Phosphorylation on histidine is accompanied by localized structural changes in the phosphocarrier protein, HPr from Bacillus subtilis.

The histidine-containing protein (HPr) of bacterial phosphoenolpyruvate:sugar phosphotransferase system (PTS) serves a central role in a series of phosphotransfer reactions used for the translocation of sugars across cell membranes. These studies report the high-definition solution structures of both the unphosphorylated and histidine phosphorylated (P-His) forms of HPr from Bacillus subtilis. Consistent with previous NMR studies, local conformational adjustments occur upon phosphorylation of His 15, which positions the phosphate group to serve as a hydrogen bond acceptor for the amide protons of Ala 16 and Arg 17 and to interact favorably with the alpha-helix macrodipole. However, the positively charged side chain of the highly conserved Arg 17 does not appear to interact directly with phospho-His 15, suggesting that Arg 17 plays a role in the recognition of other PTS enzymes or in phosphotransfer reactions directly. Unlike the results reported for Escherichia coli P-His HPr (Van Nuland NA, Boelens R, Scheek RM, Robillard GT, 1995, J Mol Biol 246:180-193), our data indicate that phosphorylation of His 15 is not accompanied by adoption of unfavorable backbone conformations for active site residues in B. subtilis P-Ser HPr.     

Metabolite-sensitive, ATP-dependent, protein kinase-catalyzed phosphorylation of HPr, a phosphocarrier protein of the phosphotransferase system in gram-positive bacteria

In this review article we summarize the recent information available concerning important mechanistic and physiological aspects of the protein kinase-mediated phosphorylation of seryl residue-46 in HPr, a phosphocarrier protein of the phosphoenolpyruvate: sugar phosphotransferase system in Gram-positive bacteria. Emphasis is placed upon the information recently obtained in two laboratories through the use of site-specific mutants of the HPr protein. The results show that (i) in contrast to eukaryotic protein kinases, the HPr(ser) kinase recognizes the tertiary structure of HPr rather than a restricted part of the primary sequence of the protein; (ii) like seryl protein kinases of eukaryotes, the HPr(ser) kinase can phosphorylate a threonyl residue, but not a tyrosyl residue when such a residue replaces the regulatory seryl residue in position-46 of the protein; (iii) the regulatory consequences of seryl phosphorylation are due to the introduction of a negative charge at position-46 in the protein rather than the bulky phosphate group; and (iv) PTS protein-HPr interactions influence the conformation of HPr, thereby retarding or stimulating the rate of kinase-catalyzed seryl-46 phosphorylation. The physiological consequences of HPr(ser) phosphorylation in vivo are still a matter of debate.     

Crh, the paralogue of the phosphocarrier protein HPr, controls the methylglyoxal bypass of glycolysis in Bacillus subtilis

The histidine protein HPr has a key role in regulation of carbohydrate utilization in low-GC Gram-positive bacteria. Bacilli possess the paralogue Crh. Like HPr, Crh becomes phosphorylated by kinase HPrK/P in response to high fructose-1,6-bisphosphate concentrations. However, Crh can only partially substitute for the regulatory functions of HPr leaving its role mysterious. Using protein co-purification, we identified enzyme methylglyoxal synthase MgsA as interaction partner of Crh in Bacillus subtilis. MgsA converts dihydroxyacetone-phosphate to methylglyoxal and thereby initiates a glycolytic bypass that prevents the deleterious accumulation of phospho-sugars under carbon overflow conditions. However, methylgyloxal is toxic and its production requires control. We show here that exclusively the non-phosphorylated form of Crh interacts with MgsA in vivo and inhibits MgsA activity in vitro. Accordingly, Crh inhibits methylglyoxal formation in vivo under nutritional famine conditions that favour a low HPr kinase activity. Thus, Crh senses the metabolic state of the cell, as reflected by its phosphorylation state, and accordingly controls flux through the harmful methylglyoxal pathway. Interestingly, HPr is unable to bind and regulate MgsA, making this a bona fide function of Crh. Four residues that differ in the interaction surfaces of HPr and Crh may account for this difference.     

Crystallization of the Bacillus subtilis histidine-containing phosphocarrier protein HPr and of some of its site-directed mutants

The histidine-containing phosphocarrier protein (HPr) from Bacillus subtilis has been crystallized. Two of the site-directed mutants aimed at probing function produce crystals suitable for X-ray studies. The mutant in which His15 is substituted by an alanyl residue crystallizes from ammonium sulfate solution in space group P3(1)21 or P3(2)21, with unit cell dimensions: a = b = 47.3 A; c = 61.5 A. These crystals diffract to at least 1.8 A resolution. The mutant in which Ser46 is substituted by an aspartyl residue crystallizes from polyethylene glycol 4000 solution in space group P2(1), with unit cell dimensions: a = 49.4 A; b = 25.6 A; c = 60.3 A; beta = 109 degrees. These crystals diffract to at least 2.0 A resolution.     

