Effect of ligand binding on the tryptic digestion pattern of rat brain hexokinase: relationship of ligand-induced conformational changes to catalytic and regulatory functions

The Type I isozyme of rat hexokinase (ATP:D-hexose 6-phosphotransferase, EC 2.7.1.1) is comprised of N- and C-terminal domains, associated with regulatory and catalytic functions, respectively. Extensive sequence similarity between the domains is consistent with evolution of the enzyme by gene duplication and fusion. Cleavage at tryptic sites located in the C-terminal domain is markedly sensitive to ligands present during digestion, while analogous sites in the N-terminal domain are either resistant to trypsin or unaffected by the presence of ligands. These results imply a lack of structural equivalence between the N- and C-terminal domains, with the overall structure of the N-terminal domain being "tighter" and with a major component of ligand-induced conformational changes being focused in the C-terminal domain. Based on a previously proposed structure for brain hexokinase, protection by substrate hexoses is attributed to substrate-induced closing of a cleft in the C-terminal domain. Similar protection at C-terminal cleavage sites results from binding of inhibitory hexose-6-phosphates to the N-terminal domain. In addition, hexose-6-phosphates evoke cleavage at a site, T5, located in a region that has been associated with binding of ATP to the C-terminal domain. Thus, alterations in this region, coupled with reduced accessibility resulting from cleft closure, may account for the mutually exclusive binding of inhibitory hexose-6-phosphates and substrate ATP. In the absence of Mg2+, all nucleoside triphosphates examined (ATP, UTP, CTP, and GTP) protected against digestion by trypsin. In contrast, ATP-Mg2+ stabilized the C-terminal domain but destabilized the N-terminal domain, while the chelated forms of the other nucleoside triphosphates were similar to the unchelated forms in their effect on proteolysis; the unique response to ATP-Mg2+ reflects the specificity for ATP as a substrate.     

Gc (vitamin D-binding protein) binds the 33.5 K tryptic fragment of actin

Limited proteolysis of G-actin was performed with trypsin and chymotrypsin to compare the binding sites for Gc and DNase. DNase I bound to the N-terminal area corresponding to the major cleavage site on G-actin (residues 62-68) and inhibited proteolysis, but did not bind the 33.5K C-terminal fragment (G-actin33.5) generated. In contrast, Gc did not exert any inhibitory effect upon proteolysis of the intact native G-actin42.0 molecule, although its presence protected G-actin33.5 from further proteolysis. This was shown by gel filtration to be due to the formation of complexes between Gc and G-actin33.5.     

ATP and the core "alpha-Crystallin" domain of the small heat-shock protein alphaB-crystallin

Electrospray ionization mass spectrometry (ESI-LC/MS) of tryptic digests of human alphaB-crystallin in the presence and absence of ATP identified four residues located within the core "alpha-crystallin" domain, Lys(82), Lys(103), Arg(116), and Arg(123), that were shielded from the action of trypsin in the presence of ATP. In control experiments, chymotrypsin was used in place of trypsin. The chymotryptic fragments of human alphaB-crystallin produced in the presence and absence of ATP were analyzed using liquid chromatography-tandem mass spectrometry (LC-MS/MS). Seven chymotryptic cleavage sites, Trp(60), Phe(61), Phe(75), Phe(84), Phe(113), Phe(118), and Tyr(122), located near or within the core alpha-crystallin domain, were shielded from the action of chymotrypsin in the presence of ATP. Chemically similar analogs of ATP were less protective than ATP against proteolysis by trypsin or chymotrypsin. ATP had no effect on the enzymatic activity of trypsin and the K(m) for trypsin was 0.031 mM in the presence of ATP and 0.029 mM in the absence of ATP. The results demonstrated an ATP-dependent structural modification in the core alpha-crystallin domain conserved in nearly all identified small heat-shock proteins that act as molecular chaperones.     

Three-dimensional structure of porcine procarboxypeptidase B: a structural basis of its inactivity.

