The recently identified CprK branch of the CRP (cyclic AMP receptor protein)-FNR (fumarate and nitrate reduction regulator) family of transcriptional regulators includes proteins that activate the transcription of genes encoding proteins involved in reductive dehalogenation of chlorinated aromatic compounds. Here we report the characterization of the CprK1 protein from Desulfitobacterium hafniense, an anaerobic low-G؉C gram-positive bacterium that is capable of reductive dechlorination of 3-chloro-4-hydroxyphenylacetic acid (Cl-OHPA). The gene encoding CprK1 was cloned and functionally overexpressed in Escherichia coli, and the protein was subsequently purified to homogeneity. To investigate the interaction of CprK1 with three of its predicted binding sequences (dehaloboxes), we performed in vitro DNA-binding assays (electrophoretic mobility shift assays) as well as in vivo promoter probe assays. Our results show that CprK1 binds its target dehaloboxes with high affinity (dissociation constant, 90 nM) in the presence of Cl-OHPA and that transcriptional initiation by CprK1 is influenced by deviations in the dehaloboxes from the consensus TTAAT----ATTAA sequence. A mutant CprK1 protein was created by a Val3Glu substitution at a conserved position in the recognition ␣-helix that gained FNR-type DNA-binding specificity, recognizing the TTGAT----ATCAA sequence (FNR box) instead of the dehaloboxes. CprK1 was subject to oxidative inactivation in vitro, most likely caused by the formation of an intermolecular disulfide bridge between Cys11 and Cys200. The possibility of redox regulation of CprK1 by a thiol-disulfide exchange reaction was investigated by using two Cys3Ser mutants. Our results indicate that a Cys11-Cys200 disulfide bridge does not appear to play a physiological role in the regulation of CprK1.Transcriptional regulators of the CRP (cyclic AMP [cAMP] receptor protein)-FNR (fumarate and nitrate reduction regulator) family play an important role in modulating the expression of numerous metabolic genes in many facultatively or strictly anaerobic bacteria. These structurally related regulators evolved to enable an efficient response to a wide range of environmental signals in organisms that are often phylogenetically distinct. In Escherichia coli, CRP is a positive regulator of catabolite repression, directly sensing elevated cAMP levels caused by glucose starvation and activating the expression of genes involved in the utilization of alternative carbon sources (26). E. coli FNR senses the changes in redox state (e.g., the decreasing availability of oxygen) through a polynuclear ironsulfur center whose presence enhances DNA binding, resulting in transcriptional activation of genes involved in anaerobic respiration (38). Apart from these archetypes of the CRP-FNR superfamily, there are several members that use other effector molecules that can stimulate or repress the expression of metabolic genes by causing structural changes in the DNA-binding domain of the corresponding regulator (18,27). Binding of carbon ...
Halorespiration is a bacterial respiratory process in which haloorganic compounds act as terminal electron acceptors. This process is controlled at transcriptional level by CprK, a member of the ubiquitous CRP-FNR family. Here we present the crystal structures of oxidized CprK in presence of the ligand orthochlorophenolacetic acid and of reduced CprK in absence of this ligand. These structures reveal that highly specific binding of chlorinated, rather than the corresponding non-chlorinated, phenolic compounds in the NH 2 -terminal -barrels causes reorientation of these domains with respect to the central ␣-helix at the dimer interface. Unexpectedly, the COOH-terminal DNA-binding domains dimerize in the non-DNA binding state. We postulate the ligand-induced conformational change allows formation of interdomain contacts that disrupt the DNA domain dimer interface and leads to repositioning of the helixturn-helix motifs. These structures provide a structural framework for further studies on transcriptional control by CRP-FNR homologs in general and of halorespiration regulation by CprK in particular.Past and present industrial and agricultural activities have led to the ever increasing presence of haloorganic compounds such as chlorophenols and chlorinated ethenes in the environment (1). Due to both toxicity and recalcitrant nature, increasing amounts of these xenobiotics threaten the integrity of the environment and human health (2). In recent years, it has emerged that several haloorganic