderson et al., Reference Anderson, Connors, Hardy, Valent and Goodman2002). This permissive role of TH seemed limited to changes related to transition to seasonal anoestrus, since thyroidectomy during anoestrus did not affect the onset of the subsequent breeding season (Thrun et al., Reference Thrun, Dahl, Evans and Karsch1997b). Anyway, TH may be required for the long-term expression and maintenance of the endogenous seasonal reproductive rhythm (Billings et al., Reference Billings, Viguié, Karsch, Goodman, Connors and Anderson2002).

In male sheep, thyroidectomy abolished seasonal cycles of gonadotropin secretion and testicular size (Parkinson and Follett, Reference Parkinson and Follett1994; Parkinson et al., Reference Parkinson, Douthwaite and Follett1995).

The anatomical substrate for TH action on seasonal reproduction may be provided by the finding of TH receptor in GnRH and other neurotransmitters–containing neurons (Jansen et al., Reference Jansen, Lubbers, Macchia, DeGroot and Lehman1997). Recently, it has been found that photoperiod regulates the expression of type II deiodinase gene in the mediobasal hypothalamus of the Saanen goat, hence seasonally affecting the bioavailability of TH for the reproductive neuroendocrine axis (Yasuo et al., Reference Yasuo, Nakao, Ohkura, Iigo, Hagiwara, Goto, Ando, Yamamura, Watanabe, Watanabe, Oda, Maeda, Lincoln, Okamura, Ebihara and Yoshimura2006).

To our knowledge, there is only one report about the requirement of TH in seasonal reproduction in goat species, and these results are in contrast with the above-mentioned numerous investigations carried on in sheep: Cashmere goats thyroidectomised in late breeding season advanced the onset of seasonal anoestrus (Walkden-Brown et al., 1996). Furthermore, T3 at the goat testis level induces the synthesis of a soluble protein in Leydig cells, which in turn stimulates androgen release (Jana and Bhattacharya, Reference Jana and Bhattacharya1994; Jana et al., Reference Jana, Halder and Bhattacharya1996).

Hair fibre growth

At the skin level, the availability of bioactive TH may depend not only on the circulating hormone levels but also on the local synthesis of T3. Type II and III, but not type I, deiodinase activity was detected in skin samples from cashmere goats (Villar et al., Reference Villar, Rhind, Dicks, McMillen, Nicol and Arthur1998 and Reference Villar, Nicol, Arthur, Dicks, Cannavan, Kennedy and Rhind2000b) and showed marked individual variability between animals and seasonal changes. Type II deiodinase enzyme was higher during winter short-day photoperiod and lower during periods of long daylength, whereas type III showed an opposite pattern. Manipulations of circulating prolactin affected further the seasonal changes in the ratios of type II and type III deiodinase enzymes, and this was associated with differences in follicle activity and cashmere moult (Rhind et al., Reference Rhind, Kyle and Duff2004). In Soay sheep, showing marked seasonal variations in hair growth rate, the quiescent period corresponded to the seasonal physiological decline in plasma TH concentrations (Lincoln et al., Reference Lincoln, Klandorf and Anderson1980). Studies correlating seasonal changes of plasma TH and cashmere growth cycle failed to ascertain the putative regulatory role of TH (Kloren et al., Reference Kloren, Norton and Waters1993) and contrasting results have been reported (Rhind and McMillen, Reference Rhind and McMillen1995; Merchant and Riach, Reference Merchant and Riach2002; Celi et al., Reference Celi, Seren, Celi, Parmeggiani and Di Trana2003; Rhind and Kyle, Reference Rhind and Kyle2004). To clarify the role of TH on hair fibre production, many investigations have been carried out on manipulating TH availability for hair growth: on the whole, also the results of such papers were often contradictory (Ryder, Reference Ryder1979; Maddocks et al., Reference Maddocks, Chandrasekhar and Setchell1985; Hynd, Reference Hynd1994; Rhind and McMillen, Reference Rhind and McMillen1996). It seems that the sensitivity to TH failure or excess may be dependent on breed, season and interactions with other regulatory factors. TH action may be permissive rather than inductive, i.e. they might be present above certain threshold levels. Very important should be the interactions with other factors: firstly prolactin (Villar et al., Reference Villar, McMillen, Dicks and Rhind2000a; Rhind et al., Reference Rhind, Kyle and Duff2004), as well as the local actions of insulin (Puchala et al., Reference Puchala, Pierzynowski and Sahlu1998) and growth factors, such as EGF (Hoath et al., Reference Hoath, Laksmanan, Scott and Fisher1983). The putative effects of TH on hair fibre diameter are very interesting from a commercial and technological viewpoint. In an earlier study, it was reported that exogenous T4 administration to intact sheep induced increased wool growth, in terms of increased fibre length, without affecting the diameter (Hart, Reference Hart1957). T4, but not T3, reduced fibre diameter in sheep supplemented with selenium (Donald et al., Reference Donald, Langlands, Bowles and Smith1994) but T4 administration failed to avoid the increase in wool diameter following increased feed intake (Lee et al., Reference Lee, Thornberry and Williams2001). Angora goats rendered hyperthyroid by daily subcutaneous injections of T4 showed increased mohair growth, with higher fibre length and lower fibre diameter (Puchala et al., Reference Puchala, Prieto, Banskalieva, Goetsch, Lachica and Sahlu2001). In Angora kids supplemented with energy and protein (horse bean), the higher plasma TH were associated with increased fibre length, decreased fibre diameter and higher percentage of active secondary follicles than controls (Todini et al., Reference Todini, Malfatti, Barbato, Trabalza-Marinucci, Acuti, Antonini and Debenedetti2005). Anyway, further investigations are needed in order to clarify the role of TH in hair fibre production. This role should be rather different between animals showing a marked seasonality and clear moulting cycles (such as cashmere goats) and animals whose hair growth is more or less continuous throughout the year (Angora goats, Merino sheep).

Foetal life

In foetal sheep, during the last one-third period of gestation, serum T4 concentrations were slightly higher or comparable with those in adult sheep, while foetal serum T3 were much lower and rT3 much higher. The elevated rT3 concentrations in foetal sheep serum decreased progressively after birth and reached comparable levels with those in adults, within few days of life (Chopra et al., Reference Chopra, Sack and Fisher1975). An opposite trend was described for T3 concentrations (Nathanielsz et al., Reference Nathanielsz, Silver and Comline1973; Klein et al., Reference Klein, Oddie and Fisher1978). These differences in serum hormone concentrations have been related to differences in peripheral deiodinase activity as the relative thyroidal content of T4 and T3 was similar in foetal and adult sheep (Chopra et al., Reference Chopra, Sack and Fisher1975). In fact, type I deiodinase activity in the liver and kidney of foetus up to the fourth month was lower than that in pre-term foetus or in the newborn (Wu et al., Reference Wu, Polk, Wong, Reviczky, Vu and Fisher1992). Low foetal T3 levels are maintained also by sulphation and deiodination (Wu et al., Reference Wu, Polk, Huang, Green, Thai and Fisher2006). In the foetus, low T3 levels allow anabolic processes to prevail, despite the high rate of foetal T4 secretion, which resulted eight-fold than maternal one during the last one-third period of gestation (Dussault et al., Reference Dussault, Hobel and Fisher1971). The pre-partum cortisol surge increased hepatic renal and perirenal adipose tissue type I deiodinase, and reduced renal and placental type III deiodinase activities (Forhead et al., Reference Forhead, Curtis, Kaptein, Visser and Fowden2006). The increased availability of active T3 is important for the latter phases of tissue differentiation. The functional development of brown adipose tissue allows to optimise non-shivering thermogenesis, thus permitting an adequate thermoregulation in the newborn (Schermer et al., Reference Schermer, Bird, Lomax, Sheperd and Symonds1996). Therefore, UCP1, induced by TH, is of primary importance for the transition from foetal to neonatal life, when cellular energy and thermoregulatory requirements are at maximal rates (Symonds et al., Reference Symonds, Mostyn, Pearce, Budge and Stephenson2003). When the pre-partum rise of cortisol occurs, TH may also influence the growth and development of foetal liver and skeletal muscle, modulating the local activity of the somatotropic axis, i.e. the local expression of growth hormone receptor and insulin-like growth factors (Forhead et al., Reference Forhead, Li, Gilmour and Fowden1998, Reference Forhead, Li, Saunders, Dauncey, Gilmour and Fowden2000 and Reference Forhead, Li, Gilmour, Dauncey and Fowden2002). At the same time TH are essential for foetal glucogenesis (Fowden et al., Reference Fowden, Mapstone and Forhead2001), allowing the pre-partum rise in glucose-6-phosphatase and phosphoenolpyruvate carboxykinase activity in the foetal liver and kidney Forhead et al., Reference Forhead, Poore, Mapstone and Fowden2003).

