Type 2 diabetes mellitus--genes or intrauterine environment? An embryo transfer paradigm in rats.

AIMS/HYPOTHESIS: The familial predisposition to Type 2 diabetes mellitus is mediated by both genetic and intrauterine environmental factors. In the normal course of events, maternal genes always develop in the same uterus, thus restricting studies aimed at investigating the relative contribution of these factors. We have developed an embryo transfer paradigm in rats to overcome this difficulty. METHODS: Euglycaemic female Wistar rats were superovulated and mated with male Wistar rats. The following day, fertilised eggs were transferred into pseudo-pregnant female Wistar rats or hyperglycaemic Goto Kakizaki (GK) rats. Pregnancies were allowed to go to term. Offspring were weighed at 6 weeks, 3 months and 6 months of age and an intravenous glucose tolerance test was carried out at 6 months of age. RESULTS: Offspring from Wistar into Wistar embryo transfers (n=20) were not significantly hyperglycaemic compared to the non-manipulated Wistar stock colony (n=26). However, offspring from Wistar gametes reared in hyperglycaemic GK mothers (n=51) were significantly lighter at 6 weeks of age (156+/-4.1 g vs 180+/-6.1 g [mean +/- SEM], p<0.01) and significantly more hyperglycaemic at 6 months of age (fasting glucose 6.6+/-0.18 mmol/l vs 4.8+/-0.21 mmol/l, mean blood glucose during glucose tolerance test 14.3+/-0.31 mmol/l vs 11.1+/-0.28 mmol/l, p<0.01) than Wistar gametes transferred back into euglycaemic Wistar mothers. When GK rats were superovulated and mated together, transfer of 1-day-old embryos into pseudo-pregnant Wistar dams did not alleviate hyperglycaemia in adult offspring. CONCLUSIONS/INTERPRETATION: In GK rats, a euglycaemic intrauterine environment cannot overcome the strong genetic predisposition to diabetes. However, in Wistar rats with a low genetic risk of diabetes, exposure to hyperglycaemia in utero significantly increases the risk of diabetes in adult life.

Is human Type 2 diabetes maternally inherited? Insights from an animal model.

AIMS: Patients with Type 2 diabetes mellitus more often report a history of an affected mother than father. However, in the few studies where both parents and offspring have been directly tested, this apparent maternal excess has not been confirmed. Rodent models of diabetes have the advantage that all parents and offspring can undergo glucose tolerance testing at a specific age in adult life. The aim of this study was to gain insights into the inheritance of human Type 2 diabetes by using a rat model. METHODS: Goto Kakizaki (GK) rats (a model of Type 2 diabetes) were mated with non-diabetic Wistar rats. Offspring were produced from 20 GK female vs. Wistar male and 20 Wistar female vs. GK male crosses. Fasting blood glucose was measured at 6 weeks and 3 months of age and an intravenous glucose tolerance test (0.8 g/kg) performed at 6 months of age. RESULTS: Wistar mothers produced litters with almost twice as many viable offspring as GK mothers (14.1 vs. 7.4, P < 0.001). Despite the larger litter size, offspring in the two groups were of comparable weight at 6 weeks and 6 months of age. At 3 months of age, male offspring of Wistar mothers were heavier than offspring of GK mothers (415.7 g vs. 379.5 g, P = 0.016) but this difference was not sustained at 6 months of age. Fasting blood glucose at all ages and average blood glucose during the glucose tolerance test were similar in both groups. CONCLUSIONS: We therefore conclude that there is no evidence for maternal transmission of diabetes in the GK rat. Mothers were able to adjust their supply of milk so that offspring attained similar weights independent of litter size. The weight of the offspring remained independent of litter size into adult life.

Maternal transmission of diabetes.

