Bacteroides dorei

Bacteroides dorei is a species of bacteria within the genus Bacteroides, first isolated in 2006. It is found in the intestinal systems of humans and animals.[1] Research is being conducted to better understand the relationship Bacteroides dorei has on the human intestinal system and the autoimmune disease, Type 1 Diabetes (T1D).[1][2]

Bacteroides dorei
Scientific classification
Domain: Bacteria
Phylum: Bacteroidota
Class: Bacteroidia
Order: Bacteroidales
Family: Bacteroidaceae
Genus: Bacteroides
Species:
B. dorei
Binomial name
Bacteroides dorei
Bakir et al. 2006

Biology and ecology

Bacteroides dorei is an gram negative, rod-shaped bacteria that contributes to normal intestinal functionality. It was isolated and differentiated from Bacteroides vulgatus by using 16S rRNA sequencing and phenotypic tests.[3] B. dorei is a non-spore-forming, non-motile, and anaerobic bacterium with a DNA G+C content of 43%. Growth occurs optimally at 37 °C with individual cell size between 1.6-4.2 μm by 0.8-1.2 μm. In addition, colonies streaked on Eggerth Gagnon (EG) agar with 5% horse blood plate and incubated over 48 hours in 100% CO2 gas at 37 °C, resulted in colony size of 2.0 mm and individual colony morphology of circular, white, raised, and convexed.[1]

Taxonomy

Bacteroides
79
94
76
51
97
94
100
100

B. dorei 175T (=JCM 13471T) (AB242142)

B. dorei 219 (=JCM 13472) (AB242143)

B. vulgatus ATCC 8482T (M58762)

B. massiliensis CCUG 48901T (AY126616)

99

B. coprocola JCM 12979T (AB200224)

B. plebeius JCM 12973T (AB200217)

B. helcogenes JCM 6297T (AB200227)

57

B.eggerthii NCTC 11155T (L16485)

B. stercoris ATCC 43183T (X83953)

B. uniformis ATCC 8492T (L16486)

B. intestinalis JCM 13265T (AB214328)

89
78

B. nordii ATCC BAA-998T (AY608697)

B. salyersiae ATCC BAA-997T (AY608696)

B. fragilis ATCC 25285T (M11656)

B.thetaiotaomicron ATCC 29148T (L16489)

B.finegoldii JCM 13345T (AB222699)

B.ovatus NCTC 11153T (L16484)

92

B. acidifaciens JCM 10556T (AB021164)

B. caccae ATCC 43185T (XB3951)

100

B. tectus JCM 10003T (AB200228)

99

B. pyogenes JCM 6294T (AB200229)

B. denticanum B78 (AF319778)

B. coprosuis CCUG 50528T (AF319778)

100

B. merdae ATCC 43184T (X83954)

B. distasonis ATCC 8503T (M86695)

100

B. capillosus ATCC 29799T (AY136666)

B. cellulosolvens ATCC 35603T (L35517)

Provotella melaninogenica ATCC 25845T (AY323525)

Neighbour-joining tree showing phylogenetic positions of isolates 175T and 219 among recognized members of the genus Bacteroides based on 16S rRNA gene sequences available in the DDBJ/EMBL/GenBank databases. Scale bar represents 0.02 substitutions per nucleotide position. Bootstrap values (>50%) based on 1000 replications are listed as percentages at the branching points.[1]

Metabolism

Bacteroides dorei has been tested for numerous different metabolic test looking at different sugars. Growth of cells was seen via production of acid occurred on the following sugars: glucose, sucrose, xylose, rhamnose, lactose, maltose, arabinose, mannose and raffinose while no growth and no acid production occurred on the following sugars: cellobiose, salicin, trehalose, mannitol, glycerol, melezitose and sorbitol.[1]

Medical significance

Previous research has shown that individuals who are genetically predisposition to various autoimmune diseases have significant differences in bacteria composition than non-genetically predisposition individuals. This difference in bacteria composition in the gut system is increasingly believed to be highly important in understanding autoimmune diseases such as Type1 Diabetes. In 2014, researchers looked at the early development of bacterial composition in high genetic risk children looking at early onset of Type 1 Diabetes. They took stool samples of 76 children looking at the early development of microbial communities from 4–6 months of age until 2.2 year old. Out of the 76 infants, 29 seroconverted to T1D autoimmune related cases, of which of 22 later on developed T1D (cases). The other 47 infants didn't seroconvert or develop T1D (control). Metagenomic sequencing results showed significantly higher composition of B. dorei and Bacteroides vulgatus in the cases versus the control group prior to seroconversion. In addition, data showed that B. dorei peaked at 7.6 months, almost 8 months prior to first inslet autoantibody in cases. This significant compositional change suggests that the increase in amount of B. dorei is a potential indicator of the development of T1D.[2]

