Protein Arp and protein H from group A streptococci. Ig binding and dimerization are regulated by temperature.

Cell surface proteins that bind to the Fc part of Ig are expressed by many strains of group A streptococci, an important human pathogen. Two such bacterial strains, AP4 and AP1, were shown to bind IgA and IgG, respectively, in a temperature-dependent manner. The binding of radiolabeled Ig to the bacterial cells was lower at 37 degrees C than at 22 and 4 degrees C. Similarly, protein Arp, the IgA-binding protein isolated from strain AP4, and protein H, the IgG-binding protein isolated from strain AP1, displayed a strong Ig-binding at 22 degrees C and lower temperatures, and virtually no binding at all at 37 degrees C. The effect was reversible: lowering of the temperature restored the binding and vice versa. A gradual shift between binding and nonbinding took place between 27 and 37 degrees C. Gel chromatography and velocity sedimentation centrifugation showed that protein Arp and protein H appeared as noncovalently associated dimers at 10 and 22 degrees C, and as monomers at 37 degrees C. These results strongly suggest that the dimerization of protein Arp and protein H, rather than the low temperature itself, yielded the strong Ig-binding of the proteins at 10 and 22 degrees C. Indeed, after covalent cross-linking of the dimers at 10 degrees C by incubation with low concentrations of glutaraldehyde, full Ig-binding was achieved even at 37 degrees C. A carboxyl-terminal proteolytic fragment of protein Arp, which completely lacked the IgA-binding capacity at any temperature, showed the same temperature-dependent dimerization as intact protein Arp, suggesting that the Ig-binding part of the protein is not required for dimerization. The implications of these results for the function of Ig-binding group A streptococcal proteins, and their role in the host-parasite relationship are discussed.     

Receptor for IgA in group A streptococci: cloning of the gene and characterization of the protein expressed in Escherichia coli

The gene for an IgA-binding protein from a group A streptococcal strain was cloned and expressed in Escherichia coli. The IgA-binding protein, called protein Arp, was purified on IgA-Sepharose, allowing complete purification in a single step. Analysis of protein Arp by Western immunoblotting demonstrated a major IgA-binding band, with an apparent molecular weight of 42 kD. The purified protein was shown to bind serum IgA and secretory IgA, as well as monoclonal IgA of both subclasses. There was no binding to IgM, IgD or IgE, but a weak binding to IgG. Inhibition experiments with whole bacteria indicated that IgA and IgG bind at separate sites. Experiments with immunoglobulin fragments showed that protein Arp binds to the Fc region of both IgA and IgG. The equilibrium constant of the reaction between protein Arp and polyclonal human IgA was determined to be 5.6 x 10(8) M-1. Amino acid sequencing of protein Arp demonstrated a direct repeat of 7 amino acids in the NH2-terminal region, a feature previously found in several streptococcal M proteins. This suggests that protein Arp, like M proteins, may be a streptococcal virulence factor.     

Extensive sequence homology between IgA receptor and M proteins in Streptococcus pyogenes

Many strains of Streptococcus pyogenes are known to express a receptor for IgA. The complete nucleotide sequence of the gene for such a receptor, protein Arp4, has been determined. The deduced amino acid sequence of 386 residues includes a signal sequence of 41 amino acids and a putative membrane anchor region, both of which are homologous to similar regions in other streptococcal surface proteins. The processed form of the IgA receptor has a length of 345 amino acids and a calculated molecular weight of 39544. The N-terminal sequence of the processed form is different from that previously found for a similar IgA receptor isolated from a S. pyogenes strain of type M60. The sequence of protein Arp4 shows extensive homology to the C-terminal half of streptococcal M proteins, but not to the streptococcal IgG receptor protein G or staphlyococcal protein A. Apart from the membrane anchor, this homology includes a sequence of 119 amino acid residues containing three repeated units and a 54-residue sequence without repeats. The protein expressed in Escherichia coli is found in the periplasmic space, in which it constitutes the major protein. Protein Arp4 is the first example of a surface protein that has both immunoglobulin-binding capacity and structural features characteristic of M proteins.     

