Enzymatic activities of human cytomegalovirus maturational protease assemblin and its precursor (pPR, pUL80a) are comparable: [corrected] maximal activity of pPR requires self-interaction through its scaffolding domain

Herpesviruses encode an essential, maturational serine protease whose catalytic domain, assemblin (28 kDa), is released by self-cleavage from a 74-kDa precursor (pPR, pUL80a). Although there is considerable information about the structure and enzymatic characteristics of assemblin, a potential pharmacologic target, comparatively little is known about these features of the precursor. To begin studying pPR, we introduced five point mutations that stabilize it against self-cleavage at its internal (I), cryptic (C), release (R), and maturational (M) sites and at a newly discovered "tail" (T) site. The resulting mutants, called ICRM-pPR and ICRMT-pPR, were expressed in bacteria, denatured in urea, purified by immobilized metal affinity chromatography, and renatured by a two-step dialysis procedure and by a new method of sedimentation into glycerol gradients. The enzymatic activities of the pPR mutants were indistinguishable from that of IC-assemblin prepared in parallel for comparison, as determined by using a fluorogenic peptide cleavage assay, and approximated rates previously reported for purified assemblin. The percentage of active enzyme in the preparations was also comparable, as determined by using a covalent-binding suicide substrate. An unexpected finding was that, in the absence of the kosmotrope Na2SO4, optimal activity of pPR requires interaction through its scaffolding domain. We conclude that although the enzymatic activities of assemblin and its precursor are comparable, there may be differences in how their catalytic sites become fully activated.     

Chemical rescue of I-site cleavage in living cells and in vitro discriminates between the cytomegalovirus protease, assemblin, and its precursor, pUL80a

Chemical rescue is an established approach that offers a directed strategy for designing mutant enzymes in which activity can be restored by supplying an appropriate exogenous compound. This method has been used successfully to study a broad range of enzymes in vitro, but its application to living systems has received less attention. We have investigated the feasibility of using chemical rescue to make a conditional-lethal mutant of the cytomegalovirus (CMV) maturational protease. The 28-kDa CMV serine protease, assemblin, has a Ser-His-His catalytic triad and an internal (I) cleavage site near its midpoint. We found that imidazole can restore I-site cleavage to mutants inactivated by replacing the critical active site His with Ala or with Gly, which rescued better. Comparable rescue was observed for counterpart mutants of the human and simian CMV assemblin homologs and occurred in both living cells and in vitro. Cleavage was established to be at the correct site by amino acid sequencing and proceeded at approximately 11%/h in bacteria and approximately 30%/h in vitro. The same mutations were unresponsive to chemical rescue in the context of the assemblin precursor, pUL80a. This catalytic difference distinguishes the two forms of the CMV protease.     

Independently cloned halves of cytomegalovirus assemblin, An and Ac, can restore proteolytic activity to assemblin mutants by intermolecular complementation.

Herpesviruses encode an essential serine proteinase called assemblin that is responsible for cleaving the precursor assembly protein during the process of capsid formation. In cytomegalovirus (CMV), assemblin undergoes autoproteolysis at an internal (I) site located near the middle of the molecule. I-site cleavage converts the enzyme to an active two-chain form consisting of the subunits An and Ac. We have recently shown that the recombinant An and Ac subunits can spontaneously associate within eukaryotic cells to yield active two-chain proteinase. This finding indicates that the subunits are able to independently assume their correct functional conformations and led us to test whether they are capable of intermolecular complementation. This was done by coexpressing inactive mutant (point, deletion, and insertion) forms of assemblin together with the wild-type subunit (either An or Ac) corresponding to the domain of assemblin that was mutated. Results of these experiments showed that both An and Ac are able to rescue the enzymatic activity of assemblin mutants. I-site cleavage of the mutated assemblin occurred during complementation but was not absolutely required, as shown by effective complementation of inactive assemblins with noncleavable I sites. We have also shown that intermolecular complementation can rescue the activity of an inactive mutant full-length proteinase precursor and can occur between different species of CMV (e.g., human CMV subunit can rescue activity of mutant simian CMV assemblin). These results indicate that assemblin is able to form active multimeric structures that may be of functional importance.     

