Bacillota


The Bacillota are a phylum of bacteria, most of which have Gram-positive cell wall structure. They have round cells, called cocci, or rod-like forms. A few Bacillota, such as Megasphaera, Pectinatus, Selenomonas, and Zymophilus from the class Negativicutes, have a porous pseudo-outer membrane that causes them to stain Gram-negative. Many Bacillota produce endospores, which are resistant to desiccation and can survive extreme conditions. They are found in various environments, and the group includes some notable pathogens. Those in one family, the Heliobacteria, produce energy through anoxygenic photosynthesis. Bacillota play an important role in beer, wine, and cider spoilage.

Taxonomy

The renaming of phyla such as Firmicutes in 2021 remains controversial among microbiologists, many of whom continue to use the earlier names of long standing in the literature. The name "Firmicutes" was derived from the Latin words for 'tough skin', referring to the thick cell wall typical of bacteria in this phylum. Scientists once classified the Firmicutes to include all Gram-positive bacteria, but have recently defined them to be of a core group of related forms called the low-G+C group, in contrast to the Actinomycetota.
The group is typically divided into the Clostridia, which are anaerobic, and the Bacilli, which are obligate or optional aerobes. On phylogenetic trees, the first two groups show up as paraphyletic or polyphyletic, as do their main genera, Clostridium and Bacillus. However, Bacillota as a whole is generally believed to be monophyletic, or paraphyletic with the exclusion of Mollicutes.

Evolution

The Bacillota are thought by some to be the source of the archaea, by models where the archaea branched relatively late from bacteria, rather than forming an independently originating early lineage from the last universal common ancestor of cellular life.

Phylogeny

The currently accepted taxonomy based on the List of Prokaryotic names with Standing in Nomenclature and the National Center for Biotechnology Information.

Genera

More than 274 genera were considered as of 2016 to be within the Bacillota phylum, notable genera of Bacillota include:
Bacilli, order Bacillales
Bacilli, order Lactobacillales
Clostridia
  • Clostridioides
  • Clostridium
  • Selenomonas
Erysipelotrichia
  • ''Erysipelothrix''

    Clinical significance

Bacillota can make up between 11% to 95% of the human gut microbiome. The phylum Bacillota as part of the gut microbiota has been shown to be involved in energy resorption, and potentially related to the development of diabetes and obesity. In multiple studies a higher abundance of Bacillota has been found in obese individuals than in lean controls. A higher relative abundance of Bacillota was seen in mice fed a western diet than in mice fed a standard low fat/ high polysaccharide diet. The higher amount of Bacillota was also correlated with more adiposity and body weight within mice. Specifically, within obese mice, the class Mollicutes was the most common. When the microbiota of obese mice with this higher Bacillota abundance was transplanted into the guts of germ-free mice, the germ-free mice gained more fat than those transplanted with the microbiota of lean mice with lower Bacillota abundance.
The presence of Christensenella, isolated from human faeces, has been found to correlate with lower body mass index.
Faecalibacterium prausnitzii is a member of the Bacillota phylum that may have anti-inflammatory effects in humans. This species is associated with reduced low-grade inflammation in obesity. Additionally, patients with inflammatory bowel disease tend to have lower levels of ''F. prausnitzii.''

Pathogenicity

Several Bacillota species are common human pathogens. Examples include Bacillus anthracis, ''Clostridioides difficile, and Clostridium botulinum. Others, such as Staphylococcus aureus and Enterococcus faecalis, are opportunistic pathogens that cause illness in a minority of their hosts. Antibiotic resistance is an increasingly common problem with these infections. Methicillin-resistant S. aureus'' is estimated to cause 100,000 deaths per year.