Variation analysis and gene annotation of eight MHC haplotypes: The MHC Haplotype Project

The human major histocompatibility complex (MHC) is contained within about 4 Mb on the short arm of chromosome 6 and is recognised as the most variable region in the human genome. The primary aim of the MHC Haplotype Project was to provide a comprehensively annotated reference sequence of a single, human leukocyte antigen-homozygous MHC haplotype and to use it as a basis against which variations could be assessed from seven other similarly homozygous cell lines, representative of the most common MHC haplotypes in the European population. Comparison of the haplotype sequences, including four haplotypes not previously analysed, resulted in the identification of >44,000 variations, both substitutions and indels (insertions and deletions), which have been submitted to the dbSNP database. The gene annotation uncovered haplotype-specific differences and confirmed the presence of more than 300 loci, including over 160 protein-coding genes. Combined analysis of the variation and annotation datasets revealed 122 gene loci with coding substitutions of which 97 were non-synonymous. The haplotype (A3-B7-DR15; PGF cell line) designated as the new MHC reference sequence, has been incorporated into the human genome assembly (NCBI35 and subsequent builds), and constitutes the largest single-haplotype sequence of the human genome to date. The extensive variation and annotation data derived from the analysis of seven further haplotypes have been made publicly available and provide a framework and resource for future association studies of all MHC-associated diseases and transplant medicine

Monolithically Integrated CMOS-Compatible III-V on Silicon Lasers

CMOS-compatible III–V lasers integrated on silicon are a crucial step to reduce power consumption and cost for next-generation optical transceivers. Here, we demonstrate a concept to co-integrate III-V lasers into a CMOS Silicon Photonics platform, in which lasers, photonics, and electronic circuitry share the same back end of line. Based on a bonded III–V epitaxial layer stack, ultra-thin laser devices, optically pumped lasing and coupling to silicon are demonstrated. Furthermore, we present all building blocks for electrically pumped laser devices.ISSN:1077-260