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Query: UNIPROT:P51532 (
transcriptional activator
)
6,546
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
The products of a minimum of 15 genes are required for the synthesis of an active formate-
hydrogenlyase
(FHL) system in Escherichia coli. All are co-ordinately regulated in response to variations in the oxygen and nitrate concentration and the pH of the culture medium. Formate is obligately required for transcriptional activation of these genes. Analysis of the transcription of one of these genes, hycB linked to the lacZ reporter gene, revealed that oxygen and nitrate repression of transcription could be relieved completely, or partially in the case of nitrate, either by the addition of formate to the medium or by increasing the copy number of the gene encoding the
transcriptional activator
(fhlA) of this regulon. These studies uncovered a further level of regulation in which the transcription of hycB was reduced in cells grown on glucose. This effect was most clearly seen in aerobically grown cells when formate was added externally. Addition of cAMP overcame this glucose repression, which could be shown to be mediated by the cAMP receptor protein. These results would be consistent with the transport of formate being regulated by catabolite repression. Moreover, the repression of transcription through high pH also could be partially overcome by addition of increasing concentrations of formate to the medium, again being consistent with regulation at the level of formate import and export. Taken together, all these observations indicate that it is the intracellular level of formate that determines the transcription of the genes of the formate regulon by FhlA. This represents a novel positive feedback mechanism in which the activator of a regulon induces its own synthesis in response to increases in the concentration of the catabolic substrate, and this in turn is governed by the relative affinities of FhlA and the three
formate dehydrogenase
isoenzymes for formate.
...
PMID:Mechanism of regulation of the formate-hydrogenlyase pathway by oxygen, nitrate, and pH: definition of the formate regulon. 177 67
A new gene whose product is required for the production of
formate hydrogenlyase
(
FHL
) has been identified in Escherichia coli. This gene, termed fhlB, maps between the frdA (94.4 min) and argI (96.6 min) genes on the E. coli chromosome and is transcribed in a clockwise direction toward argI. Biochemical analysis of an FhlB- mutant, strain SE-2011 [phi(fhlB-lacZ+)], revealed that the mutant lacks
formate dehydrogenase
activity associated with
FHL
(FDH-H) and hydrogenase activity. As a result of these defects, fermentative hydrogen production and hydrogen uptake reactions were undetectable in strain SE-2011. Fumarate reductase activity of this mutant was also reduced to about 15% of the levels of the parent (strain MC4100), and strain SE-2011 did not produce succinate as a fermentation end product. Regulation of expression of the fhlB gene, studied as production of beta-galactosidase activity by strain SE-2011, revealed that the operon is expressed at low levels under aerobic conditions. Under anaerobic growth conditions, this activity increased by two- to threefold. Addition of formate enhanced the differential rate of synthesis of the fhlB gene product to as high as 130 U of beta-galactosidase specific activity per microgram of cell protein, but only under anaerobic conditions. Formate-dependent expression of phi(fhlB-lacZ+) required the sigma 54 subunit of RNA polymerase and the fhlA gene product. The concentration of formate required for maximum expression of the fhlB gene was about 15 mM; this value decreased to about 3 mM in the presence of plasmid pSE-133, which carries the fhlA gene in a multicopy plasmid. DNA sequence analysis of the fhlA gene showed that the FhlA protein is 686 amino acids long and has an anhydrous molecular weight of 78,086. On the basis of sequence homology with other transcriptional activators such as NtrC, HydG, and Klebsiella pneumoniae NifA proteins, the FhlA protein was deduced to be a
transcriptional activator
controlling the production of
FHL
. It is proposed that formate interacts with the FhlA protein and that this active complex initiates transcription of the fhlB gene. The FhlA and FhlB proteins act as a cascade in regulating the production of FDH-H and the
FHL
-linked hydrogenase and ultimately the production of
FHL
and fermentative hydrogen.
...
PMID:Genetic regulation of formate hydrogenlyase of Escherichia coli: role of the fhlA gene product as a transcriptional activator for a new regulatory gene, fhlB. 211 3
FHLA is the
transcriptional activator
for the expression of the genes coding for components of the
formate hydrogenlyase
system of Escherichia coli. The cloned fhlA gene was overexpressed under selected growth conditions, and a purification protocol for the FHLA protein was developed. Purified FHLA in the native state is a homotetramer. It binds to the upstream regulatory sequences of the fdhF gene and of the intergenic region between the divergently transcribed hyc and hyp operons. An additional binding site of FHLA located between the hycA and hycB genes was identified. While binding to the hypA-hycA intergenic region is responsible for activation of expression of the hyc operon, the newly identified site is required for the activation of the sigma 54-dependent promoter located upstream of the hyp operon. Formate seems to have no effect on the DNA-binding properties of FHLA. The binding sites of FHLA were characterized by DNase I footprinting; sequence motifs putatively involved in the interaction with FHLA are described.
