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Abnormal carbohydrate metabolism in a canine model for muscular dystrophy

Published online by Cambridge University Press:  23 November 2017

Andressa R. Amaral
Affiliation:
Veterinary Medicine Department, Faculty of Animal Science and Food Engineering (FZEA), São Paulo University (USP), Av. Duque de Caxias Norte, 225, Pirassununga, 13635-900, SP, Brazil
Márcio A. Brunetto
Affiliation:
Animal Nutrition and Production Department, Faculty of Veterinary Medicine and Animal Science (FMVZ), University of São Paulo (USP), Av. Duque de Caxias Norte, 225, Pirassununga, 13635-900, SP, Brazil
Marina P. Brólio
Affiliation:
Surgery Department, Faculty of Veterinary Medicine and Animal Science (FMVZ), University of São Paulo (USP), Av. Prof. Dr Orlando Marques de Paiva, 87, São Paulo, 05508-270, SP, Brazil
Daniela S. Cima
Affiliation:
Veterinary Anesthesiology Department, Guarulhos University, Anton Philips Street, 1, Vila Hermínia, Guarulhos, 07030-010, SP, Brazil
Maria A. Miglino
Affiliation:
Surgery Department, Faculty of Veterinary Medicine and Animal Science (FMVZ), University of São Paulo (USP), Av. Prof. Dr Orlando Marques de Paiva, 87, São Paulo, 05508-270, SP, Brazil
João Paulo F. Santos
Affiliation:
Animal Nutrition and Production Department, Faculty of Veterinary Medicine and Animal Science (FMVZ), University of São Paulo (USP), Av. Duque de Caxias Norte, 225, Pirassununga, 13635-900, SP, Brazil
Carlos E. Ambrósio*
Affiliation:
Veterinary Medicine Department, Faculty of Animal Science and Food Engineering (FZEA), São Paulo University (USP), Av. Duque de Caxias Norte, 225, Pirassununga, 13635-900, SP, Brazil
*
*Corresponding author: C. E. Ambrósio, email [email protected]

Abstract

The canine golden retriever muscular dystrophy (GRMD) model is the best animal model for studying Duchenne muscular dystrophy in humans. Considering the importance of glucose metabolism in the muscles, the existence of metabolic and endocrine alterations in a wide range of muscular dystrophies, and the pre-existing relationship between blood insulin concentration and muscular atrophy, the present study aimed to evaluate the postprandial glucose and insulin response in GRMD dogs. A total of eighteen golden retriever dogs were randomly distributed into three experimental groups: healthy/control (G1), female GRMD carriers (G2), and male dogs affected by GRMD (G3). Higher plasma resting glucose levels (P = 0·0047) were seen in G2 and G3 compared with G1, as was the case for minimum (P = <0·0001), mean (P = 0·0002) and maximum (P = 0·0359) glucose values for G3 compared with G1. Fructosamine concentrations were in accordance with reference values found in the literature for dogs. Insulin levels were lower in G3 compared with G1 (P = 0·0065); however, there was no evidence of insulin resistance according to the homeostasis model assessment index values obtained. As for the evaluation of postprandial responses, fluctuations of glucose (P = 0·0007) and insulin (P = 0·0149) were observed in G1 and G2, while in G3 the values remained constant. The results allowed us to identify metabolic changes related to carbohydrate metabolism in GRMD dogs, highlighting the importance of adequate food management for these animals.

Type
Research Article
Creative Commons
Creative Common License - CCCreative Common License - BY
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Copyright
Copyright © The Author(s) 2017

Duchenne muscular dystrophy (DMD) is the commonest form of muscular dystrophy in humans( Reference Banks and Chamberlaim 1 ) and it is inherited from a recessive X-linked gene, affecting 1 in 3500 newborn males( Reference Ahmad, Welch and Grange 2 ). The disease involves progressive muscle degeneration until death at about 20 years of age, usually caused by cardiorespiratory events( Reference Nardes, Araújo and Ribeiro 3 ). For researching new therapies to improve the quality of life or discover an effective treatment for those affected by this disease, the use of animal models has major importance( Reference Willman, Possekel and Dubach-Powell 4 ).

There are many animal models for studying DMD, among them, the MDX mouse and the golden retriever muscular dystrophy (GRMD) dog; however, the GRMD dog is the most appropriate( Reference Gerger, Souza and Martins 5 ) because, like in humans, it is a spontaneously occurring disease that progressively causes degeneration of muscle fibres( Reference Valentine, Winan and Pradhan 6 ).

