Bacillus anthracis

B. anthracis are rod-shaped bacteria, approximately 3 to 5 μm long and 1 to 1.2 μm wide. When grown in culture, they tend to form long chains of bacteria, often described as having a “boxcar” morphology due to their rectangular, blunt-ended appearance. On agar plates, they form large colonies several millimeters across that are generally white or cream colored. Most other bacterial species are surrounded by a polysaccharide capsule rather than poly-g-D-glutamic acid which provides an evolutionary advantage to B. anthracis. Polysaccharides are associated with adhesion of neutrophil-secreted defensins that inactivate and degrade the bacteria. By not containing this macromolecule in the capsule, B. anthracis can evade a neutrophilic attack and continue to propagate infection. The difference in capsule composition is also significant because poly-g-D-glutamic acid has been hypothesized to create a negative charge which protects the vegetative phase of the bacteria from phagocytosis by host macrophages. The capsule is degraded to a lower molecular mass and released from the bacterial cell surface to act as a decoy to protect the bacteria from the host's complement system. Like Bordetella pertussis, it forms a calmodulin-dependent adenylate cyclase exotoxin known as anthrax edema factor, along with anthrax lethal factor. It bears close genotypic and phenotypic resemblance to Bacillus cereus and Bacillus thuringiensis. All three species share cellular dimensions and morphology. All form oval spores located centrally in an unswollen sporangium. B. anthracis endospores, in particular, are highly resilient, surviving extremes of temperature, low-nutrient environments, and harsh chemical treatment over decades or centuries. The endospore is a dehydrated cell with thick walls and additional layers that form inside the cell membrane. It can remain inactive for many years, but if it comes into a favorable environment, it begins to grow again. It initially develops inside the rod-shaped form. Features such as the location within the rod, the size and shape of the endospore, and whether or not it causes the wall of the rod to bulge out are characteristic of particular species of Bacillus. Depending upon the species, the endospores are round, oval, or occasionally cylindrical. They are highly refractile and contain dipicolinic acid. Electron micrograph sections show they have a thin outer endospore coat, a thick spore cortex, and an inner spore membrane surrounding the endospore contents. The endospores resist heat, drying, and many disinfectants (including 95% ethanol). Because of these attributes, B. anthracis endospores are extraordinarily well-suited to use (in powdered and aerosol form) as biological weapons. Such weaponization has been accomplished in the past by at least five state bioweapons programs—those of the United Kingdom, Japan, the United States, Russia, and Iraq—and has been attempted by several others. ==Genome structure==

B. anthracis has a single chromosome which is a circular DNA molecule consisting lf 5,227,293-bp. It also has two circular, extrachromosomal, double-stranded DNA plasmids, pXO1 and pXO2. Both the pXO1 and pXO2 plasmids are required for full virulence and represent two distinct plasmid families. pXO1 plasmid The pXO1 plasmid (182 kb) contains the genes that encode for the anthrax toxin components: pag (protective antigen, PA), lef (lethal factor, LF), and cya (edema factor, EF). These factors are contained within a 44.8-kb pathogenicity island (PAI) on the plasmid. The lethal factor toxin is a combination of PA with LF, and the edema factor toxin is a combination of PA with EF. The PAI also contains genes which encode a transcriptional activator AtxA and the repressor PagR, both of which regulate the expression of the anthrax toxin genes. pXO2 plasmid pXO2 encodes a five-gene operon (capBCADE) which synthesizes a poly-γ-D-glutamic acid (polyglutamate) capsule. This capsule allows B. anthracis to evade the host immune system by protecting itself from phagocytosis. Expression of the capsule operon is activated by the transcriptional regulators AcpA and AcpB, located in the pXO2 pathogenicity island (35 kb). The AtxA from pXO1 controls expression of both AcpA and AcpB. ==Strains==