The phosphotransferase system (PTS) of Streptomyces coelicolor identification and biochemical analysis of a histidine phosphocarrier protein HPr encoded by the gene ptsH.

HPr, the histidine-containing phosphocarrier protein of the bacterial phosphotransferase system (PTS) controls sugar uptake and carbon utilization in low-GC Gram-positive bacteria and in Gram-negative bacteria. We have purified HPr from Streptomyces coelicolor cell extracts. The N-terminal sequence matched the product of an S. coelicolor orf, designated ptsH, sequenced as part of the S. coelicolor genome sequencing project. The ptsH gene appears to form a monocistronic operon. Determination of the evolutionary relationship revealed that S. coelicolor HPr is equally distant to all known HPr and HPr-like proteins. The presumptive phosphorylation site around histidine 15 is perfectly conserved while a second possible phosphorylation site at serine 47 is not well-conserved. HPr was overproduced in Escherichia coli in its native form and as a histidine-tagged fusion protein. Histidine-tagged HPr was purified to homogeneity. HPr was phosphorylated by its own enzyme I (EI) and heterologously phosphorylated by EI of Bacillus subtilis and Staphylococcus aureus, respectively. This phosphoenolpyruvate-dependent phosphorylation was absent in an HPr mutant in which histidine 15 was replaced by alanine. Reconstitution of the fructose-specific PTS demonstrated that HPr could efficiently phosphorylate enzyme IIFructose. HPr-P could also phosphorylate enzyme IIGlucose of B. subtilis, enzyme IILactose of S. aureus, and IIAMannitol of E. coli. ATP-dependent phosphorylation was detected with HPr kinase/phosphatase of B. subtilis. These results present the first identification of a gene of the PTS complement of S. coelicolor, providing the basis to elucidate the role(s) of HPr and the PTS in this class of bacteria.     

High-resolution structure of the histidine-containing phosphocarrier protein (HPr) from Staphylococcus aureus and characterization of its interaction with the bifunctional HPr kinase/phosphorylase

A high-resolution structure of the histidine-containing phosphocarrier protein (HPr) from Staphylococcus aureus was obtained by heteronuclear multidimensional nuclear magnetic resonance (NMR) spectroscopy on the basis of 1,766 structural restraints. Twenty-three hydrogen bonds in HPr could be directly detected by polarization transfer from the amide nitrogen to the carbonyl carbon involved in the hydrogen bond. Differential line broadening was used to characterize the interaction of HPr with the HPr kinase/phosphorylase (HPrK/P) of Staphylococcus xylosus, which is responsible for phosphorylation-dephosphorylation of the hydroxyl group of the regulatory serine residue at position 46. The dissociation constant Kd was determined to be 0.10 +/- 0.02 mM at 303 K from the NMR data, assuming independent binding. The data are consistent with a stoichiometry of 1 HPr molecule per HPrK/P monomer in solution. Using transversal relaxation optimized spectroscopy-heteronuclear single quantum correlation, we mapped the interaction site of the two proteins in the 330-kDa complex. As expected, it covers the region around Ser46 and the small helix b following this residue. In addition, HPrK/P also binds to the second phosphorylation site of HPr at position 15. This interaction may be essential for the recognition of the phosphorylation state of His15 and the phosphorylation-dependent regulation of the kinase/phosphorylase activity. In accordance with this observation, the recently published X-ray structure of the HPr/HPrK core protein complex from Lactobacillus casei shows interactions with the two phosphorylation sites. However, the NMR data also suggest differences for the full-length protein from S. xylosus: there are no indications for an interaction with the residues preceding the regulatory Ser46 residue (Thr41 to Lys45) in the protein of S. xylosus. In contrast, it seems to interact with the C-terminal helix of HPr in solution, an interaction which is not observed for the complex of HPr with the core of HPrK/P of L. casei in crystals.     

