Functional sequencing read annotation for high precision microbiome analysis

Abstract

The vast majority of microorganisms on Earth reside in often-inseparable environment-specific communities-microbiomes. Meta-genomic/-transcriptomic sequencing could reveal the otherwise inaccessible functionality of microbiomes. However, existing analytical approaches focus on attributing sequencing reads to known genes/genomes, often failing to make maximal use of available data. We created faser (functional annotation of sequencing reads), an algorithm that is optimized to map reads to molecular functions encoded by the read-correspondent genes. The mi-faser microbiome analysis pipeline, combining faser with our manually curated reference database of protein functions, accurately annotates microbiome molecular functionality. mi-faser’s minutes-per-microbiome processing speed is significantly faster than that of other methods, allowing for large scale comparisons. Microbiome function vectors can be compared between different conditions to highlight environment-specific and/or time-dependent changes in functionality. Here, we identified previously unseen oil degradation-specific functions in BP oil-spill data, as well as functional signatures of individual-specific gut microbiome responses to a dietary intervention in children with Prader-Willi syndrome. Our method also revealed variability in Crohn’s Disease patient microbiomes and clearly distinguished them from those of related healthy individuals. Our analysis highlighted the microbiome role in CD pathogenicity, demonstrating enrichment of patient microbiomes in functions that promote inflammation and that help bacteria survive it.

Publication
Nucleic Acids Research
Chengsheng Zhu
Chengsheng Zhu
PostDoctoral Associate

Hello! 你好!こんにちは!

Maximilian Miller
Maximilian Miller
PostDoctoral Associate

improving variant effect predictions, deciphering metagenomes and creating an efficient service infrastructure

Srinayani Marpaka
Srinayani Marpaka
Student

Current position: Citigroup (updated 2017)

Yana Bromberg
Yana Bromberg
Principal Investigator - Professor of Bioinformatics

My research focuses on deciphering the DNA blueprints of life’s molecular machinery