Type 2 diabetes mellitus represents a heterogeneous group of conditions characterized by impaired glucose homeostasis. The disorder runs in families but the mechanism underlying this is unknown. Many, but not all, studies have suggested that mothers are excessively implicated in the transmission of the disorder. A number of possible genetic phenomena could explain this observation, including the exclusively maternal transmission of mitochondrial DNA (mtDNA). It is now apparent that mutations in mtDNA can indeed result in maternally inherited diabetes. Although several mutations have been implicated, the strongest evidence relates to a point substitution at nucleotide position 3243 (A to G) in the mitochondrial tRNA(leu(UUR)) gene. Mitochondrial diabetes is commonly associated with nerve deafness and often presents with progressive non-autoimmune beta-cell failure. Specific treatment with Coenzyme Q10 or L-carnitine may be beneficial. Several rodent models of mitochondrial diabetes have been developed, including one in which mtDNA is specifically depleted in the pancreatic islets. Apart from severe, pathogenic mtDNA mutations, common polymorphisms in mtDNA may contribute to variations of insulin secretory capacity in normal individuals. Mitochondrial diabetes accounts for less than 1% of all diabetes and other mechanisms must underlie the maternal transmission of Type 2 diabetes. Possibilities include the role of maternally controlled environments, imprinted genes and epigenetic phenomena.

Analysis of a polycytosine tract and heteroplasmic length variation in the mitochondrial DNA D-loop of patients with diabetes, MELAS syndrome and race-matched controls.

AIM: The T to C substitution at position 16189 nt of the human mitochondrial genome has been associated with the development of heteroplasmic length variation in the control region of mtDNA. Previous reports have suggested that this defect may be associated with the development of other pathogenic mtDNA mutations, including the diabetogenic A to G mutation in the tRNALEU(UUR). Recently the 16189 nt variant has also been associated with insulin resistance in British adult men. In order to investigate these associations further we studied 23 patients with the 3243 nt mutation, 150 patients with Type 2 diabetes and 149 non-diabetic controls. METHODS: The region around 16189 nt was investigated by polymerase chain reaction-restriction fragment length polymorphism analysis and automated sequencing. RESULTS: We find that the T to C substitution at 16189 nt is associated with heteroplasmic length variation only when the resultant polycytosine tract is not interrupted by a second mutation. There are no significant differences in the prevalence of the 16189 nt variant or heteroplasmic length variation between patients with the 3243 nt mutation, patients with Type 2 diabetes or race-matched normal controls. CONCLUSIONS: We conclude that these variants are likely to represent normal polymorphisms and that previously reported associations should be treated with caution unless they can be replicated in other populations.

Identification of mtDNA mutation in a pedigree with gestational diabetes, deafness, Wolff-Parkinson-White syndrome and placenta accreta.

Mitochondrial DNA (mtDNA) defects are associated with a number of human disorders. Although many occur sporadically, maternal transmission is the hallmark of diseases due to mtDNA point mutations. The same mutation may manifest strikingly different phenotypes; for example, the A to G substitution at np 3243 was first reported in patients with mitochondrial encephalomyopathy, lactic acidosis and stroke-like episodes (the MELAS syndrome), but is also found in patients with diabetes and deafness. Here we present a case of gestational diabetes, deafness, premature greying, placenta accreta and Wolff-Parkinson-White (WPW) syndrome associated with a mtDNA mutation. Although this is the first report of such an association, study of 27 other patients with WPW syndrome failed to confirm that this mtDNA mutation is a common cause of such pre-excitation disorders.

Phylogenetic analysis of mitochondrial DNA in type 2 diabetes: maternal history and ancient population expansion.

Several studies have suggested a maternal excess in the transmission of type 2 (non-insulin-dependent) diabetes. However, the majority of these reports rely on patients recalling parental disease status and hence are open to criticism. An alternative approach is to study mitochondrial DNA (mtDNA) lineages. The hypervariable region 1 of the rapidly evolving noncoding section of mtDNA is suitable for investigating maternal ancestry and has been used extensively to study the origins of human racial groups. We have sequenced this 347-bp section of mtDNA from leukocytes of subjects with type 2 diabetes (n = 63) and age- and race-matched nondiabetic control subjects (n = 57). Consensus sequences for the two study groups were identical. Pairwise sequence analysis showed unimodal distribution of pairwise differences for both groups, suggesting that both populations had undergone expansion in ancient times. The distributions were significantly different (chi2 = 180, df = 11, P < 0.001); mean pairwise differences were 4.7 and 3.8 for the diabetic and control subjects, respectively. These data suggest that the diabetic subjects belong to an ancient maternal lineage that expanded before the major expansion observed in the nondiabetic population. Phylogenetic trees constructed using maximum parsimony, neighbor-joining, Fitch-Margolish, or maximum likelihood methods failed to show the clustering of all (or a subset) of the diabetic subjects into one or more distinct lineages.