Impact of phosphorylation on structure and thermodynamics of the interaction between the N-terminal domain of enzyme I and the histidine phosphocarrier protein of the bacterial phosphotransferase system

The structural and thermodynamic impact of phosphorylation on the interaction of the N-terminal domain of enzyme I (EIN) and the histidine phosphocarrier protein (HPr), the two common components of all branches of the bacterial phosphotransferase system, have been examined using NMR spectroscopy and isothermal titration calorimetry. His-189 is located at the interface of the alpha and alphabeta domains of EIN, resulting in rather widespread chemical shift perturbation upon phosphorylation, in contrast to the highly localized perturbations seen for HPr, where His-15 is fully exposed to solvent. Residual dipolar coupling measurements, however, demonstrate unambiguously that no significant changes in backbone conformation of either protein occur upon phosphorylation: for EIN, the relative orientation of the alpha and alphabeta domains remains unchanged; for HPr, the backbone /Psi torsion angles of the active site residues are unperturbed within experimental error. His --> Glu/Asp mutations of the active site histidines designed to mimic the phosphorylated states reveal binding equilibria that favor phosphoryl transfer from EIN to HPr. Although binding of phospho-EIN to phospho-HPr is reduced by a factor of approximately 21 relative to the unphosphorylated complex, residual dipolar coupling measurements reveal that the structures of the unphosphorylated and biphosphorylated complexes are the same. Hence, the phosphorylation states of EIN and HPr shift the binding equilibria predominantly by modulating intermolecular electrostatic interactions without altering either the backbone scaffold or binding interface. This facilitates highly efficient phosphoryl transfer between EIN and HPr, which is estimated to occur at a rate of approximately 850 s(-1) from exchange spectroscopy.     

The primary structure of Salmonella typhimurium HPr, a phosphocarrier protein of the phosphoenolpyruvate:glycose phosphotransferase system. A correction

The protein HPr is a low-molecular-weight phosphocarrier protein of the bacterial phosphoenolpyruvate:glycose phosphotransferase system. We have recently reported the complete primary amino acid sequence of HPr isolated from Salmonella typhimurium (Weigel, N., Powers, D.A., and Roseman, S. (1982) J. Biol. Chem. 257, 14499-14509). This sequence is incorrect at certain residues; the correct primary structure of the protein is presented in this report. The corrected structure generally agrees with the primary sequence predicted for HPr from Escherichia coli (based on the nucleotide sequence of the corresponding ptsH gene). The one apparent ambiguity is at the carboxyl terminus.     

An N-terminal three-helix fragment of the exchangeable insect apolipoprotein apolipophorin III conserves the lipid binding properties of wild-type protein

Apolipophorin III (apoLp-III) from the greater wax moth Galleria mellonella is an exchangeable insect apolipoprotein that consists of five amphipathic alpha-helices, sharing high sequence identity with apoLp-III from the sphinx moth Manduca sexta whose structure is available. To define the minimal requirement for apoLp-III structural stability and function, a C-terminal truncated apoLp-III encompassing residues 1-91 of this 163 amino acid protein was designed. Far-UV circular dichroism spectroscopy revealed apoLp-III(1-91) has 50% alpha-helix secondary structure content in buffer (wild-type apoLp-III 86%), increasing to essentially 100% upon interactions with dimyristoylphosphatidylcholine (DMPC). Guanidine hydrochloride denaturation studies revealed similar stability properties for wild-type apoLp-III and apoLp-III(1-91). Resistance to denaturation for both proteins increased substantially upon association with phospholipid. In the absence of lipid, wild-type apoLp-III was monomeric whereas apoLp-III(1-91) partly formed dimers and trimers. Discoidal apoLp-III(1-91)-DMPC complexes were smaller in diameter (13.5 nm) compared to wild-type apoLp-III (17.7 nm), and more molecules of apoLp-III(1-91) associated with the complexes. Lipid interaction revealed that apoLp-III(1-91) binds to modified spherical lipoprotein surfaces and efficiently transforms phospholipid vesicles into discoidal complexes. Thus, the first three helices of G. mellonella apoLp-III contain the basic features required for maintenance of the structural integrity of the entire protein.     

