TY - JOUR
T1 - RcsA, an unstable positive regulator of capsular polysaccharide synthesis
AU - Stout, V.
AU - Torres-Cabassa, A.
AU - Maurizi, M. R.
AU - Gutnick, D.
AU - Gottesman, S.
PY - 1991
Y1 - 1991
N2 - RcsA is an unstable positive regulator required for the synthesis of colanic acid capsular polysaccharide in Escherichia coli. Degradation of the RcsA protein in vivo depends on the ATP-dependent Lon protease. DNA sequence analysis of the rcsA gene reveals a single open reading frame for a 23,500-Da highly basic protein (pI = 9.9), consistent with the observed size of the purified subunit of RcsA. The DNA and protein sequences are highly homologous to the rcsA gene and protein from Klebsiella pneumoniae and other species. The carboxy-terminal region of RcsA contains a possible helix-turn-helix DNA-binding motif that resembles sequences found at the carboxy terminus of RcsB, another positive regulator of capsule synthesis, and in several other transcriptional regulators including members of the LuxR family. rcsA62, a mutation in rcsA that leads to increased capsule synthesis, encodes a protein designated RcsA(*), which differs from wild-type RcsA only in the replacement of Met-145 by valine. The RcsA(*) protein is subject to Lon-dependent degradation. The stability of wild-type RcsA in vivo is increased by multicopy RcsB. Conversely, RcsA is degraded more rapidly in rcsB mutant hosts than in wild-type hosts. These results suggest that RcsA and RcsB interact in vivo and are consistent with genetic experiments that indicate an interaction between RcsA and RcsB. Based on these experiments, we propose a model for capsule regulation in which RcsA interacts directly with RcsB to promote transcription of the genes for capsule synthesis.
AB - RcsA is an unstable positive regulator required for the synthesis of colanic acid capsular polysaccharide in Escherichia coli. Degradation of the RcsA protein in vivo depends on the ATP-dependent Lon protease. DNA sequence analysis of the rcsA gene reveals a single open reading frame for a 23,500-Da highly basic protein (pI = 9.9), consistent with the observed size of the purified subunit of RcsA. The DNA and protein sequences are highly homologous to the rcsA gene and protein from Klebsiella pneumoniae and other species. The carboxy-terminal region of RcsA contains a possible helix-turn-helix DNA-binding motif that resembles sequences found at the carboxy terminus of RcsB, another positive regulator of capsule synthesis, and in several other transcriptional regulators including members of the LuxR family. rcsA62, a mutation in rcsA that leads to increased capsule synthesis, encodes a protein designated RcsA(*), which differs from wild-type RcsA only in the replacement of Met-145 by valine. The RcsA(*) protein is subject to Lon-dependent degradation. The stability of wild-type RcsA in vivo is increased by multicopy RcsB. Conversely, RcsA is degraded more rapidly in rcsB mutant hosts than in wild-type hosts. These results suggest that RcsA and RcsB interact in vivo and are consistent with genetic experiments that indicate an interaction between RcsA and RcsB. Based on these experiments, we propose a model for capsule regulation in which RcsA interacts directly with RcsB to promote transcription of the genes for capsule synthesis.
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U2 - 10.1128/jb.173.5.1738-1747.1991
DO - 10.1128/jb.173.5.1738-1747.1991
M3 - Article
C2 - 1999391
AN - SCOPUS:0026061713
SN - 0021-9193
VL - 173
SP - 1738
EP - 1747
JO - Journal of bacteriology
JF - Journal of bacteriology
IS - 5
ER -