Procarboxypeptidase B is converted to enzymatically active carboxypeptidase B by limited proteolysis catalysed by trypsin, removing the long N-terminal activation segment of 95 amino acids. The three-dimensional crystal structure of procarboxypeptidase B from porcine pancreas has been determined at 2.3 A resolution and refined to a crystallographic R-factor of 0.169. The functional determinants of its enzymatic inactivity and of its activation by limited proteolysis have thus been unveiled. The activation segment folds in a globular region with an open sandwich antiparallel-alpha antiparallel-beta topology and in a C terminal alpha-helix which connects it to the enzyme moiety. The globular region (A7-A82) shields the preformed active site, and establishes specific interactions with residues important for substrate recognition. AspA41 forms a salt bridge with Arg145, which in active carboxypeptidase binds the C-terminal carboxyl group of substrate molecules. The connecting region occupies the putative extended substrate binding site. The scissile peptide bond cleaved by trypsin during activation is very exposed. Its cleavage leads to the release of the activation segment and to exposure of the substrate binding site. An open-sandwich folding has been observed in a number of other proteins and protein domains. One of them is the C-terminal fragment of L7/L12, a ribosomal protein from Escherichia coli that displays a topology similar to the activation domain of procarboxypeptidase.     

Characterization of guanosine diphospho-D-mannose dehydrogenase from Pseudomonas aeruginosa. Structural analysis by limited proteolysis.

Alginate is believed to be a major virulence factor in the pathogenicity of Pseudomonas aeruginosa in the lungs of patients suffering from cystic fibrosis. Guanosine diphospho-D-mannose dehydrogenase (GDPmannose dehydrogenase, EC 1.1.1.132) is a key enzyme in the alginate biosynthetic pathway which catalyzes the oxidation of guanosine diphospho-D-mannose (GDP-D-mannose) to GDP-D-mannuronic acid. In this paper, we report the structural analysis of GMD by limited proteolysis using three different proteases, trypsin, submaxillary Arg-C protease, and chymotrypsin. Treatment of GMD with these proteases indicated that the amino-terminal part of this enzyme may fold into a structural domain with an apparent molecular mass of 25-26 kDa. Multiple proteolytic cleavage sites existed at the carboxyl-terminal end of this domain, indicating that this segment may represent an exposed region of the protein. Initial proteolysis also generated a carboxyl-terminal fragment with an apparent molecular mass of 16-17 kDa which was further digested into smaller fragments by trypsin and chymotrypsin. The proteolytic cleavage sites were localized by partial amino-terminal sequencing of the peptide fragments. Arg-295 was identified as the initial cleavage site for trypsin and Tyr-278 for chymotrypsin. Catalytic activity of GMD was totally abolished by the initial cleavage. However, binding of the substrate, GDP-D-mannose, increased stability toward proteolysis and inhibited the loss of enzyme activity. GMP and GDP (guanosine 5'-mono- and diphosphates) also blocked the initial cleavage, but NAD and mannose showed no effect. These results suggest that binding of the guanosine moiety at the catalytic site of GMD may induce a conformational change that reduces the accessibility of the cleavage sites to proteases. Binding of [14C]GDP-D-mannose to the amino-terminal domain was not affected by the removal of the carboxyl-terminal 16-kDa fragment. Furthermore, photoaffinity labeling of GMD with [32P]arylazido-beta-alanine-NAD followed by proteolysis demonstrated that the radioactive NAD was covalently linked to the amino-terminal domain. These observations imply that the amino-terminal domain (25-26 kDa) contains both the substrate and cofactor binding sites. However, the carboxyl-terminal fragment (16-17 kDa) may possess amino acid residues essential for catalysis. Thus, proteolysis had little effect on substrate binding, but totally eliminated catalysis. These biochemical data are in complete agreement with amino acid sequence analysis for the existence of substrate and cofactor sites of GMD. A linear peptide map of GMD was constructed for future structure/functional studies.     

Domain structure analysis of elongation factor-3 from Saccharomyces cerevisiae by limited proteolysis and differential scanning calorimetry.

