The three-dimensional structure of 6-phospho-beta-galactosidase from Lactococcus lactis.

BACKGROUND: The enzyme 6-phospho-beta-galactosidase hydrolyzes phospholactose, the product of a phosphor-enolpyruvate-dependent phosphotransferase system. It belongs to glycosidase family 1 and no structure has yet been published for a member of this family. RESULTS: The crystal structure of 6-phospho-beta-galactosidase was determined at 2.3 A resolution by multiple isomorphous replacement, using the wild-type enzyme and a designed cysteine mutant. A second crystal form, found with the mutant enzyme, was solved by molecular replacement, yielding the conformation of two chain loops that are invisible in the first crystal form. The active center, located through catalytic residues identified in previous studies, cannot be accessed by the substrate if the two loops are in their defined conformation. The enzyme contains a (beta alpha)8 barrel and the relationship of its chain fold to that of other glycosidases has been quantified. As a side issue, we observed that a cysteine point mutant designed for X-ray analysis crystallized mainly as a symmetric dimer around an intermolecular disulfide bridge formed by the newly introduced cysteine. CONCLUSIONS: The presented analysis provides a basis on which to model all other family 1 members and thereby will help in elucidating the catalytic mechanisms of these sequence-related enzymes. Moreover, this enzyme belongs to a superfamily of glycosidases sharing a (beta alpha)8 barrel with catalytic glutamates/aspartates at the ends of the fourth and the seventh strands of the beta barrel.

The structure of enzyme IIAlactose from Lactococcus lactis reveals a new fold and points to possible interactions of a multicomponent system.

BACKGROUND: The bacterial phosphoenolpyruvate: sugar phosphotransferase system (PTS) is responsible for the binding, transmembrane transport and phosphorylation of numerous sugar substrates. The system is also involved in the regulation of a variety of metabolic and transcriptional processes. The PTS consists of two non-specific energy coupling components, enzyme I and a heat stable phosphocarrier protein (HPr), as well as several sugar-specific multiprotein permeases known as enzymes II. In most cases, enzymes IIA and IIB are located in the cytoplasm, while enzyme IIC acts as a membrane channel. Enzyme IIAlactose belongs to the lactose/cellobiose-specific family of enzymes II, one of four functionally and structurally distinct groups. The protein, which normally functions as a trimer, is believed to separate into its subunits after phosphorylation. RESULTS: The crystal structure of the trimeric enzyme IIAlactose from Lactococcus lactis has been determined at 2.3 A resolution. The subunits of the enzyme, related to each other by the inherent threefold rotational symmetry, possess interesting structural features such as coiled-coil-like packing and a methionine cluster. The subunits each comprise three helices (I, II and III) and pack against each other forming a nine-helix bundle. This helical bundle is stabilized by a centrally located metal ion and also encloses a hydrophobic cavity. The three phosphorylation sites (His78 on each monomer) are located in helices III and their sidechains protrude into a large groove between helices I and II of the neighbouring subunits. A model of the complex between phosphorylated HPr and enzyme IIAlactose has been constructed. CONCLUSIONS: Enzyme IIAlactose is the first representative of the family of lactose/cellobiose-specific enzymes IIA for which a three-dimensional structure has been determined. Some of its structural features, like the presence of two histidine residues at the active site, seem to be common to all enzymes no overall structural homology is observed to any PTS proteins or to any other proteins in the Protein Data Bank. Enzyme IIAlactose shows surface complementarity to the phosphorylated form of HPr and several energetically favourable interactions between the two molecules can be predicted.

Structure and function of proteins of the phosphotransferase system and of 6-phospho-beta-glycosidases in gram-positive bacteria.