Cytomegalovirus assemblin: the amino and carboxyl domains of the proteinase form active enzyme when separately cloned and coexpressed in eukaryotic cells.

The cytomegalovirus (CMV) serine proteinase assemblin is synthesized as a precursor that undergoes three principal autoproteolytic cleavages. Two of these are common to the assemblin homologs of all herpes group viruses: one at the maturational site near the carboxyl end of the precursor and another at the release site near the midpoint of the precursor. Release-site cleavage frees the proteolytic amino domain, assemblin, from the nonproteolytic carboxyl domain of the precursor. In CMV, a third autoproteolytic cleavage at an internal site divides assemblin into an amino subunit (An) and a carboxyl subunit (Ac) of approximately the same size that remain associated as an active "two-chain" enzyme. We have cloned the sequences encoding An and Ac as separate genes and expressed them by transfecting human cells with recombinant plasmids and by infecting insect cells with recombinant baculoviruses. When An and Ac from either simian CMV or human CMV were coexpressed in human or insect cells, active two-chain assemblin was formed. This finding demonstrates that An and Ac do not require synthesis as single-chain assemblin to fold and associate correctly in these eukaryotic systems, and it suggests that they may be structurally, if not functionally, distinct domains. An interaction between the independently expressed An and Ac subunits was demonstrated by coimmunoprecipitation experiments, and efforts to disrupt the complex indicate that the subunit interaction is hydrophobic. Cell-based cleavage assays of the two-chain assemblin formed from independently expressed An and Ac also indicate that (i) its specificity for both CMV and herpes simplex virus native substrates is similar to that of single-chain assemblin, (ii) R-site cleavage is not essential for the activity of two-chain recombinant assemblin, and (iii) the human CMV and simian CMV An and Ac recombinant subunits are functionally interchangeable.     

Phosphorylation of Simian Cytomegalovirus Assembly Protein Precursor (pAPNG.5) and Proteinase Precursor (pAPNG1): Multiple Attachment Sites Identified, Including Two Adjacent Serines in a Casein Kinase II Consensus Sequence

The assembly protein precursor (pAP) of cytomegalovirus (CMV), and its homologs in other herpesviruses, functions at several key steps during the process of capsid formation. This protein, and the genetically related maturational proteinase, is distinguished from the other capsid proteins by posttranslational modifications, including phosphorylation. The objective of this study was to identify sites at which pAP is phosphorylated so that the functional significance of this modification and the enzyme(s) responsible for it can be determined. In the work reported here, we used peptide mapping, mass spectrometry, and site-directed mutagenesis to identify two sets of pAP phosphorylation sites. One is a casein kinase II (CKII) consensus sequence that contains two adjacent serines, both of which are phosphorylated. The other site(s) is in a different domain of the protein, is phosphorylated less frequently than the CKII site, does not require preceding CKII-site phosphorylation, and causes an electrophoretic mobility shift when phosphorylated. Transfection/expression assays for proteolytic activity showed no gross effect of CKII-site phosphorylation on the enzymatic activity of the proteinase or on the substrate behavior of pAP. Evidence is presented that both the CKII sites and the secondary sites are phosphorylated in virus-infected cells and plasmid-transfected cells, indicating that these modifications can be made by a cellular enzyme(s). Apparent compartmental differences in phosphorylation of the CKII-site (cytoplasmic) and secondary-site (nuclear) serines suggest the involvement of more that one enzyme in these modifications.     

Cytomegalovirus protein substrates are not cleaved by the herpes simplex virus type 1 proteinase.