Elongation-factor-3 (EF-3) is an essential factor of the fungal protein synthesis machinery. In this communication the structure of EF-3 from Saccharomyces cerevisiae is characterized by differential scanning calorimetry (DSC), ultracentrifugation, and limited tryptic digestion. DSC shows a major transition at a relatively low temperature of 39 degrees C, and a minor transition at 58 degrees C. Ultracentrifugation shows that EF-3 is a monomer; thus, these transitions could not reflect the unfolding or dissociation of a multimeric structure. EF-3 forms small aggregates, however, when incubated at room temperature for an extended period of time. Limited proteolysis of EF-3 with trypsin produced the first cleavage at the N-side of Gln775, generating a 90-kDa N-terminal fragment and a 33-kDa C-terminal fragment. The N-terminal fragment slowly undergoes further digestion generating two major bands, one at approximately 75 kDa and the other at approximately 55 kDa. The latter was unusually resistant to further tryptic digestion. The 33-kDa C-terminal fragment was highly sensitive to tryptic digestion. A 30-min tryptic digest showed that the N-terminal 60% of EF-3 was relatively inaccessible to trypsin, whereas the C-terminal 40% was readily digested. These results suggest a tight structure of the N-terminus, which may give rise to the 58 degrees C transition, and a loose structure of the C-terminus, giving rise to the 39 degrees C transition. Three potentially functional domains of the protein were relatively resistant to proteolysis: the supposed S5-homologous domain (Lys102-Ile368), the N-terminal ATP-binding cassette (Gly463-Lys622), and the aminoacyl-tRNA-synthase homologous domain (Glu820-Gly865). Both the basal and ribosome-stimulated ATPase activities were inactivated by trypsin, but the ribosome-stimulated activity was inactivated faster.     

Functional domains of the ClpA and ClpX molecular chaperones identified by limited proteolysis and deletion analysis

Escherichia coli ClpA and ClpX are ATP-dependent protein unfoldases that each interact with the protease, ClpP, to promote specific protein degradation. We have used limited proteolysis and deletion analysis to probe the conformations of ClpA and ClpX and their interactions with ClpP and substrates. ATP gamma S binding stabilized ClpA and ClpX such that that cleavage by lysylendopeptidase C occurred at only two sites. Both proteins were cleaved within in a loop preceding an alpha-helix-rich C-terminal domain. Although the loop varies in size and composition in Clp ATPases, cleavage occurred within and around a conserved triad, IG(F/L). Binding of ClpP blocked this cleavage, and prior cleavage at this site rendered both ClpA and ClpX defective in binding and activating ClpP, suggesting that this site is involved in interactions with ClpP. ClpA was also cut at a site near the junction of the two ATPase domains, whereas the second cleavage site in ClpX lay between its N-terminal and ATPase domains. ClpP did not block cleavage at these other sites. The N-terminal domain of ClpX dissociated upon cleavage, and the remaining ClpXDeltaN remained as a hexamer, associated with ClpP, and expressed ATPase, chaperone, and proteolytic activity. A truncated mutant of ClpA lacking its N-terminal 153 amino acids also formed a hexamer, associated with ClpP, and expressed these activities. We propose that the N-terminal domains of ClpX and ClpA lie on the outside ring surface of the holoenzyme complexes where they contribute to substrate binding or perform a gating function affecting substrate access to other binding sites and that a loop on the opposite face of the ATPase rings stabilizes interactions with ClpP and is involved in promoting ClpP proteolytic activity.     

Site-directed mutations within the core "alpha-crystallin" domain of the small heat-shock protein, human alphaB-crystallin, decrease molecular chaperone functions.

Site-directed mutagenesis was used to evaluate the effects on structure and function of selected substitutions within and N-terminal to the core "alpha-crystallin" domain of the small heat-shock protein (sHsp) and molecular chaperone, human alphaB-crystallin. Five alphaB-crystallin mutants containing single amino acid substitutions within the core alpha-crystallin domain displayed a modest decrease in chaperone activity in aggregation assays in vitro and in protecting cell viability of E. coli at 50 degrees C in vivo. In contrast, seven alphaB-crystallin mutants containing substitutions N-terminal to the core alpha-crystallin domain generally resembled wild-type alphaB-crystallin in chaperone activity in vitro and in vivo. Size-exclusion chromatography, ultraviolet circular dichroism spectroscopy and limited proteolysis were used to evaluate potential structural changes in the 12 alphaB-crystallin mutants. The secondary, tertiary and quaternary structures of mutants within and N-terminal to the core alpha-crystallin domain were similar to wild-type alphaB-crystallin. SDS-PAGE patterns of chymotryptic digestion were also similar in the mutant and wild-type proteins, indicating that the mutations did not introduce structural modifications that altered the exposure of proteolytic cleavage sites in alphaB-crystallin. On the basis of the similarities between the sequences of human alphaB-crystallin and the sHsp Mj HSP16.5, the only sHsp for which there exists high resolution structural information, a three-dimensional model for alphaB-crystallin was constructed. The mutations at sites within the core alpha-crystallin domain of alphaB-crystallin identify regions that may be important for the molecular chaperone functions of sHsps.     