The 89 known strains of B. anthracis include: • Sterne strain (34F2; aka the "Weybridge strain"), used by Max Sterne in his 1930s vaccines • Vollum strain, formerly weaponized by the US, UK, and Iraq; isolated from a cow in Oxfordshire, UK, in 1935 • Vollum M-36, virulent British research strain; passed through macaques 36 times • Vollum 1B, weaponized by the US and UK in the 1940s-60s • Vollum-14578, used in UK bio-weapons trials which severely contaminated Gruinard Island in 1942 • V770-NP1-R, the avirulent, nonencapsulated strain used in the BioThrax vaccine • Anthrax 836, highly virulent strain weaponized by the USSR; discovered in Kirov in 1953 • Ames strain, isolated from a cow in Texas in 1981; famously used in AMERITHRAX letter attacks (2001) • Ames Ancestor • Ames Florida • H9401, isolated from human patient in Korea; used in investigational anthrax vaccines ==Evolution==

Whole genome sequencing has made reconstruction of the B. anthracis phylogeny extremely accurate. A contributing factor to the reconstruction is B. anthracis being monomorphic, meaning it has low genetic diversity, including the absence of any measurable lateral DNA transfer since its derivation as a species. The lack of diversity is due to a short evolutionary history that has precluded mutational saturation in single nucleotide polymorphisms. A short evolutionary time does not necessarily mean a short chronological time. When DNA is replicated, mistakes occur which become genetic mutations. The buildup of these mutations over time leads to the evolution of a species. During the B. anthracis lifecycle, it spends a significant amount of time in the soil spore reservoir stage, in which DNA replication does not occur. These prolonged periods of dormancy have greatly reduced the evolutionary rate of the organism. and is a frequent cause of food poisoning It produces an emetic toxin, enterotoxins, and other virulence factors. The enterotoxins and virulence factors are encoded on the chromosome, while the emetic toxin is encoded on a 270-kb plasmid, pCER270. The genes encoding these proteins are commonly located on plasmids which can be lost from the organism, making it indistinguishable from B. cereus. Pseudogene PlcR is a global transcriptional regulator which controls most of the secreted virulence factors in B. cereus and B. thuringiensis. It is chromosomally encoded and is ubiquitous throughout the cell. In B. anthracis, however, the plcR gene contains a single base change at position 640, a nonsense mutation, which creates a dysfunctional protein. While 1% of the B. cereus group carries an inactivated plcR gene, none of them carries the specific mutation found only in B. anthracis. The plcR gene is part of a two-gene operon with papR. The papR gene encodes a small protein which is secreted from the cell and then reimported as a processed heptapeptide forming a quorum-sensing system. The lack of PlcR in B. anthracis is a principle characteristic differentiating it from other members of the B. cereus group. While B. cereus and B. thuringiensis depend on the plcR gene for expression of their virulence factors, B. anthracis relies on the pXO1 and pXO2 plasmids for its virulence. Bacillus cereus biovar anthracis, i.e. B. cereus with the two plasmids, is also capable of causing anthrax. ==Clinical aspects==

Pathogenesis B. anthracis possesses an antiphagocytic capsule essential for full virulence. The organism also produces three plasmid-coded exotoxins: edema factor, a calmodulin-dependent adenylate cyclase that causes elevation of intracellular cAMP and is responsible for the severe edema usually seen in B. anthracis infections, lethal toxin which is responsible for causing tissue necrosis, and protective antigen, so named because of its use in producing protective anthrax vaccines, which mediates cell entry of edema factor and lethal toxin. Manifestations in human disease The symptoms in anthrax depend on the type of infection and can take anywhere from 1 day to more than 2 months to appear. All types of anthrax have the potential, if untreated, to spread throughout the body and cause severe illness and even death. Four forms of human anthrax disease are recognized based on their portal of entry. • Cutaneous, the most common form (95%), causes a localized, inflammatory, black, necrotic lesion (eschar). Most often the sore will appear on the face, neck, arms, or hands. Development can occur within 1–7 days after exposure. • Inhalation, a rare but highly fatal form, is characterized by flu-like symptoms, chest discomfort, diaphoresis, and body aches. Infections with B. anthracis can be treated with β-lactam antibiotics such as penicillin, and others which are active against Gram-positive bacteria. Penicillin-resistant B. anthracis can be treated with fluoroquinolones such as ciprofloxacin or tetracycline antibiotics such as doxycycline. == Laboratory research ==