The herpesvirus maturational proteinase, assemblin, is made as a precursor that undergoes at least two autoproteolytic cleavages--one in a sequence toward its carboxyl end, called the maturational (M) site, and one in a sequence toward its midpoint, called the release (R) site. The M- and R-site sequences are both well conserved among the herpesvirus proteinase homologs, suggesting that the proteinase of one herpesvirus might be able to cleave the substrates of another. To test this possibility, we cloned and expressed in human cells the long (i.e., full-length open reading frame of proteinase gene) and short (i.e., proteolytic domain, assemblin) forms of the proteinase from human and simian cytomegalovirus (HCMV and SCMV, respectively) and from herpes simplex virus type 1 (HSV-1), as well as the genes for their respective assembly protein precursor substrates. Data from cotransfections of these proteinase genes with appropriate homologous and heterologous substrates showed that although the SCMV and HCMV enzymes cleaved the M-sites of the assembly protein substrates of all three viruses and an SCMV R-site substrate, the HSV-1 proteinase cleaved only its own substrate. This finding demonstrates that the substrate specificity properties of the HSV-1 enzyme differ from those of the two CMV enzymes.     

Cytomegalovirus assemblin (pUL80a): cleavage at internal site not essential for virus growth; proteinase absent from virions

The human cytomegalovirus (HCMV) maturational proteinase is synthesized as an enzymatically active 74-kDa precursor that cleaves itself at four sites. Two of these, called the maturational (M) and release (R) sites, are conserved in the homologs of all herpesviruses. The other two, called the internal (I) and cryptic (C) sites, have recognized consensus sequences only among cytomegalovirus (CMV) homologs and are located in the 28-kDa proteolytic portion of the precursor, called assemblin. I-site cleavage cuts assemblin in half without detected effect on its enzymatic behavior in vitro. To investigate the requirement for this cleavage during virus infection, we used the CMV-bacterial artificial chromosome system (E. M. Borst, G. Hahn, U. H. Koszinowski, and M. Messerle, J. Virol. 73:8320-8329, 1999) to construct a virus encoding a mutant I site (Ala143 to Val) intended to be blocked for cleavage. Characterizations of the resulting mutant (i) confirmed the presence of the mutation in the viral genome and the inability of the mutant virus to effect I-site cleavage in infected cells; (ii) determined that the mutation has no gross effect on the rate of virus production or on the amounts of extracellular virions, noninfectious enveloped particles (NIEPs), and dense bodies; (iii) established that assemblin and its cleavage products are present in NIEPs but are absent from CMV virions, an apparent difference from what is found for virions of herpes simplex virus; and (iv) showed that the 23-kDa protein product of C-site cleavage is more abundant in mutant virus-than in wild-type virus-infected cells and NIEPs. We conclude that the production of infectious CMV requires neither I-site cleavage of assemblin nor the presence of assemblin in the mature virion.     

Herpesvirus proteinase: site-directed mutagenesis used to study maturational, release, and inactivation cleavage sites of precursor and to identify a possible catalytic site serine and histidine.

The cytomegalovirus maturational proteinase is synthesized as a precursor that undergoes at least three processing cleavages. Two of these were predicted to be at highly conserved consensus sequences--one near the carboxyl end of the precursor, called the maturational (M) site, and the other near the middle of the precursor, called the release (R) site. A third less-well-conserved cleavage site, called the inactivation (I) site, was also identified near the middle of the human cytomegalovirus 28-kDa assemblin homolog. We have used site-directed mutagenesis to verify all three predicted sequences in the simian cytomegalovirus proteinase, and have shown that the proteinase precursor is active without cleavage at these sites. We have also shown that the P4 tyrosine and the P2 lysine of the R site were more sensitive to substitution than the other R- and M-site residues tested: substitution of alanine for P4 tyrosine at the R site severely reduced cleavage at that site but not at the M site, and substitution of asparagine for lysine at P2 of the R site reduced M-site cleavage and nearly eliminated I-site cleavage but had little effect on R-site cleavage. With the exception of P1' serine, all R-site mutations hindered I-site cleavage, suggesting a role for the carboxyl end of assemblin in I-site cleavage. Pulse-chase radiolabeling and site-directed mutagenesis indicated that assemblin is metabolically unstable and is degraded by cleavage at its I site. Fourteen amino acid substitutions were also made in assemblin, the enzymatic amino half of the proteinase precursor. Among those tested, only 2 amino acids were identified as essential for activity: the single absolutely conserved serine and one of the two absolutely conserved histidines. When the highly conserved glutamic acid (Glu22) was substituted, the proteinase was able to cleave at the M and I sites but not at the R site, suggesting either a direct (e.g., substrate recognition) or indirect (e.g., protein conformation) role for this residue in determining substrate specificity.     

