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When grown on Trypticase-soy-blood agar, Capnocytophaga gingivalis show consistent irregular colonization, staying isolated from other microorganisms (Poirier). Due to their ability to translocate via gliding, the bacterium are confined by their surrounding cells and start clumping into mounds, creating halo zones. Their irregular populations comprise of smooth cell surfaces with small pioneer colonies on the outer edges of halo zones. This is in contrast to bacteria found within the human microbiome as it is forced to co-aggregate with other microorganisms in order to gain survival advantages such as adhesion (Kolenbrander). This agglutination of neighboring cells forms the basis for biofilms and in turn, dental plaque. Co-aggregation reacts to lectin-carbohydrate molecules which are recognized by each cell. Experiments conducted in alternate ecosystems concluded that this process was unique to the oral cavity, as predation or nutritional instability were common occurrences when grown elsewhere.  
When grown on Trypticase-soy-blood agar, Capnocytophaga gingivalis show consistent irregular colonization, staying isolated from other microorganisms (Poirier). Due to their ability to translocate via gliding, the bacterium are confined by their surrounding cells and start clumping into mounds, creating halo zones. Their irregular populations comprise of smooth cell surfaces with small pioneer colonies on the outer edges of halo zones. This is in contrast to bacteria found within the human microbiome as it is forced to co-aggregate with other microorganisms in order to gain survival advantages such as adhesion (Kolenbrander). This agglutination of neighboring cells forms the basis for biofilms and in turn, dental plaque. Co-aggregation reacts to lectin-carbohydrate molecules which are recognized by each cell. Experiments conducted in alternate ecosystems concluded that this process was unique to the oral cavity, as predation or nutritional instability were common occurrences when grown elsewhere.  
This can be is definitive proof that C. gingivalis are opportunistic pathogens as they  
This is definitive proof that C. gingivalis are opportunistic pathogens as they  





Revision as of 12:10, 22 September 2016

Rochelle Overton

Bench E

31082016 [1]

Capnocytophaga gingivalis

Classification

Higher order taxa

Kingdom Bacteria
Domain Bacteroidetes
Phylum Bacteriodetes
Class Flavobacteriia
Order Flavobacteriales
Family Flavobacteriaceae
Genus Capnocytophaga

Species

Capnocytophaga gingivalis ATCC 33624

Description and significance

Capnocytophaga gingivalis are a class of Flavobacteriia that inhabit the oral cavity of the mouth (kagermeier), making up a large component of subgingival plaque (spratt). Microscopy has revealed that C. gingivalis are straight rod-shaped bacteria with a fusiform morphology, having a granulated outer surface. Capnocytophaga gingivalis are a motile facultative anaerobe, meaning that it can create ATP through aerobic respiration if oxygen is present(London), but is also to use fermentation in instances where oxygen is poor/absent (kagermeier, newman). Gram staining produced a purple, gram negative cell, which was is also able to be successfully cultured in laboratories with a preference from environments with high carbon dioxide levels (London).

Whilst present in natural microbiome of the mouth, C. gingivalis can become pathogenic under certain conditions. Dental ailments such as periodontal infections, loss of teeth and supporting tissues as well as alveolar bone loss can occur. In severe cases, C. gingivalis has also spread to the eyes, brain, lungs, digestive tract, heart or muscular skeletal system and causing disease. Although these diseases are treatable with antibiotics, there have been reports of resistant strains occurring since the mid 1980's, making it an important bacterium to study.


Discovered (when/where): Examples of citations [1], [2]

Genome structure

Capnocytophaga gingivalis strain ATCC 33624 contains approximately 5,000bp in its genome and 2,641 recorded genes (JGI IMG/M)(BioCyc). This microaerophilic organism contain a newly discovered bacterial Pnkp1-Rnl-Hen1 RNA repair mechanism(NCBI WANG). Studies have linked these heterohexamer proteins to the restoration of RNA and overall immunity. This can be seen as an adaptive defense mechanism against toxins as the organism is able to successfully excise ribotoxins, preventing infection and increasing longevity. In order for this process to occur, Hen1 must first methylate the RNA, marking the RNA for cleavage. Pnkp1 then attaches to the damaged RNA ends, followed by Rnl1 that ligates it, restoring the RNAs function. Once this process has been carried out, that strand of RNA will contain a form of immunity to that specific ribotoxin.