Additional research looked at epigenetics of B. dorei and were able to demonstrate that 1 individual had B. dorei with GATC (gene) methylation while another individual had B. dorei lacking GATC methylation. Scientist took stool samples of two babies and sequenced the genomes of B. dorei in samples 105 and 439. Sample B. dorei 105 had 49,007 total methylation in the genome with 14,322 methylation sites and in sample B. dorei 439, there was 38,203 total methylations with 24,770 methylation sites. The key result is that sample 105 includes a key gene called DamMT (DNA methyltransferase) while sample 439 lacked this gene. In addition, out of 20,554 GATC sites in sample B. dorei 105, there was only had 3 sites that weren't methylated whereas sample B. dorei 439 had 18,908 GATC sites and none of the GATC sites were methylated. Dam methylation and methylation of GATC could be significant factors for microbial colonization and functionality in the gut system and affects numerous gene expressions of transport processes such as nutrient transportation, antibiotic effluxes actions to antibiotic resistance, and movement of energy. The results suggests that Dam and GATC methylation of B. dorei 105 could have highly significant varied gene expression from B. dorei 439 that lacks GATC methylation and could affect functionality of B. dorei in the gut microbiome. Previous research has shown that Dam methylation mutants have increased susceptibility to higher antibiotic concentrations and lower minimum. This suggests that Dam methylation process plays a significant role in up-regulation of antibiotic effluxes, resulting in increased antibiotic resistance. Also, GATC methylation demonstrates important microbial functions such as DNA repair, replication, and LPS composition. Methylation of GATC motif by DamMT in pathogenic bacteria, for example, Vibrio cholerae, Yersinia pestis, and Yersinia pseudotuberculosis has been shown to increase virulence and expression of genes towards multiple operations such as, mismatch repair and DNA replication enables pathogenic bacteria to combat against antibiotics. These results show why future research to create antibiotics that prevent the creation of DamMT in pathogenetic bacteria is needed.[4]

References

  1. Bakir, M.A.; Sakamoto, M.; Kitahara, M.; Matsumoto, M.; Benno, Y. (2006). "Bacteroides dorei gen., sp. nov., isolated from human faeces". International Journal of Systematic and Evolutionary Microbiology. 56 (7): 1639–1643. doi:10.1099/ijs.0.64257-0. ISSN 1466-5026. PMID 16825642.
  2. Davis Richardson, A.G.; Ardissone, A.N.; Dias, R.; Simell, V.; Leonard, M.T.; Kemppainen, K.M.; Drew, J.C. (2014). "Bacteroides dorei dominates gut microbiome prior to autoimmunity in Finnish children at high risk for type 1 diabetes". Frontiers in Microbiology. 5 (678): 1–11. doi:10.3389/fmicb.2014.00678. ISSN 1664-302X. PMC 4261809. PMID 25540641.
  3. Pedersen, R.M.; Marmolin, E.S.; Justesen, U.S. (2013). "Species differentiation of Bacteroides dorei from Bacteroides vulgatus and Bacteroides ovatus from Bacteroides xylanisolvens–Back to basics". Anaerobe. 24 (December): 1–3. doi:10.1016/j.anaerobe.2013.08.004. ISSN 1075-9964. PMID 23994205.
  4. Leonard, M.T.; Davis-Richardson, A.G.; Ardissone, A.N.; Kemppainen, K.M.; Drew, J.C.; Ilonen, J.; Knip, M.; Simell, O.; Toppari, J.; Veijola, R.; Hyöty, H.; Triplett, E.W. (2014). "The methylome of the gut microbiome: disparate Dam methylation patterns in intestinal Bacteroides dorei". Frontiers in Microbiology. 5: 361. doi:10.3389/fmicb.2014.00361. ISSN 1664-302X. PMC 4101878. PMID 25101067.
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