Probing the H-protein-induced conformational change and the function of the N-terminal region of Escherichia coli T-protein of the glycine cleavage system by limited proteolysis

T-protein, a component of the glycine cleavage system, catalyzes a tetrahydrofolate-dependent reaction. Previously, we reported a conformational change of Escherichia coli T-protein upon interacting with E. coli H-protein (EH), showing an important role for the N-terminal region of the T-protein in the interaction. To further investigate the T-protein catalysis, the wild type (ET) and mutants were subjected to limited proteolysis. ET was favorably cleaved at Lys(81), Lys(154), Lys(288), and Lys(360) by lysylendopeptidase and the cleavages at Lys(81) and Lys(288) were strongly prevented by EH. Although ET was highly resistant to trypsinolysis, the mutant with an N-terminal 7-residue deletion (ETDelta7) was quite susceptible and instantly cleaved at Arg(16) accompanied by the rapid degradation of the resulting C-terminal fragment, indicating that the cleavage at Arg(16) is the trigger for the C-terminal fragmentation. EH showed no protection from the N-terminal cleavage, although substantial protection from the C-terminal fragmentation was observed. The replacement of Leu(6) of ET with alanine resulted in a similar sensitivity to trypsin as ETDelta7. These results suggest that the N-terminal region of ET functions as a molecular "hasp" to hold ET in the compact form required for the proper association with EH. Leu(6) seems to play a central role in the hasp function. Interestingly, Lys(360) of ET was susceptible to proteolysis even after the stabilization of the entire molecule of ET by EH, indicating its location at the surface of the ET-EH complex. Together with the buried position of Lys(81) in the complex and previous results on folate binding sites, these results suggest the formation of a folate-binding cavity via the interaction of ET with EH. The polyglutamyl tail of the folate substrate may be inserted into the bosom of the cavity leaving the pteridine ring near the entrance of the cavity in the context of the catalytic reaction.     

Lipoprotein lipases from cow, guinea-pig and man. Structural characterization and identification of protease-sensitive internal regions

Lipoprotein lipases from human, bovine or guinea-pig milk were purified, judged for domain relationships by characterization of sites sensitive to proteases, and structurally compared. The subunit of human lipoprotein lipase migrated slightly slower than those of bovine or guinea-pig lipoprotein lipases on sodium dodecyl sulfate/polyacrylamide gel electrophoresis. Bovine lipoprotein lipase is known to be a dimer of two non-covalently linked subunits of equal size, and the lipases from all three sources now yielded homogeneous N-terminal amino acid sequences (followed for 15-27 residues). The results indicate that the two subunits are identical. Bovine lipoprotein lipase had two additional N-terminal residues, Asp-Arg, compared to the human and guinea-pig enzymes, and the next two positions revealed residue differences, but further on homologies were extensive between all three enzymes as far as presently traced. Exposure of bovine lipoprotein lipase to trypsin led to production of three fragments (T1, T2a, and T2b), suggesting cleavage at exposed segments delineating domain borders. Time studies gave no evidence for precursor-product relationships between the fragments, and prolonged digestion did not lead to further cleavage. Fragments T2a and T2b had the same N-terminal sequence as intact lipase. Fragment T1 revealed a new sequence, and represents the C-terminal half of the molecule. Plasmin caused a similar cleavage as trypsin, whereas thrombin, factor Xa, and tissue plasminogen activator did not cleave the enzyme. Chymotrypsin cleaved off a relatively small fragment from the C-terminal of the molecule, after which exposure to trypsin still resulted in cleavage at the same sites as in intact lipase. Tryptic cleavage of guinea-pig lipoprotein lipase yielded two fragments. One had a similar size as bovine fragment T2b; the other had a similar size as bovine fragment T1 and an N-terminal sequence homologous with that of T1. Thus, trypsin recognizes the same unique site in guinea-pig lipoprotein lipase as in the bovine enzyme. This confirms the conclusion that this segment is the border between two domains in the subunit. The binding site for heparin was retained after both tryptic and chymotryptic cleavages and was identified as localized in the C-terminal part of the molecule.     