Cell structure and metabolism

Being a gram negative bacteria, the crystal violet stain used in gram staining does not stick to C. gingivalis as its cell wall contains a very small amount of peptidoglycan. The cell walls of gram negative bacteria are composed of a nuclear envelope, a thin layer of peptidoglycan and an outer membrane. Due to the presence of peptidoglycan in their cell walls, gram negative bacteria are still susceptible to lysozyme which catalyzes hydrolysis of the cell by weakening the glycosidic bonds, although often used in conjunction with ethylenediaminetetraacetic acid (Ianco)(Voss).

A biofilm is the clustered formation of a thin layer of microorganisms which cling together to adhere to a hard surface, such as the tooth. It begins with the pellicle (saliva) containing large quantities of absorbed macromolecules directly to the teeth (sakaguchi). Free-floating bacteria will then attach themselves to the saliva-coated tooth in order to feed, being the primary colonizers. Then the secondary colonizers, Capnocytophaga gingivalis, bind to the primary colonizers creating a second layer, proving increased strength and structure to the biofilm. When left over long periods of time, this can create instances of plaque which if left unchecked can result in periodontal infections. Throughout this micro-colony, each microorganism is exposed to different environmental conditions such as; physical proximity, oxygen and glucose requirements. This is why each C. gingivitis will exhibit different phenotype throughout the oral cavity (hosohama-saito).

Capnocytophaga gingivalis are motile organisms, despite lacking both flagella and flagellates. They create longitudinal movement in a gliding motion. Although the exact mechanisms which control this form of movement are still unknown, it is hypothesized that the front of the bacteria extends and attaches to the surface before detaching at the rear creating a gliding motion (balows).

Aerobic metabolism is the preferred method of respiration used by Capnocytophaga gingivalis, although it is capable of reverting to fermentation if oxygen is absent. To aerobically respire, the bacteria will go through the process of glycolysis whereby the cell will uptake glucose, and oxidize it. This breaks the glucose apart into two pyruvates and two NAD molecules which are then put through the citric acid cycle. In this process the pyruvates are broken down into carbon dioxide and FADH molecules. The NAD becomes NADH which goes on to stimulate the production of ATP in the electron transport chain, performed by complexes I-IV. The oxidation of NADH and FADH2 are carried out in complexes I-II, creating the proton gradient. Capnocytophaga gingivalis is a flavobacteria, meaning that the electron transfer carrier will be either a cytochrome, electron-transfer quinone, or flavoprotein in the electron transport chain, using oxygen as the terminal acceptor. In cases of anaerobic respiration, the terminal acceptor can contain a variety of organic or inorganic compounds (BIOCYC.org).

Ecology

Capnocytophaga gingivalis is present in a standard human microbiome. Individuals with plaque were discovered to have a higher prevalence of the bacteria with children having a higher risk. When compared with physical ailments results concluded that patients diagnosed with leukemia and oral diseases had 57% and 71% increase in the amount of C. gingivalis found in their oral microbiome respectively (Jolivet-gougeon).

When grown on Trypticase-soy-blood agar, Capnocytophaga gingivalis show consistent irregular colonization, staying isolated from other microorganisms (Poirier). Due to their ability to translocate via gliding, the bacterium are confined by their surrounding cells and start clumping into mounds, creating halo zones. Their irregular populations comprise of smooth cell surfaces with small pioneer colonies on the outer edges of halo zones. This is in contrast to bacteria found within the human microbiome as it is forced to co-aggregate with other microorganisms in order to gain survival advantages such as adhesion (Kolenbrander). This agglutination of neighboring cells forms the basis for biofilms and in turn, dental plaque. Co-aggregation reacts to lectin-carbohydrate molecules which are recognized by each cell. Experiments conducted in alternate ecosystems concluded that this process was unique to the oral cavity, as predation or nutritional instability were common occurrences when grown elsewhere. This is definitive proof that C. gingivalis are opportunistic pathogens as they


Aerobe/anaerobe, habitat (location in the oral cavity, potential other environments) and microbe/host interactions.

Pathology

Do these microorganisms cause disease in the oral cavity or elsewhere?

Application to biotechnology

Bioengineering, biotechnologically relevant enzyme/compound production, drug targets,…

Current research

Summarise some of the most recent discoveries regarding this species.

References

References examples

1. Sahm, K., MacGregor, B.J., Jørgensen, B.B., and Stahl, D.A. (1999) Sulphate reduction and vertical distribution of sulphate-reducing bacteria quantified by rRNA slotblot hybridization in a coastal marine sediment. Environ Microbiol 1: 65-74.

2. Human Oral Microbiome

  1. MICR3004

This page is written by Rochelle Overton for the MICR3004 course, Semester 2, 2016