A point mutation that decreases the thermal stability of human interferon gamma.

We have identified a mutation of human gamma-interferon (IFN gamma) causing a temperature-sensitive phenotype. We used a randomized oligonucleotide to mutagenize a synthetic human IFN gamma gene, then screened the resulting mutants produced in Escherichia coli for proteins with altered biological activity. One mutant protein selected for detailed characterization exhibited less than 0.3% of the specific biological activity of native IFN gamma in an antiviral activity assay performed at 37 degrees C. However, the protein bound the human IFN gamma receptor with native efficiency at 4 degrees C. Sequencing the plasmid DNA encoding this protein showed that the mutation changed the lysine residue at amino acid 43 to glutamic acid (IFN gamma/K43E). Site-specific mutagenesis at amino acid 43 showed that this protein's phenotype resulted from positioning a negative charge at position 43. Structural characterization of IFN gamma/K43E using CD demonstrated that the protein had native conformation at 25 degrees C, but assumed an altered conformation at 37 degrees C. IFN gamma/K43E in this altered conformation bound poorly to the IFN gamma receptor at 37 degrees C, providing a rationale for the mutant's decreased antiviral activity.     

Secretory production of human leptin in Escherichia coli

Human leptin is a 16 kDa (146 amino acids) protein secreted from adipocytes and influences body weight homeostasis. In this study, human leptin was produced and secreted efficiently in Escherichia coli using a novel Bacillus sp. endoxylanase signal peptide. The endoxylanase signal sequence consisted of 28 amino acids (84 bp) was fused to the leptin structural gene. The fused gene was expressed using an inducible promoter (T7 or Trc) by adding 1 mM IPTG. Using T7 promoter in E. coli BL21(DE3), most of protein produced was in a premature form. Using the Trc promoter, which is weaker than T7, leptin was efficiently produced and secreted as a mature form (40% of total proteins) at 37 degrees C. However, most of leptin (about 90%) formed the inclusion bodies in the periplasmic space of E. coli. At 30 degrees C, ca. 90% of leptin was produced in a soluble form, but the total amount of leptin produced was 40% less than that obtained at 37 degrees C. When the periplasmic oxidoreductase of E. coli, DsbA, was co-expressed, 69% of the secreted leptin (26% of total proteins) was produced as soluble form at 37 degrees C without the decrease of the amount of leptin produced.     

Immobilization of Escherichia coli Cells Containing Aspartase Activity with Polyurethane and Its Application for l-Aspartic Acid Production

Whole cells of Escherichia coli containing aspartase activity were immobilized by mixing a cell suspension with a liquid isocyanate-capped polyurethane prepolymer (Hypol). The immobilized cell preparation was used to convert ammonium fumarate to l-aspartic acid. Properties of the immobilized E. coli cells containing aspartase were investigated with a batch reactor. A 1.67-fold increase in the l-aspartic acid production rate was observed at 37 degrees C as compared to 25 degrees C operating temperature. The pH optimum was broad, ranging from 8.5 to 9.2. Increasing the concentration of ammonium fumarate to 1.5 M from 1.0 M negatively affected the reaction rate. l-Aspartic acid was produced at an average rate of 2.18 x 10 mol/min per g (wet weight) of immobilized E. coli cells with a 37 degrees C substrate solution consisting of 1.0 M ammonium fumarate with 1 mM Mg (pH 9.0).     

