Mycoplasma pneumoniae
Template:Short description Template:Italic title Template:More citations needed Template:Speciesbox Mycoplasma pneumoniae is a species of very small-cell bacteria that lack a cell wall, in the class Mollicutes. M. pneumoniae is a human pathogen that causes the disease Mycoplasma pneumonia, a form of atypical bacterial pneumonia related to cold agglutinin disease.<ref>Template:Cite journal</ref>
It is one of the smallest self-replicating organisms and its discovery traces back to 1898 when Nocard and Roux isolated a microorganism linked to cattle pneumonia. This microbe shared characteristics with pleuropneumonia-like organisms (PPLOs), which were soon linked to pneumonias and arthritis in several animals. A significant development occurred in 1944 when Monroe Eaton cultivated an agent thought responsible for human pneumonia in embryonated chicken eggs, referred to as the "Eaton agent." This agent was classified as a bacteria due to its cultivation method and because antibiotics were effective in treating the infection, questioning its viral nature. In 1961, a researcher named Robert Chanock, collaborating with Leonard Hayflick, revisited the Eaton agent and posited it could be a mycoplasma, a hypothesis confirmed by Hayflick's isolation of a unique mycoplasma, later named Mycoplasma pneumoniae. Hayflick's discovery proved M. pneumoniae was responsible for causing human pneumonia.
Taxonomically, Mycoplasma pneumoniae is part of the Mollicutes class, characterized by their lack of a peptidoglycan cell wall, making them inherently resistant to antibiotics targeting cell wall synthesis, such as beta-lactams. With a reduced genome and metabolic simplicity, mycoplasmas are obligate parasites with limited metabolic pathways, relying heavily on host resources. This bacterium uses a specialized attachment organelle to adhere to respiratory tract cells, facilitating motility and cell invasion. The persistence of M. pneumoniae infections even after treatment is associated with its ability to mimic host cell surface composition.
Pathogenic mechanisms of M. pneumoniae involve host cell adhesion and cytotoxic effects, including cilia loss and hydrogen peroxide release, which lead to respiratory symptoms and complications such as bronchial asthma and chronic obstructive pulmonary disease. Additionally, the bacterium produces a unique CARDS toxin, contributing to inflammation and respiratory distress. Treatment of M. pneumoniae infections typically involves macrolides or tetracyclines, as these antibiotics inhibit protein synthesis, though resistance has been increasing, particularly in Asia. This resistance predominantly arises from mutations in the 23S rRNA gene, which interfere with macrolide binding, complicating management and necessitating alternative treatment strategies.
Discovery and history
In 1898, Nocard and Roux isolated an agent assumed to be the cause of cattle pneumonia and named it microbe de la peripneumonie<ref name="pmid14304038">Template:Cite journal</ref><ref name="pmid14333465">Template:Cite journal</ref><ref name="Hayflick1967">Template:Cite conference</ref><ref name="L.1969">Template:Cite book</ref><ref name=Marmion_1990>Template:Cite journal</ref><ref name=Waites>Template:Cite journal</ref> Microorganisms from other sources, having properties similar to the pleuropneumonia organism (PPO) of cattle, soon came to be known as pleuropneumonia-like organisms (PPLO), but their true nature remained unknown.<ref name="pmid14304038"/><ref name="pmid14333465"/><ref name="Hayflick1967"/><ref name="L.1969"/> Many PPLO were later proven to be the cause of pneumonias and arthritis in several lower animals.<ref name="pmid14304038"/><ref name="pmid20149687">Template:Cite journal</ref><ref name="Hayflick1956">Template:Cite thesis</ref><ref name="pmid14400338">Template:Cite journal</ref>
In 1944, Monroe Eaton used embryonated chicken eggs to cultivate an agent thought to be the cause of human primary atypical pneumonia (PAP), commonly known as "walking pneumonia."<ref name="pmid19871393">Template:Cite journal</ref> This unknown organism became known as the "Eaton agent".<ref>Template:Cite journal</ref> At that time, Eaton's use of embryonated eggs, then used for cultivating viruses, supported the idea that the Eaton agent was a virus. Yet it was known that PAP was amenable to treatment with broad-spectrum antibiotics, making a viral etiology suspect.<ref name="pmid14304038"/><ref name="pmid14333465"/><ref name="pmid20149687"/><ref name="Hayflick1969-2">Template:Cite book</ref><ref name="Madoff1969">Template:Cite book</ref>
