Hsp70s contain a specific sulfogalactolipid binding site. Differential aglycone influence on sulfogalactosyl ceramide binding by recombinant prokaryotic and eukaryotic hsp70 family members

Specific 3'-sulfogalactolipid [SGL-sulfogalactosyl ceramide (SGCer) and sulfogalactosylglycerolipid (SGG)] binding is compared for hsp70s cloned from Helicobacter pylori, Haemophilus influenzae, Chlamydia trachomatis serovar E, Escherichia coli, murine male germ cells, and the hsp70-like extracellular domain within the sperm receptor from Strongylocentrotus purpuratus. This lectin activity, conserved among the different hsp70 family members, is modulated by the SGL aglycone. This is shown by differential binding to both SGC fatty acid homologues and 3'-sulfogalactolipid neoglycoproteins generated by coupling bovine serum albumin (BSA) and glycosyl ceramide acids synthesized by oxidation of the double bond of sphingosine. Eukaryotic hsp70s preferentially bound the SGCer fatty acid homologues SG(24)Cer, SG(18)Cer, and SG(20:OH)Cer, while prokaryotic hsp70s bound SG(18:1)Cer and SG(20:OH)Cer. Eukaryotic hsp70s bound SGCer-BSA and SG(24)Cer-BSA conjugates where the latter is the main constituent in SGCer-BSA, while prokaryotic hsp70s bound SG(20:OH)Cer-BSA. None of the hsp70s bound sulfogalactosyl sphingosine (SGSph) or SGSph-BSA, further demonstrating the important role of the aglycone. Although the primary SGL recognition domain of all hsp70s is conserved, we propose that aglycone organization differentially influences the interaction with the sub-site. Heterogeneous SGCer aglycone isoforms in cells and the differential in vitro binding of eukaryotic and prokaryotic hsp70s may relate to their different adhesin roles in vivo as mediators of germ cell and bacterial/host interactions, respectively.     

The ATPase domain of hsp70 possesses a unique binding specificity for 3'-sulfogalactolipids

The region(s) of hsp70 critical for sulfogalactolipid (SGL) recognition has been defined through deletion analysis and site-directed mutagenesis. Truncated polymerase chain reaction products of hsp70 generated N-terminal fragments of 43, 35, 29, and 22 kDa. The C terminus substrate-binding domain (28 kDa) was also expressed. The N-terminal ATPase domain (rP43) shared the binding specificity of hsp70, because only sulfogalactosyl ceramide and sulfogalactosyl glycerolipid were recognized by both TLC overlay and RELISA. The C-terminal domain showed no binding. SGL binding of rP29 and rP22 was severely reduced. The loss of SGL binding for rP35 by RELISA but not TLC overlay was considered as a function of receptor presentation. The truncation of rP43 to rP35 demonstrates that residues 318-387 (the base of the ATP binding cleft) are critical for high affinity SGL binding. Mutagenesis showed that Arg(342) and Phe(198) are crucial for this process. SGL binding, mediated by these conserved residues within the ATPase domain of hsp70, implies that this binding specificity is evolutionarily conserved.     

The aglycone of sulfogalactolipids can alter the sulfate ester substitution position required for hsc70 recognition

3'-Sulfogalactolipids(SGLs), sulfogalactosyl ceramide (SGC), and sulfogalactoglycerolipid (SGG) bind to the N-terminal ATPase-containing domain of members of the heat shock protein 70 family. We have probed this binding specificity using a series of synthetic positional sulfated or phosphorylated glycolipid analogues, containing either a long-chain bisalkyl hydrocarbon-2-(tetradecyl)hexadecane (B30) or C(18) ceramide (SGC(18)) backbone. By TLC overlay and receptor ELISA, recombinant hsc70 bound ceramide-based glycoconjugates having 3'- or 4'-sulfogalactose glycone moieties and the 4'-sulfogalactose positional isomer conjugated to B30. Hsc70 binding was significantly decreased to the 3'-sulfogalactose conjugated to the long-chain branched alkane. 3'-Sulfoglucose conjugated to B30 was not bound, nor were similarly conjugated di-, tri-, and tetra-sulfated or phosphorylated galactolipids. These results highlight the importance of the position, rather than the number of sulfate esters within the galactose ring. This binding selectivity was shared by the sea urchin hsp70-related sperm receptor. A 3'-SGC-based soluble inhibitor, in which the acyl chain was replaced with an adamantyl group, inhibited binding of hsc70 to both 3'- and 4'-SGC species with an IC(50) of 50 and 75 microM, respectively, indicating a shared sulfogalactose binding site. These studies demonstrate the highly specific nature of hsc70/SGL binding and show, for the first time, that the lipid aglycone can alter the substitution position requirement for glycolipid recognition.     

