©1995 by The American Society for Biochemistry and Molecular Biology, Inc.
Single-chain Recombinant Human Cytomegalovirus Protease
ACTIVITY AGAINST ITS NATURAL PROTEIN SUBSTRATE AND FLUOROGENIC PEPTIDE SUBSTRATES (*)

(Received for publication, May 22, 1995)

Christopher Pinko Stephen A. Margosiak Darin Vanderpool Jeanine C. Gutowski Brad Condon Chen-Chen Kan (§)

From the Molecular Biology/Biochemistry and Biophysics Groups, Agouron Pharmaceuticals, Inc., San Diego, California 92121

ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS AND DISCUSSION
FOOTNOTES
ACKNOWLEDGEMENTS
REFERENCES

ABSTRACT

We report here the production of active recombinant single-chain human cytomegalovirus protease in Escherichia coli and development of a continuous assay for this protease. In order to produce the human cytomegalovirus (HCMV) protease for structural studies and accurate kinetic analysis, mutation of alanine 143 at an internal cleavage site was introduced to prevent autoproteolysis. The resulting soluble 29-kDa A143Q protease was purified to homogeneity as a stable single-chain protein by hydrophobic interaction and ionic-exchange chromatography. The in vivo protein substrate, assembly protein precursor, was also expressed and purified for activity studies. To develop a continuous protease assay, fluorescent synthetic peptide substrates similar to the cleavage sequence P5 to P5` of the maturation site containing anthranilic acid and nitrotyrosine as a resonance energy transfer donor-acceptor pair were designed. Purified HCMV A143Q protease cleaved the recombinant assembly protein precursor with K and k values of 3.0 ± 1.0 µM and 13.3 ± 1.6 min. The K for peptide substrates is at least 45-fold higher than for the natural protein substrate, but the k values are similar. A sensitive assay was developed using fluorescent peptide substrates, which can detect nM HCMV protease activity.


INTRODUCTION

The Herpesviridae family includes several human pathogenic species such as herpes simplex virus 1 and 2 (HSV-1 and -2), (^1)cytomegalovirus (CMV), Epstein-Barr virus, and varicella-zoster virus. Viral infection by HCMV is very common, and 40-80% of population becomes infected by HCMV before adulthood(1) . HCMV is a serious pathogen in immunocompromised individuals, especially those patients with AIDS, receiving organ or bone marrow transplants, or undergoing cancer chemotherapy or steroid therapy. CMV can cause damage in many organs, including the lung, retina, liver, and gastrointestinal tract. Ganciclovir and foscarnet are inhibitors of viral DNA polymerase and have been used to treat HCMV infections; however, they have the undesired side effects of nucleotide analogs(2) .

All members of the Herpesviridae family are similar at both the morphological and genomic levels. Herpesviruses contain a DNA genome of over 100 kilobases, an icosahedral capsid, and a lipoprotein envelope. The viral genome replicates inside the nucleus of infected cells and is then packaged into an intermediate capsid and followed by the acquisition of a nuclear membrane envelope and release of the virion from the infected cell. The HSV-1 assembly protein precursor, ICP35, is a major component of the intermediate capsid but is absent in mature virions(3, 4, 5) . During virion maturation, ICP35 undergoes proteolytic processing to generate the mature assembly protein that lacks approximately 20 amino acids from the carboxyl terminus. An HSV-1 temperature-sensitive mutant (ts1201) that it is defective in the processing of ICP35 has been reported by Preston et al.(6) . This mutant virus fails to package progeny viral DNA into virions at the nonpermissive temperature, and only empty capsids accumulate. This ts lesion was mapped to the UL26 ORF. The UL26 ORF overlaps with the ICP35 producing UL26.5 ORF, and these two ORFs are 3`-coterminal(6) . Liu and Roizman (7) reported that the product of the UL26 ORF is an 80-kDa protease that is responsible for the proteolytic processing of ICP35 protein. The UL26.5 promoter lies within the UL26 ORF. Translation initiation of ICP35 begins at methionine codon 307 of the 80-kDa protease. The amino acid sequence of the ICP35 is therefore identical to the carboxyl-terminal region of the 80-kDa protease. During viral replication, the 80-kDa protease cleaves both itself and ICP35 at a common maturation site approximately 5 kDa from the shared carboxyl terminus. The 80-kDa protease also undergoes a unique autoproteolytic cleavage at a release site between amino acid residues 246 and 247, resulting in the release of a 29-kDa catalytic domain. These findings, together with the recent work done with the UL26 null mutant virus (8) suggested that herpes proteases play a critical role in viral particle maturation and are attractive targets for anti-viral chemotherapy.