Additionally, adult GRMD dogs show phenotypic characteristics similar to boys affected by DMD, such as decreased body weight and muscle quantity( Reference Howell, Fletcher and Kakulas 7 ), differently from the mice, where the phenotype is different from the human phenotype of the same disease( Reference Vainzof, Ayub-Guerrieri and Onofre 8 ).

Muscle atrophy is frequently observed in patients with insulin deficiency, which leads to decreased rate of protein synthesis in skeletal muscle( Reference Santos, Suzuki and Anjos 9 , Reference Wang, Hu and Hu 10 ). Skeletal muscle is also responsible for approximately 40 % of the total body mass and plays a major role in energy balance, since it stimulates the uptake, disposal and storage of glucose( Reference Smith and Muscat 11 ).

Glucose is the main energy source for cells, which may be obtained directly from the food or converted from other metabolites through gluconeogenesis( Reference Guyton 12 ). In single-stomached animals like dogs, dietary starches are hydrolysed enzymically in the gastrointestinal tract and the resulting glucose is absorbed and transported to the liver where the processes of glycolysis (postprandial conditions) or gluconeogenesis (fasting conditions) occur. The metabolic activities of this tissue, along with the hormonal signalling of glucagon and insulin released by α and β cells of pancreas, respectively, effectively regulate blood glucose homeostasis( Reference Beitz and Reece 13 ).

The values of plasma glucose concentrations are used as indicators of carbohydrate metabolism and reflect the balance between glucose production and uptake( Reference Colville and Hendrix 14 ). Fructosamine is a glycated plasma protein that can be used as a carbohydrate metabolism indicator since it reflects the glycaemic behaviour beyond that observed by plasma glucose at the time of collection( Reference Reusch, Liehs and Hoyer 15 ).

Insulin is a multifunctional hormone. It is related to the anabolic and anticatabolic processes in mammals( Reference González-Sánchez and Serrano-Rios 16 ) and plays two other important functions: stimulation of carbohydrate and lipid metabolism for induction of cellular enzymes, especially in hepatocytes, and transportation of glucose across plasma membranes of insulin-sensitive cells, mainly in fat cells and skeletal muscle.

The homeostasis model assessment (HOMA) index, a widely used tool in human medicine as an indicator of insulin sensitivity, can properly reflect how animals metabolise their diet. Evaluating the results obtained by this index enables possible correction of food management for these animals. Previous studies in dogs have already used the same methodology( Reference Serisier, Leray and Poudroux 17 Reference Verkest, Fleeman and Morton 20 ) and formed the basis for the interpretation of these results.

Considering the importance of body musculature on glucose metabolism and the existence of metabolic and endocrine alteration in some muscular dystrophies, the present study aimed to evaluate parameters related to carbohydrate metabolism in golden retriever dogs that are carriers or affected by GRMD, since information in the literature is currently unavailable.

Experimental methods

All procedures were approved by the Ethics and Animal Welfare Committee (protocol no. 13.1.1505.74.7) of the College of Animal Science and Food Engineering, University of São Paulo.

Animals and experimental design

The study was performed at a kennel located at the Department of Anatomy of Domestic and Wild Animals of the College of Veterinary Medicine and Animal Science at the University of São Paulo.

The dogs were chosen according to the kennel availability and randomised into three experimental groups: healthy/control (G1), carrier GRMD females (G2) and dogs affected by GRMD (G3), totalling six animals per experimental group.

The affected and carrier animals underwent a periodic clinical evaluation every 15 d and were weighed once per week. The groups of carrier females and controls presented ideal body condition score (4 or 5) whereas affected dog scores were under or equal to 4, according to Laflamme( Reference Laflamme 21 ).

The classification of the GRMD carriers or affected animals was confirmed by performing biochemical, immunohistochemical and molecular diagnostic methods, which consisted of detecting a high concentration of the creatine kinase isoenzyme and a lack of dystrophin protein( Reference Kornegay, Bogan and Bogan 22 , Reference Prior and Bridgeman 23 ) at the moment of birth by collecting blood samples from the umbilical cord. The tests were repeated for confirmation after 30 d.

Diet

During the study, all animals received the same commercial dry diet (Royal Canin Medium Junior; Royal Canin Brazil), and were allowed 7 d for adaptation to the diet before the start of data collection. The amount of food offered to each animal was calculated according to National Research Council( 24 ) recommendations, using the equation: 95 × (body weight)0·75 = kcal/d (397 × (body weight)0·75 = kJ/d). The food was ground and hydrated with warm water and offered as a paste for all animals as a way to standardise the management employed for the affected animals due to their difficulty in seizing and swallowing.

