The strong environmental protection response of
B. cenocepacia is attributed to the biofilm formed by groups of the organism. This biofilm contains
exopolysaccharides that strengthen the bacterium's resistance to antibiotics and contribute to the bacteria's virulence. It is made up of a highly branched polysaccharide unit with one
glucose, one
glucuronic acid, one
mannose, one
rhamnose, and three
galactose molecules. This species in the
Burkholderia cepacia complex has also created another polysaccharide with one 3-deoxy-d-
manno-2-octulosonic acid and three galactose molecules. The biofilm exopolysaccharides act as a barrier to
neutrophils from human immune resistance systems, undermining the neutrophil defense action by inhibiting neutrophil
chemotaxis and scavenging
reactive oxygen species, which are bactericidal products produced by neutrophils to destroy bacteria.
Genome B. cenocepacia's genome consists of three circular chromosomes and one
plasmid. Chromosome 1 contains 3.87 Mb, chromosome 2 contains 3.22 Mb, and chromosome 3 contains 0.88 Mb. The plasmid is approximately 0.09 Mb. Chromosome 3 has also been characterized as a large plasmid, or megaplasmid (pC3); unlike chromosomes 2 and 3, it does not contain essential
housekeeping genes, instead coding for accessory functions such as virulence and resistance to stress. In addition to the
multireplicon structure, the genome contains several
insertion sequences and can rapidly mutate during infections, which contribute to
B. cenocepacia's unique adaptability and ability to acquire diverse catabolic functions.
Environments Burkholderia cenocepacia has been found to thrive in primarily
microaerophilic conditions, which consist of little to no oxygen. Experimental studies conducted on the growth of
B. cenocepacia in environments akin to the human lungs demonstrated the pathogen's increased success in microaerophilic environments over aerophilic settings. Out of the four types of siderophores produced by the Bcc,
B. cenocepacia produces three: ornibactin, pyochelin, and salicylic acid (SA). Ornibactin is the most important iron uptake system and can sustain the bacteria in an iron-deficient environment even without the production of functioning pyochelin or SA.
B. cenocepacia has been demonstrated to colonize an array of ecological niches with diverse lifestyles. The ability to utilize a wide range of carbon sources accompanies the ability of Bcc species to be efficient with plant-growth promotion,
bioremediation, and biocontrol. High potential of Bcc species, including
B. cenocepacia, as a biocontrol of plant-growth promoting agents has been demonstrated; however, the mechanisms that support this are not known. However,
B. cenocepacia also demonstrated
phytopathogenic properties in causing fingertip rot in bananas. The two AHL-mediated QS systems, CepIR and CciIR, regulate each other; the CepR protein is required for the transcription of the
cciIR operon, while the CciR protein represses transcription of
cepI. The CciIR system can also negatively regulate the CepIR system through the production of C6-HSL, a type of AHL produced primarily by CciI proteins that inhibits the activity of CepR proteins. The bacterium also uses cis-2-dodecenoic acid signals, which are known as
Burkholderia diffusible signal factors (BDSF) because they were first identified in
Burkholderia cenocepacia.
Motility Burkholderia cenocepacia has the ability to swim and
swarm inside the body. It has a polar flagella and produces a surfactant. These characteristics are necessary for the species to have motility in an agar medium. The surfactant produced by
Burkholderia cenocepacia allows other pathogenic bacteria in the lungs to have motility. This means that the presence of
Burkholderia cenocepacia is necessary for swarms of bacteria to coexist and cooperate in the lungs. ==Pathogenicity==