Review Article
Sweet fish: Fish models for the study of hyperglycemia and diabetes
可爱的鱼儿:研究高血糖和糖尿病的鱼类模型
Jaya Krishnan,
Nicolas Rohner,
Jaya Krishnan
Stowers Institute for Medical Research, Kansas City, Missouri, USA
Search for more papers by this authorCorresponding Author
Nicolas Rohner
Stowers Institute for Medical Research, Kansas City, Missouri, USA
Department of Molecular and Integrative Physiology, KU Medical Center, Kansas City, Missouri, USA
Correspondence
Nicolas Rohner, Stowers Institute for Medical Research, 1000 E 50th Street, Kansas City, MO 64110, USA.
Tel: +1 816 926 4151
Fax: +1 816 926 2000
Email: [email protected]
Search for more papers by this authorJaya Krishnan,
Nicolas Rohner,
Jaya Krishnan
Stowers Institute for Medical Research, Kansas City, Missouri, USA
Search for more papers by this authorCorresponding Author
Nicolas Rohner
Stowers Institute for Medical Research, Kansas City, Missouri, USA
Department of Molecular and Integrative Physiology, KU Medical Center, Kansas City, Missouri, USA
Correspondence
Nicolas Rohner, Stowers Institute for Medical Research, 1000 E 50th Street, Kansas City, MO 64110, USA.
Tel: +1 816 926 4151
Fax: +1 816 926 2000
Email: [email protected]
Search for more papers by this authorAbstract
enFish are good for your health in more ways than you may expect. For one, eating fish is a common dietary recommendation for a healthy diet. However, fish have much more to provide than omega-3 fatty acids to your circulatory system. Some fish species now serve as important and innovative model systems for diabetes research, providing novel and unique advantages compared with classical research models. Not surprisingly, the largest share of diabetes research in fish occurs in the laboratory workhorse among fish, the zebrafish (Danio rerio). Established as a genetic model system to study development, these small cyprinid fish have eventually conquered almost every scientific discipline and, over the past decade, have emerged as an important model system for metabolic diseases, including diabetes mellitus. In this review we highlight the practicability of using zebrafish to study diabetes and hyperglycemia, and summarize some of the recent research and breakthroughs made using this model. Equally exciting is the appearance of another emerging discipline, one that is taking advantage of evolution by studying cases of naturally occurring insulin resistance in fish species. We briefly discuss two such models in this review, namely the rainbow trout (Oncorhynchus mykiss) and the cavefish (Astyanax mexicanus).
Abstract
zh鱼对健康的好处要远大于你所能够想象到的。举例来说,健康饮食通常都会推荐吃鱼。然而,鱼类除了对循环系统提供ω-3脂肪酸外,还有更多的营养价值。一些鱼类目前已经成为糖尿病研究重要的创新模型系统,与经典的研究模型相比具有新颖且独特的优势。在以鱼类为主的糖尿病研究实验室中,所占份额最大的是斑马鱼(Danio rerio),这并不令人意外。这些小小的鲤科鱼类作为研究发育的遗传模型系统而建立,最终几乎所有的科学学科都在采用这个模型,并且在过去的10年间已经成为包括糖尿病在内的代谢性疾病的重要模型系统。在这篇综述中我们重点描述了利用斑马鱼来研究糖尿病与高血糖的实用性,并且总结了近年来使用该模型的一些研究以及所取得的突破。同样令人兴奋的是一个新兴的学科出现了,亦即利用鱼类容易进化的优点来研究体内自然产生的胰岛素抵抗病例。在这篇综述中我们简要讨论了这样的两种模型,亦即虹鳟鱼(Oncorhynchus mykiss)与洞穴鱼(Astyanax mexicanus)。
Conflicts of interest
The authors have no conflicts of interest to declare.
References
- 1Cerf ME. Beta cell dysfunction and insulin resistance. Front Endocrinol (Lausanne). 2013; 4: 37.
- 2 World Health Organization (WHO). Global Report on Diabetes 2016. WHO, Geneva, 2016.
- 3Boyle JP, Thompson TJ, Gregg EW, Barker LE, Williamson DF. Projection of the year 2050 burden of diabetes in the US adult population: Dynamic modeling of incidence, mortality, and prediabetes prevalence. Popul Health Metr. 2010; 8: 29.