Interaction of arylsulfatase-A (ASA) with its natural sulfoglycolipid substrates: a computational and site-directed mutagenesis study

Arylsulfatase A (ASA) hydrolyzes sulfate esters with a pH optimum of 5. Interactions between p-nitrocatechol sulfate (NCS, artificial substrate) and active site residues of ASA are revealed from their co-crystal structure. Since equivalent ASA interactions with its natural substrates, sulfogalactosylceramide (SGC) and sulfogalactosylglycerolipid (SGG), are not known, we computationally docked SGC/SGG to the ASA crystal structure. Our dockings suggested that Cys69 was the active site residue, and Lys302 & Lys123 as residues anchoring the sulfate group of SGC/SGG to the active site, as observed for NCS. We further confirmed these results using 2 recombinant ASA mutants: C69A and CKK (Cys69, Lys302 and Lys123-all mutated to Ala). Both ASA mutants failed to desulfate SGC/SGG, and CKK showed minimal binding to [¹⁴C]SGC, although C69A still had affinity for this sulfoglycolipid. However, our dockings suggested additional intermolecular hydrogen bonding and hydrophobic interactions between ASA and SGC/SGG, thus contributing to the specificity of SGC/SGG as natural substrates.     

Secondary structure determination by FTIR of an archaeal ubiquitin-like polypeptide from <Emphasis Type="Italic">Natrialba magadii</Emphasis>

The ubiquitin protein belongs to the β-grasp fold family, characterized by four or five β-sheets with a single α-helical middle region. Ubiquitin-like proteins (Ubls) are structural homologues with low sequence identity to ubiquitin and are widespread among both eukaryotes and prokaryotes. We previously demonstrated by bioinformatics that P400, a polypeptide from the haloalkaliphilic archaeon Natrialba magadii, has structural homology with both ubiquitin and Ubls. This work examines the secondary structure of P400 by Fourier transform infrared spectroscopy (FTIR). After expression in Escherichia coli, recombinant P400 (rP400) was separated by PAGE and eluted pure from zinc-imidazole reversely stained gels. The requirement of high salt concentration of this polypeptide to be folded was corroborated by intrinsic fluorescence spectrum. Our results show that fluorescence spectra of rP400 in 1.5 M KCl buffer shifts and decreases after thermal denaturation as well as after chemical treatment. rP400 was lyophilized and rehydrated in buffer containing 1.5 M KCl before both immunochemical and FTIR tests were performed. It was found that rP400 reacts with anti-ubiquitin antibody after rehydration in the presence of high salt concentrations. On the other hand, like ubiquitin and Ubls, the amide I′ band for rP400 shows 10% more of its sequence to be involved in β-sheet structures than in α-helix. These findings suggest that P400 is a structural homologue of the ubiquitin family proteins.     

Kinetic analysis of hydroxylation of saturated fatty acids by recombinant P450foxy produced by an Escherichia coli expression system.

Cytochrome P450foxy (P450foxy, CYP505) is a fused protein of cytochrome P450 (P450) and its reductase isolated from the fungus Fusarium oxysporum, which catalyzes the subterminal (omega-1 approximately omega-3) hydroxylation of fatty acids. Here, we produced, purified and characterized a fused recombinant protein (rP450foxy) using the Escherichia coli expression system. Purified rP450foxy was catalytically and spectrally indistinguishable from the native protein, but most of the rP450foxy was recovered in the soluble fraction of E. coli cells unlike the membrane-bound native protein. The results are consistent with our notion that the native protein is targeted to the membrane by a post-translational modification mechanism. We also discovered that P450foxy could use shorter saturated fatty acid chains (C9 and C10) as a substrate. The regiospecificity (omega-1 approximately omega-3) of hydroxylation due to the enzymatic reaction for the short substrates (decanoate, C10; undecanoate, C11) was the same as that for longer substrates. Steady state kinetic studies showed that the kcat values for all substrates tested (C9-C16) were of the same magnitude (1200-1800 min-1), whereas the catalytic efficiency (kcat/Km) was higher for longer fatty acids. Substrate inhibition was observed with fatty acid substrates longer than C13, and the degree of inhibition increased with increasing chain length. This substrate inhibition was not apparent with P450BM3, a bacterial counterpart of P450foxy, which was the first obvious difference in their catalytic properties to be identified. Kinetic data were consistent with the inhibition due to binding of the second substrate. We discuss the inhibition mechanism based on differences between P450foxy and P450BM3 in key amino acid residues for substrate binding.     