Postprandial response test

These tests were performed after 12 h of fasting and each dog was aseptically catheterised using a peripheral intravenous catheter (Becton Dickson). Blood samples were taken before feeding (baseline sample, time 0) and 5, 10, 15, 30, 60, 120, 180, 240, 300 and 360 min after feeding according to Carciofi et al. ( Reference Carciofi, Takakura and Oliveira 25 ) and Brunetto et al. ( Reference Brunetto, Sá and Nogueira 26 ). Samples destined for glucose analysis were collected in fluoridated EDTA tubes, and samples for fructosamine and insulin analysis were collected in tubes without anticoagulant. Fructosamine was analysed only at time 0. All samples were immediately centrifuged and frozen until use.

Laboratory analysis

Plasma glucose concentrations were determined by the glucose oxidase test (Glucose assay; Randox Laboratories Ltd), using semi-automatic glucose equipment (Randox Laboratories Ltd). Plasma fructosamine concentrations were determined by the kinetic method of fixed time (Frutosamina test; Labtest Diagnóstica S.A.) in the Multiuser Laboratory of the College of Veterinary Clinics of Food Engineering and Animal Science at the University of São Paulo. Insulin analysis was performed using human insulin containing 125I as a tracer hormone and 100 % of specificity for canine insulin (Human Insulin Specific; Millipore Corporation) at Genese laboratory (São Paulo, Brazil).

Calculations and statistical analysis

The glucose increments were calculated by subtracting the baseline value for each animal from the values obtained during the 360 min of collections. The AUC were calculated for the glucose concentrations in the total range, which represents the 360 min of collections, and also for the following ranges: 0 to 60 min (AUC 0–60); from 0 to 120 min (AUC 0–120); from 0 to 240 min (AUC 0–240); from 60 to 120 min (AUC 60–120); from 60 to 240 min (AUC 60–240), and 60 to 360 min (AUC 60–360) after food consumption. Those areas were calculated using the mean blood glucose values at each time for all animals in each group, and AUC were obtained for G1, G2 and G3 by the trapezoidal numerical integration method. The results were analysed using GraphPad Prism (GraphPad Software)( 27 ). Evaluation of insulin sensitivity was calculated by the HOMA (homeostasis model assessment) index which takes into account the paired basal insulin with basal glucose levels, according to the equation: HOMA score = (basal serum insulin (mU/l) × (basal plasma glucose (mg/dl))/405 ((basal serum insulin (mU/l) × (basal plasma glucose (mmol/l))/22·5)( Reference Xenoulis 19 ), and animals are considered insulin resistant for HOMA values higher than 2·4.

The obtained results were analysed by Statistical Analysis System software (SAS Institute Inc.)( 28 ), and were previously checked for normality of residues by the Shapiro–Wilk test and the variances were compared by an F test. Basal, minimum, mean and maximum glucose, basal insulin and fructosamine, HOMA index and ages were analysed using PROC GLM and experimental groups were compared by a Tukey test. For assessing postprandial response, statistical analyses were conducted in PROC MIXED with the definition of the matrices used based on the value of the Akaike information criterion, considering effects of group, time and interaction between groups and time as fixed effects and animal within the group as a random effect. The significance level was set at P < 0·05.

Results

It was observed that plasma glucose concentrations at baseline (P = 0·0047), minimum (P < 0·0001), and mean (P = 0·0002) were higher in G2 and G3 than G1. Similarly, maximum glucose concentrations (P = 0·0359) in G3 were higher than those in G1. Baseline insulin concentrations presented an opposite trend, with G3 having reduced insulin concentrations compared with G1 (P = 0·0065). The HOMA index (P = 0·0298) was different between groups, with higher values in G1, and the fructosamine (P = 0·0160) was different only between G2 and G3, as presented in Table 1.

Table 1. Basal glucose, basal insulin, baseline fructosamine, homeostasis model assessment (HOMA) index, minimum glucose, mean blood glucose of all collection times and glucose maximum of the three experimental groups

(Mean values with their standard errors)

G1, healthy/control group; G2, carrier females; G3, affected dogs.

a,b Mean values within a row with unlike superscript letters were significantly different (P < 0·05; Tukey's test and ANOVA).

