Sequence and functional analysis of GLUT10: a glucose transporter in the Type 2 diabetes-linked region of chromosome 20q12-13.1.

We have carried out a detailed sequence and functional analysis of a novel human facilitative glucose transporter, designated GLUT10, located in the Type 2 diabetes-linked region of human chromosome 20q12-13.1. The GLUT10 gene is located between D20S888 and D20S891 and is encoded by 5 exons spanning 26.8 kb of genomic DNA. The human GLUT10 cDNA encodes a 541 amino acid protein that shares between 31 and 35% amino acid identity with human GLUT1-8. The predicted amino acid sequence of GLUT10 is nearly identical in length to the recently described GLUT9 homologue, but is longer than other known members of the GLUT family. In addition, we have cloned the mouse cDNA homolog of GLUT10 that encodes a 537 amino acid protein that shares 77.3% identity with human GLUT10. The amino acid sequence probably has 12 predicted transmembrane domains and shares characteristics of other mammalian glucose transporters. Human and mouse GLUT10 retain several sequence motifs characteristic of mammalian glucose transporters including VP497ETKG in the cytoplasmic C-terminus, G73R[K,R] between TMD2 and TMD3 (PROSITE PS00216), VD92RAGRR between TMD8 and TMD9 (PROSITE PS00216), Q242QLTG in TMD7, and tryptophan residues W430 (TMD10) and W454 (TMD11), that correspond to trytophan residues previously implicated in GLUT1 cytochalasin B binding and hexose transport. Neither human nor mouse GLUT10 retains the full P[E,D,N]SPR motif after Loop6 but instead is replaced with P186AG[T,A]. A PROSITE search also shows that GLUT10 has lost the SUGAR TRANSPORT 2 pattern (PS00217), a result of the substitution G113S in TMD4, while all other known human GLUTs retain the glycine and the pattern match. The significance of this substitution is unknown. Sites for N-linked glycosylation are predicted at N334ATG between TMD8 and TMD9 and N526STG in the cytoplasmic C-terminus. Northern hybridization analysis identified a single 4.4-kb transcript for GLUT10 in human heart, lung, brain, liver, skeletal muscle, pancreas, placenta, and kidney. By RT-PCR analysis, GLUT10 mRNA was also detected in fetal brain and liver. When expressed in Xenopus oocytes, human GLUT10 exhibited 2-deoxy-D-glucose transport with an apparent Km of approximately 0.3 mM. D-Glucose and D-galactose competed with 2-deoxy-D-glucose and transport was inhibited by phloretin. The gene localization and functional properties suggest a role for GLUT10 in glucose metabolism and Type 2 diabetes.

A high-resolution 6.0-megabase transcript map of the type 2 diabetes susceptibility region on human chromosome 20.

Recent linkage studies and association analyses indicate the presence of at least one type 2 diabetes susceptibility gene in human chromosome region 20q12-q13.1. We have constructed a high-resolution 6.0-megabase (Mb) transcript map of this interval using two parallel, complementary strategies to construct the map. We assembled a series of bacterial artificial chromosome (BAC) contigs from 56 overlapping BAC clones, using STS/marker screening of 42 genes, 43 ESTs, 38 STSs, 22 polymorphic, and 3 BAC end sequence markers. We performed map assembly with GraphMap, a software program that uses a greedy path searching algorithm, supplemented with local heuristics. We anchored the resulting BAC contigs and oriented them within a yeast artificial chromosome (YAC) scaffold by observing the retention patterns of shared markers in a panel of 21 YAC clones. Concurrently, we assembled a sequence-based map from genomic sequence data released by the Human Genome Project, using a seed-and-walk approach. The map currently provides near-continuous coverage between SGC32867 and WI-17676 ( approximately 6.0 Mb). EST database searches and genomic sequence alignments of ESTs, mRNAs, and UniGene clusters enabled the annotation of the sequence interval with experimentally confirmed and putative transcripts. We have begun to systematically evaluate candidate genes and novel ESTs within the transcript map framework. So far, however, we have found no statistically significant evidence of functional allelic variants associated with type 2 diabetes. The combination of the BAC transcript map, YAC-to-BAC scaffold, and reference Human Genome Project sequence provides a powerful integrated resource for future genomic analysis of this region.

Identification and characterization of PRKCBP1, a candidate RACK-like protein.