New information about the proteins of the phosphotransferase system (PTS) and of phosphoglycosidases of homofermentative lactic acid bacteria and related species is presented. Tertiary structures were elucidated from soluble PTS components. They help to understand regulatory processes and PTS function in lactic acid bacteria. A tertiary structure of a membrane-bound enzyme II is still not available, but expression of Gram-positive genes encoding enzymes II can be achieved in Escherichia coli and enables the development of effective isolation procedures which are necessary for crystallization experiments. Considerable progress was made in analysing the functions of structural genes which are in close vicinity of the genes encoding the sugar-specific PTS components, such as the genes encoding the tagatose-6-P pathway and the 6-phospho-beta-glycosidases. These phosphoglycosidases belong to a subfamily of the beta-glycosidase family I among about 300 different glycosidases. The active site nucleophile was recently identified to be Glu 358 in Agrobacterium beta-glucosidase. This corresponds to Glu 375 in staphylococcal and lactococcal 6-phospho-beta-galactosidase. This enzyme is inactivated by mutating Glu 375 to Gln. Diffracting crystals of the lactococcal 6-P-beta-galactosidase allow the elucidation of its tertiary structure which helps to derive the structures for the entire glycosidase family 1. In addition, a fusion protein with 6-phospho-beta-galactosidase and staphylococcal protein A was constructed.

Crystal structures and mechanism of 6-phospho-beta-galactosidase from Lactococcus lactis.

The initial structural model of 6-phospho-beta-galactosidase from Lactococcus lactis was refined to an R-factor of 16.4% (R[free] = 23.6%) to 2.3 A resolution (1 A = 0.1 nm), and the structures of three other crystal forms were solved by molecular replacement. The four structural models are essentially identical. The catalytic center of the enzyme is approximately at the mass center of the molecule and can only be reached through a 20 A long channel, which is observed with an "open" or "closed" entrance. The closed entrance is probably too small for the educt lactose-6-phosphate to enter, but large enough for the first product glucose to leave. Among the presented structures is a complex between an almost inactive mutant and the second product galactose-6-phosphate, which is exclusively bound at side-chains. A superposition (onto the native enzyme) of galactose-6-phosphate as bound to the mutant suggests the geometry of a postulated covalent intermediate. The binding mode of the educt was modeled, starting from the bound galactose-6-phosphate. A tightly fixed tryptophan is used as a chopping-board for splitting the disaccharide, and several other aromatic residues in the active center cavity are likely to participate in substrate transport/binding.

The 1.6 A structure of histidine-containing phosphotransfer protein HPr from Streptococcus faecalis.

The histidine-containing phosphocarrier protein (HPr) is a central component of the phosphoenolpyruvate: sugar phosphotransferase system (PTS) that transports carbohydrates across the cell membrane of bacteria. The three-dimensional structure of Gram-positive Streptococcus faecalis HPr has been determined using the method of multiple isomorphous replacement. The R factor for all data is 0.156 for S. faecalis HPr at 1.6 A resolution with very good geometry. The overall folding topology of HPr is a classical open-faced beta-sandwich, consisting of four antiparallel beta-strands and three alpha-helices. Remarkable disallowed Ramachandran torsion angles of Ala16 at the active center, revealed by the X-ray structure of S. faecalis HPr, demonstrate a unique example of torsion-angle strain that is likely involved directly in protein function. A brief report concerning the torsion-angle strain has been presented recently. A newly-determined pH 7.0 structure is shown to have the same open conformation of the active center and the same torsion-angle strain at Ala16, suggesting that pH is not responsible for the structural observations. The current structure suggests a role for residues 12 and 51 in HPr's function, since they are involved in the active center through direct and indirect hydrogen-bonding interactions with the imidazole ring of His15. It is found that Ser46, the regulatory site in HPr from Gram-positive bacteria, N-caps the minor alpha-B helix and is also involved in the Asn43-Ser46 beta-turn. This finding, in conjunction with the proposed routes of communication between the regulatory site Ser46 and the active center in S. faecalis HPr, provides new insight into the understanding of how Ser46 might function. The putative involvement of the C-terminal alpha-carboxyl group and the related Gly67-Glu70 reverse beta-turn with respect to the function of HPr are described.

The 1.9 A resolution structure of phospho-serine 46 HPr from Enterococcus faecalis.