HSP86 and HSP84 exhibit cellular specificity of expression and co-precipitate with an HSP70 family member in the murine testis

This study extends to the protein level our previous observations, which had established the stage and cellular specificity of expression of hsp86 and hsp84 in the murine testis in the absence of exogenous stress. Immunoblot analysis was used to demonstrate that HSP86 protein was present throughout testicular development and that its levels increased with the appearance of differentiating germ cells. HSP86 was most abundant in the germ cell population and was present at significantly lower levels in the somatic cells. By contrast, the HSP84 protein was detected in the somatic cells of the testis rather than in germ cells. The steady-state levels of HSP86 and HSP84 paralleled the pattern of the expression of their respective mRNAs, suggesting that regulation at the level of translation was not a major mechanism controlling hsp90 gene expression in testicular cells. Immunoprecipitation analysis revealed that a 70-kDa protein coprecipitated with the HSP86/HSP84 proteins in testicular homogenates. This protein was identified as an HSP70 family member by immunoblot analysis, suggesting that HSP70 and HSP90 family members interact in testicular cells. © 1993Wiley-Liss, Inc.     

The receptor for heat shock protein 60 on macrophages is saturable, specific, and distinct from receptors for other heat shock proteins.

Previous studies have shown that human heat shock protein (hsp) 60 elicits a strong proinflammatory response in cells of the innate immune system with CD14, Toll-like receptor (TLR) 2, and TLR4 as mediators of signaling, but probably not of binding. In the present study, we directly demonstrate binding of hsp60 to the macrophage surface and find the binding receptor for hsp60 different from the previously described common receptor for several other heat shock proteins, including hsp70, hsp90, and gp96. Fluorescence-labeled human hsp60 bound to cell surfaces of the murine macrophage lines J774 A.1 and RAW264.7 and to mouse bone marrow-derived macrophages. By flow cytometry, we could demonstrate for the first time that hsp60 binding to macrophages occurred at submicromolar concentrations, is saturable, and can be competed by unlabeled hsp60, but not by unrelated proteins, thus confirming the classic characteristics of specific ligand-receptor interactions. Binding of hsp60 at 4 degrees C was followed by endocytosis at 37 degrees C. Hsp60 binding to macrophages could not be competed by excess hsp70, hsp90, or gp96, all of which share the alpha(2)-macroglobulin receptor as binding site. Hsp60 binding occurred in the absence of surface TLR4. However, no cytokine response was induced by hsp60 in TLR4-deficient macrophages. We conclude that hsp60 binds to a stereo-specific receptor on macrophages, and that different surface molecules are engaged in binding and signal transduction. Furthermore, the binding site for hsp60 is separate from the common receptor for hsp70, hsp90, and gp96, which suggests an independent role of hsp60 as danger Ag and in immunoregulation.     

Structural Features of Transiently Modified Beta-Lactoglobulin Relevant to the Stable Binding of Large Hydrophobic Molecules

Binding sites for hydrophobic molecules on bovine β-lactoglobulin, and their susceptibility to temperature, were studied by using various spectroscopic probes. Binding of probes carrying a single fluorophore moiety, a single nitroxide moiety, or both moieties on the same molecule, was followed by EPR and fluorescence. The presence of a fatty acid side chain in the dual probes was found to be required for binding to β-lactoglobulin. Binding occurred only after the protein was heated at temperatures below the threshold for its irreversible denaturation. Binding became extremely tight and stable upon cooling of the protein–probe mixture. Comparison among the various probes suggests that multiple binding sites for hydrophobes are present in the native protein, and in the partially—and reversibly—modified form of β-lactoglobulin present in solution at neutral pH and subdenaturing temperatures. Thus, the specificity of hydrophobes binding to β-lactoglobulin may be modulated by simple physical treatment of the protein.     