* To convert glucose in mg/dl to mmol/l, multiply by 0·0555.

† To convert insulin in μU/ml to pmol/l, multiply by 6·945.

‡ Mean blood glucose of all collection times.

With regards to postprandial glucose responses, an interaction was observed between time of collection and the experimental groups on the glycaemic curve (P = 0·0007), with fluctuations over time in G1 (5-min difference between 60, 120, 180 and 360 min, and 10-min difference between 180 and 360 min) and in minor proportions on G2 (10-min difference in 300 min). A similar behaviour was observed on glucose increment analysis (P = 0·0006). When glycaemic curves of the experimental groups were compared over time, higher glucose concentrations were observed in G3 than those in G1 at 5, 10 and 15 min (Fig. 1(a) and Table 1).

Fig. 1. Values of blood glucose (a), insulin (c) and their respective increments (b, d) obtained by postprandial response tests of the healthy/control group (), carrier females () and affected dogs (). Values are means with their standard errors represented by vertical bars. * Mean value was significantly different from those of control and carrier dogs (P < 0·05; Tukey's test and ANOVA). To convert glucose in mg/dl to mmol/l, multiply by 0·0555. To convert insulin in μU/ml to pmol/l, multiply by 6·945.

In relation to postprandial insulin responses, an interaction was observed between time and experimental group (P = 0·0149), with similar results of glucose: fluctuations of insulin concentration were seen in G1 (5-min difference in 60 and 120 min) and G2 (baseline difference from 5, 30 and 360 min), but no difference was seen over time for G3 dogs. The insulin increment also differed over time in G1 and G2, but remained constant in G3 (P = 0·0073). The insulinaemic curves of the experimental groups did not differ, whereas the insulin increment values observed in G2 were higher than those in G3 at 360 min (Fig. 1(c) and (d); Table 1).

Finally, in respect to age, no difference was found between G1 and G3 (P = 0·1431) and G1 v. G2 (P = 0·22). However, age was different between G2 and G3 animals (P = 0·0262).

Discussion

GRMD dogs and carrier females presented higher basal plasma glucose concentrations compared with dogs in the control group, as well as minimum, average and maximum glucose levels. Following these results, regarding GRMD dogs, the observed higher plasma fructosamine values collaborate with the conclusion that this specific glycaemic behaviour represents not only the moment of collection, but apparently a recurrent behaviour. Nevertheless, all values remained within the reference range of normality (225–365 µmol/l) described by Nelson( Reference Nelson, Feldman, Nelson, Reush and Scott-Moncrieff 29 ).

Many factors( Reference De Pirro, Fusco and Bertoli 30 Reference Prince, Tsai and Olefsky 36 ) may induce variations in insulin binding. In DMD patients, we found no relationship in the literature between insulin binding and serum insulin, steroid (sexual or adrenal) or creatine phosphokinase levels; furthermore, we found no circulating antibodies, such as insulin or receptor antibodies, to explain the reduced receptor concentration( Reference Flier, Kahn and Roth 33 ). Thus, the cause of the impairment remains obscure. One possibility is that decreased receptor number is influenced by genetics( Reference Kahn and Podskalny 35 ).

Freidenberg & Olefsky( Reference Freidenberg and Olefsky 37 ) conducted oral glucose tolerance tests and insulin binding studies on erythrocytes from seventeen DMD and eight normal human males. Furthermore, they measured insulin binding to erythrocytes from twelve normal males and from eleven mothers and ten sisters of affected males. DMD patients had mild glucose intolerance and both fasting and postabsorptive marked hyperinsulinaemia (insulin resistance). Levels of glucose and insulin, expressed as incremental areas under their respective curves, were significantly elevated in the wheelchair-ridden patients. All of the ambulatory DMD males had normal oral glucose tolerance test results. Insulin binding to erythrocytes was 20–30 % lower in all DMD human patients than in normal males appropriately matched for age and degree of sexual development. This difference in binding was a result of lower affinity for the insulin receptor in DMD erythrocytes. On the contrary, insulin binding to fibroblasts was the same in normal males and DMD patients, suggesting that the abnormality of erythrocyte binding in DMD is probably not genetically induced.