Robert Chanock, a researcher from the NIH who was studying the Eaton agent as a virus, visited the Wistar Institute in Philadelphia in 1961 to obtain a cell culture of a normal human cell strain developed by Leonard Hayflick. This cell strain was known to be exquisitely sensitive to isolate and grow human viruses. Chanock told Hayflick of his research on the Eaton agent, and his belief that its viral nature was questionable. Although Hayflick knew little about the current research on this agent, his doctoral dissertation had been done on animal diseases caused by PPLO. Hayflick knew that many lower animals suffered from pneumonias caused by PPLOs (later to be termed mycoplasmas). Hayflick reasoned that the Eaton agent might be a mycoplasma, and not a virus. Chanock had never heard of mycoplasmas, and at Hayflick's request sent him egg yolk containing the Eaton agent.<ref name="pmid14304038"/><ref name="L.1969"/><ref name="Hayflick1965">Template:Cite journal</ref><ref name="L.1966">Template:Cite journal</ref><ref name="Hayflick1972">Template:Cite conference</ref><ref name="Hayflick1993">Template:Cite journal
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Using a novel agar and fluid medium formulation he had devised,<ref name="Hayflick1965"/> Hayflick isolated a unique mycoplasma from the egg yolk. This was soon proven by Chanock and Hayflick to be the causative agent of PAP.<ref name="Hayflick1965"/><ref name="pmid13878126">Template:Cite journal</ref><ref name="WebofS"/><ref name="Sharrer2007">Template:Cite journal</ref> When this discovery became known to Emmy Klieneberger-Nobel of the Lister Institute in London, the world's leading authority on these organisms, she suggested that the organism be named Mycoplasma hayflickiae.<ref name="Klieneberger-Nobel">Template:Cite book</ref> Hayflick demurred in favor of Mycoplasma pneumoniae.<ref name="pmid14020096">Template:Cite journal</ref><ref name="pmid6020298">Template:Cite journal</ref>
This smallest free-living microorganism was the first to be isolated and proven to be the cause of a human disease. For his discovery, Hayflick was presented with the Presidential Award by the International Organization of Mycoplasmology. The inverted microscope under which Hayflick discovered Mycoplasma pneumoniae is kept by the Smithsonian Institution.<ref name="Sharrer2007"/>
Taxonomy and classification
The term mycoplasma (Template:Transliteration meaning fungus, and Template:Transliteration, meaning formed) is derived from the fungal-like growth of some mycoplasma species.<ref name=Waites/> The mycoplasmas were classified as Mollicutes ("mollis", meaning soft and "cutis", meaning skin) in 1960 due to their small size and genome, lack of cell wall, low G+C content and unusual nutritional needs.<ref name=Waites/><ref name=Weisburg>Template:Cite journal</ref>
Mycoplasmas, which are among the smallest self-replicating organisms, are parasitic species that lack a cell wall and periplasmic space, have reduced genomes, and limited metabolic activity.<ref name=Waites/><ref name=Romero-Arroyo /><ref name=Dallo /> M. pneumoniae has also been designated as an arginine nonfermenting species.<ref name=Romero-Arroyo>Template:Cite journal</ref> Mycoplasmas are further classified by the sequence composition of 16s rRNA. All mycoplasmas of the pneumoniae group possess similar 16s rRNA variations unique to the group, of which M. pneumoniae has a 6.3% variation in the conserved regions, that suggest mycoplasmas formed by degenerative evolution from the gram-positive eubacterial group that includes bacilli, streptococci, and lactobacilli.<ref name=Waites/><ref name=Weisburg/><ref name=Romero-Arroyo /> M. pneumoniae is a member of the family Mycoplasmataceae and order Mycoplasmatales.<ref name=Waites/>
Cell biology
Mycoplasma pneumoniae cells have an elongated shape that is approximately 0.1–0.2 μm (100–200 nm) in width and 1–2 μm (1000-2000 nm) in length. The extremely small cell size means they are incapable of being examined by light microscopy; a stereomicroscope is required for viewing the morphology of M. pneumoniae colonies, which are usually less than 100 μm in length.<ref name=Waites/> The inability to synthesize a peptidoglycan cell wall is due to the absence of genes encoding its formation and results in an increased importance in maintenance of osmotic stability to avoid desiccation.<ref name=Waites/> The lack of a cell wall also calls for increased support of the cell membrane(reinforced with sterols), which includes a rigid cytoskeleton composed of an intricate protein network and, potentially, an extracellular capsule to facilitate adherence to the host cell.<ref name=Waites/> M. pneumoniae are the only bacterial cells that possess cholesterol in their cell membrane (obtained from the host) and possess more genes that encode for membrane lipoprotein variations than other mycoplasmas,<ref name=Romero-Arroyo /> which are thought to be associated with its parasitic lifestyle. M. pneumoniae cells also possess an attachment organelle, which is used in the gliding motility of the organism by an unknown mechanism.<ref name=Waites/>
Genomics and metabolic reconstruction