...
PMID:Purification and DNA-binding properties of FHLA, the transcriptional activator of the formate hydrogenlyase system from Escherichia coli. 803 27
This review describes a range of pH responses. Some are only induced if relevant DNA is brought to an appropriately supercoiled configuration by DNA gyrase and bent by the action of, for example, integration host factor (IHF). Bending may allow transcription by bringing activators into juxtaposition with RNA polymerase, which is CysB-associated in several of the responses. Control of arginine decarboxylase (AdiA) synthesis at acid pH is of the above type, with dependence on the presence of gyrase, H-NS, IHF and CysB; acid induction of LysU has similar requirements but also needs Lrp; lysine decarboxylase (CadA) formation at acid pH is controlled quite differently, needing the CadC activator and interaction of lysine/lysine permease; H-NS probably reverses induction by CadC. The Hyd components of formic
hydrogenlyase
are induced by acid under anaerobiosis; a
transcriptional activator
is involved and Fur may also function in regulation. Acid tolerance induced at low pH in log-phase cells needs CysB and PhoE but not DNA gyrase; tolerance is reduced by NaCl but not affected by Fe3+, Fe2+, glucose/cAMP or by lrp, him, fur, hns or nhaA/B lesions. Alkali tolerance (habituation), induced at pH0 8.5-9.0, probably involves DNA supercoiling and bending; the induction process needs IHF, CysB, PhoE, NhaA, TonB and Fur and is glucose-repressed; tolerance may result from Na+ efflux catalysed by the NhaA antiporter, which is induced at pH0 9.0. Alkali sensitivity induced at pH0 5.5 also requires gyrase, IHF and CysB, but H-NS, Lrp, NhaA and OmpC are also needed and induction is abolished by NaCl. Salt-induced acid sensitivity results from PhoE formation and is blocked by glucose (reversed by cAMP), FeCl3 and hns and relA lesions, the effect of relA being envZ-suppressed. Acid sensitivity induction (ASI) at pH0 9.0 needs H-NS, is inhibited by FeCl3 and amiloride, and is associated with alkyl hydroperoxide reductase synthesis. Leucine-induced acid sensitivity needs gyrase, CysB, H-NS, Fur, OmpA and RelA, is inhibited by Fe3+, Fe2+, tetracycline, glucose and nalidixic acid, but not by chloramphenicol; increased outer membrane proton passage may result from OmpA modification.
...
PMID:Regulatory components, including integration host factor, CysB and H-NS, that influence pH responses in Escherichia coli. 917 36
The nucleotide sequence has been determined for a twelve-gene operon of Escherichia coli designated the hyf operon (hyfABCDEFGHIR-focB). The hyf operon is located at 55.8-56.0 min and encodes a putative nine-subunit hydrogenase complex (hydrogenase four or Hyf), a potential formate- and sigma 54-dependent
transcriptional activator
, HyfR (related to FhlA), and a possible formate transporter, FocB (related to FocA). Five of the nine Hyf-complex subunits are related to subunits of both the E. coli hydrogenase-3 complex (Hyc) and the proton-translocating NADH:quinone oxidoreductases (complex I and Nuo), whereas two Hyf subunits are related solely to NADH:quinone oxidoreductase subunits. The Hyf components include a predicted 523 residue [Ni-Fe] hydrogenase (large subunit) with an N-terminus (residues 1-170) homologous to the 30 kDa or NuoC subunit of complex I. It is proposed that Hyf, in conjunction with
formate dehydrogenase
H (Fdh-H), forms a hitherto unrecognized respiration-linked proton-translocating
formate hydrogenlyase
(FHL-2). It is likely that HyfR acts as a formate-dependent regulator of the hyf operon and that FocB provides the Hyf complex with external formate as substrate.
...
