Anaerococcus

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Anaerococcus
Scientific classification
Domain:
Bacteria
Phylum:
Bacillota
Class:
Clostridia
Order:
Clostridiales
Family:
Peptoniphilaceae
Genus:
Anaerococcus

Ezaki et al. 2001
Species

Anaerococcus is a genus of bacteria. Its type species is Anaerococcus prevotii . [1] These bacteria are Gram-positive and strictly anaerobic. [2] [3] [4] The genus Anaerococcus was proposed in 2001. [2] [4] Its genome was sequenced in August 2009. The genus Anaerococcus is one of six genera classified within the group GPAC (Gram-Positive Anaerobic Cocci). [5] These six genera (Peptostreptococcus, Peptoniphilus, Parvimonas, Finegoldia, Murdochiella, and Anaerococcus) are found in the human body as part of the commensal human microbiota. [6] [7] [5]

Contents

It is commonly found in the human microbiome and is associated with various infections. [8] Most of the species in this genus can be found among microbes of the skin, human vagina, nasal cavity, oral cavity and feces, often as a pathogen found in ovarian abscesses, chronic wounds and vaginal discharge. [9] Moreover, some of the species can be isolated from foot ulcers and knee arthritis. [2] It can be present in urinary tract infections, chronic ulcers, pleural empyema, blood infections, and soft tissue infections. It is involved in polymicrobial infections. [10] Strains of Anaerococcus were found in the armpit microbiota suggesting some species in this genus could play a role in axillary odor. [10] [11]

Physiology

The genus Anaerococcus are non motile bacteria who can not form spores. [4] [12] [2] Depending on the species the arrangement can be different. The most common arrangements within this genus are pairs, tetrads, short chains and irregular formations. [10] [4] Their cells size can differ from 0.6μm to 0.9μm. [10] However, when they are grown using enrinched blood agar their size can go from 0.5μm to 2μm. [10] In this genus, there are more than one major cellular fatty acids: C18:1, C16:1, C18 and C16. [12] Most species in this genus are indole-negative and coaguase-negative. [10] In general, the species of Anaerococcus presents susceptibility to penicillins but are resistant to tetracycline, erythromycin and clindamycin. [9]

Metabolism

The genus Anaerococcus are classified as saccharolytic bacteria. [2] [13] Its species can be arranged from weakly saccharolytic (ex. A. prevotii, A. lactolyticus) to strongly saccharolytic (ex. A. hydrogenalis). [13] This genus can ferment carbohydrates weakly. [6] The major sources of energy use in the metabolism of Anaerococcus are peptones and aminoacids. [4] [10] The three major sugars fermented within this genus are glucose, mannose, fructose and sucrose. [12] [4] After fermenting the sugars, Anaerococcus produce weak acids as their metabolic end product. [13] Within these metabolic end products, this genus ca produce butyric acid, lactic acid, and some propionic and succinic acid. [12] Nonetheless, the major metabolite produced by Anaerococcus is butyrate. [13] [10] [2]

Species

Until recently, the genus Anaerococcus have 14 known species. [14] [9] Six of the species were initially classified in the genus Peptostreptococcus but then based on their characteristics were re-classified in the new genus Anaerococcus: A. hydrogenalis, A. lactolyticus, A. octavius, A. prevotii, A. tetradius, and A. vaginalis. [5] [2] Throughout the years, the specie who has been more commonly found on the body within this genus is A. prevotii. [9]

Anaerococcus octavius

Contrary to most of the species in the genus, Anaerococcus octavius was not related to human infections. [9] Nevertheless, recently a new case revealed A. octavius can cause bacteremia. [9] Even though it is uncommon, Anaerococcus octavius can be the cause for human infections. [9] Other studies have found A. octavius as part of the nasal, skin and vaginal normal flora. [9] [4] This bacteria can ferment ribose, glucose, and mannose. [4]

Anaerococcus prevotii

A. prevotii is normally found in vaginal discharge, human plasma and some types of abscesses - such as ovarian, peritoneal sacral and/or lung abscesses. [9] [6] Anaerococcus prevotii is part of the normal flora in the skin, oral cavity and the gut. [6] Studies has shown Anaerococcus prevotii presents resistance to Ceftazidime, Clindamycin, Levofloxacin. [9] Unlike the other species, A. prevotii can not ferment glucose. [15]

Anaerococcus vaginalis

A. vaginalis was first recovered from vaginal discharges and ovarian abscesses although this bacteria can also be found in pressure ulcers and diabetic foot. [4] [9] Some strains from this species can be indole-positive. [4]