Age effects: birth, neonatal period and growth. Gender effects

The pre-partum cortisol rise is accompanied by an increase in foetal T3 and a decrease in rT3 concentrations (Sensky et al., Reference Sensky, Roy, Barnes and Heath1994). This pattern should be maintained throughout the early postnatal life (Nathanielsz et al., Reference Nathanielsz, Silver and Comline1973; Klein et al., Reference Klein, Oddie and Fisher1978). Plasma free T3 (fT3) in neonatal lambs increased parallel to total T3 (Cabello and Wrutniak, Reference Cabello and Wrutniak1986), whereas the neonatal increase of free T4 (fT4) concentrations was greater and longer lasting than total T4 (Cabello and Wrutniak, Reference Cabello and Wrutniak1990). In fact, neonatal plasma T3 and fT4 rises followed that of TSH concentrations, lasting for 24 h after birth, but T4 levels declined before (after 2 h of life), when TSH levels were still elevated (Cabello and Wrutniak, Reference Cabello and Wrutniak1990). Therefore, the thyroid gland seems unable to respond, in terms of T4 secretion, to a prolonged stimulation by TSH, probably because a depletion of hormonal stores in the gland occurs during the first minutes of life (Slebodzinski, Reference Slebodzinski1972). It is likely that during the first hours of life the thyroid gland can respond to other stimulating factors: small increases of plasma TH followed exogenous prolactin administration in neonatal lamb, but not in growing lambs and ewes (Peeters et al., Reference Peeters, Buys, Vanmontfort, van Isterdael, Decuypere and Kuhn1992). Plasma rT3 levels during the first 48 h of life progressively decreased in suckling lambs, but increased in bottle-fed lambs (Cabello and Wrutniak, Reference Cabello and Wrutniak1986 and Reference Cabello and Wrutniak1990). Plasma T4 concentrations were higher in single lambs than in twins at birth (Assane and Sere, Reference Assane and Sere1990). Plasma TH levels highly correlated with lambs’ birth-weight (Dwyer and Morgan, Reference Dwyer and Morgan2006) and were lower in lambs separated from their mothers just after parturition than in those maintained with their mothers (Firat et al., Reference Firat, Ozpinar, Serpek and Haliloglu2005). Neonatal lambs had higher levels of T3 and T4 compared with growing lambs and ewes (Peeters et al., Reference Peeters, Buys, Vanmontfort, van Isterdael, Decuypere and Kuhn1992). Growing goat kids displayed higher TH levels than adults (Colavita et al., Reference Colavita, Debenedetti, Ferri, Lisi and Lucaroni1983) and the lowest values were found in elderly animals (Table 1; Lucaroni et al., Reference Lucaroni, Todini, Malfatti and Debenedetti1989). Age-related differences were particularly evident during the hot season, especially for T3 blood concentrations (Lucaroni et al., Reference Lucaroni, Todini, Malfatti and Debenedetti1989).

Table 1 Serum thyroid hormone concentrations (mean ± s.d.) in goats (local Umbrian population) at different ages (data grouped from samplings at different seasons), adapted from Lucaroni et al. (1989)

In young animals, there is no sex-dependent differences in blood TH concentrations, whereas in adult goats mean plasma TH levels were higher (significantly for T4) in does than in bucks (Table 2; Todini et al., Reference Todini, Lucaroni, Malfatti, Debenedetti and Costarelli1992). In young cashmere goats, T3 levels were lower in males than in females after 8 months of age, while T4 was not affected by sex (Celi et al., Reference Celi, Seren, Celi, Parmeggiani and Di Trana2003). Sex-related differences are reported in others mammals and are referred to several actions by sexual steroid hormones: differences in total T4 levels can be explained by oestrogen-reduced catabolism of thyroxine-binding globulin (TBG) (Ain et al., Reference Ain, Mori and Refetoff1987), or androgen inhibition of the synthesis of TBG by the liver (Federman et al., Reference Federman, Robbins and Rall1958). Moreover, androgens inhibit TSH secretion by the pituitary (Christianson et al., Reference Christianson, Roti, Vagenakis and Braverman1981).

Table 2 Plasma thyroid hormone concentrations (mean ± s.d.) in 16 adult does and 8 adult bucks (dairy Mediterranean breeds), maintained sex-separated and fed a qualitatively constant diet throughout the year (weekly samplings). Monthly mean, minimal and maximal environmental temperatures are also indicated (adapted from Todini et al. (1992)).

Breed effects

To our knowledge, there are no published data on goat breed differences. At birth, Blackface lambs had higher T3 and T4 levels than Suffolk lambs and this was correlated with higher body temperature and better thermoregulatory ability (Dwyer and Morgan, Reference Dwyer and Morgan2006). Merino lambs aged 2 to 3 days, submitted to cold stress, showed a stronger increase of TH levels compared with Romney-Marsh lambs (Doubek et al., Reference Doubek, Slosarkova, Fleischer, Malà and Skrivanek2003). Lamb breeds that are usually reared under extensive conditions (hill regions) have an improved thermoregulation than those reared intensively in lowland: this is partly related to birthcoat characteristics, accompanied by higher TH concentrations (important for endogenous heat production and hair growth) in hill than lowland lambs (Dwyer and Lawrence, Reference Dwyer and Lawrence2005). Assaf ewes had higher serum T4 concentrations than Rasa Aragonesa and Merino ewes, which was associated with differences in wool growth rate (Abecia et al., Reference Abecia, Valares and Forcada2005). Higher plasma T4 levels in Suffolk ewes than Gulf Coast native ewes in the US were shown to be positively related to larger body size and enhanced growth potential (Williams et al., Reference Williams, Calmes, Fernandez, Stanley, Lovejoy, Bateman, Gentry, Gantt and Harding2004). Higher levels of T3 and T4 in ram lambs have been associated with higher prolificacy of the Outaouais breed compared with the Suffolk breed (lower prolificacy) (Fallah-Rad and Connor, Reference Fallah-Rad and Connor1999). The decline in serum T4 levels induced by feed restriction was greater in crossbreed ewes than in native Indian sheep (Naqvi and Rai, Reference Naqvi and Rai1991).

Changes during oestrus, pregnancy, peri-parturient period and lactation

During induced or spontaneous oestrus in goats, a rise in plasma total T4 (Colavita and Malfatti, Reference Colavita and Malfatti1989) and fT4 (Blaszczyk et al., Reference Blaszczyk, Udala and Gaczrzewicz2004) levels has been observed. In ewes, plasma T4 levels were higher during oestrus and lower during the luteal phase, T3 concentrations were higher during the luteal phase, while the concentrations of rT3 were not associated with the oestrous cycle (Peeters et al., Reference Peeters, Buys, Pauwels, Kuhn, Decuypere, Siau and Van Isterdael1989).

During pregnancy, thyroid activity and circulating hormone levels are reported to increase in all the investigated mammalian species. Several mechanisms have been claimed to explain these observations: increased binding protein concentrations in plasma, secretion of thyrotropic factors by the placenta, enhanced responsiveness of pituitary TSH secretion to hypothalamic TRH and changes in maternal TH catabolism (De Leo et al., Reference De Leo, la Marca, Lanzetta and Morgante1998; Glinoer, Reference Glinoer2001). Towards the end of pregnancy, the goat foetus(es) should play a competitive role (higher thyroid activity, iodine affinity and uptake than maternal ones), so that a decrease in maternal plasma fT4 concentrations has been observed (McDonald et al., Reference McDonald, Stocks, Connell and Hoey1988). Plasma T3 and T4 levels in goats at mid-pregnancy rised compared with the low levels observed just before oestrus and mating. Then, during the second half of pregnancy, maternal hormone levels progressively decrease, probably because of the negative energy balance (Todini et al., Reference Todini, Malfatti, Valbonesi, Trabalza-Marinucci and Debenedetti2007). This is supported by the lower maternal serum TH levels (more marked and significant for T4) observed in twin-bearing does, that are often characterised by negative energy balance, compared with aborted and single-bearing does (whose energy balance is usually less negative) (Manalu et al., Reference Manalu, Sumaryadi and Kusumorini1997). Very similar findings are reported for ewes. Plasma T4 concentration was highest during early pregnancy and decreased gradually, reaching lowest values during late pregnancy and post partum (Assane and Sere, Reference Assane and Sere1990; Okab et al., Reference Okab, Elebanna, Mekkawy, Hassan, Elnouty and Salem1993; Yildiz et al., Reference Yildiz, Balikci and Gurdogan2005). Like in goats, maternal T3 and T4 in twin pregnancy were lower compared with single-bearing sheep (Yildiz et al., Reference Yildiz, Balikci and Gurdogan2005), especially at the end of pregnancy (Assane and Sere, Reference Assane and Sere1990).

In goats, maternal plasma T3 levels remained rather steady around parturition, while T4 concentrations markedly decreased and remained low until day 10 post partum (Lucaroni and Todini, Reference Lucaroni and Todini1989). Khan and Ludri (Reference Khan and Ludri2002b) reported that both TH concentrations did not change from day 20 before parturition until the day of kidding, when they reached a minimal level, followed by an increase until day 20 post partum. In ewes, plasma TH concentrations were lower post partum than during pregnancy (Okab et al., Reference Okab, Elebanna, Mekkawy, Hassan, Elnouty and Salem1993), tended to decrease from 36 h to 21 days post partum and thereafter constantly rose until day 51 post partum (Bekeova et al., Reference Bekeova, Elecko, Krajnicakova, Hendrichovsky and Maracek1991).

