Difference between revisions of "User:S4355920"
|Line 118:||Line 118:|
<b> Chapter Referencing?? <b>
<b> Chapter Referencing?? <b>
Revision as of 12:43, 14 September 2016
Name Bench ID Date MICR3004
Higher order taxa
Bacteria – Bacteroidetes – Bacteroidia – Bacteroidales – Porphyromonadaceae - Porphyromonas - P. gingivalis
Species: Porphyromonas gingivalis Strain: ATCC 33277
Description and significance
Porphyromonas gingivalis is an obligately aerobic, gram-negative bacterium belonging to the phylum Bacteroidetes. Characterised by its rod shaped morphology, it is a non-spore bearing and non-motile bacterium most commonly inhabiting the oral cavity . Recognised as an opportunistic pathogen, P. gingivalis is capable of living in commensal harmony with the host . Termed as a pathobiont, the bacterium can cause episodes of diseases when a change in the ecological balance of the periodontal microenvironment transpires . Although the bacterium is capable of existing as a commensal organism, certain strains are known to be more virulent and pathogenic than others (5). Virulent strains have found to include, W83, W50, ATCC 49417 and A7A1 . Avirulent strains include ATCC 381, 33277 and 23A4  . In vitro studies of the bacterium have found cells cultured in broth with a size range from 0.5 by 1 to 2 μm . Cells grown on a solid media showed coccobacilli or very short rod structures . On blood agar plates, the bacterium forms black-pigmented colonies, predominately smooth, shiny and convex with a diameter between 1 to 2 mm (, ).
Typically found in the oral cavity of individuals, P. gingivalis has been implicated with periodontal diseases, most commonly associated with chronic periodontitis. A report from the Centres for Disease Control and Prevention (CDC) recorded 47. 2 % of adults in the United Stated aged 30 years or older have experienced some form of periodontal disease . In light of this information, recent studies have also reported that P. gingivalis is associated with systematic diseases, including cardiovascular diseases, rheumatoid arthritis and decreased kidney function . Studies underlying the molecular mechanisms behind the bacterial pathogenesis are key to design effective treatments. Consequently reducing the potential development of inflammatory diseases that arise as a secondary consequence of periodontitis.
The genome of strain ATCC 33277 is comprised of a single circular chromosome with 2 354 886 bp (3). On average the guanine (G) and cytosine (C) content makes up approximately 48.4% of the genome (3). Covering 86.1% of the whole chromosome sequence is 2090 CDSs (coding DNA sequence) with an average size of 970 bp (3,9). The circular chromosome encodes 65 RNA genes (9). Strain ATCC 33277 contains 93 IS elements and 48 miniature inverted repeat transposable elements (MITEs) (3). 4 RNA operons (rrn, 5S rRNA-23S rRNA-tRNAAla-tRNAIle-16S rRNA), including 53 tRNA genes have also been documented (3). Interestingly the number of rrn operons and tRNA genes in strain ATCC 33277 were identical to those of a virulent strain counterpart W83 (3,10). Nonetheless the extensive rearrangement between the two strains through the introduction of mobile elements inevitably altered the virulence of the bacterium.
Further more it has been revealed a host of bacterial species such as Bacteroides fragilis exhibit a high gene similarity to those of the ATCC 33277 strain (3). Theories suggest these genes were introduced to ATCC 33277 by a horizontal gene transfer event (3).
The genome of strain W88 is comprised of a circular chromosome made up of 2 343 479 bp’s. On average the guanine and cytosine content make up approximately 48.3 % of the genome. The circular chromosome encodes 1909 protein genes 65 RNA genes. 4 ribosomal operons (rrn, 5S rRNA-23S rRNA-tRNAAla-tRNAIle-16S rRNA) including 53 tRNA genes showing specificity for all 20 amino acids have been documented. Interestingly the number of rrn operons and tRNA genes in strain W83 were identical to those of an avirulent strain counterpart ATCC 33277. Nonetheless the extensive rearrangement between the two strains through the introduction of mobile elements inevitably altered the virulence of the bacterium.
The genome of W83 is composed predominately (85%) of ORF. Encoding a total of 1,990 ORF, 1075 presented detectable biological roles. Of the remaining ORF, 184 were categorised as a conserved hypothetical protein or conserved domain protein, 208 had to known function, and 523 encoded hypothetical proteins.
