Current insights into the sulfatase pathway in human testis and cultured Sertoli cells.

Within the human testis, large amounts of sulfated steroid hormones are produced. As shown in breast tissue and placenta, these might not only be excretion intermediates, but re-activated in target cells by steroid sulfatase (STS). This process is called sulfatase pathway and may play a pivotal role in para- and/or intracrine regulation by creating a local supply for steroid hormones. This requires a facilitated transport via uptake carriers and efflux transporters as these hydrophilic molecules cannot pass the cell membrane. Moreover, blood-testis barrier formation in the testis requires a transport through Sertoli cells (SCs) to reach germ cells (GCs). Sertoli cells are therefore expected to play a key role as gate-keepers for sulfatase pathway in human seminiferous epithelium. We analyzed the mRNA and protein expression of uptake carriers and efflux transporters like organic anion-transporting polypeptides (OATP2B1, OATP3A1) and multidrug resistance-related proteins (MRP1, MRP4) in testicular tissue and cultured Sertoli cells (FS1, HSEC). Additionally, expression pattern of STS as well as sulfonating enzymes (SULTs) were assessed. OATP2B1, OATP3A1 and STS were detected in SCs as well as GCs, whereas MRP1 is only expressed in SCs, and SULT1E1 only in Leydig cells, respectively. By transcellular transport of [H3]DHEAS in HSEC, we showed a functional transport of sulfated steroids in vitro. Our data indicate that steroid synthesis via sulfatase pathway in Sertoli cells in vivo and in vitro is possible and may contribute to paracrine and intracrine regulation employing the local supply of sulfated and free steroid hormones inside seminiferous tubules.

Extended DR3-D6S273-HLA-B haplotypes are associated with increased susceptibility to type 1 diabetes in US Caucasians.

Human leukocyte antigen (HLA)-DR3 haplotypes are associated with susceptibility to type 1 diabetes (T1D). Reports from Northern European populations show that an allele (D6S273*2) at a microsatellite mapping to HLA class III marks an extended DR3-B18 haplotype associated with increased susceptibility to T1D. Consistent with previous reports, D6S273*2 marked a highly predisposing DR3 haplotype in European origin, multiplex families from the USA. Furthermore, we observed on DR3 haplotypes that other D6S273 alleles were also significantly associated with both increased transmission (D6S273*5; P < 0.02) and decreased transmission (D6S273*7; P < 0.05) to affected individuals. The differential transmission was most evident among DR3-B8 haplotypes. Neither HLA-B*1801 nor any alleles of D6S273 were associated with increased T1D predisposition on DR4 haplotypes. These data indicate that multiple alleles of D6S273 mark a susceptibility locus whose effect we were able to detect only among DR3 haplotypes but not limited to DR3-B18 haplotypes.

Seven regions of the genome show evidence of linkage to type 1 diabetes in a consensus analysis of 767 multiplex families.

Type 1 diabetes (T1D) is a genetically complex disorder of glucose homeostasis that results from the autoimmune destruction of the insulin-secreting cells of the pancreas. Two previous whole-genome scans for linkage to T1D in 187 and 356 families containing affected sib pairs (ASPs) yielded apparently conflicting results, despite partial overlap in the families analyzed. However, each of these studies individually lacked power to detect loci with locus-specific disease prevalence/sib-risk ratios (lambda(s)) <1.4. In the present study, a third genome scan was performed using a new collection of 225 multiplex families with T1D, and the data from all three of these genome scans were merged and analyzed jointly. The combined sample of 831 ASPs, all with both parents genotyped, provided 90% power to detect linkage for loci with lambda(s) = 1.3 at P=7.4x10(-4). Three chromosome regions were identified that showed significant evidence of linkage (P<2.2x10(-5); LOD scores >4), 6p21 (IDDM1), 11p15 (IDDM2), 16q22-q24, and four more that showed suggestive evidence (P<7.4x10(-4), LOD scores > or =2.2), 10p11 (IDDM10), 2q31 (IDDM7, IDDM12, and IDDM13), 6q21 (IDDM15), and 1q42. Exploratory analyses, taking into account the presence of specific high-risk HLA genotypes or affected sibs' ages at disease onset, provided evidence of linkage at several additional sites, including the putative IDDM8 locus on chromosome 6q27. Our results indicate that much of the difficulty in mapping T1D susceptibility genes results from inadequate sample sizes, and the results point to the value of future international collaborations to assemble and analyze much larger data sets for linkage in complex diseases.

Linkage studies of SOX13, the ICA12 autoantigen gene, in families with type 1 diabetes.

SOX13 is a member of the SOX family of transcription factors that encodes the type 1 diabetes autoantigen, ICA12. The SOX13 gene maps at chromosome 1q31.3-32.1 near a region containing a susceptibility locus for type 1 diabetes. SOX13 was assessed as a candidate susceptibility gene. Analysis of the SOX13 gene identified a number of single nucleotide polymorphisms and a polymorphic CA dinucleotide repeat. Linkage and association studies indicate that SOX13 is unlikely to make a substantial contribution to type 1 diabetes susceptibility.

