Enhanced insulin secretion and cholesterol metabolism in congenic strains of the spontaneously diabetic (Type 2) Goto Kakizaki rat are controlled by independent genetic loci in rat chromosome 8

Wallis, Robert H.; Wallace, Karin J.; Collins, Stephan C.; McAteer, Martina A.; Argoud, Karène; Bihoreau, Marie Thérèse; Kaisaki, Pamela J.; Guyader, Dominique

doi:10.1007/s00125-004-1416-5

Cited by 27 publications

(18 citation statements)

References 28 publications

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“…Resulting changes in the balance between GK and BN alleles in congenics may in turn unmask phenotypic effects of some gene variants at the targeted locus. This may explain the effect of GK alleles in chromosome 8 on plasma lipid up-regulation, which we detected in BN.GK congenic rats [38] but do not replicate here in the GK×BN F2 cross. We found no significant evidence of genetic interaction (epistasis) in the F2 cross between GK alleles on chromosome 8 and BN alleles in the genetic background that could explain the absence of QTL replication (data not shown).…”

Section: Discussioncontrasting

confidence: 84%

“…Further studies in congenic strains containing regions of GK QTLs introgressed on to the genetic background of the BN strain [38] are required to validate the lipid QTLs reported here and carry out the identification of the underlying gene variant(s). Congenics allow the study of phenotypic consequences of selected GK alleles at a specific locus in a different genetic context than that of a hybrid GK×BN F2 population, because GK variants throughout the genetic background, including at GK diabetes QTLs, are eliminated.…”

Section: Discussionmentioning

confidence: 99%

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Genetic control of plasma lipid levels in a cross derived from normoglycaemic Brown Norway and spontaneously diabetic Goto–Kakizaki rats

et al. 2006

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Aims/hypothesis Dyslipidaemia is a main component of the insulin resistance syndrome. The inbred Goto-Kakizaki (GK) rat is a model of spontaneous type 2 diabetes and insulin resistance, which has been used to identify diabetes-related susceptibility loci in genetic crosses. The objective of our study was to test the genetic control of lipid metabolism in the GK rat and investigate a possible relationship with known genetic loci regulating glucose homeostasis in this strain. Materials and methods Plasma concentration of triglycerides, phospholipids, total cholesterol, HDL, LDL and VLDL cholesterol were determined in a cohort of 151 hybrids of an F2 cross derived from GK and non-diabetic Brown Norway (BN) rats. Data from the genome-wide scan of the F2 hybrids were used to test for evidence of genetic linkage to the lipid quantitative traits. Results We identified statistically significant quantitative trait loci (QTLs) that control the level of plasma phospholipids and triglycerides (chromosome 1), LDL cholesterol (chromosome 3) and total and HDL cholesterol (chromosomes 1 and 5). These QTLs do not coincide with previously identified diabetes susceptibility loci in a similar cross. The significance of lipid QTLs mapped to chromosomes 1 and 5 is strongly influenced by sex. Conclusion/interpretation We established that several genetic loci control the quantitative variations of plasma lipid variables in a GK×BN cross. They appear to be distinct from known GK diabetes QTLs, indicating that lipid metabolism and traits directly relevant to glucose and insulin regulation are controlled by different gene variants in this strain combination.

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Section: Discussioncontrasting

confidence: 84%

Section: Discussionmentioning

confidence: 99%

Genetic control of plasma lipid levels in a cross derived from normoglycaemic Brown Norway and spontaneously diabetic Goto–Kakizaki rats

et al. 2006

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“…Genetic analysis. Genotyping was performed as previously described (19,20). All microsatellite primers were purchased from Sigma-Genosys available at www.well.ox.ac.uk/rat_mapping_resources.…”

Section: Methodsmentioning

confidence: 99%

A Novel Susceptibility Locus on Rat Chromosome 8 Affects Spontaneous but Not Experimentally Induced Type 1 Diabetes

et al. 2007

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OBJECTIVE—The biobreeding diabetes-prone (BBDP) rat spontaneously develops type 1 diabetes. Two of the genetic factors contributing to this syndrome are the major histocompatibility complex (Iddm1) and a Gimap5 mutation (Iddm2) responsible for a T-lymphopenia. Susceptibility to experimentally induced type 1 diabetes is widespread among nonlymphopenic (wild-type Iddm2) rat strains provided they share the BBDP Iddm1 allele. The question follows as to whether spontaneous and experimentally induced type 1 diabetes share susceptibility loci besides Iddm1. Our objectives were to map a novel, serendipitously discovered Iddm locus, confirm its effects by developing congenic sublines, and assess its differential contribution to spontaneous and experimentally induced type 1 diabetes. RESEARCH DESIGN AND METHODS—An unexpected reduction in spontaneous type 1 diabetes incidence (86 to 31%, P < 0.0001) was observed in a BBDP line congenic for a Wistar Furth–derived allotypic marker, RT7 (chromosome 13). Genome-wide analysis revealed that, besides the RT7 locus, a Wistar Furth chromosome 8 fragment had also been introduced. The contribution of these intervals to diabetes resistance was assessed through linkage analysis using 134 F2 (BBDP × double congenic line) animals and a panel of congenic sublines. One of these sublines, resistant to spontaneous type 1 diabetes, was tested for susceptibility to experimentally induced type 1 diabetes. RESULTS—Both linkage analysis and congenic sublines mapped a novel locus (Iddm24) to the telomeric 10.34 Mb of chromosome 8, influencing cumulative incidence and age of onset of spontaneous type 1 diabetes but not insulitis nor experimentally induced type 1 diabetes. CONCLUSIONS—This study has identified a type 1 diabetes susceptibility locus that appears to act after the development of insulitis and that regulates spontaneous type 1 diabetes exclusively.