- 4Islam MS, du Loots T. Experimental rodent models of type 2 diabetes: A review. Methods Find Exp Clin Pharmacol. 2009; 31: 249–261.
- 5Lohr H, Hammerschmidt M. Zebrafish in endocrine systems: Recent advances and implications for human disease. Annu Rev Physiol. 2011; 73: 183–211.
- 6Prince VE, Anderson RM, Dalgin G. Zebrafish pancreas development and regeneration: Fishing for diabetes therapies. Curr Top Dev Biol. 2017; 124: 235–276.
- 7Fuchsberger C, Flannick J, Teslovich TM et al. The genetic architecture of type 2 diabetes. Nature. 2016; 536: 41–47.
- 8Streisinger G, Walker C, Dower N, Knauber D, Singer F. Production of clones of homozygous diploid zebra fish (Brachydanio rerio). Nature. 1981; 291: 293–296.
- 9Auer TO, Del Bene F. CRISPR/Cas9 and TALEN-mediated knock-in approaches in zebrafish. Methods. 2014; 69: 142–150.
- 10Stainier DYR, Raz E, Lawson ND et al. Guidelines for morpholino use in zebrafish. PLoS Genet. 2017; 13: e1007000.
- 11Rohner N, Perathoner S, Frohnhofer HG, Harris MP. Enhancing the efficiency of N-ethyl-N-nitrosourea-induced mutagenesis in the zebrafish. Zebrafish. 2011; 8: 119–123.
- 12Gut P, Reischauer S, Stainier DYR, Arnaout R. Little fish, big data: Zebrafish as a model for cardiovascular and metabolic disease. Physiol Rev. 2017; 97: 889–938.
- 13Eames SC, Philipson LH, Prince VE, Kinkel MD. Blood sugar measurement in zebrafish reveals dynamics of glucose homeostasis. Zebrafish. 2010; 7: 205–213.
- 14Elo B, Villano CM, Govorko D, White LA. Larval zebrafish as a model for glucose metabolism: Expression of phosphoenolpyruvate carboxykinase as a marker for exposure to anti-diabetic compounds. J Mol Endocrinol. 2007; 38: 433–440.
- 15Zang L, Shimada Y, Nishimura N. Development of a novel zebrafish model for type 2 diabetes mellitus. Sci Rep. 2017; 7: 1461.
- 16Castillo J, Crespo D, Capilla E et al. Evolutionary structural and functional conservation of an ortholog of the GLUT2 glucose transporter gene (SLC2A2) in zebrafish. Am J Physiol Regul Integr Comp Physiol. 2009; 297: R1570–R1581.
- 17Marin-Juez R, Diaz M, Morata J, Planas JV. Mechanisms regulating GLUT4 transcription in skeletal muscle cells are highly conserved across vertebrates. PLoS One. 2013; 8: e80628.
- 18Kinkel MD, Prince VE. On the diabetic menu: Zebrafish as a model for pancreas development and function. Bioessays. 2009; 31: 139–152.
- 19Milewski WM, Duguay SJ, Chan SJ, Steiner DF. Conservation of PDX-1 structure, function, and expression in zebrafish. Endocrinology. 1998; 139: 1440–1449.
- 20Kimmel RA, Onder L, Wilfinger A, Ellertsdottir E, Meyer D. Requirement for Pdx1 in specification of latent endocrine progenitors in zebrafish. BMC Biol. 2011; 9: 75.
- 21Sun Z, Hopkins N. vhnf1, the MODY5 and familial GCKD-associated gene, regulates regional specification of the zebrafish gut, pronephros, and hindbrain. Genes Dev. 2001; 15: 3217–3229.
- 22Yee NS, Yusuff S, Pack M. Zebrafish pdx1 morphant displays defects in pancreas development and digestive organ chirality, and potentially identifies a multipotent pancreas progenitor cell. Genesis. 2001; 30: 137–140.
- 23Seth A, Stemple DL, Barroso I. The emerging use of zebrafish to model metabolic disease. Dis Model Mech. 2013; 6: 1080–1088.
- 24Shin D, Shin CH, Tucker J et al. Bmp and Fgf signaling are essential for liver specification in zebrafish. Development. 2007; 134: 2041–2050.