Cell structure and metabolism
Cell Wall: P. gingivalis is an obligately aerobic, non-motile gram-negative bacterium (2). Its cell wall is characterised by three distinct layers, including two membranous structures known as the inner membrane (IM) and the outer membrane (OM) (11). Connecting the two layers is a gel like structure known as the periplasm and a thin layer of peptidoglycan (11). The IM and OM possess a trilamellar structure composed of phospholipids (11). Distributed along the outer membrane are lipoproteins and lipopolysaccharides (LPS), which serve as an anchor for lipids (11). Chemically LPS is composed of three subunits, the O specific polysaccharide chain, the core and lipid A (11).
Fimbriae: Protruding the outer membrane of the cell wall, thin proteinaceous surface appendages aid and mediate bacterial attachment to the host (12). Approximately 25 μm long (12) these structures have a robust ability to interact with salivary proteins, epithelial cells, extracellular matrix proteins and the fibroblasts of the host. Two distinct fimbriae types are displayed on the cell surfaces of the bacteria, known as FimA and Mfa protein (12). These surface structures are proposed to have a role in the progression of periodontal inflammatory reactions. Six genotypes of FimA structures exist (type I-V and Ib), ranging from 40.5 to 49kDa in size (12). Strain W83 is classed under type IV and are poorly fimbriated whereas strain ATCC 33277 are an abundantly fimbriated type I strain (12). The progression of chronic periodontitis is most closely associated with type II strains followed by type IV (12).
Biofilm formation: The bacterium colonises the oral cavity by forming a complex biofilm known as plaque (5). They are recognised as secondary or late colonisers and require antecedent organisms to form the necessary environmental conditions for growth (12). Upon contact the bacterium must resist the plethora of host responses working against bacterial colonisation (5). Host factors are known to include mechanical shearing produced from the force of the tongue, saliva and gingival crevicular fluid flow (5). Successful colonisers must therefore possess a diverse repertoire of virulence factors to overcome host defences (5).
Metabolic Functions: P. gingivalis is dependent on nitrogenous substrates for energy production (5). Despite the nitrogenous compounds present in the oral cavity, the bacterium has a limited ability to ferment free amino acids. Aspartic acid and Asparagine are among the few, which can be metabolised to yield succinate.
Anaerobe: In the literature, P. gingivalis was previously regarded as a strictly anaerobic bacterium (19). However current understanding of its genome composition indicates the presence of an oxygen metabolism pathway (19). Although the bacterium grows optimally in aerobic conditions, the route towards the periodontal pockets involves exposure to oxygen (19). Oxidative stress mechanisms are most likely employed to cope with the brief exposure to oxygen. Analysis of genome composition, revealed the presence of aerobic respiration genes (cydA and cydB), encoding the haem protein cytochrome bd oxidase (19).
Habitat: P. gingivalis is a natural inhabitant of the oral microbiome and is typically found residing in the subgingival sulcus of the oral cavity (13,14). The bacterium can also be found along the cheek, gingiva and tongue (5). Although colonisation of the gingival crevice and periodontal pocket are typically associated with infection, colonisation of remote surfaces can also lead to disease (5). Recognised as a secondary or late coloniser, attachment to antecedent organisms is typically evident (12). Primary organisms provide a foundation for attachment and form the necessary environmental conditions for growth. Such as supplying growth substrates and decreasing oxygen tension (5, 12). Attachment to early plaque organisms includes species of oral streptococci (Streptococcus gordonii, S. sanguis, S. oralis, S. mitis, and S. crista) and Actinomyces naeslundii (5, 15, 16,17,18).
Microbe/Host Interaction: P. gingivalis is as an opportunistic pathogen and is capable of living in commensal harmony with the host (5). Termed as a pathobiont, the bacterium can cause episodes of diseases when a change in the ecological balance of the periodontal microenvironment arises (5,14).
Periodontal disease is an infection of the supporting structures of the periodontium (5). Initial stages of periodontal disease are associated with gingivitis resulting in the inflammation of the gums. If left untreated, periodontitis can develop, leading to tooth loss and other health issues. P. Gingivalis is the major etiologic agent causing the majority of periodontitis cases. It has also been associated with systematic diseases, including cardiovascular diseases, rheumatoid arthritis and decreased kidney function (4).
