Role of the histidine kinase, EnvZ, in the production of outer membrane proteins in the symbiotic-pathogenic bacterium Xenorhabdus nematophilus.

We show that inactivation of envZ, the gene encoding the histidine kinase sensor protein, EnvZ, of Xenorhabdus nematophilus, affected the production of several outer membrane proteins (Opns). X. nematophilus produced five major Opns during exponential growth. Insertional inactivation of envZ led to a decrease in the production of OpnP, the OmpF-like pore-forming protein which constitutes approximately 50% of the total outer membrane protein in X. nematophilus. OpnA production was also reduced, while the remaining Opns were produced normally. During the transition to stationary phase, three new outer membrane proteins, OpnB, OpnS, and OpnX, were induced in the wild-type strain. The envZ-minus strain, ANT1, did not produce OpnB and OpnX, while OpnS was induced at markedly reduced levels. These results suggest that EnvZ was required for the high-level production of OpnP during exponential growth and may be involved in the production of OpnB, OpnS, and OpnX during stationary-phase growth. We also show that ANT1 was more pathogenic than the wild-type strain when as few as five cells were injected into the hemolymph of the larval stage of the tobacco hornworm (Manduca sexta). The larvae died before significant numbers of bacteria were detectable in the hemolymph. These results are discussed in relation to the role of EnvZ in the life cycle of X. nematophilus.

Role of His243 in the phosphatase activity of EnvZ in Escherichia coli.

EnvZ undergoes autophosphorylation at His243 and subsequently transfers the phosphate group to OmpR. EnvZ also possesses an OmpR-phosphate phosphatase activity. We examined the role of His243 in the phosphatase function by replacing His with either Val, Tyr, Ser, Asp, or Asn. EnvZH243V and EnvZH243Y were both shown to possess phosphatase activity in vitro. In addition, the mutant proteins were able to reduce the high level of OmpR-phosphate present in the envZ473 strain. These results indicate that His243 of EnvZ is not essential for stimulating the dephosphorylation of OmpR-phosphate.

Characterization and environmental regulation of outer membrane proteins in Xenorhabdus nematophilus.

We have examined the production of the outer membrane proteins of the primary and secondary forms of Xenorhabdus nematophilus during exponential- and stationary-phase growth at different temperatures. The most highly expressed outer membrane protein of X. nematophilus was OpnP. The amino acid composition of OpnP was very similar to those of the porin proteins OmpF and OmpC of Escherichia coli. N-terminal amino acid sequence analysis revealed that residues 1 to 27 of the mature OpnP shared 70 and 60% sequence identities with OmpC and OmpF, respectively. These results suggest that OpnP is a major porin protein in X. nematophilus. Three additional proteins, OpnA, OpnB, and OpnS, were induced during stationary-phase growth. OpnB was present at a high level in stationary-phase cells grown at 19 to 30 degrees C and was repressed in cells grown at 34 degrees C. OpnA was optimally produced at 30 degrees C and was not present in cells grown at lower and higher temperatures. The production of OpnS was not dependent on growth temperature. In contrast, another outer membrane protein, OpnT, was strongly induced as the growth temperature was elevated from 19 to 34 degrees C. In addition, we show that the stationary-phase proteins OpnA and OpnB were not produced in secondary-form cells.

Identification of the site of phosphorylation on the osmosensor, EnvZ, of Escherichia coli.

EnvZ is a membrane-bound histidine kinase that functions as an osmotic sensor capable of phosphorylating the regulator protein OmpR in Escherichia coli. To characterize the site of phosphorylation biochemically, we overexpressed a 36-kDa truncated EnvZ protein (Glu-106 to Gly-450) that formed inclusion bodies in the cell. After solubilization, the inclusion body form of EnvZ was cleaved into two major fragments with molecular weights of 25,000 and 10,000. The 25-kDa fragment, EnvZc, was purified and found to exist as a dimer. N-terminal sequence analysis established that cleavage had occurred at Arg-214, indicating that EnvZc contained most of the cytoplasmic domain of EnvZ. After labeling EnvZc with [gamma-32P]ATP, the protein was proteolytically digested, and the resulting peptides were separated by reverse phase chromatography using high performance liquid chromatography. One major radioactive peptide containing greater than 90% of the recovered peptide-associated radioactivity was isolated. Amino acid analysis of this purified peptide indicated that the composition was consistent with a peptide that contained His-243. The amino acid sequence of this peptide was determined to be MAGVSHDLRTP (residues 238-248). These results indicate that His-243 is the major site of phosphorylation on EnvZ and represents the first biochemical characterization of the site of phosphorylation of a membrane histidine kinase of the two-component regulatory family of molecules in bacteria.

Ca2(+)-enhanced phosphorylation of a chimeric protein kinase involved with bacterial signal transduction.