The human CMV UL80 ORF was reported to share homology with HSV-1 UL26 ORF (9) as well as with the assembly protein nested genes ORF of the simian cytomegalovirus(10, 11) . Gibson and co-workers (12, 13) have demonstrated that the carboxyl-terminal region of the HCMV UL80 encodes a protein that is proteolytically processed in a similar fashion as the HSV-1 ICP35. By transient transfection assays, the simian CMV assembly protein nested gene-1 ORF was shown to encode a 590-amino acid protease whose amino-terminal 249 residues possessed proteolytic activity. This region also contains sequence motifs that are highly homologous to proteases of other herpesviruses(14) . More recently, Baum et al.(15) used [S]methionine labeling of Escherichia coli harboring expression plasmids containing UL80 ORF sequence and found an 85-kDa protease that underwent autoproteolysis in vivo and produced a set of proteins with molecular masses of 50, 29, 16, 13, and 5 kDa(15) . The three cleavage sites of the 85-kDa protease were identified as follows: (i) a maturation (M-) site at the carboxyl terminus, which shares sequence identity with the cleavage site of assembly protein precursor, (ii) an internal release (R-) site, which yielded the 29-kDa amino-terminal catalytic domain and a 50-kDa carboxyl-terminal fragment, and (iii) an internal (I-) site that lies within the 29-kDa catalytic domain between Ala-143 and Ala-144.

The design of inhibitors for the HCMV protease requires a detailed understanding of its structure and catalytic mechanism. The major difficulty in obtaining pure and stable enzyme for such studies has been due to autoproteolysis, which results in cleavage within the catalytic domain. We have expressed the stable single-chain active HCMV A143Q protease, purified it to homogeneity for crystallographic studies, and developed a sensitive continuous protease assay using fluorogenic peptides as substrates for the kinetic studies.


EXPERIMENTAL PROCEDURES

Cloning and Expression of the HCMV Protease Catalytic Domain

DNA isolated from cultured cells infected with HCMV strain AD169 was used as the template for polymerase chain reaction amplification of the coding sequences for both the protease catalytic domain (amino acids 1-256) and assembly protein precursor. Oligonucleotide primers were synthesized based on the published HCMV UL80 ORF sequences(9) . All amplifications were performed with the Taq polymerase, the Perkin-Elmer/Cetus Gene Amp DNA kit, and the standard procedure(16) . Amplified DNA fragments were separately digested with NdeI and BglII prior to ligation into corresponding sites of the expression phagemid pMGH4(17) . Substitutions of the Ala-143 within the protease catalytic domain was introduced using Kunkel's invitro oligonucleotide-directed mutagenesis method(18) . The resulting constructs, pCMVP1-5 encoding the protease catalytic domain and pPAP-6 encoding the assembly protein precursor, were confirmed by both restriction enzyme mapping and nucleotide sequencing(19) . E. coli strain BL21(DE3) (Novagen; (20) ) was used as the expression host to produce both recombinant HCMV protease and assembly protein precursor. The bacterial cells harboring expression constructs were cultured in 2 times YT medium (16 g/liter Bacto-tryptone, 10 g/liter yeast extract, 5 g/liter NaCl) at 37 °C containing 100 µg/ml ampicillin. Cultures grown to mid-log phase were induced with 0.2 mM isopropyl-1-thio-beta-D-galactopyranoside. 3 h after induction, the cells were harvested by ultrafiltration (Pelicon, Millipore) and centrifugation. Small samples of total lysates were prepared from cultures and subjected to SDS-polyacrylamide gel electrophoresis and stained with Coomassie Brilliant Blue(21) .