Characterization of the catalytic subunit of an anion pump

The ArsA protein, the 63-kDa catalytic subunit of an oxyanion-translocating ATPase, was purified by successive chromatography using Q-Sepharose, red agarose, and phenyl-Sepharose to a specific activity in excess of 1 mumol of ATP hydrolyzed per min per mg of protein. ATPase activity was dependent on the presence of the oxyanionic substrates. Inhibitors of other classes of ion-translocating ATPases had no effect on ArsA ATPase activity, including N,N'-dicyclohexyl-carbodiimide, azide, vanadate, and nitrate. The apparent Km for ATP was determined to be 0.13 mM. The optimal pH range for ATP hydrolysis was 7.5 to 7.8. ATPase activity required Mg2+ at a molar ratio of 2 ATP:1 Mg2+. Limited proteolysis by trypsin was used to study conformational changes produced upon binding of substrates to the ArsA protein. In the absence of substrates, the ArsA protein was rapidly cleaved by trypsin to a major product of 30 kDa. ATP was partially protected from trypsin digestion, while the anionic substrate antimonite alone had no effect on proteolysis. Combination of the two substrates nearly completely protected the ArsA protein from proteolysis. Proteolytic cleavage correlated with loss of anion-stimulated ATPase activity and substrate protection from cleavage correlated with retention of activity. These results demonstrate that ATP and antimonite together produce a conformational change which is different from that of the ArsA protein in the presence of either substrate alone and suggest interaction between the oxyanion and ATP binding sites.     

Identification and characterization of two functional domains in cytochrome P-450BM-3, a catalytically self-sufficient monooxygenase induced by barbiturates in Bacillus megaterium

In a previous publication (Narhi, L. O. and Fulco, A. J. (1986) J. Biol. Chem. 261, 7160-7169) we described the characterization of a soluble 119,000-dalton P-450 cytochrome (P-450BM-3) that was induced by barbiturates in Bacillus megaterium. This single polypeptide contained 1 mol each of FAD and FMN/mol of heme and, in the presence of NADPH and O2, catalyzed the oxygenation of long-chain fatty acids without the aid of any other protein. We have now utilized limited trypsin proteolysis in the presence of substrate to cleave P-450BM-3 into two polypeptides (domains) of about 66,000 and 55,000 daltons. The 66-kDa domain contains both FAD and FMN but no heme, reduces cytochrome c in the presence of NADPH, and is derived from the C-terminal portion of P-450BM-3. The 55-kDa domain is actually a mixture of three discrete peptides (T-I, T-II, and T-III) separable by high performance liquid chromatography. All three contain heme and show a P-450 absorption peak in the presence of CO and dithionite. The major component, T-I (Mr = 55 kDa), binds fatty acid substrate and has an N-terminal amino acid sequence identical to that of intact P-450BM-3, an indication that this domain constitutes the N-terminal portion of the 119-kDa protein. T-II (54 kDa) is the same as T-I except that it is missing the first nine N-terminal amino acids and does not bind substrate. T-III (Mr = 53.5 kDa) has lost the first 15 N-terminal residues and does not bind substrate. Since trypsin digestion of P-450BM-3 carried out in the absence of substrate yields T-II and T-III but no T-I, it appears that 1 or more residues of the first nine N-terminal amino acids of this protein are intimately involved in substrate binding. Although both the heme- and flavin-containing tryptic peptides retain their original half-reactions, fatty acid monooxygenase activity cannot be reconstituted after proteolysis, and the two domains, once separated, show no affinity for each other. In most respects, the reductase domain of P-450BM-3 more closely resembles the mammalian microsomal P-450 reductases than it does any known bacterial protein.     

Structural stability of GlcV, the nucleotide binding domain of the glucose ABC transporter of Sulfolobus solfataricus