Relative ability of ovine follicle stimulating hormone and itsβ-subunit to generate antibodies having bioneutralization potential in nonhuman primates

The relative ability of ovine follicle stimulating hormone and itsβ-subunit, two potential candidates for male contraceptive vaccine, to generate antibodies in monkeys capable of bioneutralizing follicle stimulating hormone was assessed usingin vitro model systems. Antiserum against native ovine follicle stimulating hormone was found to be highly specific to the intact form with no cross-reactivity with either of the two subunits while the antiserum againstβ-subunit of follicle stimulating hormone could bind to theβ-subunit in its free form as well as when it is combined withα-subunit to form the intact hormone. Both antisera could block the binding of the hormone to the receptor if the hormone was preincubated with the antibody. However, the follicle stimulating hormoneβ-antisera could only inhibit the binding of the hormone partially (33% inhibition) if the antibody and receptor were mixed prior to the addition of the hormone, while antisera to the native follicle stimulating hormone could block the binding completely (100% inhibition) in the same experiment. Similarly antisera to the native follicle stimulating hormone was significantly effective in blocking (100%) response to follicle stimulating hormone but not theβ-subunit antisera (0%) as checked using anin vitro granulosa cell system. Thus the probability of obtaining antibodies of greater bioneutralization potential is much higher if intact hormone is used as an antigen rather than itsβ-subunit as a vaccine. Majority of the work reported here was carried out during the tenure of Visiting Scientist fellowship awarded by the MRC Canada to the first author.     

Evaluation of the binding of serotonin by isolated CNS acidic lipids

Binding of serotonin by rat lipids was examined in an organic solvent-aqueous partition system. Only phospholipids and sulfatide were found to have appreciable activity: this technique was unsuitable for gangliosides due to their poor extractibility. Binding by phospholipid was abolished and that by sulfatide was greatly inhibited by increasing ionic strength in the aqueous phase. At an ionic strength of 0.3 M the apparent affinity of sulfatide for serotonin was about 3×10³ M. Both tryptamine and 5-methoxytryptamine were much more effective than serotonin in inhibiting the binding of radioactive serotonin, suggesting that the observed binding is simply a charge neutralization with little specificity. Binding of serotonin by mixed brain gangliosides was examined in an equilibrium dialysis system. Without adequate precautions, the chemical lability of serotonin was found to produce spurious data when binding was assessed by the distribution of radiolabel. Binding of serotonin by ganglioside was also greatly inhibited by increasing ionic strength: at 0.3 M an apparent affinity of about 10³ M was found. While dopamine did not inhibit the binding of radioactive serotonin, tryptamine, 5-methoxytryptamine, and serotonin were equally effective inhibitors.     

Carbohydrate ligands of human C-reactive protein: Binding of neoglycoproteins containing galactose-6-phosphate and galactose-terminated disaccharide

Binding of carbohydrate ligand by human C-reactive protein (CRP), in both native form and structurally deviated form (neoCRP or mCRP), was investigated using galactose-6-phosphate (Gal6P)- and Galβ3GalNAc-containing bovine serum albumin (BSA) derivatives. To this end, we synthesized glycosides of Gal6P and Galβ3GalNAc that can potentially generate a terminal aldehyde group. ω-Aldehydo glycosides were then conjugated to BSA via reductive amination. Using these neoglycoproteins, we showed that: (1) Gal6P-BSA and Galβ3GalNAc-BSA bound to both forms of CRP, the former with or without calcium and the latter only in the absence of calcium; (2) phosphate-containing ligands can be bound with or without calcium, but the binding is much stronger in the presence of calcium than in the absence, underscoring the importance of direct coordination of phosphate to two calcium ions observed in the X-ray structure of phosphorylcholine (PC)–CRP complex; (3) cross-inhibition studies further corroborated the hypothesis that binding sites of PC and sugar are contiguous; (4) while PC-BSA bound to the native CRP over a wide pH range of 4.5 to 9, all the carbohydrate ligands and protamine-BSA (poly-cation-based ligand) exhibited optimal binding at around pH 6 to 6.5; and (5) ligand-binding conformation of mCRP appears to be more fragile than that of the native CRP in the acidic media (pH < 6).     

