The role of human host genetics in tuberculosis resistance

ABSTRACTCandida albicansgrows within a wide range of host niches, and this adaptability enhances its success as a commensal and as a pathogen. The telomere-associatedTLOgene family underwent a recent expansion from one or two copies in other CUG clade members to 14 expressed copies inC. albicans. This correlates with increased virulence and clinical prevalence relative to those of otherCandidaclade species. The 14 expressedTLOgene family members have a conserved Med2 domain at the N terminus, suggesting a role in general transcription. The C-terminal half is more divergent, distinguishing three clades: clade α and clade β have no introns and encode proteins that localize primarily to the nucleus; clade γ sometimes undergoes splicing, and the gene products localize within the mitochondria as well as the nuclei. Additionally,TLOα genes are generally expressed at much higher levels than areTLOγ genes. We propose that expansion of theTLOgene family and the predicted role of Tlo proteins in transcription regulation provideC. albicanswith the ability to adapt rapidly to the broad range of different environmental niches within the human host.

Download Full-text

Host genetic associations with the gut microbiota in HIV-1-infected subjects: a pilot exploratory study

10.1101/427922 ◽

2018 ◽

Author(s):

Yolanda Guillén ◽

Marc Noguera-Julian ◽

Javier Rivera ◽

Maria Casadellà ◽

Muntsa Rocafort ◽

...

Keyword(s):

Gut Microbiota ◽

Methanogenic Archaea ◽

Genetic Associations ◽

Host Genetics ◽

Genetic Landscape ◽

Host Genetic ◽

Gene Richness ◽

The Impact ◽

Hiv 1

AbstractThe impact of host genetics on gut microbial dynamics is debated. No study to date has investigated the possible role of host genetics in shaping the gut microbiota in HIV-1 infected subjects. With the aim of generating preliminary data to inform future host genetic studies, we performed an exploratory host exome analysis of 147 subjects either infected or at risk of becoming infected with HIV-1 from the MetaHIV cohort in Barcelona. Using a DNA microarray chip, we sought to identify host genetic variants associated to three specific microbial features with a potentially inheritable component, and which were previously found to be associated with gut dysbiosis in HIV infection, i.e.: gut enterotype, presence of methanogenic archaea and microbial gene richness. After correction for multiple comparisons, we did not observe any statistically significant association between the host’s genetic landscape and the explored gut microbiome traits. These findings will help design future, adequately-powered studies to assess the influence of host genetics in the microbiome of HIV-1-infected subjects.

Download Full-text

Acquisition of Oral Microbiota is Driven by Environment, Not Host Genetics

10.21203/rs.3.rs-17146/v3 ◽

2020 ◽

Author(s):

Chiranjit Mukherjee ◽

Christina O. Moyer ◽

Heidi M. Steinkamp ◽

Shahr B. Hashmi ◽

Xiaohan Guo ◽

...

Keyword(s):

Genetic Relatedness ◽

Bacterial Species ◽

Oral Microbiome ◽

Individual Species ◽

Shared Environment ◽

Oral Microbiota ◽

Host Genetics ◽

Early Effects ◽

The Many

Abstract Background: The oral microbiota is acquired very early, but the factors shaping its acquisition are not well understood. Previous studies comparing monozygotic (MZ) and dizygotic (DZ) twins have suggested that host genetics plays a role. However, all twins share an equal portion of their parent’s genome, so this model is not informative for studying parent-to-child transmission. We used a novel study design that allowed us to directly examine the genetics of transmission by comparing the oral microbiota of biological versus adoptive mother-child dyads. Results: No difference was observed in how closely oral bacterial community profiles matched for adoptive versus biological mother-child pairs, indicating little if any effect of host genetics on the fidelity of transmission. Both adopted and biologic children more closely resembled their own mother as compared to unrelated women, supporting the role of contact and environment. Mother-child strain similarity increased with the age of the child, ruling out early effects of host genetic influence that are lost over time. No effect on the fidelity of mother-child strain sharing from vaginal birth or breast feeding was seen. Analysis of extended families showed that fathers and mothers were equally similar to their children, and that cohabitating couples showed even greater strain similarity than mother-child pairs. These findings support the role of contact and shared environment, and age, but not genetics, as determinants of microbial transmission, and were consistent at both species and strain level resolutions, and across multiple oral habitats. In addition, analysis of individual species all showed similar results. Conclusions: The host is clearly active in shaping the composition of the oral microbiome, since only a few of the many bacterial species in the larger environment are capable of colonizing the human oral cavity. Our findings suggest that these host mechanisms are universally shared among humans, since no effect of genetic relatedness on fidelity of microbial transmission could be detected. Instead our findings point towards contact and shared environment being the driving factors of microbial transmission, with a unique combination of these factors ultimately shaping the highly personalized human oral microbiome.

Download Full-text