The histidine-containing phosphocarrier protein HPr is a central component of the phosphoenolpyruvate:sugar phosphotransferase system (PTS), which transfers metabolic carbohydrates across the cell membrane in many bacterial species. In Gram-positive bacteria, phosphorylation of HPr at conserved serine 46 (P-Ser-HPr) plays several regulatory roles within the cell; the major regulatory effect of P-Ser-HPr is its inability to act as a phosphocarrier substrate in the enzyme I reaction of the PTS. In order to investigate the structural nature of HPr regulation by phosphorylation at Ser46, the structure of the P-Ser-HPr from the Gram- positive bacterium Enterococcus faecalis has been determined. X-ray diffraction analysis of P-Ser-HPr crystals provided 10,043 unique reflections, with a 95.1 % completeness of data to 1.9 A resolution. The structure was solved using molecular replacement, with two P-Ser-HPr molecules present in the asymmetric unit. The final R-value and R(Free) are 0.178 and 0.239, respectively. The overall tertiary structure of P-Ser-HPr is that of other HPr structures. However the active site in both P-Ser-HPr molecules was found to be in the "open" conformation. Ala16 of both molecules were observed to be in a state of torsional strain, similar to that seen in the structure of the native HPr from E. faecalis. Regulatory phosphorylation at Ser46 does not induce large structural changes to the HPr molecule. The B-helix was observed to be slightly lengthened as a result of Ser46 phosphorylation. Also, the water mediated Met51-His15 interaction is maintained, again similar to that of the native E. faecalis HPr. The major structural, and thus regulatory, effect of phosphorylation at Ser46 is disruption of the hydrophobic interactions between EI and HPr, in particular the electrostatic repulsion between the phosphoryl group on Ser46 and Glu84 of EI and the prevention of a potential interaction of Met48 with a hydrophobic pocket of EI.

15N and 1H NMR study of histidine containing protein (HPr) from Staphylococcus carnosus at high pressure.

The pressure-induced changes in 15N enriched HPr from Staphylococcus carnosus were investigated by two-dimensional (2D) heteronuclear NMR spectroscopy at pressures ranging from atmospheric pressure up to 200 MPa. The NMR experiments allowed the simultaneous observation of the backbone and side-chain amide protons and nitrogens. Most of the resonances shift downfield with increasing pressure indicating generalized pressure-induced conformational changes. The average pressure-induced shifts for amide protons and nitrogens are 0.285 ppm GPa(-1) at 278 K and 2.20 ppm GPa(-1), respectively. At 298 K the corresponding values are 0.275 and 2.41 ppm GPa(-1). Proton and nitrogen pressure coefficients show a significant but rather small correlation (0.31) if determined for all amide resonances. When restricting the analysis to amide groups in the beta-pleated sheet, the correlation between these coefficients is with 0.59 significantly higher. As already described for other proteins, the amide proton pressure coefficients are strongly correlated to the corresponding hydrogen bond distances, and thus are indicators for the pressure-induced changes of the hydrogen bond lengths. The nitrogen shift changes appear to sense other physical phenomena such as changes of the local backbone conformation as well. Interpretation of the pressure-induced shifts in terms of structural changes in the HPr protein suggests the following picture: the four-stranded beta-pleated sheet of HPr protein is the least compressible part of the structure showing only small pressure effects. The two long helices a and c show intermediary effects that could be explained by a higher compressibility and a concomitant bending of the helices. The largest pressure coefficients are found in the active center region around His15 and in the regulatory helix b which includes the phosphorylation site Ser46 for the HPr kinase. This suggests that this part of the structure occurs in a number of different structural states whose equilibrium populations are shifted by pressure. In contrast to the surrounding residues of the active center loop that show large pressure effects, Ile14 has a very small proton and nitrogen pressure coefficient. It could represent some kind of anchoring point of the active center loop that holds it in the right place in space, whereas other parts of the loop adapt themselves to changing external conditions.

Cloning, sequencing and overexpression of the mannitol-specific enzyme-III-encoding gene of Staphylococcus carnosus.