Streptococcal IgA-binding proteins bind in the Calpha 2-Calpha 3 interdomain region and inhibit binding of IgA to human CD89

Certain pathogenic bacteria express surface proteins that bind to the Fc part of human IgA or IgG. These bacterial proteins are important as immunochemical tools and model systems, but their biological function is still unclear. Here, we describe studies of three streptococcal proteins that bind IgA: the Sir22 and Arp4 proteins of Streptococcus pyogenes and the unrelated beta protein of group B streptococcus. Analysis of IgA domain swap and point mutants indicated that two loops at the Calpha2/Calpha3 domain interface are critical for binding of the streptococcal proteins. This region is also used in binding the human IgA receptor CD89, an important mediator of IgA effector function. In agreement with this finding, the three IgA-binding proteins and a 50-residue IgA-binding peptide derived from Sir22 blocked the ability of IgA to bind CD89. Further, the Arp4 protein inhibited the ability of IgA to trigger a neutrophil respiratory burst via CD89. Thus, we have identified residues on IgA-Fc that play a key role in binding of different streptococcal IgA-binding proteins, and we have identified a mechanism by which a bacterial IgA-binding protein may interfere with IgA effector function.     

Temperature-sensitive Escherichia coli mutant with an altered initiation codon of the uncG gene for the H+-ATPase gamma subunit.

A mutant of Escherichia coli showing temperature-sensitive growth on succinate was isolated, and its mutation in the initiation codon (ATG to ATA) of the uncG gene (coding for the gamma subunit of H+-ATPase F0F1) was identified. This strain could grow on succinate as the sole carbon source at 25 and 30 degrees C, but not at 37 or 42 degrees C. When this strain was grown at 25 degrees C on succinate or glycerol, its membranes had about 15% of the ATPase activity of wild-type membranes, whereas when it was grown at 42 degrees C, its membranes had about 2% of the wild-type ATPase activity. Membranes of the mutant grown at 25 or 42 degrees C could bind F1 functionally, resulting in about 40% of the specific activity of wild-type membranes. The gamma subunit was identified in an EDTA extract of membranes of the mutant grown at 25 degrees C, but was barely detectable in the same amount of extract from the mutant grown at 42 degrees C. These results indicate that initiation of protein synthesis from the AUA codon is temperature sensitive and that the gamma subunit is essential for assembly of F1 in vivo as shown by in vitro reconstitution experiments (S. D. Dunn and M. Futai, J. Biol. Chem. 255:113-118, 1980).     

Characterization of degP, a gene required for proteolysis in the cell envelope and essential for growth of Escherichia coli at high temperature.

The degP gene, required for proteolysis in the cell envelope of Escherichia coli, maps at approximately 3.5 min on the chromosome. Null mutations in degP result in temperature-sensitive growth. In certain genetic backgrounds, expression of abnormal periplasmic or inner membrane proteins (protein fusions or proteins with internal deletions) enhances the temperature-sensitive phenotype. Such growth defects were used as a selection for cloning the degP gene into Mud4042 and pACYC184 plasmid vectors, and a restriction map was determined. Analysis of deletion and insertion mutations on one of these plasmids showed that the degP gene is approximately 1.5 kilobases in size. The plasmid-encoded DegP protein had an apparent molecular weight of 50,000, as determined by maxicell analysis. Protein fusions between DegP and alkaline phosphatase had high alkaline phosphatase enzymatic activity, indicating that DegP is a periplasmic or membrane protein.     

Expression of Candida antarctica lipase B in Pichia pastoris and various Escherichia coli systems

