Islet autoantibody seroconversion in type-1 diabetes is associated with metagenome-assembled genomes in infant gut microbiomes

Zhang, Li; Jonscher, Karen R.; Zhang, Zuyuan; Xiong, Yi; Mueller, Ryan S.; Friedman, Jacob E.; Pan, Chongle

Islet autoantibody seroconversion in type-1 diabetes is associated with metagenome-assembled genomes in infant gut microbiomes

Li Zhang, Karen R. Jonscher, Zuyuan Zhang, Yi Xiong, Ryan S. Mueller, Jacob E. Friedman and Chongle Pan ()
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Li Zhang: University of Oklahoma Health Sciences Center
Karen R. Jonscher: University of Oklahoma Health Sciences Center
Zuyuan Zhang: University of Oklahoma
Yi Xiong: University of Oklahoma
Ryan S. Mueller: Oregon State University
Jacob E. Friedman: University of Oklahoma Health Sciences Center
Chongle Pan: University of Oklahoma Health Sciences Center

Nature Communications, 2022, vol. 13, issue 1, 1-14

Abstract: Abstract The immune system of some genetically susceptible children can be triggered by certain environmental factors to produce islet autoantibodies (IA) against pancreatic β cells, which greatly increases their risk for Type-1 diabetes. An environmental factor under active investigation is the gut microbiome due to its important role in immune system education. Here, we study gut metagenomes that are de-novo-assembled in 887 at-risk children in the Environmental Determinants of Diabetes in the Young (TEDDY) project. Our results reveal a small set of core protein families, present in >50% of the subjects, which account for 64% of the sequencing reads. Time-series binning generates 21,536 high-quality metagenome-assembled genomes (MAGs) from 883 species, including 176 species that hitherto have no MAG representation in previous comprehensive human microbiome surveys. IA seroconversion is positively associated with 2373 MAGs and negatively with 1549 MAGs. Comparative genomics analysis identifies lipopolysaccharides biosynthesis in Bacteroides MAGs and sulfate reduction in Anaerostipes MAGs as functional signatures of MAGs with positive IA-association. The functional signatures in the MAGs with negative IA-association include carbohydrate degradation in lactic acid bacteria MAGs and nitrate reduction in Escherichia MAGs. Overall, our results show a distinct set of gut microorganisms associated with IA seroconversion and uncovered the functional genomics signatures of these IA-associated microorganisms

Date: 2022
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DOI: 10.1038/s41467-022-31227-1

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