Blood TH levels were low at the beginning of lactation, afterwards gradually rose in does (Riis and Madsen, Reference Riis and Madsen1985; Emre and Garmo, Reference Emre and Garmo1985) and in ewes (Mitin et al., Reference Mitin, Mikulec and Karadjole1986). Administration of TH is known to stimulate lactation in many species (Tucker, Reference Tucker1994 and Reference Tucker2000) but an inverse relationship between blood hormone concentration and milk yield has been observed in goats (Riis and Madsen, Reference Riis and Madsen1985), at least during the first phases of lactation. In ewes, during late lactation, the increase of T4 concentration in blood seems related to the decrease of milk production (Bass, Reference Bass1989).

Within the first 20 days post partum, in twin-bearing does, plasma TH levels were significantly lower compared with single-bearing does (Khan and Ludri, Reference Khan and Ludri2002a), but throughout lactation very slight or no differences between single and twin-suckling ewes were found (Bass, Reference Bass1989; Rhind et al., Reference Rhind, Bass, Doney and Hunter1991). Taken together, these findings may support the meaning of blood TH levels as indicators of the energy balance, also in lactating animals.

Circadian rhythms

Circadian changes in hormone secretion are probably associated with the rhythms of environmental temperature and light, as well as with feed intake and metabolism, which in turn are related to the alternance activity/rest throughout the day. Moreover, overlapping effects by season and physiological state are expected. Because many factors can influence T4 and T3 levels and because interactions between these factors are likely, the few data available in the literature on such topics are rather discordant.

Blood samplings at 4-h intervals in late spring did not permit to find significant circadian differences in TH concentrations in lactating (milked or suckled) goats, but the maximal levels were observed during the night (Lucaroni et al., Reference Lucaroni, Todini, Malfatti and Debenedetti1989). In ewes sampled twice a day, the differences between morning and afternoon were not univocal, depending on the season (Ashutosh et al., Reference Ashutosh, Dhanda and Kundu2001). In ewes sampled at 2-h intervals, lowest blood hormone levels were found in the afternoon, concentrations then increased progressively during the night, and reached the highest levels in the morning (Velasquez et al., Reference Velasquez, Souza, Oba and Ramos1997). In winter, T3 and T4 concentrations reached maximal levels in early morning, probably because of a delayed response to cold stress to which the animals were exposed by night; furthermore, the circadian variations in winter decreased with the increase in wool length (Salem et al., Reference Salem, Elsherbiny, Khalil and Yousef1991). Combining the results obtained from samplings carried out every 2 months for 1 year, rams showed the highest TH concentrations during the afternoon and the lowest in the early morning (Souza et al., Reference Souza, Bicudo, Uribe-Velasquez and Ramos2002).

Season effects

A major exogenous regulator of thyroid gland activity is the environmental temperature (Dickson, Reference Dickson1993), so an inverse relationship between ambient temperature and blood TH concentrations has been found in sheep (Valtorta et al., Reference Valtorta, Hahn and Johnson1982; Webster et al., Reference Webster, Moenter, Woodfill and Karsh1991; Starling et al., Reference Starling, da Silva, Negrao, Maia and Bueno2005) and goats (Colavita et al., Reference Colavita, Debenedetti, Ferri, Lisi and Lucaroni1983; Todini et al., Reference Todini, Lucaroni, Malfatti, Debenedetti and Costarelli1992).

During heat stress, blood T3 and T4 concentrations, as well as metabolic rate, feed intake, growth and milk production were decreased (Valtorta et al., Reference Valtorta, Hahn and Johnson1982; Silanikove, Reference Silanikove2000). On the other hand, cold stress in ewes (Hocquette et al., Reference Hocquette, Vermorel, Bouix, Anglaret, Donnat, Leoty, Meyer and Souchet1992) ram lambs (Ekpe and Christopherson, Reference Ekpe and Christopherson2000; Doubek et al., Reference Doubek, Slosarkova, Fleischer, Malà and Skrivanek2003) and shearing (Morris et al., Reference Morris, McCutcheon and Revell2000; Merchant and Riach, Reference Merchant and Riach2002) induced increases in blood TH levels. The seasonal pattern of blood TH levels often showed maximal values during winter (cold months) and minimal during summer (hot months) (Salem et al., Reference Salem, Elsherbiny, Khalil and Yousef1991; Webster et al., Reference Webster, Moenter, Woodfill and Karsh1991; Okab et al., Reference Okab, Elebanna, Mekkawy, Hassan, Elnouty and Salem1993; Menegatos et al., Reference Menegatos, Goulas and Kalogiannis2006). However, contrasting results have been reported (Kloren et al., Reference Kloren, Norton and Waters1993; Rhind et al., Reference Rhind, McMillen, Duff, Hirst and Wright1998; Ashutosh et al., Reference Ashutosh, Dhanda and Kundu2001; Yokus et al., Reference Yokus, Cakir, Kanay, Gulten and Uysal2006). In the Sahel desert, plasma T3 and T4 levels did not change significantly from the beginning of the cool season (December) until the end of the dry warm season (May), but a highly significant rise of both hormones was observed at the onset of the humid warm season (June) (Assane and Sere, Reference Assane and Sere1990). It can be supposed that an enhanced thyroid activity during the humid warm season in such environments is functional for the animals facing the increased availability of food (quantity and quality), following the seasons characterised by food shortage.

Blood TH concentrations were high in spring (increasing daylength) and low in autumn (decreasing daylength), which was not fully explained by the changes in environmental temperature (Figure 2; Buys et al., Reference Buys, Peeters, De Clerck, Van Isterdael, Kuhn and Decuypere1990; Todini et al., Reference Todini, Lucaroni, Malfatti, Debenedetti and Costarelli1992; Rhind and McMillen, Reference Rhind and McMillen1995: Clariget et al., Reference Clariget, Forsberg and Rodriguez-Martinez1998; Rhind et al., Reference Rhind, McMillen, Duff, Kyle and Wright2000; Taha et al., Reference Taha, Abdel-Gawad and Ayoub2000; Villar et al, Reference Villar, McMillen, Dicks and Rhind2000a; Merchant and Riach, Reference Merchant and Riach2002; Souza et al., Reference Souza, Bicudo, Uribe-Velasquez and Ramos2002; Blaszczyk et al., Reference Blaszczyk, Udala and Gaczrzewicz2004; Zamiri and Khodaei, Reference Zamiri and Khodaei2005; Menegatos et al., Reference Menegatos, Goulas and Kalogiannis2006; Todini et al., Reference Todini, Delgadillo, Debenedetti and Chemineau2006). It seems that when the temperature ranges are not extreme (mild climate, indoor housing, shelter in the night time), the effect of photoperiod and season-dependent TH profiles (mainly related to the daylength changes) are present.

Figure 2 Circannual profiles of mean plasma T3 (3-5-3′-triiodothyronine) and T4 (thyroxine) in 20 female goats (local Umbrian population), mean environmental temperature, daylength and physiological state (modified from Lucaroni et al. (Reference Lucaroni, Todini, Malfatti and Debenedetti1989)).

In Alpine and Saanen bucks exposed to artificial photoperiodic cycles, alternating 1 or 2 months of long days (LD: 16 h light and 8 h dark) to 1 or 2 months of short days (SD: 16 h dark and 8 h light), plasma T3 levels rapidly followed the photoperiodic changes, increasing during LD and decreasing during SD. The effects of daylength changes on plasma T4 concentrations were seen after a delay of several weeks and the T3:T4 ratio showed very marked variations, increasing during LD and decreasing during SD (Todini et al., Reference Todini, Delgadillo, Debenedetti and Chemineau2006). Similar results were obtained by Lincoln et al. (Reference Lincoln, Klandorf and Anderson1980) in rams submitted to an alternance of 16 weeks of SD and 16 weeks of LD. The mechanisms of the photoperiodic effects on peripheral TH are far from being elucidated. Additional data on actions of the photoperiod in the brain are scanty in small ruminants: TRH from hypothalamic perfusate samples of ewes only tended to be significantly higher during LD than during SD (Leshin and Jackson, Reference Leshin and Jackson1987). Long days suppressed the expression of monodeiodinase gene in the hypothalamus of goats, thus limiting the local bioavailability of TH, which should be related to the role of the thyroid gland in seasonal reproduction (Yasuo et al., Reference Yasuo, Nakao, Ohkura, Iigo, Hagiwara, Goto, Ando, Yamamura, Watanabe, Watanabe, Oda, Maeda, Lincoln, Okamura, Ebihara and Yoshimura2006).

On the basis of the above-quoted studies, it is not possible to discriminate between the relative role of temperature and photoperiod on the seasonality of thyroid activity, in different environmental conditions. Moreover, when the feed intake is markedly seasonal, it becomes a major factor modifying the seasonal pattern of blood TH profiles.

Nutrition effects

T3 directly stimulates feed intake at the hypothalamic level (Kong et al., Reference Kong, Martin, Smith, Gardiner, Connoley, Stephens, Dhillo, Ghatei, Small and Bloom2004), while on the other hand, the quantity and quality of food eaten is a major factor determining plasma concentrations of TH (Dauncey, Reference Dauncey1990). Blood TH levels are considered to be good indicators of the nutritional status of an animal (Riis and Madsen, Reference Riis and Madsen1985) and were correlated with feed intake in ruminant species, including those that exhibit very marked seasonal cyclicity in feed intake, body weight and reproductive activity, e.g. deers (Ryg and Langvatn, Reference Ryg and Langvatn1982; Chao and Brown, Reference Chao and Brown1984; Rhind et al., Reference Rhind, McMillen, Duff, Hirst and Wright1998).