Sequencing of the M. pneumoniae genome in 1996 revealed it is 816,394 bp in size.<ref name="Weisburg" /> The genome contains 687 genes that encode for proteins, of which about 56.6% code for essential metabolic enzymes; notably those involved in glycolysis and organic acid fermentation.<ref name="Waites" /><ref name="Weisburg" /><ref name="Romero-Arroyo" /><ref name="Wodke">Template:Cite journal</ref> M. pneumoniae is consequently very susceptible to loss of enzymatic function by gene mutations, as the only buffering systems against functional loss by point mutations are for maintenance of the pentose phosphate pathway and nucleotide metabolism.<ref name="Wodke"/> Loss of function in other pathways is suggested to be compensated by host cell metabolism.<ref name="Wodke"/> In addition to the potential for loss of pathway function, the reduced genome of M. pneumoniae outright lacks a number of pathways, including the TCA cycle, respiratory electron transport chain, and biosynthesis pathways for amino acids, fatty acids, cholesterol and purines and pyrimidines.<ref name="Waites" /><ref name="Romero-Arroyo" /><ref name="Wodke"/> These limitations make M. pneumoniae dependent upon import systems to acquire essential building blocks from their host or the environment that cannot be obtained through glycolytic pathways.<ref name="Romero-Arroyo" /><ref name="Wodke"/> Along with energy costly protein and RNA production, a large portion of energy metabolism is exerted to maintain proton gradients (up to 80%) due to the high surface area to volume ratio of M. pneumoniae cells. Only 12 – 29% of energy metabolism is directed at cell growth, which is unusually low for bacterial cells, and is thought to be an adaptation of its parasitic lifestyle.<ref name="Wodke" />
Unlike other bacteria, M. pneumoniae uses the codon UGA to code for tryptophan rather than using it as a stop codon.<ref name="Waites" /><ref name="Weisburg" />
Comparative metabolomics
Mycoplasma pneumoniae has a reduced metabolome in comparison to other bacterial species.<ref name=":0">Template:Cite journal</ref> This means that the pathogen has fewer metabolic reactions in comparison to other bacterial species such as B.subtilis and Escherichia coli.<ref name=":0" /><ref name=":1">Template:Cite journal</ref>
Since Mycoplasma pneumoniae has a reduced genome, it has a smaller number of overall paths and metabolic enzymes, which contributes to its more linear metabolome.<ref name=":0" /> A linear metabolome causes Mycoplasma pneumoniae to be less adaptable to external factors.<ref name=":0" /> Additionally, since Mycoplasma pneumoniae has a reduced genome, the majority of its metabolic enzymes are essential.<ref name=":0" /> This is in contrast to another model organism, Escherichia coli, in which only 15% of its metabolic enzymes are essential.<ref name=":0" /> In summary, the linear topology of Mycoplasma pneumoniae's metabolome leads to reduced efficiency in its metabolic reactions, but still maintains similar levels of metabolite concentrations, cellular energetics, adaptability, and global gene expression.<ref name=":0" />
| Species | M. pneumoniae | L. lactis | B. subtilis | E. coli |
|---|---|---|---|---|
| Mean # Of Paths | 8.17 | 5.37 | 7.54 | 6.12 |
The table above depicts the mean path length for the metabolomes of M. pneumoniae, E. coli, L. lactis, and B. subtilis.<ref name=":0" /> This number describes, essentially, the mean number of reactions that occur in the metabolome. Mycoplasma pneumoniae, on average, has a high number of reactions per path within its metabolome in comparison to other model bacterial species.<ref name=":0" />
One effect of Mycoplasma pneumoniae's unique metabolome is its longer duplication time.<ref name=":0" /> It takes the pathogen significantly more time to duplicate on average compared to other model organism bacteria.<ref name=":0" /> This may be due to the fact that Mycoplasma pneumoniae's metabolome is less efficient than that of Escherichia coli.<ref name=":0" />
The metabolome of Mycoplasma pneumoniae can also be informative in analyzing its pathogenesis.<ref name=":2">Template:Cite journal</ref> Extensive study of the metabolic network of this organism has led to the identification of biomarkers that can potentially reveal the presence of the extensive complications the bacteria can cause.<ref name=":2" /> Metabolomics is increasingly being used as a useful tool for the verification of biomarkers of infectious pathogens.<ref name=":2" />
Pathogenicity