Stability and binding of the phosphorylated species of the N-terminal domain of enzyme I and the histidine phosphocarrier protein from the Streptomyces coelicolor phosphoenolpyruvate:sugar phosphotransferase system

The phosphotransferase system (PTS) is involved in the use of carbon sources in bacteria. It is formed by two general proteins: enzyme I (EI) and the histidine phosphocarrier (HPr), and various sugar-specific permeases. EI is formed by two domains, with the N-terminal domain (EIN) being responsible for the binding to HPr. In low-G+C Gram-positive bacteria, HPr becomes phosphorylated not only by phosphoenolpyruvate (PEP) at the active-site histidine, but also by ATP at a serine. In this work, we have characterized: (i) the stability and binding affinities between the active-site-histidine phosphorylated species of HPr and the EIN from Streptomyces coelicolor; and (ii) the stability and binding affinities of the species involving the phosphorylation at the regulatory serine of HPr(sc). Our results show that the phosphorylated active-site species of both proteins are less stable than the unphosphorylated counterparts. Conversely, the Hpr-S47D, which mimics phosphorylation at the regulatory serine, is more stable than wild-type HPr(sc) due to helical N-capping effects, as suggested by the modeled structure of the protein. Binding among the phosphorylated and unphosphorylated species is always entropically driven, but the affinity and the enthalpy vary widely.     

The role of phosphorylation of HPr,a phosphocarrier protein of the phosphotransferase system,in the regulation of carbon metabolism in gram-positive bacteria

HPr of the Gram-positive bacterial phosphotransferase system (PTS) can be phosphorylated by an ATP-dependent protein kinase on a serine residue or by PEP-dependent Enzyme I on a histidyl residue. Both phosphorylation events appear to influence the metabolism of non-PTS carbon sources. Catabolite repression of the gluconate (gnt) operon of B. subtilis appears to be regulated by the former phosphorylation event, while glycerol kinase appears to be regulated by the latter phosphorylation reaction. The extent of our understanding of these processes will be described. © 1993 Wiley-Liss, Inc.     

Properties of ATP-dependent protein kinase from Streptococcus pyogenes that phosphorylates a seryl residue in HPr, a phosphocarrier protein of the phosphotransferase system.

Transport of sugars across the cytoplasmic membranes of gram-positive bacteria appears to be regulated by the action of a metabolite-activated, ATP-dependent protein kinase that phosphorylates a seryl residue in the phosphocarrier protein of the phosphotransferase system, HPr. We have developed a quantitative assay for measuring the activity of this enzyme from Streptococcus pyogenes. The product of the in vitro protein kinase-catalyzed reaction was shown to be phosphoseryl-HPr by several independent criteria (rates of hydrolysis in the presence of various agents, detection of serine-phosphate in acid hydrolysates, immunological assay, and electrophoretic migration rates). HPrs isolated from four different gram-positive bacteria (S. pyogenes, Streptococcus faecalis, Staphylococcus aureus, and Bacillus subtilis) were shown to be phosphorylated by the kinase from S. pyogenes. In contrast, Escherichia coli HPr was not a substrate of this enzyme. The soluble kinase released from the particulate fraction of the cells with high salt in the presence of a protease inhibitor was shown to have an approximate molecular weight of 60,000 as estimated by gel filtration. Its activity was dependent on divalent cations, with Mg2+ and Mn2+ being most active. EDTA, Pi, and high concentrations of salt were strongly inhibitory. The enzyme was optimally active at pH 7.0, exhibited high affinity for its substrates, and was dependent on the presence of one of several metabolites. Of these compounds, fructose 1-6-diphosphate was most active, with gluconate 6-phosphate, 2-phosphoglycerate, 2,3-diphosphoglycerate, phosphoenolpyruvate, and pyruvate exhibiting moderate to low stimulatory activities. Other compounds tested, including a variety of sugar phosphates, pyridine nucleotides, and other metabolites were without effect. The ATP-dependent phosphorylation of HPr on the seryl residue was strongly inhibited by phosphoenolpyruvate-dependent phosphorylation of the active histidyl residue of this protein. Treatment of the kinase with diethyl pyrocarbonate strongly inhibited the ATP-dependent phosphorylation activity, although the sulfhydryl reagents N-ethylmaleimide, p-chloromercuribenzoate, and iodoacetate were without effect. These results serve to characterize the HPr (serine) kinase, which apparently regulates the rates of carbohydrate transport in streptococcal cells via the phosphotransferase system. A primary role of this kinase in the control of cellular inducer levels and carbohydrate metabolic rates is proposed.     

Structure and dynamics of the N-terminal half of hepatitis C virus core protein: An intrinsically unstructured protein

Hepatitis C virus core protein plays an important role in the assembly and packaging of the viral genome. We have studied the structure of the N-terminal half of the core protein (C82) which was shown to be sufficient for the formation of nucleocapsid-like particle (NLP) in vitro and in yeast. Structural bioinformatics analysis of C82 suggests that it is mostly unstructured. Circular dichroism and structural NMR data indicate that C82 lacks secondary structure. Moreover, NMR relaxation data shows that C82 is highly disordered. These results indicate that the N-terminal half of the HCV core protein belongs to the growing family of intrinsically unstructured proteins (IUP). This explains the tendency of the hepatitis C virus core protein to interact with several host proteins, a well-documented characteristic of IUPs.     