Letellier et al. ( Reference Letellier, Mok and Alberti 38 ) concluded that fasting insulin concentration and HOMA might provide quantifiable indices of disease progression. Rodríguez-Cruz et al. ( Reference Rodríguez-Cruz, Sanchez and Escobar 39 ) observed significant differences in insulin concentrations and HOMA-insulin resistance (IR) values among nutritional status groups, but no differences in age were detected. Overweight/obese boys presented higher glucose, insulin and HOMA-IR values compared with boys with normal BMI. Interestingly, an important percentage of underweight patients presented hyperinsulinaemia and IR (27·3 %). Body fat mass was higher in overweight/obese patients and lower in underweight patients than in patients with normal nutritional status. Both fasting insulin and HOMA-IR were positively correlated with all anthropometric and body composition parameters. However, the highest correlation was found between HOMA-IR and body fat mass.

Some hypotheses have been raised by some authors. Insulin is a powerful inhibitor of fat lysis and its deficiency is accompanied by lipolysis( Reference Cheville 40 ). Importantly, the GRMD dogs show less deposition of body fat in addition to their muscular phenotypes. This can be explained partially by the decreased insulin concentrations in affected GRMD dogs, whereas another study from our research group found no differences in digestibility of nutrients in these animals( Reference Brólio 41 ). The insulin receptors are located in the target cells of tissues such as liver, adipose tissue, and muscle cell membranes( Reference Watanabe and Hayasaki 42 ). Some authors reported that muscle cell membranes from individuals affected by muscular dystrophy show progressive degeneration( Reference Kornegay, Bogan and Bogan 22 ) followed by replacement by fibrous and fat tissue( Reference Kornegay, Childers and Bogan 43 ). It could be interesting to investigate if those changes in the plasma membranes of the myocytes could possibly lead to a decreased number of insulin receptors and, therefore, alter carbohydrate metabolism.

In this study, minimum serum concentrations of insulin were observed, which may have more relevance for the hepatocytes compared with glucagon. A decline in the insulin:glucagon ratio can induce increased gluconeogenesis and ketogenic capacity of hepatocytes( Reference Cheville 40 , Reference Wolfsheimer 44 , Reference Nelson, Couto, Nelson, Couto, Grauer, Johnson, Hawkins, Lappin, Scott-Moncrieff, Taylor, Ware, Watson and Willard 45 ). The activation of gluconeogenesis is disadvantageous since it requires consumption of amino acids that could have been used for tissue synthesis and cell renovation. Instead, these are redirected to the formation of glucose and energy production; consequently, synthesis of this tissue is impaired, which can further aggravate the loss of muscle mass in animals that already have a reduced amount of this tissue.

In this respect, Grando et al. ( Reference Grando, Mariana and Miglino 46 ) reported hepatomegaly associated with fatty infiltration after conducting ultrasounds on the abdominal region of dogs affected by GRMD. The authors attributed these findings to excess metabolites derived from the catabolism of skeletal muscle. The results of our study may partially explain the findings reported by these authors. The reduced production of insulin and metabolic adaptations exhibited by these animals for maintenance of glucose homeostasis can partially explain the muscle catabolism, fatty infiltration and increased liver size. Note that this information has not been previously reported in the literature. Combining the results obtained by the present study and previous studies, we can hypothesise that there is fatty infiltration of the liver as a compensatory response to low insulin secretion. Possibly, the GMRD dogs may have increased protein turnover due to higher accumulation of fatty acids in the liver by activation of lipolysis and also by increased gluconeogenesis.

Regarding age, according to the National Research Council( 24 ), there is no consensus about the influence of this parameter on carbohydrate metabolism. Strasser et al. ( Reference Strasser, Niedermuller and Hofecker 47 ) have already described a lower glucose tolerance resulting from lower tissue insulin responsiveness in geriatric compared with young adult dogs. However, Lowseth et al. ( Reference Lowseth, Gillett and Gerlach 48 ) found no significant changes in blood glucose concentrations in beagle dogs aged 3 to 14 years.

At the same time, still according to the National Research Council( 24 ), geriatric dogs are considered to be, at least, 7 years old for medium breeds. In our study, the maximum age of affected dogs was 6 years old (only two dogs), which means that concerns related to variations of metabolism between G2 and G3 (where there is difference between ages) do not apply to the present experiment.

Nishio et al. ( Reference Nishio, Wada and Matsuo 49 ) observed in a correlational study that glucose concentration decreased with age and decrease in creatine kinase activity, i.e. with the progress of DMD. The NEFA and ketone body concentrations increased with decreasing glucose concentration.

