Fine Mapping of the Psoriasis Susceptibility Locus PSORS1 Supports HLA-C as the Susceptibility Gene in the Han Chinese Population

PSORS1 (psoriasis susceptibility gene 1) is a major susceptibility locus for psoriasis. Several fine-mapping studies have highlighted a 300-kb candidate region of PSORS1 where multiple biologically plausible candidate genes were suggested. The most recent study has indicated HLA-Cw6 as the primary PSORS1 risk allele within the candidate region in a Caucasian population. In this study, a family-based association analysis of the PSORS1 locus was performed by analyzing 10 polymorphic microsatellite markers from the PSORS1 region as well as HLA-B, HLA-C and CDSN loci in 163 Chinese families of psoriasis. Five marker loci show strong evidence (P<10−3), and one marker locus shows weak evidence (P = 0.04) for association. The haplotype cluster analysis showed that all the risk haplotypes are Cw6 positive and share a 369-kb region of homologous marker alleles which carries all the risk alleles, including HLA-Cw6 and CDSN*TTC, identified in this study. The recombinant haplotype analysis of the HLA-Cw6 and CDSN*TTC alleles in 228 Chinese families showed that the HLA-Cw6−/CDSN*TTC+ recombinant haplotype is clearly not associated with risk for psoriasis (T∶NT = 29:57, p = 0.0025) in a Chinese population, suggesting that the CDSN*TTC allele itself does not confer risk without the presence of the HLA-Cw6 allele. The further exclusion analysis of the non-risk HLA-Cw6−/CDSN*TTC+ recombinant haplotypes with common recombination breakpoints has allowed us to refine the location of PSORS1 to a small candidate region. Finally, we performed a conditional linkage analysis and showed that the HLA-Cw6 is a major risk allele but does not explain the full linkage evidence of the PSORS1 locus in a Chinese population. By performing a series of family-based association analyses of haplotypes as well as an exclusion analysis of recombinant haplotypes, we were able to refine the PSORS1 gene to a small critical region where HLA-C is a strong candidate to be the PSORS1 susceptibility gene

Biomarker: indications for microbial contributions to Recent and Late Jurassic carbonate deposits

Biomarker investigations were applied to the hydrocarbon fractions of three Recent (cyanobacterial mat, Lake Van microbialite and Lake Satonda microbialite) and two Late Jurassic carbonate samples obtained from sponge bioherms. The relative concentrations of n-alkanes, monomethyl alkanes, acyclic isoprenoids, steroids and hopanoids in these samples are studied and their probable biological precursors are discussed. Normal alkanes with carbon chain lenghts ranging from C15 to C34 and monomethyl alkanes ranging from C17 to C21 with a varying methyl branching pattern are found. The major hydrocarbons are low molecular (LMW) n-alkanes (C15 - C21) with a slight to strong predominance of n-heptadecane (C17). High molecular weight (HMW) n-alkanes occur in low to moderate relative concentrations showing a preference of odd-numbered compounds with a maximum at C29. Within the acyclic isoprenoids, pristane, phytane/phytene, pentamethyleicosane, squalane and lycopane could be identified. Polycyclic terpenoids of the sterane and/or hopane type are present in all carbonate samples. The carbon atom numbers of these compounds range from 27 to 29 and 27 to 32, respectively. These organic compounds identified can be attributed to various source organisms such as cyanobacteria, archaebacteria, algae and vascular plants. All hydrocarbon fractions of the samples are characterized by moderate to high relative concentrations of cmpounds derived from caynobacteria, signifying the role of these organisms as contributors to the Recent as well as to the Late Jurassic carbonate deposits

New strategies for efficient typing of HLA class-II loci DQB1 and DRB1 by using PyrosequencingTM

The characterization of genetic risk factors for complex diseases located on chromosome-6 frequently requires human leucocyte antigen (HLA) genotyping of large patient cohorts. Currently available methods do not support high-throughput HLA typing beyond the major allele group level. We, thus, developed a high-throughput approach for the HLA-DQB1 and HLA-DRB1 loci that is based on Pyrosequencing™. Pyrosequencing™ offers a higher degree of automation than direct sequencing or oligotyping. Using a dispensation order optimized for the particular HLA locus, rapid group typing and fine resolution can be achieved. We implemented the method for two important HLA loci - DQB1 and DRB1. The HLA-DQB1 typing method comprises the following steps: splitting the potential alleles after a generic polymerase chain reaction (PCR) amplification into groups with a first Pyrosequencing™ reaction and resolving the split allele groups by means of five further Pyrosequencing™ reactions. The HLA-DR gene family is known to be the most polymorphic one in the HLA class-II region because of a large number of DRB1 alleles. Because of this complex nature, HLA-DRB1 typing was performed by means of a combination of sequence-specific PCR typing and Pyrosequencing™. HLA-DQB1 typing and HLA-DRB1 typing were performed successfully by using standard DNA samples with the help of known HLA genotypes and in a blind study by using the samples from the Deutscher Zell Austausch 2002 and 2003. The approach was optimized and was practically tested for genotyping in disease association studies. Our well-elaborated Pyrosequencing™-based protocols offer a new alternative to the existing HLA class-II typing methods and represent a convenient and economic solution, a unique combination of high accuracy with high-sample throughput