The receptors for activated C-kinase (RACK) family of proteins function as anchors for activated protein kinase C (PKC) isoenzymes. Using a monoclonal antibody to RACK1 in the screening of a human hippocampus cDNA library, we identified a novel member of the RACK family, designated PRKCBP1. Immunoprecipitation assays performed with a GST-fused PRKCBP1 protein suggest the carboxy terminus of PRKCBP1 interacts specifically with PKCbetaI. Northern analysis detected a 3.1-kb PRKCBP1 transcript in all tissues examined including brain, heart, liver, lung, pancreas, skeletal muscle, kidney, and spleen. The PRKCBP1 gene has been localized to human Chromosome (Chr) 20q12-13.1. Several groups have reported evidence for genetic linkage of Type II diabetes to this region in Caucasian families. This localization, combined with the observation that abnormalities in the activation, translocation, and inhibition of PKC occur in the development of Type II diabetes, suggested that PRKCBP1 was a candidate for contributing to Type II diabetes. We determined the PRKCBP1 coding sequence is 1845 bp in length, dispersed over 9 exons, spanning approximately 34 kb of genomic DNA. SSCP analysis was used to screen PRKCBP1 coding regions for mutations or polymorphisms in 100 Caucasian Type II diabetics and 100 Caucasian unaffected individuals. A silent C/T transition (bp1413, Thr137) was present in 23% of both diabetic and control individuals. A C/T transition (bp198) was also identified in a single diabetic individual, which resulted in no coding change (Ser66). The results of this analysis suggest that PRKCBP1 coding variations are uncommon and do not contribute to Type II diabetes in the general population.

Analysis of the HNF4 alpha gene in Caucasian type II diabetic nephropathic patients.

AIMS/HYPOTHESIS: Linkage and association studies in Caucasian patients with Type II (non-insulin-dependent) diabetes mellitus suggest that one or more diabetes susceptibility gene(s) reside within human chromosome 20q12-13.1. This region of chromosome 20 contains the maturity-onset diabetes of the young type 1 gene, HNF4 alpha. The purpose of this study was to assess the possible involvement of HNF4 alpha in Type II diabetes. METHODS: Mutation analysis was done on the 12 exons and promoter regions of the HNF4 alpha gene in 182 Caucasian diabetic nephropathic patients and 100 Caucasian control subjects. The functional consequences of a novel promoter mutation were examined using a reporter system in the HepG2 liver cell line and electrophoretic mobility shift assays. RESULTS: We identified two novel mutations in the HNF4 alpha, an R323H missense mutation in exon 8, and a 7 bp deletion (delta 7) in the proximal promoter region resulting in deletion of a single putative Sp1 binding site. Using a reporter assay system, the delta 7 sequence was found to exhibit a 51.2% (standard error +/- 4.2%) reduction in promoter activity relative to the normal sequence. In electrophoretic mobility shift assays using specific and non-specific competitors, the delta 7 sequence had a 45.5% (range 40.4-46.6) reduction in binding compared with the normal sequence. The delta 7 allele occurs in a family with multiple cases of Type II diabetes in a pattern consistent with coinheritance of the delta 7 allele and diabetes. CONCLUSION/INTERPRETATION: Analysis of the HNF4 alpha gene revealed two possible mutations in 182 diabetic patients which suggests that the HNF4 alpha gene does not make a large contribution to diabetes susceptibility in the general population of Caucasian diabetic nephropathic patients. Functional analysis of the delta 7 promoter deletion suggests, however, that promoter mutations in otherwise normal genes could contribute to diabetes susceptibility.

A physical map of the 20q12-q13.1 region associated with type 2 diabetes.

Several recent genetic studies have suggested linkage of Type 2 diabetes (non-insulin-dependent diabetes mellitus) susceptibility to a region of chromosome 20q12-q13.1. To facilitate the identification and cloning of a diabetes susceptibility gene(s) in this region, we have constructed correlated radiation hybrid and YAC/BAC contig physical maps of the region. A high-resolution radiation hybrid map encompassing 9.5 Mb between the PLC and the CEBPB genes was constructed using 68 markers: 25 polymorphic markers, 15 known genes, 21 ESTs, and 7 random genomic sequences. The physical order of the polymorphic markers within this radiation hybrid map is consistent with published genetic maps. A YAC/BAC contig that gives continuous coverage between PLC and CEBPB was also constructed. This contig was constructed from 24 YACs, 34 BACs, and 1 P1 phage clone onto which 71 markers were mapped: 23 polymorphic markers, 12 genes, 24 ESTs, and 12 random genomic sequences. The radiation hybrid map and YAC/BAC physical map enable precise mapping of newly identified transcribed sequences and polymorphic markers that will aid in linkage and linkage disequilibrium studies and facilitate identification and cloning of candidate Type 2 diabetes susceptibility genes residing in 20q12-q13.1.