The gene which encodes the mannitol-specific enzyme III (EIIImtl) of the phosphoenolpyruvate-dependent phosphotransferase system of Staphylococcus carnosus, has been cloned. Genomic libraries of S. carnosus DNA were constructed using the expression vector pUC19 and EIIImtl-producing clones were identified using rabbit polyclonal antiserum. A 700-bp Dde I fragment, containing the complete gene encoding EIIImtl, was sequenced by the dideoxy chain-termination technique. Upstream from the ORF for EIIImtl one can find a sequence analogous to that of the Escherichia coli promoter. This region acts as a strong promoter when subcloned into the promoter test vector M13HDL17. EIIImtl was overproduced using the inducible T7 polymerase system and purified to homogeneity. Amino acid sequence comparison confirmed a 38% similarity to the hydrophilic enzyme-III-like portion of enzyme IImtl of E. coli. There is also a 36% similarity to the N terminus of the fructose-specific phospho-carrier protein from E. coli.

Purification and characterisation of the restriction endonuclease ItaI from Ilyobacter tartaricus recognizing 5'-GC decreases NGC-3'.

ItaI, an isoschizomer of the subclass IIW [Kessler and Manta, Gene 92 (1990) 1-248] restriction endonuclease (ENase), Fnu4HI [Leung et al., Nucleic Acids Res. 6 (1979) 17-25], has been isolated from Ilyobacter tartaricus. The ENase has the five-base palindromic recognition sequence, 5'GC decreases NGC-3'. It cleaves behind the second nucleotide and produces a one-nt 5' overhang.

Solubilization of the membrane bound lactose specific component of the staphylococcal PEP dependant phosphotransferase system.

The membrane bound lactose specific component of the PEP dependant phosphotransferase system of Staphylococcus aureus has been solubilized using the non ionic detergent Triton X-100. Some properties of the crude soluble enzyme are reported.

Staphylococcal lactose phosphoenolpyruvate-dependent phosphotransferase system: site-specific mutagenesis on the lacE gene gives evidence that a cysteine residue is responsible for phosphorylation.

The lactose-specific phosphocarrier protein enzyme II of the bacterial phosphoenol-pyruvate-dependent phosphotransferase system of Staphylococcus aureus was modified by site-specific mutagenesis on the corresponding lacE gene in order to replace the histidine residues 245, 274 and 510 and the cysteine residue 476 of the amino acid sequence with a serine residue. The wild-type and mutant genes were expressed in Escherichia coli and the gene products were characterized in different in vitro test systems. In vitro phosphorylation studies on mutant derivatives of the lactose-specific enzyme II led to the conclusion that cysteine residue 476 is the active-site for phosphorylation of this enzyme II by a phospho-enzyme III of the same sugar specificity. A cysteine residue phosphorylated intermediate was first postulated for the mannitol-specific enzyme II of E. coli and studies performed independently concerning the lactose-specific enzyme II of Lactobacillus casei are in agreement with the above results.

Cloning and sequencing of two genes from Staphylococcus carnosus coding for glucose-specific PTS and their expression in Escherichia coli K-12.

Phosphoenolpyruvate (PEP)-dependent phosphorylation experiments have indicated that the gram-positive bacterium Staphylococcus carnosus possesses an EIICBA fusion protein specific for glucose. Here we report the cloning of a 7 kb genomic DNA fragment containing two genes, glcA and glcB, coding for the glucose-specific PTS transporters EII(Glc)1 and EII(Glc)2 which are 69% identical. The translation products derived from the nucleotide sequence consist of 675 and 692 amino acid residues and have calculated molecular weights of 73025 and 75256, respectively. Both genes can be stably maintained in Escherichia coli cells and restore the ability to ferment glucose to ptsG deletion mutants of E. coli. This demonstrates the ability of the PTS proteins HPr and/or EIIA(Glc) of a gram-negative organism (E. coli) to phosphorylate an EIICBA(Glc) from a gram-positive organism (S. carnosus).