PMID:A 12-cistron Escherichia coli operon (hyf) encoding a putative proton-translocating formate hydrogenlyase system. 938 41
In Escherichia coli, ModE-molybdate, a repressor of modABCD operon (molybdate transport), was previously shown to be an additional
transcriptional activator
of hyc operon (
formate hydrogenlyase
) and narGHJI operon (respiratory nitrate reductase). However, in a modE mutant, both operons were expressed at about 50% of the wild-type level in a molybdate-dependent manner. This ModE-independent, molybdate-dependent, expression of hyc, narG and narK operons required MoeA protein. An E. coli modE, moeA double mutant failed to produce
formate hydrogenlyase
or respiratory nitrate reductase activity irrespective of the growth medium. Tungstate substituted for molybdate in the activation of transcription of hyc and nar operons by ModE could not replace molybdate for MoeA-dependent expression. It is proposed that the MoeA-catalyzed product, an activated form of molybdate, interacts with a
transcriptional activator
/regulator other than ModE and regulates hyc and nar operons.
...
PMID:Molybdate-dependent transcription of hyc and nar operons of Escherichia coli requires MoeA protein and ModE-molybdate. 985 Oct 41
Escherichia coli growing under anaerobic conditions produces several molybdoenzymes, such as
formate hydrogenlyase
(formate to H2 and CO2; hyc and fdhF genes) and nitrate reductase (narGHJI genes). Synthesis of these molybdoenzymes, even in the presence of the cognate transcriptional activators and effectors, requires molybdate in the medium. Besides the need for molybdopterin cofactor synthesis, molybdate is also required for transcription of the genes encoding these molybdoenzymes. In E. coli, ModE was previously identified as a repressor controlling transcription of the operon encoding molybdate transport components (modABCD). In this work, the ModE protein was also found to be a required component in the activation of hyc-lacZ to an optimum level, but only in the presence of molybdate. Mutant ModE proteins which are molybdate-independent for repression of modA-lacZ also restored hyc-lacZ expression to the wild-type level even in the absence of molybdate. Nitrate-dependent enhancement of transcription of narX-lacZ was completely abolished in a modE mutant. Nitrate-response by narG-lacZ and narK-lacZ was reduced by about 50% in a modE mutant. DNase I footprinting experiments revealed that the ModE protein binds the hyc promoter DNA in the presence of molybdate. ModE-molybdate also protected DNA in the intergenic region between narXL and narK from DNase I hydrolysis. DNA sequences (5' TAYAT 3' and 5' GTTA 3') found in ModE-molybdate-protected modABCD operator DNA were also found in the ModE-molybdate-protected region of hyc promoter DNA (5' GTTA-7 bp-CATAT 3') and narX-narK intergenic region (5' GTTA-7 bp-TACAT 3'). Based on these results, a working model is proposed in which ModE-molybdate serves as a secondary
transcriptional activator
of both the hyc and narXL operons which are activated primarily by the transcriptional activators, FhlA and NarL, respectively.
...
PMID:Transcriptional regulation of molybdoenzyme synthesis in Escherichia coli in response to molybdenum: ModE-molybdate, a repressor of the modABCD (molybdate transport) operon is a secondary transcriptional activator for the hyc and nar operons. 1020 9
The transcriptional regulator gene fdsR was identified 150 bp upstream of the divergently oriented fdsGBACD operon encoding the soluble,
NAD+-linked formate dehydrogenase
in the chemoautotrophic bacterium Ralstonia eutropha H16. Its deduced product, FdsR, displays a basal sequence similarity to the regulatory proteins of the LysR family. The carboxy-terminal domain of FdsR contains a short region that is conserved in formate dehydrogenases. Deletion of fdsR revealed a dual regulatory effect of FdsR on the fds operon by acting as
transcriptional activator
in the presence of formate or as repressor in the absence of formate. Studies with fdsR transcriptional fusions also suggested a negative autoregulation of the gene. A promoter structure resembling sigma70-dependent promoters from Escherichia coli was identified upstream of the fdsR transcriptional start site. FdsR purified to homogeneity after overexpression of fdsR in E. coli is a 130 kDa homotetramer binding to the fds control region located between the fdsR and fdsG genes. Formate significantly increased the binding affinity of FdsR for this region. Two FdsR binding sites characterized by the inverted-repeat structure ATANG-N10-CNTAT were identified. The regulatory pattern found in R. eutropha was also observed in the heterologous host E. coli and results from a novel mode of control of
formate dehydrogenase
genes.
...