Circulating TH concentrations seem better correlated with feed intake than adiposity status (McCann et al., Reference McCann, Bergman and Beermann1992; Caldeira et al., Reference Caldeira, Belo, Santos, Vazques and Portugal2007a and Reference Caldeira, Belo, Santos, Vazques and Portugalb).

Energy deprivation decreased concentrations of T3 and fT3 in adult sheep, while subsequent overnutrition increased them. Plasma total T3 concentrations significantly correlated with energy and nitrogen balances. Plasma rT3 levels showed an opposite pattern, increasing during energy deprivation and decreasing during overnutrition (Blum et al., Reference Blum, Gingins, Vitins and Bickel1980). Concentrate supplementation induced an increase of plasma T4 levels in lactating ewes (Shetaewi and Ross, Reference Shetaewi and Ross1991) and plasma T3 concentrations was higher in rams with high amounts of ingested energy and protein (Zhang et al., Reference Zhang, Blache, Blackberry and Martin2004). Following feed restriction or food deprivation, plasma TH concentrations were reduced in sheep (Naqvi and Rai, Reference Naqvi and Rai1991; Wronska-Fortuna et al., Reference Wronska-Fortuna, Sechman, Niezgoda and Bobek1993; Wester et al., Reference Wester, Britton, Klopfenstein, Ham, Hickok and Krehbiel1995; Ekpe and Christopherson, Reference Ekpe and Christopherson2000; Abecia et al., Reference Abecia, Zuniga and Forcada2001; Rae et al., Reference Rae, Rhind, Miller and Brooks2002). Feed-restricted animals also showed an earlier and more marked decline in plasma TH concentrations during the late summer/early autumn, compared with ad libitum fed animals (Rhind et al., Reference Rhind, McMillen, Duff, Hirst and Wright1998 and Reference Rhind, McMillen, Duff, Kyle and Wright2000).

Lactating Angora does and their kids supplemented with energy and protein (horse bean) had higher plasma TH concentrations than controls (Todini et al., Reference Todini, Malfatti, Barbato, Trabalza-Marinucci, Acuti, Antonini and Debenedetti2005). Goats with a slightly higher energy intake showed higher plasma TH concentrations during the second half of gestation, and the decrease of plasma TH in mid- and late gestation was attenuated and delayed (Todini et al., Reference Todini, Malfatti, Valbonesi, Trabalza-Marinucci and Debenedetti2007). These effects suggested that energy balance could play a major role in affecting the decrease in plasma TH levels usually observed at the end of gestation in small ruminants (see above). Furthermore, in the higher energy diet-fed goats, the variations of circulating T4 during different physiological states were not significant (Todini et al., Reference Todini, Malfatti, Valbonesi, Trabalza-Marinucci and Debenedetti2007). Recently, no significant difference in the rates of type II and type III deiodinase activity in the skin or in blood TH concentrations was found between cashmere goats maintained at a different plane of nutrition (Rhind et al., Reference Rhind, Kyle, Riach and Duff2006).

Selenium is present in deiodinase enzymes, and other selenoproteins play a protective role for the thyrocytes against damage by hydrogen peroxide produced for TH biosynthesis (Kohrle et al., Reference Kohrle, Jakob, Contempré and Dumont2005). Oral iodine and selenium supplements increased blood concentrations of TH in sheep, and selenium supplementation alone increased plasma T3 concentrations and decreased T4 concentrations (Bik, Reference Bik2003). Following selenium supplementation, type I deiodinase activity decreased in the liver and increased in the pituitary, while pituitary type II deiodinase was unaffected, indicating that enzyme activity is homeostatically controlled when a sufficient amount of selenium is present, in order to ensure TH homeostasis (Chadio et al., Reference Chadio, Kotsampasi, Menegatos, Zervas and Kalogiannis2006).

Conclusion

Changes of blood TH concentrations are an indirect measure of the changes in thyroid gland and extrathyreoidal deiodination activity. Many factors act simultaneously modulating thyroid gland activity and/or peripheral monodeiodination. Besides endogenous and environmental climatic factors, nutrition plays a primary role on thyroid gland activity and on blood TH concentrations. The physiological range of the endocrine responses to different conditions is very large, thus reference values are very difficult to obtain. Assay results must be carefully evaluated, not only for diagnostic and clinical purposes but also to evaluate the physiological states and responses of the animals. The systemic actions of TH justify their pivotal role in the mechanisms permitting the animals to adapt to the surrounding environment. New insights are gathered from investigations on the regulation of monodeiodinase activity, hence of TH bioavailability, in the central nervous system and at the peripheral level. Little is known about TH receptor expression and activity or about the targets at molecular levels, even in humans and rodents. The field of the non-genomic, rapid TH actions needs further research. Knowledge on such topics will possibly allow the monitoring and manipulation of thyroid physiology, in order to improve animal health, welfare and production (meat, milk, hair fibre).

Acknowledgements

The author wishes to thank Professor Alessandro Debenedetti and Professor Alessandro Malfatti for their guidance and encouragement, Dr Alessia Zicavo and Mr Diego Todini for their patient support.