Different cleavage specificities of RNases III from Rhodobacter capsulatus and Escherichia coli.

23S rRNA in Rhodobacter capsulatus shows endoribonuclease III (RNase III)-dependent fragmentation in vivo at a unique extra stem-loop extending from position 1271 to 1331. RNase III is a double strand (ds)-specific endoribonuclease. This substrate preference is mediated by a double-stranded RNA binding domain (dsRBD) within the protein. Although a certain degree of double strandedness is a prerequisite, the question arises what structural features exactly make this extra stem-loop an RNase III cleavage site, distinguishing it from the plethora of stem-loops in 23S rRNA? We used RNase III purified from R.capsulatus and Escherichia coli, respectively, together with well known substrates for E.coli RNase III and RNA substrates derived from the special cleavage site in R.capsulatus 23S rRNA to study the interaction between the Rhodobacter enzyme and the fragmentation site. Although both enzymes are very similar in their amino acid sequence, they exhibit significant differences in binding and cleavage of these in vitro substrates.     

Nuclear localization sequences in cytomegalovirus capsid assembly proteins (UL80 proteins) are required for virus production: inactivating NLS1, NLS2, or both affects replication to strikingly different extents

Scaffolding proteins of spherical prokaryotic and eukaryotic viruses have critical roles in capsid assembly. The primary scaffolding components of cytomegalovirus, called the assembly protein precursor (pAP, pUL80.5) and the maturational protease precursor (pPR, pUL80a), contain two nuclear localization sequences (NLS1 and NLS2), at least one of which is required in coexpression experiments to translocate the major capsid protein (MCP, pUL85) into the nucleus. In the work reported here, we have mutated NLS1 and NLS2, individually or together, in human cytomegalovirus (HCMV, strain AD169) bacmid-derived viruses to test their effects on virus replication. Consistent with results from earlier transfection/coexpression experiments, both single-mutant bacmids gave rise to infectious virus but the double mutant did not. In comparisons with the wild-type virus, both mutants showed slower cell-to-cell spread; decreased yields of infectious virus (3-fold lower for NLS1(-) and 140-fold lower for NLS2(-)); reduced efficiency of pAP, pPR, and MCP nuclear translocation (sixfold lower for NLS1(-) and eightfold lower for NLS2(-)); increased amounts of a 120-kDa MCP fragment; and reduced numbers of intranuclear capsids. All effects were more severe for the NLS2(-) mutant than the NLS1(-) mutant, and a distinguishing feature of cells infected with the NLS2(-) mutant was the accumulation of large, UL80 protein-containing structures within the nucleus. We conclude that these NLS assist in the nuclear translocation of MCP during HCMV replication and that NLS2, which is unique to the betaherpesvirus UL80 homologs, may have additional involvements during replication.     