- 25Jurczyk A, Roy N, Bajwa R et al. Dynamic glucoregulation and mammalian-like responses to metabolic and developmental disruption in zebrafish. Gen Comp Endocrinol. 2011; 170: 334–345.
- 26Intine RV, Olsen AS, Sarras MP Jr. A zebrafish model of diabetes mellitus and metabolic memory. J Vis Exp. 2013; 72: e50232.
- 27Olsen AS, Sarras MP Jr, Intine RV. Limb regeneration is impaired in an adult zebrafish model of diabetes mellitus. Wound Repair Regen. 2010; 18: 532–542.
- 28Pisharath H, Rhee JM, Swanson MA, Leach SD, Parsons MJ. Targeted ablation of beta cells in the embryonic zebrafish pancreas using E. coli nitroreductase. Mech Dev. 2007; 124: 218–229.
- 29Ninov N, Hesselson D, Gut P, Zhou A, Fidelin K, Stainier DY. Metabolic regulation of cellular plasticity in the pancreas. Curr Biol. 2013; 23: 1242–1250.
- 30Curado S, Anderson RM, Jungblut B, Mumm J, Schroeter E, Stainier DY. Conditional targeted cell ablation in zebrafish: a new tool for regeneration studies. Dev Dyn. 2007; 236: 1025–1035.
- 31Wendik B, Maier E, Meyer D. Zebrafish mnx genes in endocrine and exocrine pancreas formation. Dev Biol. 2004; 268: 372–383.
- 32Dalgin G, Prince VE. Differential levels of Neurod establish zebrafish endocrine pancreas cell fates. Dev Biol. 2015; 402: 81–97.
- 33Kimmel RA, Dobler S, Schmitner N, Walsen T, Freudenblum J, Meyer D. Diabetic pdx1-mutant zebrafish show conserved responses to nutrient overload and anti-glycemic treatment. Sci Rep. 2015; 5: 14241.
- 34Gleeson M, Connaughton V, Arneson LS. Induction of hyperglycaemia in zebrafish (Danio rerio) leads to morphological changes in the retina. Acta Diabetol. 2007; 44: 157–163.
- 35Yin L, Maddison LA, Li M et al. Multiplex conditional mutagenesis using transgenic expression of Cas9 and sgRNAs. Genetics. 2015; 200: 431–441.
- 36Maddison LA, Joest KE, Kammeyer RM, Chen W. Skeletal muscle insulin resistance in zebrafish induces alterations in beta-cell number and glucose tolerance in an age- and diet-dependent manner. Am J Physiol Endocrinol Metab. 2015; 308: E662–E669.
- 37Li M, Page-McCaw P, Chen W. FGF1 mediates overnutrition-induced compensatory beta-cell differentiation. Diabetes. 2016; 65: 96–109.
- 38Karanth S, Zinkhan EK, Hill JT, Yost HJ, Schlegel A. FOXN3 regulates hepatic glucose utilization. Cell Rep. 2016; 15: 2745–2755.
- 39Jorgens K, Hillebrands JL, Hammes HP, Kroll J. Zebrafish: A model for understanding diabetic complications. Exp Clin Endocrinol Diabetes. 2012; 120: 186–187.
- 40Lee J, Jung DW, Kim WH et al. Development of a highly visual, simple, and rapid test for the discovery of novel insulin mimetics in living vertebrates. ACS Chem Biol. 2013; 8: 1803–1814.
- 41Gut P, Baeza-Raja B, Andersson O et al. Whole-organism screening for gluconeogenesis identifies activators of fasting metabolism. Nat Chem Biol. 2013; 9: 97–104.
- 42Kimmel RA, Meyer D. Zebrafish pancreas as a model for development and disease. Methods Cell Biol. 2016; 134: 431–461.
- 43Moss LG, Caplan TV, Moss JB. Imaging beta cell regeneration and interactions with islet vasculature in transparent adult zebrafish. Zebrafish. 2013; 10: 249–257.
- 44Hesselson D, Anderson RM, Beinat M, Stainier DY. Distinct populations of quiescent and proliferative pancreatic beta-cells identified by HOTcre mediated labeling. Proc Natl Acad Sci USA. 2009; 106: 14896–14901.
- 45White RM, Sessa A, Burke C et al. Transparent adult zebrafish as a tool for in vivo transplantation analysis. Cell Stem Cell. 2008; 2: 183–189.