References

Abecia, JA, Zuniga, O, Forcada, F 2001. Effect of melatonin treatment in spring and feed intake on wool growth and thyroxine secretion in Rasa Aragonesa ewes. Small Ruminant Research 41, 265270.Google Scholar
Abecia, JA, Valares, JA, Forcada, F 2005. The effect of melatonin treatment on wool growth and thyroxine secretion in sheep. Small Ruminant Research 56, 265270.Google Scholar
Ain, KB, Mori, Y, Refetoff, S 1987. Reduced clearance rate of thyroxine-binding globulin (TBG) with increased sialylation: a mechanism for estrogen-induced elevation of serum TBG concentration. Journal of Clinical Endocrinology and Metabolism 65, 689696.Google Scholar
Anderson, GM, Connors, JM, Hardy, SL, Valent, M, Goodman, RL 2002. Thyroid hormones mediate steroid-independent seasonal changes in luteinizing hormone pulsatility in the ewe. Biology of Reproduction 66, 701706.Google Scholar
Ashutosh, , Dhanda, OP, Kundu, RL 2001. Effect of climate on the seasonal endocrine profile of native and crossbred sheep under semi-arid conditions. Tropical Animal Health and Production 33, 241252.CrossRefGoogle Scholar
Assane, M, Sere, A 1990. Seasonal and gestational variations of triiodothyronine and thyroxine plasma-concentrations in Sahel Peulh ewe. Annales de Recherches Veterinaires 21, 285289.Google Scholar
Bartalena, L 1990. Recent achievements in studies on thyroid hormone-binding proteins. Endocrine Reviews 11, 4764.Google Scholar
Bass, J 1989. Effect of litter size, dietary protein content, ewe genotype and season on milk production and associated endocrine and blood metabolite status of ewes. Animal Breeding Abstracts 58, 275.Google Scholar
Bekeova, E, Elecko, J, Krajnicakova, M, Hendrichovsky, V, Maracek, I 1991. Dynamics of changes in concentrations of cholesterol and thyroid and ovarian hormones in blood-serum during postparturient period of ewes. Veterinarni Medicina 36, 673684.Google Scholar
Bianco, AC, Kim, BW 2006. Deiodinases: implications of the local control of thyroid hormone action. Journal of Clinical Investigation 116, 25712579.Google Scholar
Bianco, AC, Salvatore, D, Gereben, B, Berry, MJ, Larsen, PR 2002. Biochemistry, cellular and molecular biology, and physiological roles of the iodothyronine selenodeiodinases. Endocrine Reviews 23, 3889.Google Scholar
Bik, DE 2003. Influence of selenium and iodine supplementation on thyroid hormone concentrations in the blood serum of sheep. Medycyna Weterynaryjna 59, 11261129.Google Scholar
Billings, HJ, Viguié, C, Karsch, FJ, Goodman, RL, Connors, JM, Anderson, GM 2002. Temporal requirements of thyroid hormones for seasonal changes in LH secretion. Endocrinology 143, 26182625.Google Scholar
Blaszczyk, B, Udala, J, Gaczrzewicz, D 2004. Changes in estradiol, progesterone, melatonin, prolactin and thyroxine concentrations in blood plasma of goats following induced estrus in and outside the natural breeding season. Small Ruminant Research 51, 209219.Google Scholar
Blum, JW, Gingins, M, Vitins, P, Bickel, H 1980. Thyroid hormone levels related to energy and nitrogen balance during weight loss and regain in adult sheep. Acta Endocrinologica 93, 440447.Google Scholar
Buys, N, Peeters, R, De Clerck, B, Van Isterdael, J, Kuhn, ER, Decuypere, E 1990. Seasonal variations in prolactin, growth hormone and thyroid hormones and the prolactin surge at ovulation do not affect litter size of ewes during pregnancy in the oestrous or the anoestrous season. Journal of Reproduction and Fertility 90, 4753.Google Scholar
Cabello, G, Wrutniak, C 1986. Plasma free and total iodothyronine levels in the newborn lamb. Physiological consideration. Reproduction, Nutrition, Development 26, 12811288.Google Scholar
Cabello, G, Wrutniak, C 1990. Thyroid function in the newborn lamb. Physiological approach of the mechanisms inducing the changes in plasma thyroxine, free thyroxine and triiodothyronine concentrations. Journal of Developmental Physiology 13, 2532.Google Scholar
Caldeira, RM, Belo, AT, Santos, CC, Vazques, MI, Portugal, AV 2007a. The effect of body condition score on blood metabolites and hormonal profiles in ewes. Small Ruminant Research 68, 233241.Google Scholar
Caldeira, RM, Belo, AT, Santos, CC, Vazques, MI, Portugal, AV 2007b. The effect of long-term feed restriction and over-nutrition on body condition score, blood metabolites and hormonal profiles in ewes. Small Ruminant Research 68, 242255.Google Scholar
Capen, CC, Martin, SL 1989. The thyroid gland. In Veterinary endocrinology and reproduction, fourth edition (ed. LE McDonald, MH Pineda), pp. 5891. Lea and Febiger, Philadelphia, PA.Google Scholar
Celi, P, Seren, E, Celi, R, Parmeggiani, A, Di Trana, A 2003. Relationships between blood hormonal concentrations and secondary fibre shedding in young cashmere-bearing goats at their first moult. Animal Science 77, 371381.Google Scholar
Chadio, SE, Kotsampasi, BM, Menegatos, JG, Zervas, GP, Kalogiannis, DG 2006. Effect of selenium supplementation on thyroid hormone levels and selenoenzyme activities in growing lambs. Biological Trace Element Research 109, 145154.Google Scholar
Chao, CC, Brown, RD 1984. Seasonal relationships of thyroid, sexual and adrenocortical hormones to nutritional parameters and climatic factors in white-tailed deer (Odocoileus virginianus) of south Texas. Comparative Biochemistry and Physiology – Part A: Physiology 77, 299306.Google Scholar
Chopra, IJ, Sack, J, Fisher, DA 1975. 3,3′,5′-Triiodothyronine (Reverse T3) and 3,3,5′-Triiodothyronine (T3) in fetal and adult sheep: studies on metabolic clearance rates, production rates, serum binding, and thyroidal content relative o thyroxine. Endocrinology 97, 10801088.Google Scholar
Chopra, IJ, Solomon, DH, Chopra, U, Wu, SY, Fisher, DA, Nakamura, Y 1978. Pathways of metabolism of thyroid hormones. Recent Progress in Hormone Research 34, 521567.Google Scholar
Chopra, IJ, Huang, TS, Beredo, A, Solomon, DH, Chua, Teco, GN, Mead, JF 1985. Evidence for an inhibitor of extrathyroidal conversion of thyroxine to 3,5,3’-triiodothyronine in sera of patients with nonthyroidal illnesses. Journal of Clinical Endocrinology and Metabolism 60, 666672.Google Scholar
Christianson, D, Roti, E, Vagenakis, AG, Braverman, LE 1981. The sex related difference in serum thyrotropin concentration is androgen mediated. Endocrinology 108, 529535.Google Scholar
Clariget, RP, Forsberg, M, Rodriguez-Martinez, H 1998. Seasonal variation in live weight, testes size, testosterone, LH secretion, melatonin and thyroxine in Merino and Corriedale rams in a subtropical climate. Acta Veterinaria Scandinavica 39, 3547.Google Scholar
Colavita, GP, Malfatti, A 1989. Hematic concentration of thyroid hormones T3 and T4 in goats at the beginning of the seasonal sexual activity. Atti della Società Italiana delle Scienze Veterinarie 43, 467471.Google Scholar
Colavita, GP, Debenedetti, A, Ferri, C, Lisi, C, Lucaroni, A 1983. Blood thyroid hormone concentrations by the domestic goat: seasonal and age-related variations. Bollettino della Società Italiana di Biologia Sperimentale 49, 779785.Google Scholar
Collin, A, Cassy, S, Buyse, J, Decuypere, E, Damon, M 2005. Potential involvement of mammalian and avian uncoupling proteins in the thermogenic effect of thyroid hormones. Domestic Animal Endocrinology 29, 7887.Google Scholar
Darby, CJ, Clarke, L, Lomax, MA, Symonds, ME 1996. Brown adipose tissue and liver development during early postnatal life in hand-reared and ewe-reared lambs. Reproduction Fertility and Development 8, 137145.Google Scholar
Davis, PJ, Tillman, HC, Davis, FB, Wehling, M 2002. Comparison of the mechanisms of nongenomic actions of thyroid hormone and steroid hormones. Journal of Endocrinological Investigation 25, 377388.Google Scholar
Davis, PJ, Davis, FB, Cody, V 2005. Membrane receptors mediating thyroid hormone action. Trends in Endocrinology and Metabolism 16, 429435.Google Scholar
Dauncey, MJ 1990. Thyroid hormones and thermogenesis. Proceedings of the Nutrition Society 49, 203215.Google Scholar
De Leo, V, la Marca, A, Lanzetta, D, Morgante, G 1998. Thyroid function in early pregnancy I: Thyroid-stimulating hormone response to thyrotropin-releasing hormone. Gynecological Endocrinology 12, 191196.Google Scholar
Dickson, WM 1993. Endocrine glands. In: Duke's physiology of domestic animals, 11th edition (ed. MJ Swenson and WO Reece), pp. 629664. Comstock Publishers Association, Ithaca and London.Google Scholar
Donald, GE, Langlands, JP, Bowles, JE, Smith, AJ 1994. Subclinical selenium insufficiency. 5. Selenium status and the growth and wool production of sheep supplemented with thyroid hormones. Australian Journal of Experimental Agriculture 34, 1318.Google Scholar
Doubek, J, Slosarkova, S, Fleischer, P, Malà, G, Skrivanek, M 2003. Metabolic and hormonal profiles of potentiated cold stress in lambs during early postnatal period. Czech Journal of Animal Science 48, 403411.Google Scholar
Dussault, JH, Hobel, CJ, Fisher, DA 1971. Maternal and fetal thyroxine secretion during pregnancy in the sheep. Endocrinology 88, 4751.Google Scholar