Anaerococcus provencensis

A. provencensis was isolated from a cervical abscess. [16] This species can ferment lactose, unlike A. tetradius, A. prevotii, and A. octavius. [16] The first analysis made on Anaerococcus provencensis showed it is susceptible to penicillin G, imipenem, amoxillin, metronidazole, cefotetan and vancomycin. [16]

Anaerococcus senegalensis

A. senegalensis is one of the few species in the genus whose genome has been sequenced. [2] The genome has a size of 1,790,835 bp. [2] Analysis did not show presence of a plasmid. [2] Initially, Anaerococcus senegalensis was found in the fecal flora of a healthy person. [2]

Anaerococcus rubiinfantis

A.rubiinfantis was discovered from a stool sample taken from an infant with severe acute malnutrition in Senegal. [17] Based on a genomic analysis, Anaerococcus rubiinfantis has high antibiotic susceptibility. [17] For that reason this bacteria can be treated with common oral antibiotics. [17] A.rubiinfantis have catalase activity, which is not common from an anaerobic bacteria. [17]

Anaerococcus marasmi

A. marasmi was first found in 2016 from a stool sample on a child with marasmus. [14] Just like A. rubiinfantis, Anaerococcus marasmi is catalase positive. [14] A. marasmi can grow in a range of pH between 6.5 and 8. [14] Moreover, A. marasmi has a high 16S rRNA sequence similarity (97.6%) with A. prevotii [14]

Anaerococcus urinomassiliensis

A. urinomassiliensis was isolated from a urine sample of a male adolescent with membranoproliferative glomerulonephritis and autoimmune hepatitis. [18] It took 10 days of anaerobic incubation to observe growth from this bacteria. [18] Anaerococcus urinomassiliensis does not have either oxidase or catalase activity. [18]

Related Research Articles

<i>Actinomyces naeslundii</i> Species of bacterium

Actinomyces naeslundii is a Gram-positive, rod-shaped bacterium found in the mouth of humans. The species has been implicated in periodontal disease, as well as various tooth cavities. In other cases, A. naeslundii is associated with good oral health. It is one of the first bacteria to occupy the oral cavity and colonize the tooth's surface. It has also been isolated from women with bacterial vaginosis.

<i>Actinomyces</i> Genus of bacteria

Actinomyces is a genus of the Actinomycetia class of bacteria. They all are gram-positive. Actinomyces species are facultatively anaerobic and they grow best under anaerobic conditions. Actinomyces species may form endospores, and while individual bacteria are rod-shaped, Actinomyces colonies form fungus-like branched networks of hyphae. The aspect of these colonies initially led to the incorrect assumption that the organism was a fungus and to the name Actinomyces, "ray fungus".

<span class="mw-page-title-main">Clostridia</span> Class of bacteria

The Clostridia are a highly polyphyletic class of Bacillota, including Clostridium and other similar genera. They are distinguished from the Bacilli by lacking aerobic respiration. They are obligate anaerobes and oxygen is toxic to them. Species of the class Clostridia are often but not always Gram-positive and have the ability to form spores. Studies show they are not a monophyletic group, and their relationships are not entirely certain. Currently, most are placed in a single order called Clostridiales, but this is not a natural group and is likely to be redefined in the future.

<i>Peptostreptococcus</i> Genus of bacteria

Peptostreptococcus is a genus of anaerobic, Gram-positive, non-spore forming bacteria. The cells are small, spherical, and can occur in short chains, in pairs or individually. They typically move using cilia. Peptostreptococcus are slow-growing bacteria with increasing resistance to antimicrobial drugs. Peptostreptococcus is a normal inhabitant of the healthy lower reproductive tract of women.

<i>Bacteroides fragilis</i> Species of bacterium

Bacteroides fragilis is an anaerobic, Gram-negative, pleomorphic to rod-shaped bacterium. It is part of the normal microbiota of the human colon and is generally commensal, but can cause infection if displaced into the bloodstream or surrounding tissue following surgery, disease, or trauma.

<span class="mw-page-title-main">Vaginal flora</span> Microorganisms present in the vagina

Vaginal flora, vaginal microbiota or vaginal microbiome are the microorganisms that colonize the vagina. They were discovered by the German gynecologist Albert Döderlein in 1892 and are part of the overall human flora. The amount and type of bacteria present have significant implications for an individual's overall health. The primary colonizing bacteria of a healthy individual are of the genus Lactobacillus, such as L. crispatus, and the lactic acid they produce is thought to protect against infection by pathogenic species.

Prevotella is a genus of Gram-negative bacteria.