Purification of HCMV A143Q Mutant Protease Catalytic Domain

All purification steps were carried out at 4 °C. Approximately 30 g (wet weight) of induced bacterial cell pellet was suspended in 150 ml of lysis buffer (40 mM Tris-HCl, pH 8.0, 500 mM NaCl, 2 mM DTT) and lysed by passes through a microfluidizer (Microfluidics Corp). The lysate was centrifuged at 35,000 rpm for 50 min in Ti 45 rotor at 4 °C to pellet any insoluble material. After adding NaCl to a final concentration of 2.75 M, the soluble lysate was loaded on a phenyl-Sepharose hydrophobic interaction column, and eluted with a 2.75-0 M NaCl gradient in 20 mM Tris-HCl, pH 8.0, 1 mM DTT. Fractions containing the A143Q protease were pooled and dialyzed against 20 mM Tris-HCl, pH 8.0, 1 mM DTT. The dialyzed pool was then loaded onto a 75-ml Q-Sepharose column (Pharmacia Biotech Inc.), which was equilibrated in DT buffer (1 mM DTT and 20 mM Tris-HCl, pH 8.0), followed by a 180 ml of DT buffer wash and eluted with a 675 ml of linear gradient of 0-300 mM NaCl in DT buffer. Fractions containing HCMV protease were pooled, dialyzed against DM buffer (1 mM DTT, 20 mM Mes, pH 6.0) and loaded onto a 75-ml S-Sepharose column (Pharmacia) equilibrated with the same buffer. The column was washed with 120 ml of DM buffer and eluted with a 675-ml linear gradient of 0-50 mM NaCl in DM buffer. Fractions containing the protease were eluted at 15-25 mM NaCl and yielded approximately 150 mg of the purified protease. The amino-terminal sequence of purified HCMV protease was determined after separation by SDS-PAGE and electroblotting onto Immobilon-P transfer membrane (Millipore). Automated Edman degradation was carried out on an Applied Biosystems model 447A pulse-liquid sequenator(22) . The free thiol groups of A143Q protease was determined by Ellman titration(23) . Purified A143Q protease was dialyzed extensively to remove DTT. Each 1-ml sample containing 2 nmol of purified A143Q protease in 0.1 M phosphate buffer, pH 7.3, 1 mM EDTA, with or without denaturation in 6 M guanidinium chloride, was incubated with 50 µl of 3 mM 5,5`-dithionitrobenzoic acid at room temperature. The release of nitrothiobenzoate was monitored by the increase in absorbance at 412 nm from which the molar concentration of free thiols was calculated based on the molar extinction coefficients of nitrothiobenzoate at 412 nm being 13,700 and 14,150 M cm, respectively, in the presence or absence of 6 M guanidinium chloride.

Purification of HCMV Assembly Protein Precursor

The soluble lysate was prepared from induced bacterial culture as described above except for the addition of the following protease inhibitors: 1 µg/ml aprotinin, 1 µg/ml leupeptin, 0.6 µg/ml pepstatin A, 1 mM phenylmethanesulfonyl fluoride, and 1 mM EDTA. The soluble fraction of the E. coli lysate was dialyzed against 10 mM Tris pH 8.0, 1 mM DTT, centrifuged, and loaded onto a 20-ml Q-Sepharose column equilibrated in the same buffer. Flow-through fractions were collected, dialyzed against PD buffer (1 mM sodium phosphate buffer, pH 6.9, 1 mM DTT), and loaded onto a 20-ml hydroxylapatite column (Bio-Rad). The column was washed with 60 ml of PD buffer and eluted with a 300-ml linear gradient of 0-500 mM MgCl(2) in PD buffer. Fractions containing the assembly protein precursor were pooled and concentrated to at least 0.65 mg/ml by ultrafiltration using a 10-kDa cut-off polysulfone membrane (Millipore). Ammonium sulfate was added to the concentrated protein solution to a final concentration of 1.62 M and centrifuged at 30,000 times g for 30 min. The protein pellet was resuspended in one-fourth of the initial volume and precipitated by adding potassium chloride to 1.7 M and centrifugation. The final protein pellet, which contained assembly protein precursor, was resuspended in 10 mM HEPES, pH 7.0, 1 mM DTT.

Natural Protein Substrate Cleavage Assays

Purified assembly protein precursor was incubated at 37 °C with purified HCMV A143Q protease in 10 mM HEPES, pH 7.0, and 6 mM DTT without additional co-solvents. After incubation, sample mixtures were boiled immediately and subjected to SDS-PAGE. After Coomassie Blue staining, intensities of both 45-kDa assembly protein precursor and the 40-kDa cleaved assembly protein were determined by densitometric tracing using a Molecular Dynamics personal densitometer.

