Clostridium difficile

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Microbiology – Professor Dennehy Alex Pinhas Citizendium Article - Draft 1 4/1/08

Classification Higher order taxa Prokaryote; Firmicutes; Clostridia; Clostridiales; Clostridiaceae Species Clostridium difficile Description and significance Clostridium difficile is a species of bacteria that is the leading cause of infectious diarhhea among patients in hospitals worldwide. C. difficile causes pseudomembranous colitis, a plaque-forming infection of the colon that leads to heavy diarrhea and may be life-threatening. The infection occurs when a person is treated with antibiotics targeted against other bacteria. C. difficile is present at low levels in the gut flora of about 3% of adults. These people however show no symptoms and do not need to be treated. Patients who are hospitalized come in contact and are often inoculated with the bacteria. When the patient is treated with antibiotics, especially those with a broad range of activity, the normal gut flora is disrupted, and C. difficile, with its multi-drug resistance, experiences overgrowth. The bacteria releases large quantities of enterotoxins (toxin A) and cytotoxins (toxin B), causing pseudomembranous colitis. To treat infection, antibiotic intake must cease and anticlostridial antibiotics (vancomycin, amoxicillin, ciprofloxacin, metronidazole, doxycycline, gentamicin, clindamycin) must be ingested. Clostridia are Gram-positive, anaerobic, spore-forming, rod-shaped, motile bacteria. They are found throughout nature, especially in soil. When producing spores, they look like drumsticks, with a bulge located at their terminal end. C. difficile produces an S layer (polysaccharide capsule) that contributes to its pathogenicity. It moves around via flagellae. C. difficile is an obligate fermenter, and exhibits optimal growth in blood agar at human body temperatures in the absence of oxygen. In 1935, Hall and O’Toole first isolated the bacteria from the stools of newborns and described it. They named it Bacillus difficilis because it was hard to isolate and grew very slowly in culture. C. difficile is an important pathogen that is currently increasing in prevalence world-wide. A complete genome sequence will enable geneticists to come up with a more direct and efficient treatment against the pathogen. The genetic material encodes for antimicrobial resistance, production of toxins (virulence), host interaction (adaptations for survival and growth within the gut environment), and the production of surface structures. The understanding of how these genes interact with their environment will be useful in developing therapies against C. difficile associated diseases. Genome structure





Genome Structure

Sebaihia et al (2006) determined the complete genomic sequence of C. difficile strain 630, a highly virulent and multidrug-resistant strain. It was found that the genome consists of a circular chromosome of 4,290,252 bp and a plasmid, pCD630, of 7,881 bp. The chromosome encodes 3,776 predicted coding sequences (CDSs), with resistance, virulence, and host interaction genes, while the plasmid carries only 11 CDSs, none of which has any obvious function. C. difficile has a highly mobile genome, with 11% of the genome consisting of mobile genetic elements, mostly in the form of conjugative transposons. Conjugative transposons are mobile genetic elements that are capable of integrating into and excising from the host genome and transferring themselves, and are responsible for the evolutionary acquisition by C. difficile of genes involved in resistance, virulence, and host interactions. Some of the mobile elements are prophage sequences. Host interaction genes involve genes that code for metabolic capability adaptations for survival and growth within the guy environment. The genome carries several copies of a very interesting genetic element, the IStron. The IStron is a hybrid between an intron and an insertion sequence (IS), and can therefore insert itself into a DNA sequence, and later be excised from the primary mRNA transcript by cellular machinery. For example, a copy inserted in the tcdA gene (that encodes the enterotoxin A) renders the gene nonfunctional until the IStron is excised. Truncated copies of the IStron (containing only the IS sequence) were found in intergenic regions. Possibly, these truncated variants may be the answer to make C. difficile unable to produce functional toxins. Cell structure and metabolism Clostridia are Gram-positive, rod-shaped, motile bacteria. As spores, the bacteria look like drumsticks, with a bulge located at one end. C. difficile produces an S layer that contributes to its pathogenicity. C. difficile is an obligate fermenter, and exhibits optimal growth in blood agar at human body temperatures in the absence of oxygen. The metabolism of C. difficile is in large part adapted to life in the intestinal tract. It produces enzymes that degrade nutrients abundant in the intestine. Carbohydrates are the preferred nutrient source, and C. difficile has the ability to metabolize a wide range of carbohydrates. The bacteria also have a relatively unique ability to utilize ethanolamine, an abundant phospholipid provided by the host’s dietary intake, as a carbon and nitrogen source. C. difficile has the enzyme that catalyzes the decarboxylation of p-hydroxyphenylacetate (a tyrosine degradation product) to p¬-crysol, a compound that stunts bacterial growth. C. difficile produces and tolerates high concentrations of p-crysol, giving it a competitive advantage over the normal bacterial flora in the intestine. Ecology C. difficile is found throughout nature, especially in soil. It exhibits optimal growth in blood agar at human body temperatures in the absence of oxygen. It can remain dormant in hospitals in the form of spores until patient inoculation. Following treatment of antibiotics, C. difficile overgrows in the intestinal tract, causing pseudomembranous colitis, and consequently diarrhea. Pathology How does this organism cause disease? Human, animal, plant hosts? Virulence factors, as well as patient symptoms. C. difficile is transmitted from person to person in a fecal-oral fashion in the form of vegetative cells and heat-resistant spores. Most vegetative cells are killed in the stomach, but spores pass through the stomach unaffected because of their acid resistance. Spores germinate in the small bowel upon exposure to bile acids. C. difficile multiplies in the colon and overgrow in the absence of competitors (following antibiotic treatment). Gut mucosa facilitates adherence to the colonic epithelium. Different pathogenic strains of C. difficile produce different toxins, but the most common ones are enterotoxin (toxin A) and cytotoxin (toxin B). The two toxins lead to the production of tumour necrosis factor-alpha and pro-inflammatory interleukins, increased vascular permeability, neutrophil and monocyte recruitment, opening pf epithelial cell junctions and epithelial cell apoptosis. Hydrolytic enzymes cause connective tissue to degrade, leading to colitis, pseudomembrane formation and watery diarrhea. Clostridium Difficile infection (CDI) can range in severity from asymptomatic to life threatening. Death is more common among the aged (>65). Patient symptoms include severe diarrhea, exposure to antibiotics, foul stool odor, and abdominal pain. Application to Biotechnology Does this organism produce any useful compounds or enzymes? What are they and how are they used? Current Research Enter summaries of the most recent research here--at least three required References http://sitemaker.umich.edu/mc2/psuedomembranous_colitis

http://en.wikipedia.org/wiki/Clostridium_difficile

http://microbewiki.kenyon.edu/index.php/Clostridium

http://www.nature.com/ng/journal/v38/n7/full/ng1830.html