Dimerization of Crh by reversible 3D domain swapping induces structural adjustments to its monomeric homologue Hpr

The crystal structure of the regulatory protein Crh from Bacillus subtilis was solved at 1.8A resolution and showed an intertwined dimer formed by N-terminal beta1-strand swapping of two monomers. Comparison with the monomeric NMR structure of Crh revealed a domain swap induced conformational rearrangement of the putative interaction site with the repressor CcpA. The resulting conformation closely resembles that observed for the monomeric Crh homologue HPr, indicating that the Crh dimer is the active form binding to CcpA. An analogous dimer of HPr can be constructed without domain swapping, suggesting that HPr may dimerize upon binding to CcpA. Our data suggest that reversible 3D domain swapping of Crh might be an efficient regulatory mechanism to modulate its activity.     

Evidence for a dimerisation state of the Bacillus subtilis catabolite repression HPr-like protein, Crh

The Bacillus subtilis catabolite repression HPr (Crh) exhibits 45% sequence identity when compared to histidine-containing protein (HPr), a phosphocarrier protein of the phosphoenolpyruvate:carbohydrate phosphotransferase system. We report here that Crh preparations contain a mixture of monomers and homodimers, whereas HPr is known to be monomeric in solution. The dissociation rate of dimers is very slow (t1/2 of about 10 hours), and the percentage of dimers in Crh preparations increases with rising temperature or protein concentration. However, at temperatures above 25 degrees C and a protein concentration of 10 mg/ml, Crh dimers slowly aggregate. Typically, NMR spectra recorded at 25 degrees C showed the coexistence of both forms of Crh, while in Crh solutions kept at 35 degrees C, almost exclusively Crh monomers could be detected. Circular dichroism analysis revealed that the monomeric and dimeric forms of Crh are well folded and exhibit the same overall structure. The physiological significance of the slow Crh monomer/dimer equilibrium remains enigmatic.     

trans-Acting factors and cis elements involved in glucose repression of arabinan degradation in Bacillus subtilis

In Bacillus subtilis, the synthesis of enzymes involved in the degradation of arabinose-containing polysaccharides is subject to carbon catabolite repression (CCR). Here we show that CcpA is the major regulator of repression of the arabinases genes in the presence of glucose. CcpA acts via binding to one cre each in the promoter regions of the abnA and xsa genes and to two cres in the araABDLMNPQ-abfA operon. The contributions of the coeffectors HPr and Crh to CCR differ according to growth phase. HPr dependency occurs during both exponential growth and the transitional phase, while Crh dependency is detected mainly at the transitional phase. Our results suggest that Crh synthesis may increase at the end of exponential growth and consequently contribute to this effect, together with other factors.     

Quantification of the influence of HPrSer46P on CcpA-cre interaction

Carbon catabolite repression (CCR) of the Bacillus megateriumxyl operon is dependent on the catabolite responsive element cre, the catabolite control protein (CcpA) and the histidine-containing phosphocarrier protein phosphorylated at the serine 46 residue (HPrSer46P). The latter is formed in the presence of glucose and mediates CCR via CcpA. We present evidence for the presence of HPrSer46P in a ternary complex with CcpA and cre. We also demonstrate increased stability of this complex compared to the CcpA-cre complex by electrophoretic mobility shift analysis (EMSA). This stabilization by HPrSer46P is the same for the xyl cre and an improved cre. Thus, HPrSer46P is a co-repressor for CcpA. In addition, surface plasmon resonance (SPR) experiments yielded binding constants of CcpA and the CcpA-HPrSer46P complex with cre. HPrSer46P stimulated CcpA binding to cre 50-fold. The binding constant is 4.9(+/- 0.5) x 10(6) M(-1). Non-phosphorylated HPr did not affect the complex formation between CcpA and cre. Previously proposed effects by glucose-6-phosphate, fructose-1,6-diphosphate and NADP on CcpA-cre or CcpA-HPrSer46P-cre formation were not found in EMSA and SPR experiments.     