The Tar-EnvZ hybrid molecule (Taz1) is an inner membrane transducer that activates OmpR, a transcriptional activator for porin gene expression (ompC), in response to an aspartic acid signal. Signal transduction by Taz1 most likely involves a phosphorylated Taz1 intermediate that donates its phosphate to OmpR. Phosphorylated OmpR has already been implicated in transcriptional activation of porin genes. Using a cell-free system containing Taz1-enriched membrane fractions, we have examined the phosphorylation properties of Taz1 and the stimulatory effects of divalent and monovalent ions. Highest activation of Taz1 phosphorylation was observed with CaCl2, and its stimulation could be observed with as low as 60 microM of CaCl2. Phosphorylated Taz1 could readily donate its phosphate group to OmpR in the presence of calcium. CaCl2 was also able to enhance phosphorylation of intact membrane-bound EnvZ and a cytoplasmic fragment of EnvZ lacking the receptor and transmembrane domains. These results indicate that the site for CaCl2 stimulation is within the cytoplasmic region of EnvZ and probably involves an enhanced rate of EnvZ phosphorylation.

micF RNA in ompB mutants of Escherichia coli: different pathways regulate micF RNA levels in response to osmolarity and temperature change.

The repressor RNA, micF RNA, is regulated by temperature, osmolarity, and other stress conditions during growth of Escherichia coli. Northern (RNA) blot analyses showed that levels of micF RNA differ widely in various ompB mutant strains when cells are grown at 24 degrees C in LB broth. For example, relative to the parental strain MC4100, the ompR101 mutant strain (which contains no functional OmpR) had about a 10-fold reduction in micF RNA, whereas the envZ11 strain showed about a 5-fold increase. At 37 degrees C, however, micF RNA levels in the ompR101 and envZ11 strains and other ompB mutants differed by less than two-fold compared with the level in strain MC4100, thus indicating that a factor(s) independent of the ompB locus regulates micF RNA expression with temperature increase and that there is an additional control mechanism(s) which maintains the levels of micF RNA in these mutants close to that of the wild type during growth at high temperatures. In a plasmid strain containing the micF gene but without the upstream OmpR-binding site, steady-state levels of micF RNA increased with temperature increase but did not change with osmolarity increase. This showed that osmolal regulation but not temperature regulation of micF depends on these upstream sequences and suggested that while osmolal regulation of the micF gene depends on OmpR, thermal regulation does not.

The function of micF RNA. micF RNA is a major factor in the thermal regulation of OmpF protein in Escherichia coli.

The role of chromosomally derived micF RNA as a repressor of outer membrane protein OmpF of Escherichia coli was examined for various growth conditions. Levels of micF RNA as determined by Northern analyses are found to increase in response to cell growth at high temperature, in high osmolarity or in the presence of ethanol. After a switch to higher growth temperature, the levels of ompF mRNA and of newly synthesized OmpF decrease with time in E. coli strain, MC4100 but these decreases are not observed in isogenic micF deletion strain, SM3001. In addition, while levels of ompF mRNA are substantially reduced in both strains in response to high osmolarity or ethanol at 24 degrees C, the reduced levels in the parental strain are still 4-5-fold lower compared with the micF deletion strain. These findings indicate that chromosomally derived micF RNA plays a major role in the thermal regulation of OmpF and represses OmpF synthesis in response to several environmental signals by decreasing the levels of ompF mRNA. Analyses of the effect of a multicopy micF plasmid on the levels of OmpF and ompF mRNA after an increase in temperature indicated that multicopies of micF RNA markedly inhibited OmpF synthesis but did not accentuate ompF mRNA decrease. These data suggest that multicopy micF inhibits OmpF synthesis primarily through translational inactivation of ompF mRNA and that a limiting factor in addition to micF RNA is necessary to destabilize ompF mRNA.

Activation of bacterial porin gene expression by a chimeric signal transducer in response to aspartate.

The Tar chemoreceptor of Escherichia coli is a membrane-bound sensory protein that facilitates bacterial chemotaxis in response to aspartate. The EnvZ molecule has a membrane topology similar to Tar and is a putative osmosensor that is required for osmoregulation of the genes for the major outer membrane porin proteins, OmpF and OmpC. The cytoplasmic signaling domain of Tar was replaced with the carboxyl portion of EnvZ, and the resulting chimeric receptor activated transcription of the ompC gene in response to aspartate. The activation of ompC by the chimeric receptor was absolutely dependent on OmpR, a transcriptional activator for ompF and ompC.

DNA-binding properties of the transcription activator (OmpR) for the upstream sequences of ompF in Escherichia coli are altered by envZ mutations and medium osmolarity.

Expression in Escherichia coli of the genes that encode the major outer membrane porin proteins (OmpF and OmpC) is regulated by the transcription activator protein OmpR and the receptorlike protein EnvZ, which is located in the inner membrane. Using synthesized oligonucleotide fragments containing the OmpR-binding site of ompF, we show that soluble extracts and partially purified OmpR derived from both the parent strain grown in nutrient broth plus 20% sucrose and the envZ11 strain grown in nutrient broth produced high-affinity DNA-binding activity, whereas soluble extracts from the parent strain grown in nutrient broth produced low-affinity binding. We also show that the soluble extracts from the envZ22(Am) strain grown in nutrient broth did not produce detectable bound forms of the ompF fragments, but low levels of DNA binding were detected with soluble extracts of the envZ22 strain grown in nutrient broth plus sucrose. In addition, the time course of the repression of OmpF synthesis produced by a shift to high-osmolarity growth medium was correlated with an increase in the DNA-binding affinity of soluble extracts to the ompF fragment. These results provide evidence that envZ function influences the DNA-binding activity of OmpR and suggest that high-affinity binding of OmpR to the upstream sequences of ompF is correlated with the repression of OmpF production.