compounds are also naturally produced (3) and that several species of strictly anaerobic bacteria are able to conserve energy via the reductive dehalogenation of these compounds by respiratory metabolism (4, 5). In view of their favorable degrading capacities, e.g. high dehalogenation rate and low residual concentration of the contaminant, it has been anticipated that halorespiring microorganisms should be of utmost significance for efficient biological remediation of halogenated hydrocarbons in anoxic environments (6, 7). The versatile, strictly anaerobic Gram-positive bacterium Desulfitobacterium dehalogenans and the closely related Desulfitobacterium hafniense have the capacity of degrading ortho-chlorophenol. Both have been used as model organisms in halorespiration studies, representing one of the most significant groups of halorespiring isolates (8). In these organisms, proteins involved in halorespiration are encoded by the cpr (chlorophenol reductive dehalogenase) operon, of which multiple copies are present within the genome. This potentially allows for reductive dehalogenation of a wide range of haloorganic compounds by the use of a series of paralogous enzymes (9).The cpr operon is transcriptionally regulated by CprK, a member of the CRP-FNR family of regulators that is ubiquitous in bacteria (10). Recent in vivo and in vitro studies reveal that CprK binds 3-chloro-4-hydroxyphenylacetate (CHPA) 2 with micromolar affinity promoting a tight interaction with a specific DNA sequence in the promoter region of the cprencod...
SummaryCertain bacteria are able to conserve energy via the reductive dehalogenation of halo-organic compounds in a respiration-type metabolism. The transcriptional regulator CprK from Desulfitobacterium spp. induces expression of halorespiratory genes upon binding of o-chlorophenol ligands and is reversibly inactivated by oxygen through disulphide bond formation. We report crystal structures of D. hafniense CprK in the ligand-free (both oxidation states), ligand-bound (reduced) and DNA-bound states, making it the first member of the widespread CRP-FNR superfamily for which a complete structural description of both redox-dependent and allosteric molecular rearrangements is available. In conjunction with kinetic and thermodynamic ligand binding studies, we provide a model for the allosteric mechanisms underpinning transcriptional control. Amino acids that play a key role in this mechanism are not conserved in functionally distinct CRP-FNR members. This suggests that, despite significant structural homology, distinct allosteric mechanisms are used, enabling this protein family to control a very wide range of processes.
Clostridium acetobutylicum ATCC 824 is a solventogenic bacterium that grows heterotrophically on a variety of carbohydrates, including glucose, cellobiose, xylose, and lichenan, a linear polymer of -1,3-and -1,4-linked -D-glucose units. C. acetobutylicum does not degrade cellulose, although its genome sequence contains several cellulase-encoding genes and a complete cellulosome cluster of cellulosome genes. In the present study, we demonstrate that a low but significant level of induction of cellulase activity occurs during growth on xylose or lichenan. The celF gene, located in the cellulosome-like gene cluster and coding for a unique cellulase that belongs to glycoside hydrolase family 48, was cloned in Escherichia coli, and antibodies were raised against the overproduced CelF protein. A Western blot analysis suggested a possible catabolite repression by glucose or cellobiose and an up-regulation by lichenan or xylose of the extracellular production of CelF by C. acetobutylicum. Possible reasons for the apparent inability of C. acetobutylicum to degrade cellulose are discussed.
Gene duplication and horizontal gene transfer play an important role in the evolution of prokaryotic genomes. We have investigated the role of three CprK paralogues from the cAMP receptor protein-fumarate and nitrate reduction regulator (CRP-FNR) family of transcriptional regulators that are encoded in the genome of Desulfitobacterium hafniense DCB-2 and possibly regulate expression of genes involved in the energy-conserving terminal reduction of organohalides (halorespiration). The results from in vivo and in vitro promoter probe assays show that two regulators (CprK1 and CprK2) have an at least partially overlapping effector specificity, with preference for ortho-chlorophenols, while meta-chlorophenols proved to be effectors for CprK4.
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