| Abstract [eng] |
Prokaryotic toxin antitoxin systems consist of two adjacent genes, where one encodes a stable toxin harmful to essential cellular processes (translation or DNA synthesis), and the other a labile antitoxin, capable of blocking the toxin's activity by binding into stable protein complex. TA systems are proposed to be involved in bacterial adaptation to stress conditions by modulating the level of essential biological processes. There are at least ten characterized chromosome-encoded TA loci in Escherichia coli. The dinJ-yafQ operon codes for YafQ toxin which is neutralized by its cognate antitoxin, DinJ. YafQ is known to inhibit translation in vivo and belongs to the RelE toxin family of toxin ribonucleases. By using site-specific mutagenesis of YafQ, we have investigated the protein regions important for its interaction with DinJ antitoxin. Transcriptional autoregulation has been reported for members of all known TA gene families and appears to be general characteristic of regulation of TA loci. In this work electrophoretic mobility shift assay was used to investigate the interaction between the antitoxin DinJ and DinJ-YafQ complex and dinJ-yafQ operon promoter DNA. Antitoxin DinJ in the complex with YafQ had an enhanced DNA-binding affinity compared to free DinJ. N-terminal domain of antitoxin is crucial for interaction with DNA. Bioinformatic analysis of dinJ-yafQ operon promoter region revealed several palindromic DNA islands and their importance for interaction with DinJ and YafQ proteins have been investigated. |