Residues His-15 and Arg-17 of HPr participate differently in catabolite signal processing via CcpA

The carbon catabolite control protein A (CcpA) senses the physiological state of the cell by binding several effectors and responds with differential regulation of many genes in Bacilli. HPr-Ser46-P or Crh-Ser46-P interact with CcpA and stimulate binding to catabolite responsive elements. In addition, the glycolytic intermediates fructose 1,6-bisphosphate (FBP) and glucose 6-phosphate (Glc-6-P) stimulate HPr-Ser46-P but not Crh-Ser46-P binding to CcpA. The mechanisms by which coeffector binding to CcpA is linked to differential gene expression are unclear. To address this question we mutated residues participating in the interaction between HPr-Ser46-P or Crh-Ser46-P and CcpA and analyzed their effects on CcpA binding and stimulation of cre binding by surface plasmon resonance. The HPrH15A and CcpAD297A mutations do not affect complex formation but abolish FBP and Glc-6-P stimulation. Likewise, the CrhQ15H mutant becomes sensitive to these glycolytic intermediates. Hence, the contact of HPrHis-15 to Asp-297 in CcpA is a determinant for HPr specific FBP and Glc-6-P stimulation. The HPrR17A and -K mutants are both strongly impaired in stimulation of CcpA binding to cre, but only HPrR17A is defect in binding to CcpA indicating that these residues affect allostery of CcpA. Mutations of the residues of CcpA, which contact Arg-17 of HPr, exhibit differential effects on regulation of catabolic genes. Taken together, His-15 of HPr processes sensing information, while Arg-17 is involved in determining the genetic output.     

Insights into the functioning of Bacillus subtilis HPr kinase/phosphatase: affinity for its protein substrates and role of cations and phosphate

In Bacillus subtilis, carbon catabolite repression is mediated by the HPr kinase/phosphatase (HprK/P) which catalyzes both an ATP-dependent phosphorylation and a dephosphorylation on Ser-46 of either HPr (histidine-containing protein) or Crh (catabolite repression HPr). By using a surface plasmon resonance approach, it was shown here that the presence of magnesium is a prerequisite for the interaction of HprK/P with either HPr or Crh. HprK/P binds both protein substrates with a similar affinity (K(D) of about 40 nM), and addition of nucleotides increases by about 10-fold its affinity for each substrate. In addition, the specificity and the concentration of the cation required for the binding of protein substrates are different from that exhibited by the cation-binding site involved in the nucleotide binding, suggesting the presence of two cation-binding sites on HprK/P. The effects of phosphate on enzymatic activities of HprK/P were also investigated. Phosphate was able to unmask the phosphatase activity, especially in the presence of ATP or both ATP and fructose 1,6-bisphosphate whereas it was shown to inhibit the kinase activity of HprK/P. An apparent competition between phosphate and a fluorescent analogue of nucleotide led to the suggestion that phosphate mediates its effect by binding directly to the ATP-binding site of the enzyme.     

Catabolite regulation of the pta gene as part of carbon flow pathways in Bacillus subtilis

In Bacillus subtilis, the products of the pta and ackA genes, phosphotransacetylase and acetate kinase, play a crucial role in the production of acetate, one of the most abundant by-products of carbon metabolism in this gram-positive bacterium. Although these two enzymes are part of the same pathway, only mutants with inactivated ackA did not grow in the presence of glucose. Inactivation of pta had only a weak inhibitory effect on growth. In contrast to pta and ackA in Escherichia coli, the corresponding B. subtilis genes are not cotranscribed. Expression of the pta gene was increased in the presence of glucose, as has been reported for ackA. The effects of the predicted cis-acting catabolite response element (CRE) located upstream from the promoter and of the trans-acting proteins CcpA, HPr, Crh, and HPr kinase on the catabolite regulation of pta were investigated. As for ackA, glucose activation was abolished in ccpA and hprK mutants and in the ptsH1 crh double mutant. Footprinting experiments demonstrated an interaction between CcpA and the pta CRE sequence, which is almost identical to the proposed CRE consensus sequence. This interaction occurs only in the presence of Ser-46-phosphorylated HPr (HPrSer-P) or Ser-46-phosphorylated Crh (CrhSer-P) and fructose-1,6-bisphosphate (FBP). In addition to CcpA, carbon catabolite activation of the pta gene therefore requires at least two other cofactors, FBP and either HPr or Crh, phosphorylated at Ser-46 by the ATP-dependent Hpr kinase.     