Identification of the ATP-binding domain of vaccinia virus thymidine kinase

Although small in size (20 kDa), the vaccinia virus (VV) thymidine kinase protein (EC 2.7.1.21 TK) is a relatively complex enzyme which must contain domains involved in binding both substrates (ATP and thymidine) and a feedback inhibitor (dTTP), as well as sequences directing the association of individual protein monomers into a functional tetrameric enzyme. Alignment of predicted amino acid sequences of the thymidine kinase genes from a variety of sources was used to identify highly conserved regions as a first step toward locating potential regions housing essential domains. A conserved domain (domain I) near the amino terminus of VV TK protein had characteristics consistent with a nucleotide-binding site. Analysis of the nucleotide substrate specificity of VV TK indicated that ATP acts as the major phosphate donor for thymidine phosphorylation while GTP, CTP, and UTP were inefficient substrates. Site-directed mutagenesis was performed on domain I to generate 11 mutant enzymes. Comparison of the wild-type and mutant proteins with regard to enzyme activity revealed that two of the mutant enzymes, T18 and S19, exhibited enhanced enzyme activity (3.73-fold and 1.35-fold, respectively) relative to the control. The other mutations introduced led to greatly reduced levels of enzyme activity which correlated with a reduced or altered ability of the mutant enzymes to bind ATP as determined by ATP-agarose affinity chromatography. Wild-type VV TK bound to an ATP affinity column could also be eluted with dTTP. Glycerol gradient separation of wild-type TK in the presence or absence of dTTP indicated that dissociation of the tetrameric complex was not the means by which enzymatic inhibition was achieved. Taken together, these results suggest that (i) domain I (amino acids 11-22) of the VV TK corresponds to the ATP-binding site, and (ii) that dTTP is able to interfere with ATP binding, either directly or indirectly, and thereby inhibit enzymatic activity without dissociating the native enzyme.     

Cleavage of human cytomegalovirus protease pUL80a at internal and cryptic sites is not essential but enhances infectivity

The cytomegalovirus (CMV) maturational protease, assemblin, contains an "internal" (I) cleavage site absent from its homologs in other herpesviruses. Blocking this site for cleavage did not prevent replication of the resulting I(-) mutant virus. However, cells infected with the I(-) virus showed increased amounts of a fragment produced by cleavage at the nearby "cryptic" (C) site, suggesting that its replication may bypass the I-site block by using the C site as an alternate cleavage pathway. To test this and further examine the biological importance of these cleavages, we constructed two additional virus mutants-one blocked for C-site cleavage and another blocked for both I- and C-site cleavage. Infectivity comparisons with the parental wild-type virus showed that the I(-) mutant was the least affected for virus production, whereas infectivity of the C(-) mutant was reduced by approximately 40% and when both sites were blocked virus infectivity was reduced by nearly 90%, providing the first evidence that these cleavages have biological significance. We also present and discuss evidence suggesting that I-site cleavage destabilizes assemblin and its fragments, whereas C-site cleavage does not.     

The role of the membrane-spanning domain of type I signal peptidases in substrate cleavage site selection

Type I signal peptidase (SPase I) catalyzes the cleavage of the amino-terminal signal sequences from preproteins destined for cell export. Preproteins contain a signal sequence with a positively charged n-region, a hydrophobic h-region, and a neutral but polar c-region. Despite having no distinct consensus sequence other than a commonly found c-region "Ala-X-Ala" motif preceding the cleavage site, signal sequences are recognized by SPase I with high fidelity. Remarkably, other potential Ala-X-Ala sites are not cleaved within the preprotein. One hypothesis is that the source of this fidelity is due to the anchoring of both the SPase I enzyme (by way of its transmembrane segment) and the preprotein substrate (by the h-region in the signal sequence) in the membrane. This limits the enzyme-substrate interactions such that cleavage occurs at only one site. In this work we have, for the first time, successfully isolated Bacillus subtilis type I signal peptidase (SipS) and a truncated version lacking the transmembrane domain (SipS-P2). With purified full-length as well as truncated constructs of both B. subtilis and Escherichia coli (Lep) SPase I, in vitro specificity studies indicate that the transmembrane domains of either enzyme are not important determinants of in vitro cleavage fidelity, since enzyme constructs lacking them reveal no alternate site processing of pro-OmpA nuclease A substrate. In addition, experiments with mutant pro-OmpA nuclease A substrate constructs indicate that the h-region of the signal peptide is also not critical for substrate specificity. In contrast, certain mutants in the c-region of the signal peptide result in alternate site cleavage by both Lep and SipS enzymes.     

