Ensembl 2022.

Ensembl (https://www.ensembl.org) is unique in its flexible infrastructure for access to genomic data and annotation. It has been designed to efficiently deliver annotation at scale for all eukaryotic life, and it also provides deep comprehensive annotation for key species. Genomes representing a greater diversity of species are increasingly being sequenced. In response, we have focussed our recent efforts on expediting the annotation of new assemblies. Here, we report the release of the greatest annual number of newly annotated genomes in the history of Ensembl via our dedicated Ensembl Rapid Release platform (http://rapid.ensembl.org). We have also developed a new method to generate comparative analyses at scale for these assemblies and, for the first time, we have annotated non-vertebrate eukaryotes. Meanwhile, we continually improve, extend and update the annotation for our high-value reference vertebrate genomes and report the details here. We have a range of specific software tools for specific tasks, such as the Ensembl Variant Effect Predictor (VEP) and the newly developed interface for the Variant Recoder. All Ensembl data, software and tools are freely available for download and are accessible programmatically.

Widespread non-coding polymorphism in HLA class II genes of International HLA and Immunogenetics Workshop cell lines.

As the primary genetic determinant of immune recognition of self and non-self, the hyperpolymorphic HLA genes play key roles in disease association and transplantation. The large, variably sized HLA class II genes have historically been less well characterized than the shorter HLA class I genes. Here, we have used Pacific Biosciences Single Molecule Real-Time (SMRT®) DNA sequencing to perform four-field resolution HLA typing of HLA-DRB1/3/4/5, -DQA1, -DQB1, -DPA1 and -DPB1 from a panel of 181 B-lymphoblastoid cell lines from the International HLA and Immunogenetics Workshops. By interrogating all exons, introns, and the untranslated regions of these important reference cells, we have improved their HLA typing resolution on the IPD-IMGT/HLA database. We observed widespread non-coding polymorphism, with over twice as many unique genomic sequences identified compared with coding sequences (CDS). We submitted 263 unique sequences to the IPD-IMGT/HLA Database, often from multiple cell lines, including 114 confirmations of existing alleles, of which 30 were also extensions to full-length genomic sequences where only CDS was available previously. A total of 149 novel alleles were identified, largely differing from their closest reference allele sequences by a single nucleotide polymorphism (SNP). However, some highly divergent alleles were deemed to be recombinants, only detectable by full-length sequencing with long, phased reads. The fourth-field variation we observed allowed fine mapping of linkage disequilibrium patterns and haplotypes to particular ancestries. This study has highlighted the under-appreciated non-coding diversity in HLA class II genes, with potential implications for population genetic and clinical studies.

Extending the sequences of HLA class I alleles without full-length genomic coverage using single molecule real-time DNA sequencing.

The assignment of an HLA allele name to a sequence requires a comparison between the generated target sequence and a reference sequence on the IPD-IMGT/HLA database. Absence of a full-length reference sequence can result in the inability of HLA typing software to accurately compare and assign the sequence. We sequenced the most frequently seen HLA class I alleles on the Anthony Nolan register present in the database with only a partial genomic sequence, with the aim of increasing the number of complete reference sequences. We successfully extended 95 full-length HLA class I sequences and identified 13 novel variants. Increasing the number of full-length HLA class I reference sequences in the database has aided accuracy of HLA analysis tools for all histocompatibility and immunogenetics laboratories.

Single molecule real-time DNA sequencing of the full HLA-E gene for 212 reference cell lines.

We have developed a genotyping assay that produces fully phased, unambiguous HLA-E genotyping using Pacific Biosciences' single molecule real-time DNA sequencing. In total 212 cell lines were genotyped, including the panel of 107 established at the 10th International Histocompatibility Workshop. Our results matched the previously known HLA-E genotype in 94 (44.3%) cell lines, in all cases either improving or equalling previous genotyping resolution. Three (1.4%) cells had discrepant HLA-E genotyping data and 115 (54.2%) had no previous HLA-E data. The HLA-E genotypes for four (1.9%) cell lines resulted in a change of zygosity by identifying two distinct haplotypes. We discovered eight novel HLA-E alleles, extended the known reference sequence of seven and confirmed the existence of a further 10.