Studies on the spermatogenic sulfogalactolipid binding protein SLIP 1

We have purified the testicular sulfogalactolipid binding protein SLIP 1 and shown by photoaffinity labeling that it contains an ATP binding site. Purified SLIP 1 was fluorescently labeled and shown to retain specific sulfogalactolipid binding function. This probe was used to investigate the topology of SLIP 1 binding sites on testicular germ cells. The binding pattern precisely coincided with the previously demonstrated asymmetric surface domains of sulfogalactoglycerolipid (SGG). Occasionally these SGG-containing, SLIP 1-binding cell surface domains exactly coincided with structural features on the cell surface as detected by differential interference contrast microscopy. These results demonstrate that SLIP 1/SGG interactions could provide an effective intercellular communication network between testicular germ cells within the seminiferous tubule.     

Cloning and characterization of the Brucella ovis heat shock protein DnaK functionally expressed in Escherichia coli.

The Brucella ovis dnaK gene, homolog to the eukaryotic hsp70 genes, was cloned by using a Drosophila melanogaster probe. Comparison of B. ovis and Escherichia coli sequences revealed a similar organization for the dnaK and dnaJ genes and putative regulatory signals. In E. coli transfected with the cloned fragment, B. ovis hsp70 was expressed at 30 and 50 degrees C apparently under the control of its own promoter. The recombinant protein and a B. ovis native protein displaying the same molecular weight were both recognized by anti-E. coli DnaK serum. Native B. ovis protein was also recognized by sera of sheep either infected or vaccinated with an attenuated Brucella strain, suggesting that Brucella hsp70 could be up-regulated during host colonization. A thermosensitive E. coli dnaK mutant transfected with the cloned fragment recovered colony-forming ability at 42 degrees C, showing that the B. ovis DnaK protein could behave as a functional heat shock protein in E. coli.     

The platelet glycoprotein thrombospondin binds specifically to sulfated glycolipids

The human platelet glycoprotein thrombospondin (TSP) binds specifically and with high affinity to sulfatides (galactosylceramide-I3-sulfate). Binding of 125I-TSP to lipids from sheep and human erythrocytes and human platelets resolved on thin layer chromatograms indicates that sulfatides are the only lipids in the membrane which bind TSP. Binding to less than 2 ng of sulfatide could be detected. TSP failed to bind to other purified lipids including cholesterol 3-sulfate, phospholipids, neutral glycolipids, and gangliosides. Binding of 125I-TSP was inhibited by unlabeled TSP, by low pH, and by reduction of intersubunit disulfide bonds with dithiothreitol. A monoclonal antibody against TSP (A2.5), which inhibits hemagglutination and agglutination of fixed activated platelets by TSP, strongly inhibited TSP binding to sulfatides. A second monoclonal antibody (C6.7), which inhibits hemagglutination and aggregation of thrombin-activated live platelets, weakly inhibited sulfatide binding. Binding was inhibited by high ionic strength and by some monosaccharide sulfates including methyl-alpha-D-GlcNAc-3-sulfate. Neutral sugars did not inhibit. Fucoidan, a sulfated fucan, strongly inhibited binding with 50% inhibition at 0.3 micrograms/ml fucoidan. Other sulfated polysaccharides including heparin and dextran sulfates were good inhibitors, whereas hyaluronic acid and keratan sulfate were very weak.     

Colocalization of sulfogalactosylacylalkylglycerol (SGG) and its binding protein during spermatogenesis and sperm maturation. Topology of SGG defines a new testicular germ cell membrane domain

By use of double-labelling indirect immunofluorescence, we have shown that the major mammalian testicular glycolipid sulfogalactosylacylalkylglycerol (SGG) and a membrane protein, previously shown to bind specifically to SGG in vitro, are colocalized on the surface of rat testicular germ cells during spermatogenesis. SGG is restricted to convoluted membrane domains within these cells. Thus, the binding affinity in vitro is reflected in the cell surface topology. The topological relationship between these two antigens was also studied during epididymal sperm maturation. Whereas these antigens were colocalized in caput spermatozoa (on the middle and principal piece of the tail and on the concave surface of the head), the distribution of the binding protein was altered for cauda sperm in that the convex surface of the sperm head was now strongly labelled. These studies illustrate the dynamic nature of protein-glycolipid interactions during germ cell differentiation.     