- 46Singh SP, Janjuha S, Hartmann T et al. Different developmental histories of beta-cells generate functional and proliferative heterogeneity during islet growth. Nat Commun. 2017; 8: 664.
- 47Hugo SE, Cruz-Garcia L, Karanth S, Anderson RM, Stainier DY, Schlegel A. A monocarboxylate transporter required for hepatocyte secretion of ketone bodies during fasting. Genes Dev. 2012; 26: 282–293.
- 48Tsuji N, Ninov N, Delawary M et al. Whole organism high content screening identifies stimulators of pancreatic beta-cell proliferation. PLoS One. 2014; 9: e104112.
- 49Rovira M, Huang W, Yusuff S et al. Chemical screen identifies FDA-approved drugs and target pathways that induce precocious pancreatic endocrine differentiation. Proc Natl Acad Sci USA. 2011; 108: 19264–19269.
- 50Andersson O, Adams BA, Yoo D et al. Adenosine signaling promotes regeneration of pancreatic beta cells in vivo. Cell Metab. 2012; 15: 885–894.
- 51Siccardi AJ III, Garris HW, Jones WT, Moseley DB, D'Abramo LR, Watts SA. Growth and survival of zebrafish (Danio rerio) fed different commercial and laboratory diets. Zebrafish. 2009; 6: 275–280.
- 52Smith DL Jr, Barry RJ, Powell ML, Nagy TR, D'Abramo LR, Watts SA. Dietary protein source influence on body size and composition in growing zebrafish. Zebrafish. 2013; 10: 439–446.
- 53Michel M, Page-McCaw PS, Chen W, Cone RD. Leptin signaling regulates glucose homeostasis, but not adipostasis, in the zebrafish. Proc Natl Acad Sci USA. 2016; 113: 3084–3089.
- 54Hwang WY, Fu Y, Reyon D et al. Efficient genome editing in zebrafish using a CRISPR-Cas system. Nat Biotechnol. 2013; 31: 227–229.
- 55Shin J, Chen J, Solnica-Krezel L. Efficient homologous recombination-mediated genome engineering in zebrafish using TALE nucleases. Development. 2014; 141: 3807–3818.
- 56Otis JP, Zeituni EM, Thierer JH et al. Zebrafish as a model for apolipoprotein biology: Comprehensive expression analysis and a role for ApoA-IV in regulating food intake. Dis Model Mech. 2015; 8: 295–309.
- 57Rawls JF, Samuel BS, Gordon JI. Gnotobiotic zebrafish reveal evolutionarily conserved responses to the gut microbiota. Proc Natl Acad Sci USA. 2004; 101: 4596–4601.
- 58Wong S, Stephens WZ, Burns AR et al. Ontogenetic differences in dietary fat influence microbiota assembly in the zebrafish gut. MBio. 2015; 6: e00687–e00615.
- 59Young HM, Cane KN, Anderson CR. Development of the autonomic nervous system: a comparative view. Auton Neurosci. 2011; 165: 10–27.
- 60Yang YHC, Kawakami K, Stainier DY. A new mode of pancreatic islet innervation revealed by live imaging in zebrafish. Elife. 2018; 7: e34519.
- 61Edison AS, Hall RD, Junot C et al. The time is right to focus on model organism metabolomes. Metabolites. 2016; 6: 1.
- 62Ong ES, Chor CF, Zou L, Ong CN. A multi-analytical approach for metabolomic profiling of zebrafish (Danio rerio) livers. Mol Biosyst. 2009; 5: 288–298.
- 63Kelley KM, Gray ES, Siharath K, Nicoll CS, Bern HA. Experimental diabetes mellitus in a teleost fish. II. Roles of insulin, growth hormone (GH), insulin-like growth factor-I, and hepatic GH receptors in diabetic growth inhibition in the goby, Gillichthys mirabilis. Endocrinology. 1993; 132: 2696–2702.
- 64Kelley KM. Experimental diabetes mellitus in a teleost fish. I. Effect of complete isletectomy and subsequent hormonal treatment on metabolism in the goby, Gillichthys mirabilis. Endocrinology. 1993; 132: 2689–2695.