The authors explain that muscle degeneration may result in depletion of substrates for gluconeogenesis. In the present study, however, the affected animals presented higher values of glucose compared with carriers and control animals. It is important to remember that the children studied by Nishio et al.(49) were, in the majority, wheelchair-ridden and only two of them were able to walk with difficulty while our dogs, in the majority (four individuals), were still able to walk with difficulty. This difference in the ability to perform muscle activity and progression of disease may justify such variations.

All animals in this study showed normal HOMA index values according to the study of Xenoulis( Reference Xenoulis 19 ). Therefore, insulin resistance was not detected in any of the groups.

Conclusion

In conclusion, GRMD animals have changes in carbohydrate metabolism, with lower basal insulin and higher glucose in plasma compared with carriers and control animals, but do not show insulin resistance.

Acknowledgements

We acknowledge the São Paulo Research Foundation (FAPESP; grant no. 2013/01191-4) for financial support.

A. R. A., M. A. B. and M. P. B. conceived the present study and drafted the manuscript. Moreover, A. R. A. was responsible for the collection of data and handling the animals. M. A. M. is the owner of the research kennel, and J. P. F. S. was responsible for statistical analysis. D. S. C., M. P. B. and C. E. A. contributed to the execution of the present study and C. E. A. was the principal investigator of the group. All authors contributed to critical revision of the manuscript.