The HPr proteins from the thermophile Bacillus stearothermophilus can form domain-swapped dimers

The study of proteins from extremophilic organisms continues to generate interest in the field of protein folding because paradigms explaining the enhanced stability of these proteins still elude us and such studies have the potential to further our knowledge of the forces stabilizing proteins. We have undertaken such a study with our model protein HPr from a mesophile, Bacillus subtilis, and a thermophile, Bacillus stearothermophilus. We report here the high-resolution structures of the wild-type HPr protein from the thermophile and a variant, F29W. The variant proved to crystallize in two forms: a monomeric form with a structure very similar to the wild-type protein as well as a domain-swapped dimer. Interestingly, the structure of the domain-swapped dimer for HPr is very different from that observed for a homologous protein, Crh, from B.subtilis. The existence of a domain-swapped dimer has implications for amyloid formation and is consistent with recent results showing that the HPr proteins can form amyloid fibrils. We also characterized the conformational stability of the thermophilic HPr proteins using thermal and solvent denaturation methods and have used the high-resolution structures in an attempt to explain the differences in stability between the different HPr proteins. Finally, we present a detailed analysis of the solution properties of the HPr proteins using a variety of biochemical and biophysical methods.     

Control of the glycolytic gapA operon by the catabolite control protein A in Bacillus subtilis: a novel mechanism of CcpA-mediated regulation

Glycolysis is one of the main pathways of carbon catabolism in Bacillus subtilis. Expression of the gapA gene encoding glyceraldehyde-3-phosphate dehydrogenase, the key enzyme of glycolysis from an energetic point of view, is induced by glucose and other sugars. Two regulators are involved in induction of the gapA operon, the product of the first gene of the operon, the CggR repressor, and catabolite control protein A (CcpA). CcpA is required for induction of the gapA operon by glucose. Genetic evidence has demonstrated that CcpA does not control the expression of the gapA operon by binding directly to a target in the promoter region. Here, we demonstrate by physiological analysis of the inducer spectrum that CcpA is required only for induction by sugars transported by the phosphotransferase system (PTS). A functional CcpA is needed for efficient transport of these sugars. This interference of CcpA with PTS sugar transport results from an altered phosphorylation pattern of HPr, a phosphotransferase of the PTS. In a ccpA mutant strain, HPr is nearly completely phosphorylated on a regulatory site, Ser-46, and is trapped in this state, resulting in its inactivity in PTS phosphotransfer. A mutation in HPr affecting the regulatory phosphorylation site suppresses both the defect in PTS sugar transport and the induction of the gapA operon. We conclude that a low-molecular effector derived from glucose that acts as an inducer for the repressor CggR is limiting in the ccpA mutant.     

A Crh-specific function in carbon catabolite repression in Bacillus subtilis

Carbon catabolite repression in Bacillus subtilis is mediated by phosphorylation of the phosphoenolpyruvate:carbohydrate phosphotransferase system intermediate HPr at a serine residue catalyzed by HPr kinase. The orthologous protein Crh functions in a similar way, but, unlike HPr, it is not functional in carbohydrate uptake. A specific function for Crh is not known. The role of HPr and Crh in repressing the citM gene encoding the Mg(2+)-citrate transporter was investigated during growth of B. subtilis on different carbon sources. In glucose minimal medium, full repression was supported by both HPr and Crh. Strains deficient in Crh or the regulatory function of HPr revealed the same repression as the wild-type strain. In contrast, in a medium containing succinate and glutamate, repression was specifically mediated via Crh. Repression was relieved in the Crh-deficient strain, but still present in the HPr mutant strain. The data are the first demonstration of a Crh-specific function in B. subtilis and suggest a role for Crh in regulation of expression during growth on substrates other than carbohydrates.     