- 65Wright JR Jr, Abraham C, Dickson BC, Yang H, Morrison CM. Streptozotocin dose-response curve in tilapia, a glucose-responsive teleost fish. Gen Comp Endocrinol. 1999; 114: 431–440.
- 66Pohajdak B, Mansour M, Hrytsenko O, Conlon JM, Dymond LC, Wright JR Jr. Production of transgenic tilapia with Brockmann bodies secreting [desThrB30] human insulin. Transgenic Res. 2004; 13: 313–323.
- 67Barma P. Nutritionally induced insulin resistance in an Indian perch: a possible model for type 2 diabetes. Curr Sci. 2006; 90: 188–194.
- 68Martin SL. Mammalian hibernation: a naturally reversible model for insulin resistance in man? Diab Vasc Dis Res. 2008; 5: 76–81.
- 69Capilla E, Diaz M, Albalat A et al. Functional characterization of an insulin-responsive glucose transporter (GLUT4) from fish adipose tissue. Am J Physiol Endocrinol Metab. 2004; 287: E348–E357.
- 70Polakof S, Panserat S, Soengas JL, Moon TW. Glucose metabolism in fish: A review. J Comp Physiol B. 2012; 182: 1015–1045.
- 71Moon TW. Glucose intolerance in teleost fish: Fact or fiction? Comp Biochem Physiol B Biochem Mol Biol. 2001; 129: 243–249.
- 72Falkmer S. Experimental diabetes research in fish. Acta Endocrinol Suppl (Copenh). 1961; 37 (Suppl 59): 1–122.
- 73Mazur CN, Higgs DA, Plisetskaya E, March BE. Utilization of dietary starch and glucose tolerance in juvenile chinook salmon (Oncorhynchus tshawytscha) of different strains in seawater. Fish Physiol Biochem. 1992; 10: 303–313.
- 74Wilson RP, Poe WE. Apparent inability of channel catfish to utilize dietary mono- and disaccharides as energy sources. J Nutr. 1987; 117: 280–285.
- 75Panserat S, Capilla E, Gutierrez J et al. Glucokinase is highly induced and glucose-6-phosphatase poorly repressed in liver of rainbow trout (Oncorhynchus mykiss) by a single meal with glucose. Comp Biochem Physiol B Biochem Mol Biol. 2001; 128: 275–283.
- 76Skiba-Cassy S, Panserat S, Larquier M et al. Apparent low ability of liver and muscle to adapt to variation of dietary carbohydrate: Protein ratio in rainbow trout (Oncorhynchus mykiss). Br J Nutr. 2013; 109: 1359–1372.
- 77Marandel L, Veron V, Surget A, Plagnes-Juan E, Panserat S. Glucose metabolism ontogenesis in rainbow trout (Oncorhynchus mykiss) in the light of the recently sequenced genome: New tools for intermediary metabolism programming. J Exp Biol. 2016; 219: 734–743.
- 78Bergot F. Carbohydrate in rainbow trout diets: Effects of the level and source of carbohydrate and the number of meals on growth and body composition. Aquaculture. 1979; 18: 157–167.
- 79Panserat S. Regulation of gene expression by nutritional factors in fish. Aquacult Res. 2010; 41: 751–762.
- 80Cowey CB, de la Higuera M, Adron JW. The effect of dietary composition and of insulin on gluconeogenesis in rainbow trout (Salmo gairdneri). Br J Nutr. 1977; 38: 385–395.
- 81Reid SG, Bernier NJ, Perry SF. The adrenergic stress response in fish: Control of catecholamine storage and release. Comp Biochem Physiol C Pharmacol Toxicol Endocrinol. 1998; 120: 1–27.
- 82Figueiredo-Silva AC, Panserat S, Kaushik S, Geurden I, Polakof S. High levels of dietary fat impair glucose homeostasis in rainbow trout. J Exp Biol. 2012; 215: 169–178.
- 83Panserat S, Skiba-Cassy S, Seiliez I et al. Metformin improves postprandial glucose homeostasis in rainbow trout fed dietary carbohydrates: A link with the induction of hepatic lipogenic capacities? Am J Physiol Regul Integr Comp Physiol. 2009; 297: R707–R715.
- 84Craig PM, Moon TW. Methionine restriction affects the phenotypic and transcriptional response of rainbow trout (Oncorhynchus mykiss) to carbohydrate-enriched diets. Br J Nutr. 2013; 109: 402–412.