Binding site amino acid residues of jack fruit (artocarpus integrifolia) seed lectin: chemical modification and protein difference spectral studies

The effect of chemical modification of amino acid residues essential for sugar binding in the α-D-galactoside specific jack fruit (Artocarpus integrifolia) seed lectin and the protection of the residues by specific sugar from modification were studied. Citraconylation or maleylation of 75 % of its lysyl residues or acetylation of 70 % of the tyrosyl residues completely abolished sugar binding and agglutination without dissociation of subunits. 1-O-methyl α-D-galactoside could protect its essential lysyl and tyrosyl groups from modification. Tryptophan could not be detected in the protein. Difference absorption spectra on binding of the above sugar confirmed the role of tyrosine residues and showed an association constantK = 0.4 × 10³ M⁻¹. Data suggests that the lectin could be immobilized without any loss of sugar binding activity     

Mutational analysis of the hsp70-interacting protein Hip.

The hsp70-interacting protein Hip participates in the assembly pathway for progesterone receptor complexes. During assembly, Hip appears at early assembly stages in a transient manner that parallels hsp70 interactions. In this study, a cDNA for human Hip was used to develop various mutant Hip forms in the initial mapping of functions to particular Hip structural elements. Hip regions targeted for deletion and/or truncation included the C-terminal region (which has some limited homology with Saccharomyces cerevisiae Sti1 and its vertebrate homolog p60), a glycine-glycine-methionine-proline (GGMP) tandem repeat, and a tetratricopeptide repeat (TPR). Binding of Hip to hsp70's ATPase domain was lost with deletions from the TPR and from an adjoining highly charged region; correspondingly, these Hip mutant forms were not recovered in receptor complexes. Truncation of Hip's Sti1-related C terminus resulted in Hip binding to hsp70 in a manner suggestive of a misfolded peptide substrate; this hsp70 binding was localized to the GGMP tandem repeat. Mutants lacking either the C terminus or the GGMP tandem repeat were still recovered in receptor complexes. Truncations from Hip's N terminus resulted in an apparent loss of Hip homo-oligomerization, but these mutants retained association with hsp70 and were recovered in receptor complexes. This mutational analysis indicates that Hip's TPR is required for binding of Hip with hsp70's ATPase domain. In addition, some data suggest that hsp70's peptide-binding domain may alternately or concomitantly bind to Hip's GGMP repeat in a manner regulated by Sti1-related sequences.     

Histone H1 proteins act as receptors for the 987P fimbriae of enterotoxigenic Escherichia coli

The tip adhesin FasG of the 987P fimbriae of enterotoxigenic Escherichia coli mediates two distinct adhesive interactions with brush border molecules of the intestinal epithelial cells of neonatal piglets. First, FasG attaches strongly to sulfatide with hydroxylated fatty acyl chains. This interaction involves lysine 117 and other lysine residues of FasG. Second, FasG recognizes specific intestinal brush border proteins that migrate on a sodium-dodecyl sulfate-polyacrylamide gel like a distinct set of 32-35-kDa proteins, as shown by ligand blotting assays. The protein sequence of high performance liquid chromatography-purified tryptic fragments of the major protein band matched sequences of human and murine histone H1 proteins. Porcine histone H1 proteins isolated from piglet intestinal epithelial cells demonstrated the same SDS-PAGE migration pattern and 987P binding properties as the 987P-specific protein receptors from porcine intestinal brush borders. Binding was dose-dependent and shown to be specific in adhesion inhibition and gel migration shift assays. Moreover, mapping of the histone H1 binding domain suggested that it is located in their lysine-rich C-terminal domains. Histone H1 molecules were visualized on the microvilli of intestinal epithelial cells by immunohistochemistry and electron microscopy. Taken together these results indicated that the intestinal protein receptors for 987P are histone H1 proteins. It is suggested that histones are released into the intestinal lumen by the high turnover of the intestinal epithelium. Their strong cationic properties can explain their association with the negatively charged brush border surfaces. There, the histone H1 molecules stabilize the sulfatide-fimbriae interaction by simultaneously binding to the membrane and to 987P.