Determination of kand K for the Natural Protein Substrate by Saturation Analysis

A143Q protease at 58 nM and assembly protein precursor substrate at 1.08-8.6 µM were incubated as described above, and samples were taken at 0, 2, 4, 6, and 8 min. Each sample contained 100 ng (3.5 pmol) of A143Q protease and 2.5, 5, 10, or 20 µg (65-520 pmol) of assembly protein precursor. These samples were subjected to SDS-PAGE and Coomassie Blue staining as described above. Potential nonlinearity in densitometric tracing was eliminated by electrophoresing amounts equivalent of 2.5 µg of substrate from all samples. Known amounts of protein were also electrophoresed with each series of samples as a control for densitometric tracing. The percentage of remaining uncleaved assembly protein precursor was calculated from the densitometric intensity and plotted against time for each substrate concentration. Data from each substrate concentration were fit to a single exponential decay curve using KaleidaGraph data analysis software (Abelbeck Software). The time required for 10% substrate cleavage was calculated from the fitted curves, and reaction rates were then calculated as pmol of substrate cleaved per second. The K(m) and k values were determined by plotting the reaction rates versus substrate concentrations and fitting to the Michaelis-Menten equation. Concentrations of HCMV protease were determined by its UV absorbance at 280 nm using a mg/ml extinction coefficient of 0.989 cm. All protein present was assumed to be active.

HPLC-Based Peptide Assay

The peptide A6376 (Table 1) was synthesized by American Peptide Co., Sunnyvale, CA. The standard 100-µl cleavage reaction contained 25 mM MOPS, pH 7.2, 50% glycerol, 1 mM DTT, 2% Me(2)SO, 200 µM peptide substrate, 200-300 nM HCMV protease and was performed at 25 °C. The reaction progressed for only 15 min so that the initial rate could be determined for the cleavage reaction while less than 5% of the substrate was cleaved. The reaction was stopped by adding glacial acetic acid to a final concentration of 2%. The reaction mixture was then subjected to reverse phase/perfusion HPLC using a POROS R2H column (Perceptive Biosystems). Products generated by cleavage were resolved from substrate, and other components with a 1-12% acetonitrile gradient in 0.1% trifluoroacetic acid/H(2)0. Product peak areas were determined and used to calculate initial rates.



Continuous RET Fluorogenic Assay

PK03 and AM1013 (Table 1) are internally quenched fluorogenic peptide substrates that were synthesized by Enzyme Products Systems, Dublin, CA, and American Peptide Co., respectively. The anthranilic acid group emits fluorescence at 420 nm when excited with 320 nm monochromatic light. The fluorescence of the anthranilic acid group is significantly quenched by resonance energy transfer to the nitrotyrosine residue (24) . When the peptide is cleaved at the A/S scissile bond, an increase in the observed fluorescence of the anthranilic acid is obtained. The standard 600-µl cleavage reaction was performed at 25 °C in a microfluorescence cuvette containing 25 mM MOPS, pH 7.2, 50% glycerol, 1 mM DTT, 2% Me(2)SO (same as for HPLC assay), and 20 µM peptide substrate. The concentration of HCMV protease was 80 nM so that less than 5% of the substrate was cleaved over the 5-min reaction time. The initial rates were calculated as the increase in fluorescence versus time.

Determination of kK(m)for Peptide Substrates by Progress Curve Analysis

For the fluorogenic assay, the concentrations of HCMV protease, PK03, and AM1013, were 0.5-1.0, 20, and 20 µM, respectively. The continuous change in fluorescence was monitored. For the HPLC-based assay, the enzyme concentration varied at 1-4 µM, and both the substrate peptide A6376 and product peptide peak areas were monitored. Progress curves were allowed to proceed to completion and were fit to an equation describing a first order single exponential decay using KaleidaGraph. k/K(m) was calculated by k/K(m) = k/[HCMV protease].

Determination of kand K(m)for Peptide Substrates by Saturation Analysis

The individual values of k and K(m) were determined by measuring initial rates with variable substrate concentrations. The initial rates were fitted to the nonlinear form of the Michaelis-Menten equation using KaleidaGraph. The fluorogenic assay could not be used for this experiment since high concentrations of substrate caused inner filter effects. This effect erroneously decreases the apparent rate. Reverse-phase HPLC was therefore used to analyze product formation from PK03 and A6376 after being cleaved by the HCMV protease.


RESULTS AND DISCUSSION

Initially, the expression of the wild-type HCMV protease was attempted with the T7 expression phagemid pMGH4 (17) in the E. coli strain BL21(DE3). By using this expression system, wild-type HCMV protease could only be accumulated as an insoluble intact 29-kDa protein (Fig. 1A) at 42 °C. Upon refolding, proteolytic degradation of the 29-kDa protease into 16- and 13-kDa fragments started to occur as the protease concentration was increased to 2 mg/ml (data not shown). The same 16- and 13-kDa proteins were observed in induced E. coli lysate prepared from 37 °C cultures. These degradation fragments were previously seen in metabolically labeled E. coli lysates by Baum et al.(15) , and they were identified as the products of a cleavage event occurring between Ala-143 and Ala-144 at the I-site. Other groups have recently reported expression and purification of the wild-type HCMV protease catalytic domain either from inclusion bodies (25, 26) or as a two-chain protease due to autoproteolytic processing at the I-site (27) . As a consequence of this autoproteolytic breakdown, preparation of active single-chain wild-type HCMV protease at high concentrations required for crystallographic studies is not feasible.