A second-generation screen of the human genome for susceptibility to insulin-dependent diabetes mellitus.

During the past decade, the genetics of type 1 (insulin-dependent) diabetes mellitus (IDDM) has been studied extensively and the disorder has become a paradigm for genetically complex diseases. Previous genome screens and studies focused on candidate genes have provided evidence for genetic linkage between polymorphic DNA markers and 15 putative IDDM susceptibility loci, designated IDDM1-IDDM15. We have carried out a second-generation screen of the genome for linkage and analysed the data by multipoint linkage methods. An initial panel of 212 affected sibpairs (ASPs) was genotyped for 438 markers spanning all autosomes, and an additional 467 ASPs were used for follow-up genotyping. Other than the well-established linkage with the HLA region at chromosome 6p21.3, there was only one region, located on chromosome 1q and not previously reported, where the log likelihood ratio (lod) was greater than 3. Lods between 1.0 and 1.8 were found in six other regions, three of which have been reported in other studies. Another reported region, on chromosome 6q and loosely linked to HLA, also had an elevated lod. Little or no support was found for most reported IDDM loci (lods were less than 1), despite larger sample sizes in the present study.

A genome-wide search for human non-insulin-dependent (type 2) diabetes genes reveals a major susceptibility locus on chromosome 2.

Non-insulin-dependent (type 2) diabetes mellitus (NIDDM) is a common disorder of middle-aged individuals characterized by high blood glucose levels which, if untreated, can cause serious medical complications and lead to early death. Genetic factors play an important role in determining susceptibility to this disorder. However, the number of genes involved, their chromosomal location and the magnitude of their effect on NIDDM susceptibility are unknown. We have screened the human genome for susceptibility genes for NIDDM using non-and quasi-parametric linkage analysis methods in a group of Mexican American affected sib pairs. One marker, D2S125, showed significant evidence of linkage to NIDDM and appears to be a major factor affecting the development of diabetes mellitus in Mexican Americans. We propose that this locus be designated NIDDM1.

Linkage and association between insulin-dependent diabetes mellitus (IDDM) susceptibility and markers near the glucokinase gene on chromosome 7.

Insulin-dependent diabetes mellitus (IDDM) is characterized by autoimmune destruction of the insulin secreting beta-cells of the pancreas and subsequent disruption of glucose metabolism. The tendency of IDDM to cluster in families and the modest (36%) concordance rate in monozygotic twins indicates that both genetic and environmental factors contribute to IDDM susceptibility. Recent genome-wide searches using the affected sib-pair (ASP) approach have provided evidence for novel loci, in addition to HLA (IDDM1) and insulin (IDDM2), which show evidence of linkage to IDDM (P < 0.05). We have evaluated 35 microsatellite marker loci on human chromosome 7 for linkage to IDDM in 339 affected sib-pair families. Increased sharing of parental haplotypes in affected sib-pairs was detected for two microsatellite markers flanking glucokinase (GCK). Preferential transmission of alleles to affected offspring was observed at one of these marker loci, GCK3, indicating linkage disequilibrium between the marker and a disease susceptibility locus. This combination of linkage and disease association suggests that glucokinase, or a gene in the vicinity, plays an important part in IDDM susceptibility.

Linkage and association studies in insulin-dependent diabetes with a new dinucleotide repeat polymorphism at the GAD65 locus.

Glutamic acid decarboxylase (GAD) is an important autoantigen in insulin-dependent diabetes mellitus (IDDM). The islet cell specific, 65 kDa form of GAD (GAD65) is encoded by a gene on chromosome 10p. Recently, a putative IDDM susceptibility gene has been localized to the same general region based on allele sharing for the anonymous marker D10S193. To determine whether variation in the GAD65 gene plays a role in genetic susceptibility to IDDM, possibly explaining the reported evidence for linkage on 10p, we isolated cosmid clones containing GAD65, and identified a highly polymorphic dinucleotide repeat physically linked to the gene. This GAD65 microsatellite marker, along with the other 10p markers D10S193 and D10S211, were used to genotype the members of 186 multiplex IDDM families with 2 or more affected siblings. Linkage analysis localized the GAD65 marker 5.6 cM from D10S193. Sharing of alleles identical by descent (IBD) in affected sib pairs for each of the markers was determined and compared to the expected 50:50 distribution under an assumption of no linkage. Analyses were also carried out after stratification of the data for sharing of HLA class.II alleles. The family data for GAD65 were further assessed for allelic association with IDDM using the transmission/disequilibrium test. No significant deviations from expected values were observed in any of these tests, suggesting that variation in the GAD65 gene does not play a significant role in genetic susceptibility to IDDM.