Dwyer, CM, Lawrence, AB 2005. A review of the behavioural and physiological adaptations of hill and lowland breeds of sheep that favour lamb survival. Applied Animal Behaviour Science 92, 235260.Google Scholar
Dwyer, CM, Morgan, A 2006. Maintenance of body temperature in the neonatal lamb: Effects of breed, birth weight, and litter size. Journal of Animal Science 84, 10931101.Google Scholar
Ekpe, ED, Christopherson, RJ 2000. Metabolic and endocrine responses to cold and feed restriction in ruminants. Canadian Journal of Animal Science 80, 8795.Google Scholar
Emre, Z, Garmo, G 1985. Plasma thyroxine through parturition and early lactation in goats fed silage of grass and rape. Acta Veterinaria Scandinavica 26, 417418.Google Scholar
Fallah-Rad, AH, Connor, ML 1999. Relationships of thyroid hormones, IGF-I and testosterone in breeds of ram lambs with low and high prolificacies. Canadian Journal of Animal Science 79, 441448.Google Scholar
Federman, DD, Robbins, J, Rall, JE 1958. Effects of methyl testosterone on thyroid function, thyroxine metabolism and thyroxine-binding protein. Journal of Clinical Investigations 37, 10241030.Google Scholar
Firat, A, Ozpinar, A, Serpek, B, Haliloglu, S 2005. Comparisons of serum somatotropin, 3,5,3'-triiodothyronine, thyroxine, total protein and free fatty acid levels in newborn Sakiz lambs separated from or suckling their dams. Annals of Nutrition and Metabolism 49, 8894.Google Scholar
Fisher, DA, Chopra, IJ, Dussault, JH 1972. Extrathyroidal conversion of thyroxine to triiodothyronine in sheep. Endocrinology 91, 11411144.Google Scholar
Follett, BK, Potts, C 1990. Hypothyroidism affects reproductive refractoriness and the seasonal oestrous period in Welsh Mountain ewes. Journal of Endocrinology 127, 103109.Google Scholar
Forhead, AJ, Li, J, Gilmour, RS, Fowden, AL 1998. Control of hepatic insulin-like growth factor II gene expression by thyroid hormones in fetal sheep near term. American Journal of Physiology – Endocrinology and Metabolism 275, E149E156.CrossRefGoogle Scholar
Forhead, AJ, Li, J, Saunders, JC, Dauncey, MJ, Gilmour, RS, Fowden, AL 2000. Control of ovine hepatic growth hormone receptor and insulin-like growth factor I by thyroid hormones in utero. American Journal of Physiology – Endocrinology and Metabolism 278, E1166E1174.Google Scholar
Forhead, AJ, Li, J, Gilmour, RS, Dauncey, MJ, Fowden, AL 2002. Thyroid hormones and the mRNA of the GH receptor and IGFs in skeletal muscle of fetal sheep. American Journal of Physiology – Endocrinology and Metabolism 282, E80E86.Google Scholar
Forhead, AJ, Poore, KR, Mapstone, J, Fowden, AL 2003. Developmental regulation of hepatic and renal gluconeogenic enzymes by thyroid hormones in fetal sheep during late gestation. The Journal of Physiology 548, 941947.Google Scholar
Forhead, AJ, Curtis, K, Kaptein, E, Visser, TJ, Fowden, AL 2006. Developmental control of iodothyronine deiodinases by cortisol in the ovine fetus and placenta near term. Endocrinology 147, 59885994.Google Scholar
Fowden, AL, Mapstone, J, Forhead, AJ 2001. Regulation of glucogenesis by thyroid hormones in fetal sheep during late gestation. Journal of Endocrinology 170, 461469.Google Scholar
Friesema, EC, Jansen, J, Milici, C, Visser, TJ 2005. Thyroid hormone transporters. Vitamins and Hormones 70, 137167.Google Scholar
Galton, VA 2005. The roles of the iodothyronine deiodinases in mammalian development. Thyroid 15, 823834.Google Scholar
Glinoer, D 2001. Pregnancy and iodine. Thyroid 11, 471481.Google Scholar
Greenspan, FS 2001. The thyroid gland. In: Basic and clinical endocrinology, sixth edition (ed. FS Greenspan and DG Gardner), pp. 201272. Lange/McGraw Hill, New York.Google Scholar
Hart, DS 1957. Stimulation of wool growth by thyroxine implantation. New Zealand Journal of Science and Technologies 38, 871880.Google Scholar
Hennemann, G, Docter, R, Friesema, EC, de Jong, M, Krenning, EP, Visser, TJ 2001. Plasma membrane transport of thyroid hormones and its role in thyroid hormone metabolism and bioavailability. Endocrine Reviews 22, 451476.Google Scholar
Hernandez, JA, Hallford, DM, Wells, NH 2003. Ovarian cyclicity in thyroid-suppressed ewes treated with propylthiouracil immediately before onset of seasonal anestrus. Journal of Animal Science 81, 2934.Google Scholar
Hernandez, A, Martinez, ME, Fiering, S, Galton, VA, St Germain, D 2006. Type 3 deiodinase is critical for the maturation and function of the thyroid axis. Journal of Clinical Investigation 116, 476484.Google Scholar
Hiroi, Y, Kim, HH, Ying, H, Furuya, F, Huang, ZH, Simoncini, T, Noma, K, Ueki, K, Nguyen, NH, Scanlan, TS, Moskowitz, MA, Cheng, SY, Liao, JK 2006. Rapid nongenomic actions of thyroid hormone. Proceedings of the National Academy of Sciences of the United States of America 103, 1410414109.Google Scholar
Hoath, SB, Laksmanan, J, Scott, SM, Fisher, DA 1983. Effect of thyroid hormones on epidermal growth factor concentration in neonatal mouse skin. Endocrinology 112, 308314.Google Scholar
Hocquette, JF, Vermorel, M, Bouix, J, Anglaret, Y, Donnat, JP, Leoty, C, Meyer, M, Souchet, R 1992. Effects of cold, wind and rain on energy-expenditure and thermoregulation of ewes from 7 genetic types. Genetics Selection Evolution 24, 147169.Google Scholar
Hynd, PI 1994. Follicular determinants of the length and diameter of wool fibres. 2. Comparison of sheep differing in thyroid hormone status. Australian Journal Agricultural Research 45, 11491157.Google Scholar
Jana, NR, Bhattacharya, S 1994. Binding of thyroid hormone to the goat testicular Leydig cell induces the generation of a proteinaceous factor which stimulates androgen release. Journal of Endocrinology 143, 549556.Google Scholar
Jana, NR, Halder, S, Bhattacharya, S 1996. Thyroid hormone induces a 52 kDa soluble protein in goat testis Leydig cell which stimulates androgen release. Biochimica et Biophysica Acta 1292, 209214.Google Scholar
Jansen, HT, Lubbers, LS, Macchia, E, DeGroot, LJ, Lehman, MN 1997. Thyroid hormone receptor (α) distribution in hamster and sheep brain: colocalization in gonadotropin-releasing hormone and other identified neurons. Endocrinology 138, 50395047.Google Scholar
Kaiser, CA, Goumaz, MO, Burger, AG 1986. In vivo inhibition of the 5′-deiodinase type II in brain cortex and pituitary by reverse triiodothyronine. Endocrinology 119, 762770.Google Scholar
Karsch, FJ, Dahl, GE, Hachigian, TM, Thrun, LA 1995. Involvement of thyroid hormones in seasonal reproduction. Journal of Reproduction and Fertility Supplement 49, 409422.Google Scholar
Khan, JR, Ludri, RS 2002a. Hormone profiles during periparturient period in single and twin fetus bearing goats. Asian-Australasian Journal of Animal Sciences 15, 346351.Google Scholar
Khan, JR, Ludri, RS 2002b. Hormone profile of crossbred goats during the periparturient period. Tropical Animal Health and Production 34, 151162.Google Scholar
Klein, AH, Oddie, TH, Fisher, DA 1978. Effect of parturition on serum iodothyronine concentrations in fetal sheep. Endocrinology 103, 14531457.Google Scholar
Kloren, WRL, Norton, BW, Waters, MJ 1993. Fleece growth in Australian cashmere goats. III. The seasonal patterns of cashmere and hair growth, and association with growth hormone, prolactin and thyroxine in blood. Australian Journal of Agricultural Research 44, 10351050.Google Scholar
Kong, WM, Martin, NM, Smith, KL, Gardiner, JV, Connoley, IP, Stephens, DA, Dhillo, WS, Ghatei, MA, Small, CJ, Bloom, SR 2004. Triiodothyronine stimulates food intake via the hypothalamic ventromedial nucleus independent of changes in energy expenditure. Endocrinology 145, 52525258.Google Scholar
Kohrle, J 1999. Local activation and inactivation of thyroid hormones: the deiodinase family. Molecular and Cellular Endocrinology 151, 103119.Google Scholar
Kohrle, J, Jakob, F, Contempré, B, Dumont, JE 2005. Selenium, the thyroid, and the endocrine system. Endocrine Reviews 26, 944984.Google Scholar
Lee, GJ, Thornberry, KJ, Williams, AJ 2001. The use of thyroxine to reduce average fibre diameter in fleece wool when feed intake is increased. Australian Journal of Experimental Agriculture 41, 611617.Google Scholar
Leshin, LS, Jackson, GL 1987. Effect of photoperiod and morphine on plasma prolactin concentration and thyrotropin-releasing hormone secretion in the ewe. Neuroendocrinology 46, 461467.CrossRefGoogle Scholar
Lincoln, GA, Klandorf, H, Anderson, N 1980. Photoperiodic control of thyroid function and wool and horn growth in rams and the effect of cranial sympathectomy. Endocrinology 107, 15431548.Google Scholar
Lucaroni, A, Todini, L 1989. Thyroid hormones blood concentration during pregnancy, delivery and lactation by the goat. Atti della Società Italiana della Scienze Veterinarie 43, 473477.Google Scholar
Lucaroni, A, Todini, L, Malfatti, A, Debenedetti, A 1989. Thyroid hormones blood level by the goat. Annual and diurnal variations. Effect of different physiological states. In: Atti del XXIV Simposio Internazionale di Zootecnia: Piccoli Ruminanti oggi (ed. GF Greppi and M Corti), pp. 91104. Società Italiana per il Progresso della Zootecnia, Milano.Google Scholar