- 85Stone KP, Wanders D, Orgeron M, Cortez CC, Gettys TW. Mechanisms of increased in vivo insulin sensitivity by dietary methionine restriction in mice. Diabetes. 2014; 63: 3721–3733.
- 86Marandel L, Seiliez I, Veron V, Skiba-Cassy S, Panserat S. New insights into the nutritional regulation of gluconeogenesis in carnivorous rainbow trout (Oncorhynchus mykiss): A gene duplication trail. Physiol Genomics. 2015; 47: 253–263.
- 87Polakof S, Skiba-Cassy S, Choubert G, Panserat S. Insulin-induced hypoglycaemia is co-ordinately regulated by liver and muscle during acute and chronic insulin stimulation in rainbow trout (Oncorhynchus mykiss). J Exp Biol. 2010; 213: 1443–1452.
- 88Berthelot C, Brunet F, Chalopin D et al. The rainbow trout genome provides novel insights into evolution after whole-genome duplication in vertebrates. Nat Commun. 2014; 5: 3657.
- 89Marandel L, Lepais O, Arbenoits E et al. Remodelling of the hepatic epigenetic landscape of glucose-intolerant rainbow trout (Oncorhynchus mykiss) by nutritional status and dietary carbohydrates. Sci Rep. 2016; 6: 32187.
- 90Page A, Paoli P, Moran Salvador E, White S, French J, Mann J. Hepatic stellate cell transdifferentiation involves genome-wide remodeling of the DNA methylation landscape. J Hepatol. 2016; 64: 661–673.
- 91Santin AE, Searle AJ, Winston VD, Powell MS, Hardy RW, Rodnick KJ. Glycated hemoglobin is not an accurate indicator of glycemia in rainbow trout. Comp Biochem Physiol A Mol Integr Physiol. 2013; 165: 343–352.
- 92Krishnan J, Rohner N. Cavefish and the basis for eye loss. Philos Trans R Soc Lond B Biol Sci. 2017; 372: 1713.
- 93Jeffery WR. Regressive evolution in Astyanax cavefish. Annu Rev Genet. 2009; 43: 25–47.
- 94Aspiras AC, Rohner N, Martineau B, Borowsky RL, Tabin CJ. Melanocortin 4 receptor mutations contribute to the adaptation of cavefish to nutrient-poor conditions. Proc Natl Acad Sci USA. 2015; 112: 9668–9673.
- 95Moran D, Softley R, Warrant EJ. Eyeless Mexican cavefish save energy by eliminating the circadian rhythm in metabolism. PLoS One. 2014; 9: e107877.
- 96Penney CC, Volkoff H. Peripheral injections of cholecystokinin, apelin, ghrelin and orexin in cavefish (Astyanax fasciatus mexicanus): effects on feeding and on the brain expression levels of tyrosine hydroxylase, mechanistic target of rapamycin and appetite-related hormones. Gen Comp Endocrinol. 2014; 196: 34–40.
- 97Xiong S, Krishnan J, Peuss R, Rohner N. Early adipogenesis contributes to excess fat accumulation in cave populations of Astyanax mexicanus. Dev Biol. 2018; 441: 297–304.
- 98Culver D, Pipan T. The Biology of Caves and Other Subterranean Habitats. Oxford University Press, Oxford, 2009.
- 99McGaugh SE, Gross JB, Aken B et al. The cavefish genome reveals candidate genes for eye loss. Nat Commun. 2014; 5: 5307.
- 100Ma L, Jeffery WR, Essner JJ, Kowalko JE. Genome editing using TALENs in blind Mexican cavefish, Astyanax mexicanus. PLoS One. 2015; 10: e0119370.
- 101Gross JB, Meyer B, Perkins M. The rise of Astyanax cavefish. Dev Dyn. 2015; 244: 1031–1038.
- 102Elipot Y, Legendre L, Pere S, Sohm F, Retaux S. Astyanax transgenesis and husbandry: How cavefish enters the laboratory. Zebrafish. 2014; 11: 291–299.
- 103Riddle MR, Aspiras AC, Gaudenz K et al. Insulin resistance in cavefish as an adaptation to a nutrient-limited environment. Nature. 2018; 555: 647–651.
Citing Literature
