Joseph K. Bedree scite author profile

A monumental milestone in human microbiology within the past few decades was uncovering the vast microbial abundance and diversity associated with the human body (Peterson et al. 2009; Chen et al. 2010; Dewhirst et al. 2010). These microbial communities coevolve with their host and significantly influence health and disease in humans (Nishihara and Koseki 2004; Ley et al. 2006). Due to its easy access and clinical relevance, the human oral cavity has become a model for advanced microbiome analysis to gain an understanding of microbial ecology and functionality (Chen et al. 2010; Edlund et al. 2013; Edlund et al. 2015; Baker et al. 2017; Nowicki et al. 2018). However, a significant portion (≈30%) of oral microbial species remains uncultivable (http://www.homd.org); thus, their metabolic potential, physiologic properties, ecologic function, and influence in human health are unknown. A primary example is the bacterial phylum Saccharibacteria (formerly known as phylum TM7 and referred to as such in this review). Members of the TM7 phylum are ubiquitous in the human oral microbiome, and accumulating evidence links their association with periodontal disease. However, due to the lack of cultivated representatives, knowledge of TM7 was scarce until the recent cultivation of the first oral strain, which provided the first view on its unique cell size and lifestyle and the means to study these bacteria (He et al. 2015). In this review, we provide an update on the current knowledge of this enigmatic bacterial phylum. TM7: Ubiquitous yet "Enigmatic" Bacterial Phylum Associated with the Human Oral Cavity General Introduction to TM7 TM7 16S rRNA gene sequences were first detected from a peat bog sample in northern Germany (TM stands for Torf, mittlere Schicht; German for "a middle layer of peat") in the mid-1990s by using a culture-independent molecular approach (Rheims, Rainey, and Stackebrandt 1996; Rheims, Sproer, et al. 1996) with highly divergent sequences from a number of additional candidate bacteria, such as TM6 (McLean et al. 2013). TM7 831671J DRXXX10.

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Insights Obtained by Culturing Saccharibacteria With Their Bacterial Hosts

Bor

Collins

Murugkar

et al. 2020

J Dent Res

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Oral microbiome research has moved from asking “Who’s there?” to “What are they doing?” Understanding what microbes “do” involves multiple approaches, including obtaining genomic information and examining the interspecies interactions. Recently we isolated a human oral Saccharibacteria (TM7) bacterium, HMT-952, strain TM7x, which is an ultrasmall parasite of the oral bacterium Actinomyces odontolyticus. The host-parasite interactions, such as phage-bacterium or Saccharibacteria–host bacterium, are understudied areas with large potential for insight. The Saccharibacteria phylum is a member of Candidate Phyla Radiation, a large lineage previously devoid of cultivated members. However, expanding our understanding of Saccharibacteria-host interactions requires examining multiple phylogenetically distinct Saccharibacteria-host pairs. Here we report the isolation of 3 additional Saccharibacteria species from the human oral cavity in binary coculture with their bacterial hosts. They were obtained by filtering ultrasmall Saccharibacteria cells free of other larger bacteria and inoculating them into cultures of potential host bacteria. The binary cocultures obtained could be stably passaged and studied. Complete closed genomes were obtained and allowed full genome analyses. All have small genomes (<1 Mb) characteristic of parasitic species and dramatically limited de novo synthetic pathway capabilities but include either restriction modification or CRISPR-Cas systems as part of an innate defense against foreign DNA. High levels of gene synteny exist among Saccharibacteria species. Having isolates growing in coculture with their hosts allowed time course studies of growth and parasite-host interactions by phase contrast, fluorescence in situ hybridization, and scanning electron microscopy. The cells of the 4 oral Saccharibacteria species are ultrasmall and could be seen attached to their larger Actinobacteria hosts. Parasite attachment appears to lead to host cell death and lysis. The successful cultivation of Saccharibacteria species has significantly expanded our understanding of these ultrasmall Candidate Phyla Radiation bacteria.