Maddocks, S, Chandrasekhar, Y, Setchell, BP 1985. Effect on wool growth of thyroxine replacement in thyroidectomized Merino rams. Australian Journal of Biological Science 38, 405410.Google Scholar
Manalu, W, Sumaryadi, MY, Kusumorini, N 1997. Maternal serum concentrations of total triiodothyronine, tetraiodothyronine and cortisol in different status of pregnancy during late pregnancy in Ettawah-cross does. Asian-Australasian Journal of Animal Sciences 10, 385390.CrossRefGoogle Scholar
Maurenbrecher, S, Barrell, GK 2003. Suppression of thyroid gland function and its effects on the breeding season of Coopworth ewes. New Zealand Journal of Agricultural Research 46, 17.Google Scholar
McDonald, BJ, Stocks, DC, Connell, JA, Hoey, WA 1988. Thyroxine concentration in maternal and foetal plasma during pregnancy in Australian feral goats. Journal of Agricultural Science, Cambridge 110, 2530.Google Scholar
McCann, JP, Bergman, EN, Beermann, DH 1992. Dynamic and static phases of severe dietary obesity in sheep: food intakes, endocrinology and carcass and organ chemical-composition. Journal of Nutrition 122, 496505.Google Scholar
Menegatos, J, Goulas, C, Kalogiannis, D 2006. The productivity, ovarian and thyroid activity of ewes in an accelerated lambing system in Greece. Small Ruminant Research 65, 209216.Google Scholar
Merchant, M, Riach, DJ 2002. The effect of plane of nutrition and shearing on the pattern of the moult in Scottish Cashmere goats. Animal Science 74, 177188.Google Scholar
Mitin, V, Mikulec, K, Karadjole, I 1986. Thyroid hormones and insulin concentration in sheep. Veterinarski Arhiv 55, S73S75.Google Scholar
Moreno, M, Lombardi, A, Beneduce, L, Silvestri, E, Pinna, G, Goglia, F, Lanni, A 2002. Are the effects of T-3 on resting metabolic rate in euthyroid rats entirely caused by T-3 itself? Endocrinology 143, 504510.Google Scholar
Morris, ST, McCutcheon, SN, Revell, DK 2000. Birth weight responses to shearing ewes in early to mid gestation. Animal Science 70, 363369.Google Scholar
Mostyn, A, Wilson, V, Dandrea, J, Yakubu, DP, Budge, H, Alves-Guerra, MC, Pecqueur, C, Miroux, B, Symonds, ME, Stephenson, T 2003. Ontogeny and nutritional manipulation of mitochondrial protein abundance in adipose tissue and the lungs of postnatal sheep. British Journal of Nutrition 90, 323328.CrossRefGoogle Scholar
Naqvi, SMK, Rai, AK 1991. Influence of dietary energy-level on sheep for mutton during winter. 2. Effect on cardiorespiratory responses, rectal temperature, some blood metabolites, enzymes and thyroidal hormones. Indian Journal of Animal Sciences 61, 11261131.Google Scholar
Nathanielsz, PW, Silver, M, Comline, RS 1973. Plasma tri-iodothyronine concentration in the foetal and newborn lamb. Journal of Endocrinology 58, 683684.Google Scholar
Nicholls, TJ, Goldsmith, AR, Dawson, A 1988a. Photorefractoriness in birds and comparison with mammals. Physiological Reviews 68, 133176.Google Scholar
Nicholls, TJ, Follett, BK, Goldsmith, AR, Pearson, H 1988b. Possible homologies between photorefractoriness in sheep and birds: the effect of thyroidectomy on the length of the ewe's breeding season. Reproduction Nutrition Development 28, 375385.Google Scholar
Nicol, F, Lefranc, H, Arthur, JR, Trayhurn, P 1994. Characterization and postnatal-development of 5’-deiodinase activity in goat perirenal fat. American Journal of Physiology 267, R144R149.Google Scholar
Okab, AB, Elebanna, IM, Mekkawy, MY, Hassan, GA, Elnouty, FD, Salem, MH 1993. Seasonal-changes in plasma thyroid-hormones, total lipids, cholesterol and serum transaminases during pregnancy and at parturition in barki and rahmani ewes. Indian Journal of Animal Sciences 63, 946951.Google Scholar
Okamoto, R, Leibfritz, D 1997. Adverse effect of reverse triiodothyronine on cellular metabolism as assessed by 1H and 31P NMR spectroscopy. Research in Experimental Medicine 197, 211217.Google Scholar
Parkinson, TJ, Follett, BK 1994. Effect of thyroidectomy upon seasonality in rams. Journal of Reproduction and Fertility 101, 5158.Google Scholar
Parkinson, TJ, Douthwaite, JA, Follett, BK 1995. Responses of prepubertal and mature rams to thyroidectomy. Journal of Reproduction and Fertility 104, 5156.Google Scholar
Peeters, R, Buys, N, Pauwels, T, Kuhn, ER, Decuypere, E, Siau, O, Van Isterdael, J 1989. Relationship between the thyroidal and gonadal axes during the estrus cycle of ewes of different breeds and ages. Reproduction Nutrition Development 29, 237245.Google Scholar
Peeters, R, Buys, N, Vanmontfort, D, van Isterdael, J, Decuypere, E, Kuhn, ER 1992. Preferential release of triiodothyronine following stimulation by thyrotropin or thyrotropin-releasing hormone in sheep of different ages. Journal of Endocrinology 132, 93100.Google Scholar
Puchala, R, Pierzynowski, SG, Sahlu, T 1998. Effects of methionine and hormones on amino acid concentration in the skin of Angora goats. Small Ruminant Research 29, 93102.Google Scholar
Puchala, R, Prieto, I, Banskalieva, V, Goetsch, AL, Lachica, M, Sahlu, T 2001. Effects of bovine somatotropin and thyroid hormone levels, body weight gain, and mohair fiber growth of Angora goats. Journal of Animal Science 79, 29132919.Google Scholar
Rae, MT, Rhind, SM, Miller, DW, Brooks, AN 2002. Maternal undernutrition alters triiodothyronine concentrations and pituitary response to GnRH in fetal sheep. Journal of Endocrinology 173, 449455.Google Scholar
Rhind, S, McMillen, SR 1995. Seasonal changes in systemic hormone profiles and their relationship to patterns of fibre growth and moulting in goats of contrasting genotypes. Australian Journal of Agricultural Research 46, 12731283.CrossRefGoogle Scholar
Rhind, SM, McMillen, SR 1996. Effects of methylthiouracil treatment on the growth and moult of cashmere fibre in goats. Animal Science 62, 513520.Google Scholar
Rhind, SM, Kyle, CE 2004. Skin deiodinase profiles and associated patterns of hair follicle activity in cashmere goats of contrasting genotypes. Australian Journal of Agricultural Research 55, 443448.Google Scholar
Rhind, SM, Bass, J, Doney, JM, Hunter, EA 1991. Effect of litter size on the milk production, blood metabolite profiles and endocrine status of ewes lambing in January and April. Animal Production 53, 7180.Google Scholar
Rhind, SM, McMillen, SR, Duff, E, Hirst, D, Wright, S 1998. Seasonality of meal patterns and hormonal correlates in red deer. Physiology & Behavior 65, 295302.Google Scholar
Rhind, SM, McMillen, SR, Duff, E, Kyle, CE, Wright, S 2000. Effect of long-term feed restriction on seasonal endocrine changes in Soay sheep. Physiology & Behavior 71, 343351.Google Scholar
Rhind, SM, Kyle, CE, Duff, EI 2004. Effects of season and of manipulation of circulating prolactin concentrations on deiodinase activity in cashmere goat skin. Australian Journal of Agricultural Research 55, 211221.Google Scholar
Rhind, SM, Kyle, CE, Riach, DJ, Duff, EI 2006. Effects of nutrition on hormone profiles and patterns od deiodinase activity in the skin and associated patterns of hair follicle activity and moult in cashmere goats. Animal Science 82, 723730.Google Scholar
Riis, PM, Madsen, A 1985. Thyroxine concentration and secretion rates in relation to pregnancy, lactation and energy balance in goats. Journal of Endocrinology 107, 421427.Google Scholar
Ryder, ML 1979. Thyroxine and wool follicle activity. Animal Production 28, 109114.Google Scholar
Ryg, M, Langvatn, R 1982. Seasonal changes in weight gain, growth hormone, and thyroid hormones in male red deer (Cervus elaphus atlanticus). Canadian Journal of Zoology 60, 25772581.Google Scholar
Salem, MH, Elsherbiny, AA, Khalil, MH, Yousef, MK 1991. Diurnal and seasonal rhythm in plasma-cortisol, triiodothyronine and thyronine as affected by the wool coat in barki sheep. Indian Journal of Animal Sciences 61, 946951.Google Scholar
Santini, F, Chopra, IJ, Hurd, RE, Teco, GNC 1992. A study of the characteristics of hepatic iodothyronine 5’-monodeiodinase in various vertebrate species. Endocrinology 131, 830834.Google Scholar
Schermer, SJ, Bird, JA, Lomax, MA, Sheperd, DAL, Symonds, ME 1996. Effect of fetal thyroidectomy on brown adipose tissue and thermoregulation in newborn lambs. Reproduction, Fertility and Development 8, 9951002.Google Scholar
Sensky, PL, Roy, CH, Barnes, RJ, Heath, MF 1994. Changes in fetal thyroid hormone levels in adrenalectomized fetal sheep following continuous cortisol infusion 72 h before delivery. Journal of Endocrinology 140, 7983.Google Scholar
Shetaewi, MM, Ross, TT 1991. Effects of concentrate supplementation and lasalocid on serum chemistry and hormone profiles in Rambouillet ewes. Small Ruminant Research 4, 365377.Google Scholar
Silanikove, N 2000. Effects of heat stress on the welfare of extensively managed domestic ruminants. Livestock Production Science 67, 118.Google Scholar
Silva, JE 2005. Thyroid hormone and the energetic cost of keeping body temperature. Bioscience Reports 25, 129148.Google Scholar