References

1. Banks, GB & Chamberlaim, JS (2008) The value of mammalian models for Duchenne muscular dystrophy in developing therapeutic strategies. Curr Top Dev Biol 84, 431453.Google Scholar
2. Ahmad, N, Welch, I, Grange, R, et al. (2011) Use of imaging biomarkers to assess perfusion and glucose metabolism in the skeletal muscle of dystrophic mice. BMC Musculoskelet Disord 12, 127.Google Scholar
3. Nardes, F, Araújo, APQC & Ribeiro, MG (2012) Mental retardation in Duchenne muscular dystrophy. J Pediatr 88, 616.CrossRefGoogle ScholarPubMed
4. Willman, R, Possekel, S, Dubach-Powell, J, et al. (2009) Mammalian animal models for Duchenne muscular dystrophy. Neuromuscul Disord 19, 241249.Google Scholar
5. Gerger, AAC, Souza, CC, Martins, DS, et al. (2010) Alterações do trato digestório de cães da raça golden retriever afetados pela distrofia muscular (Changes in the digestive tract of golden retriever dogs affected by muscular dystrophy). Pesq Vet Bras 30, 10641070.CrossRefGoogle Scholar
6. Valentine, BA, Winan, NJ, Pradhan, D, et al. (1992) Canine X-linked muscular dystrophy as an animal model of Duchenne muscular dystrophy: a review. Am J Med Genet 42, 352356.Google Scholar
7. Howell, JM, Fletcher, S, Kakulas, BA, et al. (1997) Use of the dog model for Duchenne muscular dystrophy in gene therapy trials. Neuromuscul Disord 7, 325328.Google Scholar
8. Vainzof, M, Ayub-Guerrieri, D, Onofre, PC, et al. (2008) Animal models for genetic neuromuscular diseases. J Mol Neurosci 34, 241248.CrossRefGoogle ScholarPubMed
9. Santos, AMC, Suzuki, A, Anjos, JS, et al. (2012) Indução de diabetes tipo 2 por dieta hiperlipídica e baixa dose de estr lipídica e baixa dose de estreptozotocina em ratas Wistar (Induction of type 2 diabetes by hyperlipidic diet and low dose of lipid and low dose of streptozotocin in Wistar rats). Medicina (Ribeirão Preto) 45, 436444.CrossRefGoogle Scholar
10. Wang, X, Hu, Z, Hu, J, et al. (2006) Insulin resistance accelerates muscle protein degradation: activation of the ubiquitin–proteasome pathway by defects in muscle cell signaling. Endocrinology 147, 41604168.CrossRefGoogle ScholarPubMed
11. Smith, AG & Muscat, GEO (2005) Skeletal muscle and nuclear hormone receptors: implications for cardiovascular and metabolic disease. Int J Biochem Cell Biol 37, 20472063.Google Scholar
12. Guyton, AC (editor) (1988) Textbook of Medical Physiology. Philadelphia, PA: W.B. Saunders.Google Scholar
13. Beitz, D (2006) Carbohydrate metabolism. In Duke's Physiology of Domestic Animals, 12th ed., pp. 462465 [Reece, WO, editor]. Rio de Janeiro: Guanabara Koogan S.A.Google Scholar
14. Colville, J (2006) Blood biochemistry. In Laboratory Procedures for Veterinary Technicians, 4th ed., p. 97 [Hendrix, CM, editor]. São Paulo: Roca.Google Scholar
15. Reusch, CE, Liehs, MR, Hoyer, M, et al. (1993) Fructosamine: a new parameter for diagnosis and metabolic control in diabetic dogs and cats. J Vet Intern Med 7, 177182.Google Scholar
16. González-Sánchez, JL & Serrano-Rios, M (2007) Molecular basis of insulin action. Drug News Perspect 20, 527531.Google ScholarPubMed
17. Serisier, S, Leray, V, Poudroux, W, et al. (2008) Effects of green tea on insulin sensitivity, lipid profile and expression of PPARα and PPARγ and their target genes in obese dogs. Br J Nutr 99, 12081216.Google Scholar
18. Verkest, KR, Fleeman, LM, Rand, JS, et al. (2010) Basal measures of insulin sensitivity and insulin secretion and simplified glucose tolerance tests in dogs. Domest Anim Endocrinol 39, 194204.Google Scholar
19. Xenoulis, PG (2011) Association of hypertriglyceridemia with insulin resistance in healthy miniature schnauzers. J Am Vet Med Assoc 238, 10111016.Google Scholar
20. Verkest, KR, Fleeman, LM, Morton, JM, et al. (2011) Compensation for obesity-induced insulin resistance in dogs: assessment of the effects of leptin, adiponectin, and glucagon-like peptide-1 using path analysis. Domest Anim Endocrinol 2011, 2434.Google Scholar
21. Laflamme, DP (1997) Development and validation of a body condition score system for dogs: a clinical tool. Canine Pract 22, 1015.Google Scholar
22. Kornegay, JN, Bogan, DJ, Bogan, JR, et al. (1999) Contraction force by tarsal joint flexion and extension in dogs with golden retriever muscular dystrophy. J Neurol Sci 166, 115121.Google Scholar
23. Prior, TW & Bridgeman, SJ (2005) Experience and strategy for the molecular testing of Duchenne muscular dystrophy. J Molec Diag 7, 317326.Google Scholar
24. National Research Council (2006) Nutrient Requirements of Dogs. Washington, DC: National Academies Press.Google Scholar
25. Carciofi, AC, Takakura, FS, Oliveira, LD, et al. (2008) Effects of six carbohydrate sources on dog diet digestibility and post-prandial glucose and insulin response. J Anim Physiol Anim Nutr 92, 326336.CrossRefGoogle ScholarPubMed
26. Brunetto, MA, , FC, Nogueira, SP, et al. (2011) The intravenous glucose tolerance and postprandial glucose tests may present different responses in the evaluation of obese dogs. Br J Nutr 106, Suppl. 1, S194S197.Google Scholar
27. GraphPad Software (2007) GraphPad Prism. Version 5.00 for Windows. San Diego, CA: GraphPad Software.Google Scholar