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“…Construction of the congenics was specifically designed to introgress GK alleles from RNO2 regions covering the QTL Nidd/gk2 and Niddm2 onto the genetic background of the BN strain (BN.GK congenics), using a genetic marker-assisted breeding strategy (24), as previously described (35). Although the production of reciprocal congenics (GK.BN) was also initiated, it proved to be problematic, because of a high perinatal mortality rate in (GKϫBN)ϫGK backcross progenies, which remained, however, similar to that observed in GK rats.…”

Section: Microsatellite Marker-assisted Production Of Congenic Rats Fmentioning

confidence: 99%

“…Linkage between marker genotypes and diabetes-related phenotypes in the GKϫBN F2 cross was initially evaluated by an ANOVA test followed by a permutation test as previously used (35). Interval mapping was performed with the MAPMAKER/QTL computer package (22).…”

Section: Statistical Analysesmentioning

confidence: 99%

Quantitative trait locus dissection in congenic strains of the Goto-Kakizaki rat identifies a region conserved with diabetes loci in human chromosome 1q

Wallace

Wallis

Collins

et al. 2004

Physiological Genomics

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Quantitative trait locus dissection in congenic strains of the Goto-Kakizaki rat identifies a region conserved with diabetes loci in human chromosome 1q. Physiol Genomics 19: 1-10, 2004. First published July 20, 2004 doi:10.1152/physiolgenomics.00114.2004.-Genetic studies in human populations and rodent models have identified regions of human chromosome 1q21-25 and rat chromosome 2 showing evidence of significant and replicated linkage to diabetes-related phenotypes. To investigate the relationship between the human and rat diabetes loci, we fine mapped the rat locus Nidd/gk2 linked to hyperinsulinemia in an F2 cross derived from the diabetic (type 2) Goto-Kakizaki (GK) rat and the Brown Norway (BN) control rat, and carried out its genetic and pathophysiological characterization in BN.GK congenic strains. Evidence of glucose intolerance and enhanced insulin secretion in a congenic strain allowed us to localize the underlying diabetes gene(s) in a rat chromosomal interval of ϳ3-6 cM conserved with an 11-Mb region of human 1q21-23. Positional diabetes candidate genes were tested for transcriptional changes between congenics and controls and sequence variations in a panel of inbred rat strains. Congenic strains of the GK rats represent powerful novel models for accurately defining the pathophysiological impact of diabetes gene(s) at the locus Nidd/gk2 and improving functional annotations of diabetes candidates in human 1q21-23. type 2 diabetes mellitus; genetics; comparative genomics THE INBRED GOTO-KAKIZAKI (GK) rat strain is a well-characterized nonobese model of spontaneous type 2 diabetes mellitus (T2DM), which is widely used for investigating important aspects of the pathogenesis of diabetes (1, 28) and mapping quantitative trait loci (QTL) involved in altered regulation of glucose and insulin levels. Replicated linkage between diabetes phenotypes and rat chromosome (RNO) 2 is suggested by results from QTL mapping studies in crosses derived from GK and the nondiabetic Brown Norway (BN) (13) or F344 rats (10) (loci Nidd/gk2 and Niddm2, respectively) and more recently in a cross involving the spontaneously diabetic Torii (SDT) rat, a new inbred model of nonobese type 2 diabetes (25).Comparative genome analyses have highlighted the possible conservation of synteny homology between the Nidd/gk2 region and human chromosome 1q21-24 (3), which shows evidence of replicated linkage to T2DM in at least eight populations, including European Americans (7), French whites (34), the UK Warren 2 repository (37), Pima Indians (17), and Chinese (38). This region is therefore the focus of intense interest in T2DM genetics.Progress in the completion of the rat genome sequence (30) provides a unique opportunity to refine homology relationships between RNO2 and human 1q and take advantage of genome annotations for T2DM candidate gene identification. The integration of comparative genomics and studies in rat congenic strains, which are designed to fine map QTL and test the phenotypic impact of gene variants in well-characterized re...

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Enhanced insulin secretion and cholesterol metabolism in congenic strains of the spontaneously diabetic (Type 2) Goto Kakizaki rat are controlled by independent genetic loci in rat chromosome 8

Cited by 27 publications

References 28 publications

Genetic control of plasma lipid levels in a cross derived from normoglycaemic Brown Norway and spontaneously diabetic Goto–Kakizaki rats

Genetic control of plasma lipid levels in a cross derived from normoglycaemic Brown Norway and spontaneously diabetic Goto–Kakizaki rats

A Novel Susceptibility Locus on Rat Chromosome 8 Affects Spontaneous but Not Experimentally Induced Type 1 Diabetes

Quantitative trait locus dissection in congenic strains of the Goto-Kakizaki rat identifies a region conserved with diabetes loci in human chromosome 1q

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