Subunit assembly and mode of DNA cleavage of the type III restriction endonucleases EcoP1I and EcoP15I

DNA cleavage by type III restriction endonucleases requires two inversely oriented asymmetric recognition sequences and results from ATP-dependent DNA translocation and collision of two enzyme molecules. Here, we characterized the structure and mode of action of the related EcoP1I and EcoP15I enzymes. Analytical ultracentrifugation and gel quantification revealed a common Res(2)Mod(2) subunit stoichiometry. Single alanine substitutions in the putative nuclease active site of ResP1 and ResP15 abolished DNA but not ATP hydrolysis, whilst a substitution in helicase motif VI abolished both activities. Positively supercoiled DNA substrates containing a pair of inversely oriented recognition sites were cleaved inefficiently, whereas the corresponding relaxed and negatively supercoiled substrates were cleaved efficiently, suggesting that DNA overtwisting impedes the convergence of the translocating enzymes. EcoP1I and EcoP15I could co-operate in DNA cleavage on circular substrate containing several EcoP1I sites inversely oriented to a single EcoP15I site; cleavage occurred predominantly at the EcoP15I site. EcoP15I alone showed nicking activity on these molecules, cutting exclusively the top DNA strand at its recognition site. This activity was dependent on enzyme concentration and local DNA sequence. The EcoP1I nuclease mutant greatly stimulated the EcoP15I nicking activity, while the EcoP1I motif VI mutant did not. Moreover, combining an EcoP15I nuclease mutant with wild-type EcoP1I resulted in cutting the bottom DNA strand at the EcoP15I site. These data suggest that double-strand breaks result from top strand cleavage by a Res subunit proximal to the site of cleavage, whilst bottom strand cleavage is catalysed by a Res subunit supplied in trans by the distal endonuclease in the collision complex.     

Human cytomegalovirus proteinase: candidate glutamic acid identified as third member of putative active-site triad.

The human cytomegalovirus (HCMV) proteinase is synthesized as a 709-amino-acid precursor that undergoes at least three autoproteolytic cleavages. The mature proteinase, called assemblin, is one of the products of autoproteolysis and is composed of the first 256 amino acids of the precursor. HCMV assemblin and its homologs in other herpes group viruses contain five highly conserved domains (CD1 through CD5). An absolutely conserved serine in CD3 has been shown by site-directed mutagenesis of the simian cytomegalovirus (SCMV) and herpes simplex virus type 1 (HSV-1) enzymes and by inhibitor affinity labeling of the HSV-1 and HCMV enzymes to be the active-site nucleophile of assemblin. An absolutely conserved histidine in CD2 has also been demonstrated by site-directed mutagenesis of the SCMV and HSV-1 enzymes to be essential for proteolytic activity and has been proposed to be a second member of the catalytic triad of this serine proteinase. We report here the use of site-directed mutagenesis to investigate the active-site amino acids of HCMV assemblin. Substitutions were made for the CD3 serine and CD2 histidine residues implicated as active-site components, and for other amino acids whose influence on enzyme activity was of interest. The mutant proteinases were tested in a transient transfection assay for their ability to cleave their natural substrate, the assembly protein precursor. Results of these experiments verified that HCMV CD3 serine (Ser-132) and CD2 histidine (His-63) are essential for proteolytic activity and identified a glutamic acid (Glu-122) within CD3 that is also essential for proteolytic activity and may be conserved among all herpesvirus assemblin homologs. We suggest that CD3 Glu-122, CD3 Ser-132, and CD2 His-63 constitute the active-site triad of this serine proteinase.     