Candida antarctica lipase B (CALB) carrying a point mutation, N74S, resulting in a non-glycosylated protein was actively expressed in Pichia pastoris yielding 44 mg/L which was similar to that of the glycosylated CALB wild type expressed in P. pastoris. Hence, the major obstacle in the Escherichia coli expression of CALB is not the lack of glycosylation. To understand and improve the expression of CALB in E. coli, a comprehensive investigation of four different systems were tested: periplasmic expression in Rosetta (DE3), cytosolic expression in Rosetta-gami 2(DE3) and Origami 2(DE3) as well as co-expression with chaperones groES and groEL in Origami B(DE3), all using the pET-22b(+) vector and the T7lac promoter. Furthermore the E. coli expression was carried out at three different temperatures (16, 25 and 37 degrees C) to optimise the expression. Periplasmic expression resulted in highest amount of active CALB of the four systems, yielding a maximum of 5.2mg/L culture at 16 degrees C, which is an improvement to previous reports. The specific activity of CALB towards tributyrin in E. coli was found to be the same for periplasmic and cytosolic expression. Active site titration showed that the CALB mutant N74S had a lower specific activity in comparison to wild type CALB regardless of expression host. The expected protein identity was confirmed by LC-ESI-MS analysis in E. coli, whereas in P. pastoris produced CALB carried four additional amino acids from an incomplete protein processing.     

Expression of a temperature-sensitive esterase in a novel chaperone-based Escherichia coli strain

A new principle for expression of heat-sensitive recombinant proteins in Escherichia coli at temperatures close to 4 degrees C was experimentally evaluated. This principle was based on simultaneous expression of the target protein with chaperones (Cpn60 and Cpn10) from a psychrophilic bacterium, Oleispira antarctica RB8(T), that allow E. coli to grow at high rates at 4 degrees C (maximum growth rate, 0.28 h(-1)). The expression of a temperature-sensitive esterase in this host at 4 to 10 degrees C yielded enzyme specific activity that was 180-fold higher than the activity purified from the non-chaperonin-producing E. coli strain grown at 37 degrees C (32,380 versus 190 micromol min(-1) g(-1)). We present evidence that the increased specific activity was not due to the low growth temperature per se but was due to the fact that low temperature was beneficial to folding, with or without chaperones. This is the first report of successful use of a chaperone-based E. coli strain to express heat-labile recombinant proteins at temperatures below the theoretical minimum growth temperature of a common E. coli strain (7.5 degrees C).     

Protein synthesis kinetics with ribosomes from temperature-sensitive mutants of Escherichia coli.

The kinetics of MS2 ribonucleic acid (RNA) directed protein synthesis have been investigated at seven temperatures between 30 and 47 degrees C by using ribosomes isolated from a wild type strain and seven temperature-sensitive mutants of Escherichia coli. The amount of MS2 coat protein formed at each temperature was determined by gel electrophoresis of the products formed with control ribosomes. With ribosomes from each of the mutant strains, the activation energy required to drive protein synthesis below the maximum temperature (up to 40 degrees C) was increased relative to the control (wild type) activity. Preincubation of the ribosomes at 44 degrees C revealed the kinetics of thermal inactivation, with ribosomes from each of the mutants having a half-life for inactivation less than that of the control ribosomes. A good correlation was observed between the relative activity of the different ribosomes at 44 degrees C and their relative rate of thermal inactivation. Mixing assays allowed the identification of a temperature-sensitive ribosomal subunit for each of the mutants. Defects in one or more of three specific steps in protein synthesis (messenger RNA binding, transfer RNA binding, transfer RNA binding, and subunit reassociation) were identified for the ribosomes from each mutant. The relationship between temperature sensitivity and protein synthesis in these strains is discussed.     

Biochemical characterization of the essential GTP-binding protein Obg of Bacillus subtilis.

An essential guanine nucleotide-binding protein, Obg, of Bacillus subtilis has been characterized with respect to its enzymatic activity for GTP. The protein was seen to hydrolyze GTP with a Km of 5.4 microM and a kcat of 0.0061 min-1 at 37 degrees C. GDP was a competitive inhibitor of this hydrolysis, with an inhibition constant of 1.7 microM at 37 degrees C. The dissociation constant for GDP from the Obg protein was 0.5 microM at 4 degrees C and was estimated to be 1.3 microM at 37 degrees C. Approximately 80% of the purified protein was capable of binding GDP. In addition to hydrolysis of GTP, Obg was seen to autophosphorylate with this substrate. Subsequent release of the covalent phosphate proceeds at too slow a rate to account for the overall rate of GTP hydrolysis, indicating that in vitro hydrolysis does not proceed via the observed phosphoamidate intermediate. It was speculated that the phosphorylated form of the enzyme may represent either a switched-on or a switched-off configuration, either of which may be normally induced by an effector molecule. This enzyme from a temperature-sensitive mutant of Obg did not show significantly altered GTPase activity at the nonpermissive temperature.     