Mycoplasma pneumoniae parasitizes the respiratory tract epithelium of humans.<ref name=Waites/> Adherence to the respiratory epithelial cells is thought to occur via the attachment organelle, followed by evasion of host immune system by intracellular localization and adjustment of the cell membrane composition to mimic the host cell membrane.Template:Citation needed Mycoplasma pneumoniae grows exclusively by parasitizing mammals. Reproduction, therefore, is dependent upon attachment to a host cell. According to Waites and Talkington, specialized reproduction occurs by "binary fission, temporally linked with duplication of its attachment organelle, which migrates to the opposite pole of the cell during replication and before nucleoid separation".<ref name=Waites/> Mutations that affect the formation of the attachment organelle not only hinder motility and cell division, but also reduce the ability of M. pneumoniae cells to adhere to the host cell.<ref name="Romero-Arroyo"/>
Cytoadherence
Adherence of M. pneumoniae to a host cell (usually a respiratory tract cell, but occasionally an erythrocyte or urogenital lining cell) is the initiating event for pneumonic disease and related symptoms.<ref name=Waites/> The specialized attachment organelle is a polar, electron dense and elongated cell extension that facilitates motility and adherence to host cells.<ref name=Waites/><ref name="Romero-Arroyo"/> It is composed of a central filament surrounded by an intracytoplasmic space, along with a number of adhesins and structural and accessory proteins localized at the tip of the organelle.<ref name=Waites/><ref name="Romero-Arroyo"/> A variety of proteins are known to contribute to the formation and functionality of the attachment organelle, including the accessory proteins HMW1–HMW5, P30, P56, and P90 that confer structure and adhesin support, and P1, P30 and P116 which are involved directly in attachment.<ref name=Waites/><ref name=Drasbek>Template:Cite journal</ref><ref name=Baseman>Template:Cite journal</ref> This network of proteins participates not only in the initiation of attachment organelle formation and adhesion but also in motility.<ref name="Baseman"/> The P1 adhesin (trypsin-sensitive protein) is a 120 kDa protein highly clustered on the surface of the attachment organelle tip in virulent mycoplasmas.<ref name=Waites/><ref name="Baseman"/><ref name=Hahn>Template:Cite journal</ref> Both the presence of P1 and its concentration on the cell surface are required for the attachment of M. pneumoniae to the host cell. M. pneumoniae cells treated with monoclonal antibodies specific to the immunogenic C-terminus of the P1 adhesin have been shown to be inhibited in their ability to attach to the host cell surface by approximately 75%, suggesting P1 is a major component in adherence.<ref name=Waites/><ref name="Drasbek"/><ref name="Baseman"/> These antibodies also decreased the ability of the cell to glide quickly, which may contribute to decreased adherence to the host by hindering their capacity to locate a host cell.<ref name="Drasbek"/> Furthermore, mutations in P1 or degradation by trypsin treatment yield avirulent M. pneumoniae cells.<ref name=Waites/> Loss of proteins in the cytoskeleton involved in the localization of P1 in the tip structure, such as HMW1–HMW3, also cause avirulence due to the lack of adhesin clustering.<ref name="Baseman"/><ref name=Hahn/> Another protein considered to play an important role in adherence is P30, as M. pneumoniae cells with mutations in this protein or that have had antibodies raised against P30 are incapable of adhering to host cells.<ref name=Waites/><ref name="Romero-Arroyo"/> P30 is not involved in the localization of P1 in the tip structure since P1 is trafficked to the attachment organelle in P30 mutants, but rather it may function as a receptor-binding accessory adhesin.<ref name="Romero-Arroyo"/><ref name=Hahn/> P30 mutants also display distinct morphological features such as multiple lobes and a rounded shape as opposed to elongated, which suggests P30 may interact with the cytoskeleton during formation of the attachment organelle.<ref name="Romero-Arroyo"/> A number of eukaryotic cell surface components have been implicated in the adherence of M. pneumoniae cells to the respiratory tract epithelium. Among them are sialoglycoconjugates, sulfated glycolipids, glycoproteins, fibronectin, and neuraminic acid receptors.<ref name=Waites/><ref name="Drasbek"/><ref name= Sobeslavsky>Template:Cite journal</ref> Lectins on the surface of the bacterial cells are capable of binding oligosaccharide chains on glycolipids and glycoproteins to facilitate attachment, in addition to the proteins TU and pyruvate dehydrogenase E1 β, which bind to fibronectin.<ref name=Waites/><ref name="Drasbek"/>
Intracellular localization
Mycoplasma pneumoniae fuses with host cells and survive intracellularly. Thus it can evade host immune system detection, resist antibiotic treatment, and cross mucosal barriers,.<ref name=Waites/><ref name=Dallo>Template:Cite journal</ref> In addition to the close physical proximity of M. pneumoniae and host cells, the lack of cell wall and peculiar cell membrane components, like cholesterol, may facilitate fusion. Internal localization may produce chronic or latent infections as M. pneumoniae is capable of persisting, synthesizing DNA, and replicating within the host cell even after treatment with antibiotics.<ref name="Dallo"/> The exact mechanism of intracellular localization is unknown, however the potential for cytoplasmic sequestration within the host explains the difficulty in completely eliminating M. pneumoniae infections in afflicted individuals.<ref name=Waites/>