Glutamine-181 is crucial in the enzymatic activity and substrate specificity of human endoplasmic-reticulum aminopeptidase-1

ERAP-1 (endoplasmic-reticulum aminopeptidase-1) is a multifunctional enzyme with roles in the regulation of blood pressure, angiogenesis and the presentation of antigens to MHC class I molecules. Whereas the enzyme shows restricted specificity toward synthetic substrates, its substrate specificity toward natural peptides is rather broad. Because of the pathophysiological significance of ERAP-1, it is important to elucidate the molecular basis of its enzymatic action. In the present study we used site-directed mutagenesis to identify residues affecting the substrate specificity of human ERAP-1 and identified Gln(181) as important for enzymatic activity and substrate specificity. Replacement of Gln(181) by aspartic acid resulted in a significant change in substrate specificity, with Q181D ERAP-1 showing a preference for basic amino acids. In addition, Q181D ERAP-1 cleaved natural peptides possessing a basic amino acid at the N-terminal end more efficiently than did the wild-type enzyme, whereas its cleavage of peptides with a non-basic amino acid was significantly reduced. Another mutant enzyme, Q181E, also revealed some preference for peptides with a basic N-terminal amino acid, although it had little hydrolytic activity toward the synthetic peptides tested. Other mutant enzymes, including Q181N and Q181A ERAP-1s, revealed little enzymatic activity toward synthetic or peptide substrates. These results indicate that Gln(181) is critical for the enzymatic activity and substrate specificity of ERAP-1.     

Comparison of the substrate specificity of the human T-cell leukemia virus and human immunodeficiency virus proteinases.

Human T-cell leukemia virus type-1 (HTLV-1) is associated with a number of human diseases. Based on the therapeutic success of human immunodeficiency virus type 1 (HIV-1) PR inhibitors, the proteinase (PR) of HTLV-1 is a potential target for chemotherapy. To facilitate the design of potent inhibitors, the subsite specificity of HTLV-1 PR was characterized and compared to that of HIV-1 PR. Two sets of substrates were used that contained single amino-acid substitutions in peptides representing naturally occurring cleavage sites in HIV-1 and HTLV-1. The original HIV-1 matrix/capsid cleavage site substrate and most of its substituted peptides were not hydrolyzed by the HTLV-1 enzyme, except for those with hydrophobic residues at the P4 and P2 positions. On the other hand, most of the peptides representing the HTLV-1 capsid/nucleocapsid cleavage site were substrates of both enzymes. A large difference in the specificity of HTLV-1 and HIV-1 proteinases was demonstrated by kinetic measurements, particularly with regard to the S4 and S2 subsites, whereas the S1 subsite appeared to be more conserved. A molecular model of the HTLV-1 PR in complex with this substrate was built, based on the crystal structure of the S9 mutant of Rous sarcoma virus PR, in order to understand the molecular basis of the enzyme specificity. Based on the kinetics of shortened analogs of the HTLV-1 substrate and on analysis of the modeled complex of HTLV-1 PR with substrate, the substrate binding site of the HTLV-1 PR appeared to be more extended than that of HIV-1 PR. Kinetic results also suggested that the cleavage site between the capsid and nucleocapsid protein of HTLV-1 is evolutionarily optimized for rapid hydrolysis.     