GlcV is the nucleotide binding domain of the ABC-type glucose transporter of the hyperthermoacidophile Sulfolobus solfataricus. GlcV consists of two domains, an N-terminal domain containing the typical nucleotide binding-fold and a C-terminal beta-barrel domain with unknown function. The unfolding and structural stability of the wild-type (wt) protein and three mutants that are blocked at different steps in the ATP hydrolytic cycle were studied. The G144A mutant is unable to dimerize, while the E166A and E166Q mutants are defective in ATP hydrolysis and dimer dissociation. Unfolding of the wt GlcV and G144A GlcV occurred with a single transition, whereas the E166A and E166Q mutants showed a second transition at a higher melting temperature indicating an increased stability of the ABCalpha/beta subdomain. The structural stability of GlcV was increased in the presence of nucleotides suggesting that the transition corresponds to the unfolding of the NBD domain. Unfolding of the C-terminal domain appears to occur at temperatures above the unfolding of the NBD which coincides with the aggregation of the protein. Analysis of the domain organization of GlcV by trypsin digestion demonstrates cleavage of the NBD domain into three fragments, while nucleotides protect against proteolysis. The cleaved GlcV protein retained the ability to bind nucleotides and to dimerize. These data indicate that the wt GlcV NBD domain unfolds as a single domain protein, and that its stability is modified by mutations in the glutamate after the Walker B motif and by nucleotide binding.     

Limited proteolysis as a probe of the conformation and nucleic acid binding regions of nucleolin.

Nucleolin, also called protein C23, is a RNA-associated protein implicated in the early stages of ribosome assembly. To study the general conformation and map the nucleic acid binding regions, rat nucleolin was subjected to limited proteolysis using trypsin and chymotrypsin in the presence or absence of poly(G). The cleavage sites were classified according to their locations in the three putative domains: the highly polar amino-terminal domain, the central nucleic acid binding domain, which contains four 90-residue repeats, and the carboxyl-terminal domain, which is rich is glycine, dimethylarginine, and phenylalanine. The most labile sites were found in basic segments of the amino-terminal domain. This region was stabilized by Mg2+. At low enzyme concentrations, cleavage by trypsin or chymotrypsin in the amino-terminal domain was enhanced by poly(G). Trypsin produced a relatively stable 48-kDa fragment containing the central and carboxyl-terminal domains. The enhanced cleavage suggests that binding of nucleic acid by the central domain alters the conformation of the amino-terminal domain, exposing sites to proteolytic cleavage. At moderate enzyme concentrations, the 48-kDa fragment was protected by poly(G) against tryptic digestion. At the highest enzyme concentrations, both enzymes cleaved near the boundaries between repeats 2, 3, and 4 with some sites protected by poly(G), suggesting that the repeats themselves form compact units. The carboxyl-terminal domain was resistant to trypsin but was cleaved by chymotrypsin either in the presence or in the absence of poly(G), indicating exposure of some phenylalanines in this region. These studies provide a general picture of the topology of nucleolin and suggest that the nucleic acid binding region communicates with the amino-terminal domain.     

The N-terminal arm of small heat shock proteins is important for both chaperone activity and substrate specificity

Small heat shock proteins (sHSPs) are a ubiquitous class of molecular chaperones that interacts with substrates to prevent their irreversible insolubilization during denaturation. How sHSPs interact with substrates remains poorly defined. To investigate the role of the conserved C-terminal alpha-crystallin domain versus the variable N-terminal arm in substrate interactions, we compared two closely related dodecameric plant sHSPs, Hsp18.1 and Hsp16.9, and four chimeras of these two sHSPs, in which all or part of the N-terminal arm was switched. The efficiency of substrate protection and formation of sHSP-substrate complexes by these sHSPs with three different model substrates, firefly luciferase, citrate synthase, and malate dehydrogenase (MDH) provide new insights into sHSP/substrate interactions. Results indicate that different substrates have varying affinities for different domains of the sHSP. For luciferase and citrate synthase, the efficiency of substrate protection was determined by the identity of the N-terminal arm in the chimeric proteins. In contrast, for MDH, efficient protection clearly required interactions with the alpha-crystallin domain in addition to the N-terminal arm. Furthermore, we show that sHSP-substrate complexes with varying stability and composition can protect substrate equally, and substrate protection is not correlated with sHSP oligomeric stability for all substrates. Protection of MDH by the dimeric chimera composed of the Hsp16.9 N-terminal arm and Hsp18.1 alpha-crystallin domain supports the model that a dimeric form of the sHSP can bind and protect substrate. In total, results demonstrate that sHSP-substrate interactions are complex, likely involve multiple sites on the sHSP, and vary depending on substrate.     

Recognition, targeting, and hydrolysis of the lambda O replication protein by the ClpP/ClpX protease.