Extracellular recombinant protein production from an Escherichia coli lpp deletion mutant

E. coli is one of the most commonly used host strains for recombinant protein production. However, recombinant proteins are usually found intracellularly, in either cytoplasm or periplasmic space. Inadequate secretion to the extracellular environment is one of its limitations. This study addresses the outer membrane barrier for the translocation of recombinant protein directed to the periplasmic space. Specifically, using recombinant maltose binding protein (MalE), xylanase, and cellulase as model proteins, we investigated whether the lpp deletion could render the outer membrane permeable enough to allow extracellular protein production. In each case, significantly higher excretion of recombinant protein was observed with the lpp deletion mutant. Up to 90% of the recombinant xylanase activity and 70% of recombinant cellulase activity were found in the culture medium with the deletion mutant, whereas only 40-50% of the xylanase and cellulase activities were extracellular for the control strain. Despite the weakened outer membrane in the mutant strain, cell lysis did not occur, and increased excretion of periplasmic protein was not due to cell lysis. The lpp deletion is a simple method to generate an E. coli strain to effect significant extracellular protein production. The phenotype of extracellular protein production without cell lysis is useful in many biotechnological applications, such as bioremediation and plant biomass conversion.     

A spin label study on human low density lipoprotein

Selective labeling with N-(1-oxyl-2,2,6,6-tetramethyl-4-piperidinyl)-maleimide of human serum LDL has been performed. The spin-labeled LDL exhibited an ESR spectrum containing signals of a strongly immobilized component only. The signals were completely reversible between 4 degrees C and 37 degrees C and fairly stable at each temperature. The spin-labeled LDL which was prepared by the usual method exhibited an ESR spectrum containing signals of both strongly immobilized and weakly immobilized components (5, 6). The latter was unstable above 25 degrees C and changed irreversibly. The strongly binding site showed higher affinity for the nitroxide radical than the weakly binding site, and two kinds of the strongly binding site were demonstrated kinetically. The rate of binding of the nitroxide radical to the two kinds of strongly binding site were estimated to be 4.7 x 10(4) M-1 . day-1 and 0.16 x 10(4) M-1 . day-1 at pH 7.4 and 4 degrees C, respectively. Both the strongly immobilized and weakly immobilized radicals were reduced with ascorbate at the same rate. It was also shown on gel filtration of the SDS-treated LDL derivatives that the strongly immobilized component was on the apoprotein B moiety, whereas either noncovalent binding to LDL or binding to some small molecular species other than protein was suggested for the weakly immobilized component.     

Identification of an osmotically induced periplasmic glycine betaine-binding protein from Rhizobium meliloti.