Comparison of backbone dynamics of monomeric and domain-swapped stefin A

Three-dimensional domain swapping has been observed in increasing number of proteins and has been implicated in the initial stages of protein aggregation, including that of the cystatins. Stefin A folds as a monomer under native conditions, while under some denaturing conditions domain-swapped dimer is formed. We have determined the backbone dynamics of the monomeric and domain-swapped dimeric forms of stefin A by (15)N relaxation using a model-free approach. The overall correlation times of the molecules were determined to be 4.6 +/- 0.1 ns and 9.2 +/- 0.2 ns for the monomer and the dimer, respectively. In the monomer, decreased order parameters indicate an increased mobility for the N-terminal trunk, the first and the second binding loops. At the opposite side of the molecule, the loop connecting the alpha-helix with strand B, the beginning of strand B and the loop connecting strands C and D show increased localized mobility. In the domain-swapped dimer, a distinctive feature of the structure is the concatenation of strands B and C into a single long beta-strand. The newly formed linker region between strands B and C, which substitutes for the first binding loop in the monomer, has order parameters typical for the remainder of the beta-strands. Thus, the interaction between subunits that occurs on domain-swapping has consequences for the dynamics of the protein at long-range from the site of conformational change, where an increased rigidity in the newly formed linker region is accompanied by an increased mobility of loops remote from that site.     

Antitermination by GlpP, catabolite repression via CcpA and inducer exclusion triggered by P-GlpK dephosphorylation control Bacillus subtilis glpFK expression

The Bacillus subtilis glpFK operon encoding the glycerol transport facilitator (GlpF) and glycerol kinase (GlpK) is induced by glycerol-3-P and repressed by rapidly metabolizable sugars. Carbon catabolite repression (CCR) of glpFK is partly mediated via a catabolite response element cre preceding glpFK. This operator site is recognized by the catabolite control protein A (CcpA) in complex with one of its co-repressors, P-Ser-HPr or P-Ser-Crh. HPr is a component of the phosphoenolpyruvate:sugar phosphotransferase system (PTS), and Crh is an HPr homologue. The hprK-encoded HPr kinase phosphorylates HPr and Crh at Ser-46. But in neither ccpA nor hprK mutants was expression of a glpF'-lacZ fusion relieved from CCR, as a second, CcpA-independent CCR mechanism implying the terminator tglpFK, whose formation is prevented by the glycerol-3-P-activated antiterminator GlpP, is operative. Deletion of tglpFK led to elevated expression of the glpF'-lacZ fusion and to partial relief from CCR. CCR completely disappeared in DeltatglpFK mutants carrying a disruption of ccpA or hprK. The tglpFK-requiring CCR mechanism seems to be based on insufficient synthesis of glycerol-3-P, as CCR of glpFK was absent in ccpA mutants growing on glycerol-3-P or synthesizing H230R mutant GlpK. In cells growing on glycerol, glucose prevents the phosphorylation of GlpK by P-His-HPr. P-GlpK is much more active than GlpK, and the absence of P~GlpK formation in DeltaptsHI strains prevents glycerol metabolism. As a consequence, only small amounts of glycerol-3-P will be formed in glycerol and glucose-exposed cells (inducer exclusion). The uptake of glycerol-3-P via GlpT provides high concentrations of this metabolite in the ccpA mutant and allows the expression of the glpF'-lacZ fusion even when glucose is present. Similarly, despite the presence of glucose, large amounts of glycerol-3-P are formed in a glycerol-exposed strain synthesizing GlpKH230R, as this mutant GlpK is as active as P-GlpK.