<i>Porphyromonas</i> Genus of bacteria

Porphyromonas is a Gram-negative, non-spore-forming, obligately anaerobic and non-motile genus from the family Porphyromonadaceae. There were 16 different Porphyromonas species documented as of 2015, which reside in both animal and human reservoirs. It was discovered more recently that Porphyromonas also exist in the environment, albeit to a lesser extent. This genus is notably implicated in the modulation of oral cavity, respiratory tract, and gastrointestinal tract disease states. It is suggested that Porphyromonas either operate as benign bacteria pertinent to host immunity or are potential pathobionts that opportunistically provoke diseased states when homeostasis is disrupted. Despite its characterization not being fully elucidated due to sparse research, various studies report the prevalence of this genus at 58.7% in healthy states compared with 41.3% in diseased states.

Anaerobic infections are caused by anaerobic bacteria. Obligately anaerobic bacteria do not grow on solid media in room air ; facultatively anaerobic bacteria can grow in the presence or absence of air. Microaerophilic bacteria do not grow at all aerobically or grow poorly, but grow better under 10% carbon dioxide or anaerobically. Anaerobic bacteria can be divided into strict anaerobes that can not grow in the presence of more than 0.5% oxygen and moderate anaerobic bacteria that are able of growing between 2 and 8% oxygen. Anaerobic bacteria usually do not possess catalase, but some can generate superoxide dismutase which protects them from oxygen.

Alistipes is a Gram-negative genus of rod-shaped anaerobic bacteria in the phylum Bacteroidota. When members of this genus colonize the human gastrointestinal (GI) tract, they provide protective effects against colitis, autism, and cirrhosis. However, this genus can also cause dysbiosis by contributing to anxiety, chronic fatigue syndrome, depression, and hypertension. Showcasing priority effects in microbiome assembly, when infant GI tracts have bacteria of the species Staphylococcus but not the species Faecalibacterium, Alistipes species become less capable of colonization.

Lautropia mirabilis is a Gram-negative, facultatively anaerobic, oxidase- and catalase-positive, motile bacterium of the genus Lautropia and family Burkholderiaceae, isolated from the mouth of children who were infected with human immunodeficiency virus.

Peptostreptococcus anaerobius is a species of bacteria belonging to the Peptostreptococcus genus of anaerobic, Gram-positive, non-spore forming bacteria. The cells are small, spherical, and can occur in short chains, in pairs or individually. Peptostreptococcus are slow-growing bacteria sometimes resistance to antimicrobial drugs. P. anaerobius is intrinsically resistant to sodium polyethanol sulfonate (SPS), a component found in many types of blood culture media.

Peptoniphilus is a genus of bacteria in the phylum Bacillota (Bacteria).

Christensenella is a genus of non-spore-forming, anaerobic, and nonmotile bacteria from the family Christensenellaceae. They are also part of the order Clostridiales, the class Clostridia and the phylum Firmicutes. Phylogenetic analyzes of 16S rRNA gene sequences are used to describe this family. Due to the recent discovery of the Christensenellaceae family, it was not given importance until a few years ago. This is why very little is known about its ecology and how it may be associated with host factors and other microbiota. However, recent studies establish that members of this family, with exceptions, may be associated with a healthy phenotype for humans. The species C. minuta has been published and validated, and C. timonensis and C. massiliensis have been proposed as novel species of the genus Christensenella, all isolated from human feces.

Peptoniphilus gorbachii is a Gram-positive and anaerobic bacterium from the genus of Peptoniphilus which has been isolated from a human abscess from Los Angeles in the United States.

Bacteroides caccae is a saccharolytic gram-negative bacterium from the genus Bacteroides. They are obligate anaerobes first isolated from human feces in the 1980s. Prior to their discovery, they were known as the 3452A DNA homology group. The type strain is now identified as ATCC 43185.

Anaerococcus hydrogenalis is a bacterium from the family Peptoniphilaceae. It is present in vaginal discharges and ovarian abscesses. Presence of Anaerococcus hydrogenalis in the gut metabolism and their coline consumption has been associated to cardiovascular diseases. Contrary to most of the species in this genus, Anaerococcus hydrogenalis is indole-positive. Also, some strains in this specie can produce urease.

Anaerococcus tetradius is a bacterium from the family Peptoniphilaceae. It was first isolated from vaginal discharges and ovarian abscesses, but is a common member of the vaginal flora.

Anaerococcus murdochii is a bacterium from the family Peptoniphilaceae. A. murdochii has been reported from skin and wound infections. Resistance or reduced susceptibility to several antibiotics, such as colistin sulphate, clindamycin and kanamycin A or penicillin has been reported.

Anaerococcus nagyae is a bacterium from the family Peptoniphilaceae. It was first found in a blood culture from a patient with ischemia and influenza. The cells of Anaerococcus nagyae are arranged in pairs. Although it can weakly ferment mannose, studies has shown this anaerobic bacteria can not ferment glucose and raffinose. A. nagyae is resistant to colistin, but it is susceptible to vancomycin and kanamycin.

References

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