Mutagenesis of Ala290, which modulates substrate subsite affinity at the catalytic interface of dimeric ThMA

The goal of this study was to develop a maltose-producing enzyme using protein engineering and to clarify the relation between the substrate specificity and the structure of the substrate-binding site of dimeric maltogenic amylase isolated from Thermus (ThMA). Ala290 at the interface of ThMA dimer in the vicinity of the substrate-binding site was substituted with isoleucine, which may cause a structural change due to its bulky side chain. TLC analysis of the action pattern of the mutant ThMA-A290I, using maltooligosaccharides as substrates, revealed that ThMA-A290I used maltotetraose to produce mostly maltose, while wild-type ThMA produced glucose as well as maltose. The wild-type enzyme eventually hydrolyzed the maltose produced from maltotetraose into glucose, but the mutant enzyme did not. For both enzymes, the cleavage frequency of the glycosidic bond of maltooligosaccharides was the highest at the second bond from the reducing end. The mutant ThMA had a much higher Km value for maltose than the wild-type ThMA. The kinetic parameter, kcat/Km) of ThMA-A290I for maltose was 48 times less than that of wild-type ThMA, suggesting that the subsite affinity and hydrolysis mode of ThMA were modulated by the residue located at the interface of ThMA dimer near the active site. The conformational rearrangement in the catalytic interface probably led to the change in the substrate binding affinity of the mutant ThMA. Our results provide basic information for the enzymatic preparation of high-maltose syrup.     

S-adenosyl methionine prevents promiscuous DNA cleavage by the EcoP1I type III restriction enzyme

DNA cleavage by the type III restriction endonuclease EcoP1I was analysed on circular and catenane DNA in a variety of buffers with different salts. In the presence of the cofactor S-adenosyl methionine (AdoMet), and irrespective of buffer, only substrates with two EcoP1I sites in inverted repeat were susceptible to cleavage. Maximal activity was achieved at a Res2Mod2 to site ratio of approximately 1:1 yet resulted in cleavage at only one of the two sites. In contrast, the outcome of reactions in the absence of AdoMet was dependent upon the identity of the monovalent buffer components, in particular the identity of the cation. With Na+, cleavage was observed only on substrates with two sites in inverted repeat at elevated enzyme to site ratios (>15:1). However, with K+ every substrate tested was susceptible to cleavage above an enzyme to site ratio of approximately 3:1, including a DNA molecule with two directly repeated sites and even a DNA molecule with a single site. Above an enzyme to site ratio of 2:1, substrates with two sites in inverted repeat were cleaved at both cognate sites. The rates of cleavage suggested two separate events: a fast primary reaction for the first cleavage of a pair of inverted sites; and an order-of-magnitude slower secondary reaction for the second cleavage of the pair or for the first cleavage of all other site combinations. EcoP1I enzymes mutated in either the ATPase or nuclease motifs did not produce the secondary cleavage reactions. Thus, AdoMet appears to play a dual role in type III endonuclease reactions: Firstly, as an allosteric activator, promoting DNA association; and secondly, as a "specificity factor", ensuring that cleavage occurs only when two endonucleases bind two recognition sites in a designated orientation. However, given the right conditions, AdoMet is not strictly required for DNA cleavage by a type III enzyme.     

Specificity assay of serine proteinases by reverse-phase high-performance liquid chromatography analysis of competing oligopeptide substrate library

In this paper we present an HPLC method developed for quick activity and specificity analysis of serine proteinases. The method applies a carefully designed peptide library in which the individual components differ only at the potential cleavage site for enzymes. The library has seven members representing seven different cleavage sites and it offers substrates for both trypsin and chymotrypsin-like enzymes. The individual peptide substrates compete for the proteinase during the enzymatic reaction. The reaction is monitored by RP-HPLC separation of the components. We describe the systematic design of the competitive peptide substrate library and the test of the system with eight different serine proteinases. The specificity profiles of the investigated enzymes as determined by the new method were essentially identical to the ones reported in the literature, verifying the ability of the system to characterize substrate specificity. The tests also demonstrated that the system could detect even subtle specificity differences of two isoforms of an enzyme. In addition to recording qualitative specificity profiles, data provided by the system can be analyzed quantitatively, yielding specificity constant values. This method can be a useful tool for quick analysis of uncharacterized gene products as well as new forms of enzymes generated by protein engineering.