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Phenotypic and Physiological Characterization of the Epibiotic Interaction Between TM7x and Its Basibiont Actinomyces

et al. 2015

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Despite many examples of obligate epibiotic symbiosis (one organism living on the surface of another) in nature, such an interaction has rarely been observed between two bacteria. Here, we further characterize a newly reported interaction between a human oral obligate parasitic bacterium TM7x (cultivated member of Candidatus Saccharimonas formerly Candidate Phylum TM7), and its basibiont Actinomyces odontolyticus species (XH001), providing a model system to study epiparasitic symbiosis in the domain Bacteria. Detailed microscopic studies indicate that both partners display extensive morphological changes during symbiotic growth. XH001 cells manifested as short rods in monoculture, but displayed elongated and hyphal morphology when physically associated with TM7x. Interestingly, these dramatic morphological changes in XH001 were also induced in oxygen-depleted conditions, even in the absence of TM7x. Targeted qRT-PCR analyses revealed that both the physical association with TM7x as well as oxygen depletion triggered up-regulation of key stress response genes in XH001, and in combination, these conditions act in an additive manner. TM7x and XH001 co-exist with relatively uniform cell morphologies under nutrient-replete conditions. However, upon nutrient depletion, TM7x-associated XH001 displayed a variety of cell morphologies, including swollen cell body, clubbed ends and even cell lysis, and a large portion of TM7x cells transformed from ultrasmall cocci into elongated cells. Our study demonstrates a highly dynamic interaction between epibiont TM7x and its basibiont XH001 in response to physical association or environmental cues such as oxygen level and nutritional status, as reflected by their morphological and physiological changes during symbiotic growth.

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Episymbiotic Saccharibacteria suppresses gingival inflammation and bone loss in mice through host bacterial modulation

Chipashvili¹,

Utter

Bedree

et al. 2021

Cell Host & Microbe

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Quorum Sensing Modulates the Epibiotic-Parasitic Relationship Between Actinomyces odontolyticus and Its Saccharibacteria epibiont, a Nanosynbacter lyticus Strain, TM7x

Bedree

Bor²,

Cen³

et al. 2018

Front. Microbiol.

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The ultra-small, obligate parasitic epibiont, TM7x, the first and only current member of the long-elusive Saccharibacteria (formerly the TM7 phylum) phylum to be cultivated, was isolated in co-culture with its bacterial host, Actinomyces odontolyticus subspecies actinosynbacter, XH001. Initial phenotypic characterization of the TM7x-associated XH001 co-culture revealed enhanced biofilm formation in the presence of TM7x compared to XH001 as monoculture. Genomic analysis and previously published transcriptomic profiling of XH001 also revealed the presence of a putative AI-2 quorum sensing (QS) operon, which was highly upregulated upon association of TM7x with XH001. This analysis revealed that the most highly induced gene in XH001 was an lsrB ortholog, which encodes a putative periplasmic binding protein for the auto inducer (AI)-2 QS signaling molecule. Further genomic analyses suggested the lsrB operon in XH001 is a putative hybrid AI-2/ribose transport operon as well as the existence of a luxS ortholog, which encodes the AI-2 synthase. In this study, the potential role of AI-2 QS in the epibiotic-parasitic relationship between XH001 and TM7x in the context of biofilm formation was investigated. A genetic system for XH001 was developed to generate lsrB and luxS gene deletion mutants in XH001. Phenotypic characterization demonstrated that deletion mutations in either lsrB or luxS did not affect XH001’s growth dynamic, mono-species biofilm formation capability, nor its ability to associate with TM7x. TM7x association with XH001 induced lsrB gene expression in a luxS-dependent manner. Intriguingly, unlike wild type XH001, which displayed significantly increased biofilm formation upon establishing the epibiotic-parasitic relationship with TM7x, XH001ΔlsrB, and XH001ΔluxS mutants failed to achieve enhanced biofilm formation when associated with TM7x. In conclusion, we demonstrated a significant role for AI-2 QS in modulating dual-species biofilm formation when XH001 and TM7x establish their epibiotic-parasitic relationship.

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Joseph K. Bedree

Saccharibacteria (TM7) in the Human Oral Microbiome

Insights Obtained by Culturing Saccharibacteria With Their Bacterial Hosts

Phenotypic and Physiological Characterization of the Epibiotic Interaction Between TM7x and Its Basibiont Actinomyces

Episymbiotic Saccharibacteria suppresses gingival inflammation and bone loss in mice through host bacterial modulation

Quorum Sensing Modulates the Epibiotic-Parasitic Relationship Between Actinomyces odontolyticus and Its Saccharibacteria epibiont, a Nanosynbacter lyticus Strain, TM7x

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