Slebodzinski, A 1972. Acute depletion of the hormonal-iodine stores from the thyroid gland after birth in lambs. Journal of Endocrinology 53, 195200.Google Scholar
Souza, MIL, Bicudo, SD, Uribe-Velasquez, LF, Ramos, AA 2002. Circadian and circannual rhythms of T3 and T4 secretions in Polwarth-Ideal rams. Small Ruminant Research 46, 15.Google Scholar
Starling, JMC, da Silva, RG, Negrao, JA, Maia, ASC, Bueno, AR 2005. Seasonal variation of thyroid hormones and cortisol of sheep in tropical environment. Revista Brasileira de Zootecnia 34, 20642073.Google Scholar
Symonds, ME, Mostyn, A, Pearce, S, Budge, H, Stephenson, T 2003. Endocrine and nutritional regulation of fetal adipose tissue development. Journal of Endocrinology 179, 293299.Google Scholar
Taha, TA, Abdel-Gawad, EI, Ayoub, MA 2000. Monthly variations in some reproductive parameters of Barki and Awassi rams throughout 1 year under subtropical conditions. 1. Semen characteristics and hormonal levels. Animal Science 71, 317324.Google Scholar
Thrun, LA, Dahl, GE, Evans, NP, Karsch, FJ 1996. Time-course of thyroid hormone involvement in the development of anestrus in the ewe. Biology of Reproduction 55, 833837.Google Scholar
Thrun, LA, Dahl, GE, Evans, NP, Karsch, FJ 1997a. A critical period for thyroid hormone action on seasonal changes in reproductive neuroendocrine function in the ewe. Endocrinology 138, 34023409.Google Scholar
Thrun, LA, Dahl, GE, Evans, NP, Karsch, FJ 1997b. Effect of thyroidectomy on maintenance of seasonal reproductive suppression in the ewe. Biology of Reproduction 56, 10351040.Google Scholar
Todini, L, Lucaroni, A, Malfatti, A, Debenedetti, A, Costarelli, S 1992. Male–female differences in the annual profiles of the thyroid hormones blood level by the goat. Atti della Società Italiana della Scienze Veterinarie 46, 169173.Google Scholar
Todini, L, Malfatti, A, Barbato, O, Trabalza-Marinucci, M, Acuti, G, Antonini, M, Debenedetti, A 2005. Plasma thyroid hormones, fibre characteristics and hair follicle activity in angora kids: effects of supplementation with horse bean (Vicia faba minor). Atti della Società Italiana della Scienze Veterinarie 59, 3940.Google Scholar
Todini, L, Delgadillo, JA, Debenedetti, A, Chemineau, P 2006. Plasma total T3 and T4 concentrations in bucks as affected by photoperiod. Small Ruminant Research 65, 813.Google Scholar
Todini, L, Malfatti, A, Valbonesi, A, Trabalza-Marinucci, M, Debenedetti, A 2007. Plasma total T3 and T4 concentrations in goats at different physiological stages, as affected by the energy intake. Small Ruminant Research 68, 285290.Google Scholar
Tucker, HA 1994. Lactation and its hormonal control. In:The physiology of reproduction, second edition (ed. E Knobil and JD Neil), pp. 10651098. Raven Press, New York.Google Scholar
Tucker, HA 2000. Hormones, mammary growth, and lactation: a 41-year perspective. Journal of Dairy Science 83, 874884.Google Scholar
Utiger, RD 1995. The thyroid: physiology, thyrotoxicosis, hypothyroidism, and the painful thyroid. In:Endocrinology and metabolism, third edition (ed. P Felig, JD Baxter and LA Frohman), pp. 435519. McGraw-Hill Inc., New York.Google Scholar
Valtorta, S, Hahn, L, Johnson, HD 1982. Effect of high ambient temperature (35 degrees), and feed intake on plasma T4 levels in sheep. Proceedings of the Society for Experimental Biology and Medicine 169, 260265.Google Scholar
Velasquez, LFU, Souza, MIL, Oba, E, Ramos, AD 1997. Circadian rhythms of plasma triiodothyronine (T-3) and thyroxine (T-4) in ideal ewe sheep during seasonal anoestrus. Revista da Sociedade Brasileira de Zootecnia 26, 508513.Google Scholar
Viguié, C, Battaglia, DF, Krasa, HB, Thrun, LA, Karsch, FJ 1999. Thyroid hormones act primarily within the brain to promote the seasonal inhibition of luteinizing hormone secretion in the ewe. Endocrinology 140, 11111117.Google Scholar
Villar, D, Rhind, SM, Dicks, P, McMillen, SR, Nicol, F, Arthur, JR 1998. Effect of propylthiouracil-induced hypothyroidism on thyroid hormone profiles and tissue deiodinase activity in cashmere goats. Small Ruminant Research 29, 317324.Google Scholar
Villar, D, McMillen, SR, Dicks, P, Rhind, SM 2000a. The roles of thyroid hormones and prolactin in the control of fibre moult and associated changes in hair follicle activities in cashmere goats. Australian Journal of Agricultural Research 51, 407414.Google Scholar
Villar, D, Nicol, F, Arthur, JR, Dicks, P, Cannavan, A, Kennedy, DG, Rhind, SM 2000b. Type II and type III monodeiodinase activities in the skin of untreated and propylthiouracil-treated cashmere goats. Research in Veterinary Science 68, 119123.Google Scholar
Walkden-Brown SW, Davidson RH, Milton JTB and Martin GB. 1996. Thyroidectomy late in the breeding season advances the onset of seasonal anovulation in cashmere goats. Proceedings of the 13th international congress on animal reproduction, Sydney, Australia, P1.19.Google Scholar
Wartofsky, L, Burman, KD 1982. Alterations in thyroid function in patients with systemic illness: the “euthyroid sick syndrome”. Endocrine Reviews 3, 164217.Google Scholar
Webster, JR, Moenter, SM, Woodfill, CJI, Karsh, FJ 1991. Role of the thyroid gland in seasonal reproduction. II. Thyroxine allows a season-specific –suppression of gonadotropin secretion in sheep. Endocrinology 129, 176183.Google Scholar
Wester, TJ, Britton, RA, Klopfenstein, TJ, Ham, GA, Hickok, DT, Krehbiel, CR 1995. Differential effects of plane of protein or energy nutrition on visceral organs and hormones in lambs. Journal of Animal Science 73, 16741688.Google Scholar
Williams, CC, Calmes, KJ, Fernandez, JM, Stanley, CC, Lovejoy, JC, Bateman, HG, Gentry, LR, Gantt, DT, Harding, GD 2004. Glucose metabolism and insulin sensitivity in Gulf Coast native and Suffolk ewes during late gestation and early lactation. Small Ruminant Research 54, 167171.Google Scholar
Wronska-Fortuna, D, Sechman, A, Niezgoda, J, Bobek, S 1993. Modified responses of circulating cortisol, thyroid hormones, and glucose to exogenous corticotropin and thyrotropin-releasing hormone in food-deprived sheep. Pharmacology Biochemistry and Behavior 45, 601606.Google Scholar
Wrutniak-Cabello, C, Casas, F, Cabello, G 2001. Thyroid Hormone action in mitochondria. Journal of Molecular Endocrinology 26, 6777.Google Scholar
Wu, SY, Polk, D, Wong, S, Reviczky, A, Vu, R, Fisher, DA 1992. Thyroxine sulfate is a major thyroid hormone metabolite and a potential intermediate in the monodeiodination pathways in fetal sheep. Endocrinology 131, 17511756.Google Scholar
Wu, SY, Green, WL, Huang, WS, Hays, MT, Chopra, IJ 2005. Alternate pathways of thyroid hormone metabolism. Thyroid 15, 943958.Google Scholar
Wu, SY, Polk, DH, Huang, WS, Green, WL, Thai, B, Fisher, DA 2006. Fetal-to-maternal transfer of thyroid hormone metabolites in late gestation in sheep. Pediatric Research 59, 102106.Google Scholar
Yasuo, S, Nakao, N, Ohkura, S, Iigo, M, Hagiwara, S, Goto, A, Ando, H, Yamamura, T, Watanabe, M, Watanabe, T, Oda, S, Maeda, K, Lincoln, GA, Okamura, H, Ebihara, S, Yoshimura, T 2006. Long-day suppressed expression of type 2 deiodinase gene in the mediobasal hypothalamus of the Saanen goat, a short-day breeder: implications for seasonal window of thyroid hormone action on reproductive neuroendocrine axis. Endocrinology 147, 432440.Google Scholar
Yildiz, A, Balikci, E, Gurdogan, F 2005. Changes in some serum hormonal profiles during pregnancy in single- and twin-foetus-bearing Akkaraman sheep. Medycyna Weterynaryjna 61, 11381141.Google Scholar
Yokus, B, Cakir, DU, Kanay, Z, Gulten, T, Uysal, E 2006. Effects of seasonal and physiological variations on the serum chemistry, vitamins and thyroid hormone concentrations in Sheep. Journal of Veterinary Medicine – Series A 53, 271276.Google Scholar
Zamiri, MJ, Khodaei, HR 2005. Seasonal thyroidal activity and reproductive characteristics of Iranian fat-tailed rams. Animal Reproduction Science 88, 245255.Google Scholar
Zhang, S, Blache, D, Blackberry, MA, Martin, GB 2004. Dynamics of the responses in secretion of luteinizing hormone, leptin and insulin following an acute increase in nutrition in mature male sheep. Reproduction, Fertility and Development 16, 823829.Google Scholar
Figure 0

Figure 1 Schematic representation of the regulation of thyroid gland and thyroid hormones activity.

Figure 1

Table 1 Serum thyroid hormone concentrations (mean ± s.d.) in goats (local Umbrian population) at different ages (data grouped from samplings at different seasons), adapted from Lucaroni et al. (1989)

Figure 2

Table 2 Plasma thyroid hormone concentrations (mean ± s.d.) in 16 adult does and 8 adult bucks (dairy Mediterranean breeds), maintained sex-separated and fed a qualitatively constant diet throughout the year (weekly samplings). Monthly mean, minimal and maximal environmental temperatures are also indicated (adapted from Todini et al. (1992)).

Figure 3

Figure 2 Circannual profiles of mean plasma T3 (3-5-3′-triiodothyronine) and T4 (thyroxine) in 20 female goats (local Umbrian population), mean environmental temperature, daylength and physiological state (modified from Lucaroni et al. (1989)).