Immune response
In addition to evasion of host immune system by intracellular localization, M. pneumoniae can change the composition of its cell membrane to mimic the host cell membrane and avoid detection by immune system cells. M. pneumoniae cells possess a number of protein and glycolipid antigens that elicit immune responses, but variation of these surface antigens would allow the infection to persist long enough for M. pneumoniae cells to fuse with host cells and escape detection. The similarity between the compositions of M. pneumoniae and human cell membranes can also result in autoimmune responses in several organs and tissues.<ref name=Waites/>
Cytotoxicity and organismal effects
The main cytotoxic effect of M. pneumoniae is local disruption of tissue and cell structure along the respiratory tract epithelium due to its attachment to host cells. Attachment of the bacteria to host cells can result in loss of cilia, a reduction in metabolism, biosynthesis, and import of macromolecules, and, eventually, infected cells may be shed from the epithelial lining.<ref name=Waites/> Local damage may also be a result of lactoferrin acquisition and subsequent hydroxyl radical, superoxide anion and peroxide formation.<ref name=Waites/>
Secondly, M. pneumoniae produces a unique virulence factor known as Community Acquired Respiratory Distress Syndrome (CARDS) toxin.<ref>Template:Cite web</ref> The CARDS toxin most likely aids in the colonization and pathogenic pathways of M. pneumoniae, leading to inflammation and airway dysfunction.
The third virulence factor is the formation of hydrogen peroxide in M. pneumoniae infections.<ref name=Waites/> When M. pneumoniae is attached to erythrocytes, hydrogen peroxide diffuses from the bacteria to the host cell without it being detoxified by catalase or peroxidase, thus injuring the host cell by reducing glutathione, damaging lipid membranes and causing protein denaturation, i.e. oxidation of heme and hemolysis.<ref name=Waites/><ref name="Sobeslavsky"/>
Most recently it was shown that hydrogen peroxide plays a minor if any role in haemolysis, but that hydrogen sulfide is the true culprit.<ref>Template:Cite journal</ref>
The cytotoxic effects of M. pneumoniae infections translate into common symptoms like coughing and lung irritation that may persist for months after infection has subsided. Local inflammation and hyperresponsiveness by infection induced cytokine production has been associated with chronic conditions such as bronchial asthma and has also been linked to progression of symptoms in individuals with cystic fibrosis and COPD.<ref name=Waites/>
Antimicrobial activity
Template:See also Infections can be treated with oral antibiotics from the macrolide family, which work by inhibiting the Mycoplasma protein biosynthesis. Historically, erythromycin is the oldest drug. As first choice, azithromycin or clarithromycin are used, as they have more convenient pharmacokinetics than erythromycin: they only need to be taken once or twice and not four times a day and they have fewer side effects. Alternatively, tetracyclines (eg, doxycycline), and respiratory fluoroquinolones (eg, levofloxacin or moxifloxacin) can be used; they have an undesirable side effect profile in children. Beta-lactams such as penicillin are completely ineffective, because they target the cell wall synthesis.Template:Citation needed
Resistance
Resistance to macrolides has been reported as early as 1967. Increased antibiotic usage has been followed by an increase in resistance since 2000. Resistance in the 2020s has been highest in Asia, as high as 100%, while rates in the United States have varied from 3.5% to 13%. A single base mutation in the V region of 23S rRNA, like A2063/2064G<ref name="EID">Template:Cite journal</ref> is responsible for more than 90% of the macrolide-resistant infections.<ref>Template:Cite journal</ref>
Since routine culture and susceptibility testing is not performed, as M. pneumoniae is difficult to grow, clinicians will select an antibiotic based on an estimate of local resistance, on treatment response and on other factors.Template:Which<ref name="EID"/>
See also
References
Template:Reflist This article incorporates public domain text from the CDC as cited.
Further reading
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- See also Hayflick's comments on Meredith Wadman's book, "The Vaccine Race: Science, Politics and the Human Costs of Defeating Disease", 2017 Errors in "The Vaccine Race" book