Periodontitis can be classified into three different classes depending on its severity. (21)
Categories of periodontitis include: (21) Aggressive periodontitis Destructive periodontitis Chronic periodontitis
Aggressive periodontitis is accompanied by the induction of pro-inflammatory cytokines, IL1-β and IL-6 produced by CD4+ T helper cells (21). Destructive periodontitis is associated with Th1 and Th17 immune response and chronic periodontitis is associated with primarily Th17 pathways. (21)
The length of infection is partly dependent on the bacterial modulation of host responses (22). By residing in periodontal tissues the bacterium can evade host defence mechanisms (22). An arsenal of virulence factors is exploited to ensure the long-term survival of the bacterium within the oral cavity (22).
The virulence factors produced by P. gingivalis include the following:
- Enzymes (hyaluronidase, chondroitin and sulfatases)
- Outer membrane proteins
- Trypsin-like protease
Expression of these virulence factors can lead to destruction of the periodontal tissue, induction of host response and inhibition of host protective mechanisms (5). Virulence factors also known to play a significant role in various stages of the bacterium’s life cycle.
Application to biotechnology
Bioengineering, biotechnologically relevant enzyme/compound production, drug targets,…
Summarise some of the most recent discoveries regarding this species.
NOT YET LINKED TO TEXT
2. Shah N, H., Collins D, M. (1988) Proposal for Reclassification of Bacteroides asaccharolyticus, Bacteroides gingivalis, and Bacteroides endodontalis in a New Genus, Porphyromonas. Int J Syst Evol Microbiol 38 :128-131.
3. Naito, M., Hirakawa, H., Yamashita, A., Ohara, N., Shoji, M., Yukitake, H., Nakayama, K., Toh, H., Yoshimura, F., Kuhara, S., Hattori, M., Hayashi, T., Nakayama, K. (2008) Determination of the genome sequence of Porphyromonas gingivalis strain ATCC 33277 and genomic comparison with strain W83 revealed extensive genome rearrangements in P. gingivalis. DNA Res 15 :215-225.
4. Ohara-Nemoto, Y., Rouf, S. M., Naito, M., Yanase, A., Tetsuo, F., Ono, T., Kobayakawa, T., Shimoyama, Y., Kimura, S., Nakayama, K., Saiki, K., Konishi, K. & Nemoto, T. K. (2014) Identification and characterization of prokaryotic dipeptidyl-peptidase 5 from Porphyromonas gingivalis. J Biol Chem, 289: 5436-48.
10. Chen, T., Hosogi, Y., Nishikawa, K., Abbey, K., Fleischmann, R. D., Walling, J. & Duncan, M. J. (2004) Comparative whole-genome analysis of virulent and avirulent strains of Porphyromonas gingivalis. J Bacteriol, 186: 5473-9.
13. Bao, K., Belibasakis, G. N., Thurnheer, T., Aduse-Opoku, J., Curtis, M. A. and Bostanci, N. (2014) Role of Porphyromonas gingivalis gingipains in multi-species biofilm formation. BMC Microbiol, 14: 258.
18. Nagata, H., Murakami, Y., Inoshita, E., Shizukuishi, S. and Tsunemitsu, A. (1990) Inhibitory effect of human plasma and saliva on co-aggregation between Bacteroides gingivalis and Streptococcus mitis. J Dent Res, 69: 1476-9.
19. Lewis, J. P., Iyer, D. and Anaya-Bergman, C. (2009) Adaptation of Porphyromonas gingivalis to microaerophilic conditions involves increased consumption of formate and reduced utilization of lactate. Microbiology, 155: 3758-74.
20. K. E., Fleischmann, R. D., Deboy, R. T., Paulsen, I. T., Fouts, D. E., Eisen, J. A., Daugherty, S. C., Dodson, R. J., Durkin, A. S., Gwinn, M., Haft, D. H., Kolonay, J. F., Nelson, W. C., Mason, T., Tallon, L., Gray, J., Granger, D., Tettelin, H., Dong, H., Galvin, J. L., Duncan, M. J., Dewhirst, F. E. and Fraser, C. M. (2003) Complete genome sequence of the oral pathogenic Bacterium porphyromonas gingivalis strain W83. J Bacteriol, 185: 5591-601.
21. [https://www.hindawi.com/journals/jir/2014/476068/ Mysak, J., Podzimek, S., Sommerova, P., Lyuya-Mi, Y., Bartova, J., Janatova, T., Prochazkova, J. and Duskova, J. (2014) Porphyromonas gingivalis: major periodontopathic pathogen overview. J Immunol Res, 2014: 476068.
This page is written by Amy Pham for the MICR3004 course, Semester 2, 2016