It has previously been established that sequences at the C termini of polypeptide substrates are critical for efficient hydrolysis by the ClpP/ClpX ATP-dependent protease. We report for the bacteriophage lambda O replication protein, however, that N-terminal sequences play the most critical role in facilitating proteolysis by ClpP/ClpX. The N-terminal portion of lambda O is degraded at a rate comparable with that of wild type O protein, whereas the C-terminal domain of O is hydrolyzed at least 10-fold more slowly. Consistent with these results, deletion of the first 18 amino acids of lambda O blocks degradation of the N-terminal domain, whereas proteolysis of the O C-terminal domain is only slightly diminished as a result of deletion of the C-terminal 15 amino acids. We demonstrate that ClpX retains its capacity to bind to the N-terminal domain following removal of the first 18 amino acids of O. However, ClpX cannot efficiently promote the ATP-dependent binding of this truncated O polypeptide to ClpP, the catalytic subunit of the ClpP/ClpX protease. Based on our results with lambda O protein, we suggest that two distinct structural elements may be required in substrate polypeptides to enable efficient hydrolysis by the ClpP/ClpX protease: (i) a ClpX-binding site, which may be located remotely from substrate termini, and (ii) a proper N- or C-terminal sequence, whose exposure on the substrate surface may be induced by the binding of ClpX.     

Use of fragments of hirudin to investigate thrombin-hirudin interaction

Site-directed mutagenesis was used to create hirudin in which Asn52 was replaced by methionine. Cyanogen bromide cleavage at this unique methionine resulted in two fragments. These fragments have been used to study the kinetic mechanism of the inhibition of thrombin by hirudin and to identify areas of the two molecules which interact with each other. The binding of the C-terminal fragment (residues 53-65) to thrombin resulted in a decrease in the Michaelis constant for the substrate D-phenylalanylpipecolylarginyl-p-nitroanilide (DPhe-Pip-Arg-NH-Ph). The N-terminal fragment (residues 1-52) was a competitive inhibitor of thrombin. There was a small amount of cooperativity in the binding of the two fragments. Whereas hirudin and its C-terminal fragment protected alpha-thrombin against cleavage by trypsin, the N-terminal fragment did not. Hirudin and the N-terminal fragment completely prevented the cleavage of alpha-thrombin by pancreatic elastase while the C-terminal fragment afforded a lesser degree of protection. The results of these experiments with trypsin and elastase are discussed in terms of interaction areas on thrombin and hirudin.     

Limited proteolysis of Escherichia coli cytidine 5'-triphosphate synthase. Identification of residues required for CTP formation and GTP-dependent activation of glutamine hydrolysis.

Cytidine 5'-triphosphate synthase catalyses the ATP-dependent formation of CTP from UTP using either ammonia or l-glutamine as the source of nitrogen. When glutamine is the substrate, GTP is required as an allosteric effector to promote catalysis. Limited trypsin-catalysed proteolysis, Edman degradation, and site-directed mutagenesis were used to identify peptide bonds C-terminal to three basic residues (Lys187, Arg429, and Lys432) of Escherichia coli CTP synthase that were highly susceptible to proteolysis. Lys187 is located at the CTP/UTP-binding site within the synthase domain, and cleavage at this site destroyed all synthase activity. Nucleotides protected the enzyme against proteolysis at Lys187 (CTP > ATP > UTP > GTP). The K187A mutant was resistant to proteolysis at this site, could not catalyse CTP formation, and exhibited low glutaminase activity that was enhanced slightly by GTP. K187A was able to form tetramers in the presence of UTP and ATP. Arg429 and Lys432 appear to reside in an exposed loop in the glutamine amide transfer (GAT) domain. Trypsin-catalyzed proteolysis occurred at Arg429 and Lys432 with a ratio of 2.6 : 1, and nucleotides did not protect these sites from cleavage. The R429A and R429A/K432A mutants exhibited reduced rates of trypsin-catalyzed proteolysis in the GAT domain and wild-type ability to catalyse NH3-dependent CTP formation. For these mutants, the values of kcat/Km and kcat for glutamine-dependent CTP formation were reduced approximately 20-fold and approximately 10-fold, respectively, relative to wild-type enzyme; however, the value of Km for glutamine was not significantly altered. Activation of the glutaminase activity of R429A by GTP was reduced 6-fold at saturating concentrations of GTP and the GTP binding affinity was reduced 10-fold. This suggests that Arg429 plays a role in both GTP-dependent activation and GTP binding.