Di-phosphorylated BAF shows altered structural dynamics and binding to DNA,but interacts with its nuclear envelope partners

Barrier-to-autointegration factor (BAF), encoded by the BANF1 gene, is an abundant and ubiquitously expressed metazoan protein that has multiple functions during the cell cycle. Through its ability to cross-bridge two double-stranded DNA (dsDNA), it favours chromosome compaction, participates in post-mitotic nuclear envelope reassembly and is essential for the repair of large nuclear ruptures. BAF forms a ternary complex with the nuclear envelope proteins lamin A/C and emerin, and its interaction with lamin A/C is defective in patients with recessive accelerated aging syndromes. Phosphorylation of BAF by the vaccinia-related kinase 1 (VRK1) is a key regulator of BAF localization and function. Here, we demonstrate that VRK1 successively phosphorylates BAF on Ser4 and Thr3. The crystal structures of BAF before and after phosphorylation are extremely similar. However, in solution, the extensive flexibility of the N-terminal helix α1 and loop α1α2 in BAF is strongly reduced in di-phosphorylated BAF, due to interactions between the phosphorylated residues and the positively charged C-terminal helix α6. These regions are involved in DNA and lamin A/C binding. Consistently, phosphorylation causes a 5000-fold loss of affinity for dsDNA. However, it does not impair binding to lamin A/C Igfold domain and emerin nucleoplasmic region, which leaves open the question of the regulation of these interactions.     

The N-terminal domain of the Drosophila histone mRNA binding protein, SLBP, is intrinsically disordered with nascent helical structure

Stem-loop binding protein (SLBP) is a 31 kDa protein that is central to the regulation of histone mRNAs and is highly conserved in metazoans. In vertebrates, the N-terminal domain of SLBP has sequence determinants necessary for histone mRNA translation, SLBP degradation, cyclin binding, and histone mRNA import. We have used high-resolution NMR spectroscopy and circular dichroism to characterize the structural and dynamic features of this domain of SLBP from Drosophila (dSLBP). We report that the N-terminal domain of dSLBP is stably unfolded but has nascent helical structure at physiological pH and native-like solution conditions. The conformational and dynamic properties of the isolated domain are mimicked in a longer 175-residue region of the N-terminus, as well as in the full-length protein. Complete resonance assignments, secondary structure propensity, and motional properties of a 91-residue N-terminal domain (G17-K108) of dSLBP are reported here. The deviation of (1)H(alpha), (13)C(alpha), and (13)C(beta) chemical shifts from random coil reveals that there are four regions between residues I28-A45, S50-L57, S66-G75, and F91-N96 that have helical propensity. These regions also have small but positive heteronuclear NOEs, interresidue d(NN) NOEs, and small but significant protection from solvent exchange. However the lack of medium- and long-range NOEs in 3D (15)N- and (13)C-edited spectra, fast amide proton exchange rates (all greater than 1 s(-1)), and long (15)N relaxation (T(1), T(2)) times suggest that the domain from dSLBP does not adopt a well-defined tertiary fold. The backbone residual dipolar couplings (RDCs) for this domain are small and lie close to 0 Hz (+/-2 Hz) for most residues with no well-defined periodicity. The implications of this unfolded state for the function of dSLBP in regulating histone metabolism are discussed.     

An N-terminal, 830 residues intrinsically disordered region of the cytoskeleton-regulatory protein supervillin contains Myosin II- and F-actin-binding sites

Supervillin, the largest member of the villin/gelsolin family, is a cytoskeleton regulating, peripheral membrane protein. Supervillin increases cell motility and promotes invasive activity in tumors. Major cytoskeletal interactors, including filamentous actin and myosin II, bind within the unique supervillin amino terminus, amino acids 1–830. The structural features of this key region of the supervillin polypeptide are unknown. Here, we utilize circular dichroism and bioinformatics sequence analysis to demonstrate that the N-terminal part of supervillin forms an extended intrinsically disordered region (IDR). Our combined data indicate that the N-terminus of human and bovine supervillin sequences (positions 1–830) represents an IDR, which is the largest IDR known to date in the villin/gelsolin family. Moreover, this result suggests a potentially novel mechanism of regulation of myosin II and F-actin via the intrinsically disordered N-terminal region of hub protein supervillin.