The effect of salt stress on glycine betaine-binding activity has been investigated in periplasmic fractions released from Rhizobium meliloti 102F34 by cold osmotic shock. Binding activity was monitored by three techniques: equilibrium dialysis, filter procedure, and detection of 14C ligand-protein binding by direct non-denaturing polyacrylamide gel electrophoresis (PAGE) followed by autoradiography. The three methods demonstrated the existence of a strong glycine betaine-binding activity, but only in periplasmic fractions from cells grown at high osmolarity. The non-denaturing PAGE of such periplasmic shock fluids mixed with [methyl-14C]glycine betaine showed only one radioactive band, indicating the involvement of one glycine betaine-binding protein. To determine the possible implication of this binding protein in glycine betaine uptake, transport activity was measured with cells submitted to cold osmotic shock. No significant decrease of transport activity was noticed. This lack of effect could be explained by the small quantity of periplasmic proteins released as judged by the low activity of phosphodiesterase, a periplasmic marker enzyme, observed in the shock fluid. The specificity of binding was analysed with different potential competitors: other betaines such as gamma-butyrobetaine, proline betaine, pipecolate betaine, trigonelline and homarine, or amino acids like glycine and proline, did not bind to the glycine betaine-binding protein, whereas glycine betaine aldehyde and choline were weak competitors. Optimum pH for binding was around 7.0, but approx. 90% of the glycine betaine-binding activity remained at pH 6.0 or 8.0. The calculated binding affinity (KD) was 2.5 microM. Both glycine betaine-binding activity and affinity were not significantly modified whether or not the binding assays were done at high osmolarity. A 32 kDa osmotically inducible periplasmic protein, identified by SDS-PAGE, apparently corresponds to the glycine betaine-binding protein.     

A yeast sir2 mutant temperature sensitive for silencing

A screen for Saccharomyces cerevisiae temperature-sensitive silencing mutants identified a strain with a point mutation in the SIR2 gene. The mutation changed Ser276 to Cys. This amino acid is in the highly conserved NAD(+) binding pocket of the Sir2 family of proteins. Haploid strains of either mating type carrying the mutation were severely defective at mating at 37 degrees but normal at 25 degrees . Measurements of RNA from the HMR locus demonstrated that silencing was lost rapidly upon shifting the mutant from the low to the high temperature, but it took >8 hours to reestablish silencing after a shift back to 25 degrees . Silencing at the rDNA locus was also temperature sensitive. On the other hand, telomeric silencing was totally defective at both temperatures. Enzymatic activity of the recombinant wild-type and mutant Sir2 protein was compared by three different assays. The mutant exhibited less deacetylase activity than the wild-type protein at both 37 degrees and 25 degrees . Interestingly, the mutant had much more NAD(+)-nicotinamide exchange activity than wild type, as did a mutation in the same region of the protein in the Sir2 homolog, Hst2. Thus, mutations in this region of the NAD(+) binding pocket of the protein are able to carry out cleavage of NAD(+) to nicotinamide but are defective at the subsequent deacetylation step of the reaction.     

Analysis of the temperature-sensitive mutation of Escherichia coli pantothenate kinase reveals YbjN as a possible protein stabilizer

Pantothenate kinase (PanK), a key regulatory enzyme in the coenzyme A (CoA) biosynthetic pathway, catalyzes the rate-limiting phosphorylation of pantothenic acid to form phosphopantothenate during CoA biosynthesis. Escherichia coli ts9 strain manifests temperature-sensitive phenotype on LB media due to its mutation in the coaA gene (coaA1). Sequencing analysis revealed that coaA1 arises from a single base pair mutation that results in an amino acid change, L236F. This change, located proximate to the ATP binding site of CoaA, destabilizes both enzymatic activity and structural integrity or stability of the mutant protein in vitro. Spontaneously, revertants of ts9 were occasionally found on LB medium plates. Two groups of revertants were isolated: for those that can grow at 40 degrees C, a reversion of the original amino acid mutation L236F to L236L or other amino acid (such as L236C) occurs; for those that can grow at 37 degrees C but not 40 degrees C, a mutation at another gene or intergenic suppression is strongly indicated. Towards genetic identification of genes that might interact with coaA1, ybjN, which encodes a putative sensory transduction regulator protein, and whose over-expression is capable of ameliorating the temperature-sensitive phenotype of the structurally unstable CoaA1 or CoaA[L236F], was isolated. Over-expression of ybjN appears to suppress the temperature-sensitive phenotype of several other temperature-sensitive mutations, including coaA14 (carried by DV51 strain), coaA15 (carried by DV70 strain), and ilu-1, suggesting it not only helps CoaA1, but possibly works as a general stabilizer for some other unstable proteins.