28. SAS Institute (2002–2008) SAS/STAT: User's Guide. Version 9.2. Cary, NC: SAS Institute Inc.Google Scholar
29. Nelson, RW (2015) Canine diabetes mellitus. In Canine and Feline Endocrinology, 4th ed., p. 234 [Feldman, EC, Nelson, RW, Reush, CE and Scott-Moncrieff, JCR, editors]. St Louis, MO: Elsevier Saunders.Google Scholar
30. De Pirro, R, Fusco, A, Bertoli, A, et al. (1978) Insulin receptors during the menstrual cycle in normal women. Endocrinol Metab 47, 13871389.Google Scholar
31. Bertoli, A, de Pirro, R, Fusco, A, et al. (1980) Differences in insulin receptors between men and menstruating women and influence of sex hormones on insulin binding during the menstrual cycle. J Clin Endocrinol Metab 50, 246250.Google Scholar
32. Andreani, D, de Pirro, R, Lauro, R, et al. (1982) Current Views on Insulin Receptors. London: Academic Press.Google Scholar
33. Flier, JS, Kahn, CR, Roth, J, et al. (1975) Antibodies that impair insulin receptor binding in an unusual diabetic syndrome with severe insulin resistance. Science 190, 6365.CrossRefGoogle Scholar
34. de Pirro, R, Fusco, A, Spallone, L, et al. (1980) Insulin antibodies prevent insulin-receptor interactions. Diabetologia 19, 118122.CrossRefGoogle ScholarPubMed
35. Kahn, CR & Podskalny, JM (1980) Demonstration of a primary (? genetic) defect in insulin receptors in fibroblasts from a patient with the syndrome of insulin resistance and acanthosis nigricans type A. J Clin Endocrinol Metab 50, 11391141.CrossRefGoogle ScholarPubMed
36. Prince, MJ, Tsai, P & Olefsky, JM (1981) Insulin binding, internalization, and insulin receptor regulation in fibroblasts from type II, non-insulin-dependent diabetic subjects. Diabetes 30, 596600.CrossRefGoogle ScholarPubMed
37. Freidenberg, GR & Olefsky, JM (2013) Dissociation of insulin resistance and decreased insulin receptor binding in Duchenne muscular dystrophy. J Clin Endocrinol Metab 60, 320327.Google Scholar
38. Letellier, G, Mok, E, Alberti, C, et al. (2013) Effect of glutamine on glucose metabolism in children with Duchenne muscular dystrophy. Clin Nutr 32, 386390.Google Scholar
39. Rodríguez-Cruz, M, Sanchez, R, Escobar, RE, et al. (2015) Evidence of insulin resistance and other metabolic alterations in boys with Duchenne or Becker muscular dystrophy. Int J Endocrinol 2015, 867273.Google Scholar
40. Cheville, NF (2006) Metabolic and nutritional diseases. In Introduction to Veterinary Pathology, 3rd ed., pp. 370393. Ames, IA: Blackwell Publishing.Google Scholar
41. Brólio, MP (2012) Morfofisiologia e imagologia do comportamento das fibra musculares lisas no modelo canino GRMD (golden retriever muscular dystrophy) (Morphology and imagery of smooth muscle fibre behaviour in the canine GRMD (golden retriever muscular dystrophy) model). PhD Thesis, São Paulo University.Google Scholar
42. Watanabe, M & Hayasaki, H (1998) Histologic distribution of insulin and glucagon receptors. Braz J Med Biol Res 31, 243256.Google Scholar
43. Kornegay, JN, Childers, MK, Bogan, DJ, et al. (2012) The paradox of muscle hypertrophy in muscular dystrophy. Phys Med Rehabil Clin N Am 23, 149172.Google Scholar
44. Wolfsheimer, KJ (1991) Insulin therapy in dogs and cats. Canine Pract 16, 612.Google Scholar
45. Nelson, RW & Couto, CG (2010) Disorders of the endocrine pancreas. In Small Animal Internal Medicine, 4th ed., pp. 765811 [Nelson, RW, Couto, CG, Grauer, GR, Johnson, CA, Hawkins, EC, Lappin, MR, Scott-Moncrieff, JCR, Taylor, SM, Ware, WA, Watson, MA and Willard, MD editors]. Philadelphia, PA: WB Saunders Co. Google Scholar
46. Grando, AP, Mariana, ANB, Miglino, MA, et al. (2009) Ultra-sonografia abdominal e pélvica em cães da raça golden retriever sadios, portadores e afetados pela distrofia muscular progressive (Abdominal and pelvic ultrasound in healthy golden retriever dogs, carriers and affected by progressive muscular dystrophy). Cienc Rural 39, 123128.Google Scholar
47. Strasser, A, Niedermuller, H, Hofecker, G, et al. (1993) The effect of aging on laboratory values in dogs. Zentralbl Veterinarmed A 40, 720730.Google Scholar
48. Lowseth, LA, Gillett, NA, Gerlach, RF, et al. (1990) The effects of aging on hematology and serum chemistry values in the beagle dog. Vet Clin Pathol 19, 1319.Google Scholar
49. Nishio, H, Wada, H & Matsuo, T (1990) Glucose, free fatty acid and ketone body metabolism in Duchenne muscular dystrophy. Brain Dev 12, 390402.Google Scholar
Figure 0

Table 1. Basal glucose, basal insulin, baseline fructosamine, homeostasis model assessment (HOMA) index, minimum glucose, mean blood glucose of all collection times and glucose maximum of the three experimental groups(Mean values with their standard errors)

Figure 1

Fig. 1. Values of blood glucose (a), insulin (c) and their respective increments (b, d) obtained by postprandial response tests of the healthy/control group (), carrier females () and affected dogs (). Values are means with their standard errors represented by vertical bars. * Mean value was significantly different from those of control and carrier dogs (P < 0·05; Tukey's test and ANOVA). To convert glucose in mg/dl to mmol/l, multiply by 0·0555. To convert insulin in μU/ml to pmol/l, multiply by 6·945.