PMID:Dual control by regulatory gene fdsR of the fds operon encoding the NAD+-linked formate dehydrogenase of Ralstonia eutropha. 1056 79
The
formate hydrogenlyase
complex of Escherichia coli catalyses the cleavage of formate to CO2 and H2 and consists of a molybdoenzyme
formate dehydrogenase
-H, hydrogenase 3 and intermediate electron carriers. The structural genes of this enzyme complex are activated by the FhlA protein in the presence of both formate and molybdate; ModE-Mo serves as a secondary activator. Mutational analysis of the FhlA protein established that the unique N-terminal region of this protein was responsible for formate- and molybdenum-dependent transcriptional control of the hyc operon. Analysis of the N-terminal sequence of the FhlA protein revealed a unique motif (amino acids 7-37), which is also found in ATPases associated with several members of the ABC-type transporter family. A deletion derivative of FhlA lacking these amino acids (FhlA9-2) failed to activate the hyc operon in vivo, although the FhlA9-2 did bind to hyc promoter DNA in vitro. The ATPase activity of the FhlA9-2-DNA-formate complex was at least three times higher than that of the native protein-DNA-formate complex, and this degree of activity was achieved at a lower formate level. Extending the deletion to amino acid 117 (FhlA167) not only reversed the FhlA(-) phenotype of FhlA9-2, but also led to both molybdenum- and formate-independence. Deleting the entire N-terminal domain (between amino acids 5 and 374 of the 692 amino acid protein) also led to an effector-independent
transcriptional activator
(FhlA165), which had a twofold higher level of hyc operon expression than the native protein. Both FhlA165 and FhlA167 still required ModE-Mo as a secondary activator for an optimal level of hyc-lac expression. The FhlA165 protein also had a twofold higher affinity to hyc promoter DNA than the native FhlA protein, while the FhlA167 protein had a significantly lower affinity for hyc promoter DNA in vitro. Although the ATPase activity of the native protein was increased by formate, the ATPase activity of neither FhlA165 or FhlA167 responded to formate. Removal of the first 117 amino acids of the FhlA protein appears to result in a constitutive, effector-independent activation of transcription of the genes encoding the components of the
formate hydrogenlyase
complex. The sequence similarity to ABC-ATPases, combined with the properties of the FhlA deletion proteins, led to the proposal that the N-terminal region of the native FhlA protein interacts with formate transport proteins, both as a formate transport facilitator and as a cytoplasmic acceptor.
...
PMID:N-terminal truncations in the FhlA protein result in formate- and MoeA-independent expression of the hyc (formate hydrogenlyase) operon of Escherichia coli. 1170 Mar 59
The hyf locus (hyfABCDEFGHIJ-hyfR-focB) of Escherichia coli encodes a putative 10-subunit hydrogenase complex (hydrogenase-4 [Hyf]); a potential sigma(54)-dependent
transcriptional activator
, HyfR (related to FhlA); and a putative formate transporter, FocB (related to FocA). In order to gain insight into the physiological role of the Hyf system, we investigated hyf expression by using a hyfA-lacZ transcriptional fusion. This work revealed that hyf is induced under fermentative conditions by formate at a low pH and in an FhlA-dependent fashion. Expression was sigma(54) dependent and was inhibited by HycA, the negative transcriptional regulator of the formate regulon. Thus, hyf expression resembles that of the hyc operon. Primer extension analysis identified a transcriptional start site 30 bp upstream of the hyfA structural gene, with appropriately located -24 and -12 boxes indicative of a sigma(54)-dependent promoter. No reverse transcriptase PCR product could be detected for hyfJ-hyfR, suggesting that hyfR-focB may be independently transcribed from the rest of the hyf operon. Expression of hyf was strongly induced ( approximately 1,000-fold) in the presence of a multicopy plasmid expressing hyfR from a heterologous promoter. This induction was dependent on low pH, anaerobiosis, and postexponential growth and was weakly enhanced by formate. The hyfR-expressing plasmid increased fdhF-lacZ transcription just twofold but did not influence the expression of hycB-lacZ. Interestingly, inactivation of the chromosomal hyfR gene had no effect on hyfA-lacZ expression. Purified HyfR was found to specifically interact with the hyf promoter/operator region. Inactivation of the hyf operon had no discernible effect on growth under the range of conditions tested. No Hyf-derived hydrogenase or
formate dehydrogenase
activity could be detected, and no Ni-containing protein corresponding to HyfG was observed.
...
PMID:Regulation of the hydrogenase-4 operon of Escherichia coli by the sigma(54)-dependent transcriptional activators FhlA and HyfR. 1242 53
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