Improved high-throughput MHC typing for non-model species using long-read sequencing

The major histocompatibility complex (MHC) plays a critical role in the vertebrate immune system. Accurate MHC typing is critical to understanding not only host fitness and disease susceptibility, but also the mechanisms underlying host-pathogen co-evolution. However, due to the high degree of gene duplication and diversification of MHC genes, it is often technically challenging to accurately characterise MHC genetic diversity in non-model species. Here we conducted a systematic review to identify common issues associated with current widely used MHC typing approaches. Then to overcome these challenges, we developed a long-read based MHC typing method along with a new analysis pipeline. Our approach enables the sequencing of fully phased MHC alleles spanning all key functional domains and the separation of highly similar alleles as well as the removal of technical artefacts such as PCR heteroduplexes and chimeras. Using this approach, we performed population-scale MHC typing in the Tasmanian devil (Sarcophilus harrisii), revealing previously undiscovered MHC functional diversity in this endangered species. Our new method provides a better solution for addressing research questions that require high MHC typing accuracy. Since the method is not limited by species or the number of genes analysed, it will be applicable for studying not only the MHC but also other complex gene families.

Automated summary

The major histocompatibility complex (MHC) is crucial for the vertebrate immune system, but accurately characterizing MHC genetic diversity in non-model species is technically challenging due to gene duplication and diversification. A new long-read based MHC typing method has been developed to address these challenges and provide better solutions for high accuracy MHC typing in research. This approach allows for population-scale MHC typing in various species, revealing new insights into genetic diversity.