Components of tea, such as polyphenols, have the ability to inhibit the activity both of B. anthracis and its toxin considerably; spores, however, are not affected. The addition of milk to the tea completely inhibits its antibacterial activity against anthrax. Activity against the B. anthracis in the laboratory does not prove that drinking tea affects the course of an infection, since it is unknown how these polyphenols are absorbed and distributed within the body. B. anthracis can be cultured on PLET agar, a selective and differential media designed to select specifically for B. anthracis. Recent research Advances in genotyping methods have led to improved genetic analysis for variation and relatedness. These methods include multiple-locus variable-number tandem repeat analysis (MLVA) and typing systems using canonical single-nucleotide polymorphisms. The Ames ancestor chromosome was sequenced in 2003 The H9401 strain isolated in the Republic of Korea was sequenced using 454 GS-FLX technology and analyzed using several bioinformatics tools to align, annotate, and compare H9401 to other B. anthracis strains. The sequencing coverage level suggests a molecular ratio of pXO1:pXO2:chromosome as 3:2:1 which is identical to the Ames Florida and Ames Ancestor strains. H9401 has 99.679% sequence homology with Ames Ancestor with an amino acid sequence homology of 99.870%. H9401 has a circular chromosome (5,218,947 bp with 5,480 predicted ORFs), the pXO1 plasmid (181,700 bp with 202 predicted ORFs), and the pXO2 plasmid (94,824 bp with 110 predicted ORFs). Three of these modifications have been identified and characterized. These include (1) N-glycosylation of N-acetyl-muramic acid, (2) O-acetylation of N-acetylmuramic acid and (3) N-deacetylation of N-acetyl-glucosamine. Research during the last few years has focused on inhibiting such modifications. As a result the enzymatic mechanism of polysaccharide de-acetylases is being investigated, that catalyze the removal of an acetyl group from N-acetyl-glucosamine and N-acetyl-muramic acid, components of the peptidoglycan layer. == Host interactions ==

As with most other pathogenic bacteria, B. anthracis must acquire iron to grow and proliferate in its host environment. The most readily available iron sources for pathogenic bacteria are the heme groups used by the host in the transport of oxygen. To scavenge heme from host hemoglobin and myoglobin, B. anthracis uses two secretory siderophore proteins, IsdX1 and IsdX2. These proteins can separate heme from hemoglobin, allowing surface proteins of B. anthracis to transport it into the cell. B. anthracis must evade the immune system to establish a successful infection. B. anthracis spores are immediately phagocytosed by macrophages and dendritic cells once they enter the host. The dendritic cells can control the infection through effective intracellular elimination, but the macrophages can transport the bacteria directly inside the host by crossing a thin layer of epithelial or endothelial cells to reach the circulatory system. Normally, in the phagocytosis process, the pathogen is digested upon internalization by the macrophage. However, rather than being degraded, the anthrax spores hijack the function of the macrophage to evade recognition by the host immune system. Phagocytosis of B. anthracis spores begins when the transmembrane receptors on the extracellular membrane of the phagocyte interacts with a molecule on the surface of the spore. CD14, an extracellular protein embedded in the host membrane, binds to rhamnose residues of BclA, a glycoprotein of the B. anthracis exosporium, which promotes inside-out activation of the integrin Mac-1, enhancing spore internalization by macrophages. This cascade results in phagocytic cellular activation and induction of an inflammatory response. ==Sampling==

The presence of B. anthracis can be determined through samples taken on non-porous surfaces. File:Anthrax surface sampling - How to sample with cellulose sponge on nonporous surfaces.webm|How to sample with cellulose sponge on non-porous surfaces Anthrax surface sampling- How to sample with macrofoam swab on nonporous surfaces.webm|How to sample with macrofoam swab on non-porous surfaces == Historical background ==

French physician Casimir Davaine (1812–1882) demonstrated the symptoms of anthrax were invariably accompanied by the microbe B. anthracis. German physician Aloys Pollender (1799–1879) is credited for discovery. B. anthracis was the first bacterium conclusively demonstrated to cause disease, by Robert Koch in 1876. The species name anthracis is from the Greek anthrax (ἄνθραξ), meaning "coal" and referring to the most common form of the disease, cutaneous anthrax, in which large, black skin lesions are formed. Throughout the 19th century, Anthrax was an infection that involved several very important medical developments. The first vaccine containing live organisms was Louis Pasteur's veterinary anthrax vaccine. == References ==