AI Article Synopsis
- Bacteria called Bacillus subtilis use a communication system called comQXPA for regulating gene expression in stationary phase.
- There’s a high level of genetic variation in the comQXP' region among closely related strains found in desert soil, creating distinct communication groups or "pherotypes" that can only effectively exchange information within their own group.
- Microscale analysis of B. subtilis from tiny soil samples showed the same number of pherotypes as larger samples, supporting ongoing evolution of their communication system, potentially leading to new communication "languages" among these bacteria.
Article Abstract
Bacillus subtilis strains communicate through the comQXPA quorum sensing (QS) system, which regulates genes expressed during early stationary phase. A high polymorphism of comQXP' loci was found in closely related strains isolated from desert soil samples separated by distances ranging from meters to kilometers. The observed polymorphism comprised four communication groups (pherotypes), such that strains belonging to the same pherotype exchanged information efficiently but strains from different pherotypes failed to communicate. To determine whether the same level of polymorphism in the comQXP' QS system could be detected at microscale, B. subtilis isolates were obtained from two separate 1-cm(3) soil samples, which were progressively divided into smaller sections. Cross-activation studies using pherotype-responsive reporter strains indicated the same number of communication pherotypes at microscale as previously determined at macroscale. Sequencing of the housekeeping gene gyrA and the QS comQ gene confirmed different evolutionary rates of these genes. Furthermore, an asymmetric communication response was detected inside the two pherotype clusters, suggesting continuous evolution of the QS system and possible development of new languages. To our knowledge, this is the first microscale study demonstrating the presence of different QS languages among isolates of one species, and the implications of this microscale diversity for microbial interactions are discussed.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC2648371 | PMC |
| http://dx.doi.org/10.1128/JB.01290-08 | DOI Listing |
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