Figure 1: Expression of the HCMV protease catalytic domain in E. coli. Each sample of total crude lysate was prepared from E. coli equivalent to 0.2 A, boiled in the reducing sample buffer, and loaded on a 16% SDS-polyacrylamide gel that was stained with Coomassie Brilliant Blue after electrophoresis. + and - denote the induced and uninduced culture lysates, respectively. Arrowhead marks positions of two proteolytic fragments and the intact HCMV protease catalytic domain. LaneM, molecular mass markers. Molecular masses of markers are indicated in kDa. A, expression of the wild-type HCMV protease. Lanes1 and 2 and lanes 3 and 4 are uninduced (-) and induced (+) cultures bearing pCMVP1-5 grown at 37 and 42 °C after induction, respectively. B, expression of the HCMV proteases with various substitutions of Ala-143 at 37 °C. Lane1 is the lysate from an induced culture bearing pCMVP1-5 with the A143Q mutation. Lanes2-11 are pairs of uninduced and induced cultures with A143G, A143N, A143S, A143T, or an A143V mutation. Lane12 is the induced culture with the wild-type Ala-143 residue.



Ala-143 of the I-site lies between the conserved sequence motifs CD1 and CD2 among herpes proteases. Deletion of the corresponding region in the simian CMV resulted in a stable protease and autolytic cleavage at the I-site was not observed. This mutated protease could still cleave its own assembly protein precursor at the M-site with approximately the same efficiency as the wild-type enzyme(28) . In light of this observation, we mutated the alanine 143 residue of the HCMV protease to test if this mutation might confer resistance to autoproteolysis but still retain wild-type proteolytic activity. Mutations at Ala-143 to Gly, Gln, Asn, Ser, Thr, and Val were made. Based on their autoproteolytic activities in crude lysates (see Fig. 1B), mutants can be divided into two groups. Group I mutants, A143G and A143S, still produced 16- and 13-kDa fragments. Autoproteolytic activities observed with the group I mutants suggests that the I-site prefers amino acid residues with small side chains at P1 position. All group II mutants: A143Q, A143N, A143V, and A143T, produced intact 29-kDa protease abundantly at 37 °C in E. coli. During the preparation of this manuscript, a similar approach was reported by Holwerda et al.(27) . They disrupted the I-site by changing valine 141 to alanine (VEAA to AEAA) and recovered active 30-kDa one-chain enzyme. In our expression construct, the histidine tag used by Holwerda et al.(27) for purification purposes was avoided so as to obtain crystallographic information reflective of the native HCMV protease without unnecessary changes.

We chose to purify the HCMV A143Q protease and to test whether this mutant protease retains proteolytic activity. Purification included phenol-Sepharose, Q- and S-Sepharose chromatographic steps (Fig. 2). HCMV A143Q protease was stable during purification and at 4 °C for up to 1 month at less than 10 mg/ml. The amino-terminal amino acid sequencing of purified A143Q showed the correct sequence of HCMV protease with 80% of the protease retaining methionine as the first residue, while the remaining 20% had the initiation methionine cleaved off and thus started at the second residue threonine. Ellman titration showed that only three of the five sulfhydryl groups in the native A143Q protease were reactive against 5,5`-dithionitrobenzoic acid. After denaturation, the number of sulfhydryl groups/protease molecule accessible to 5,5`-dithionitrobenzoic acid reaction increased from 3 to 4.5. These results indicate that no disulfide bonds exist in the HCMV protease catalytic domain and that two of the five cysteines may be buried in the hydrophobic core of the native protein. The reported thiol content of wild-type HCMV protease after exposure to 2% SDS is 4.9 ± 0.5 (26) , which is similar to the 4.5 thiol groups found in the denatured A143Q protease. It was therefore concluded that as an intracellular enzyme, all five cysteines in the catalytic domain of HCMV protease are kept in the reduced form. HCMV protease, unlike papain, does not have cysteine as an active site residue. However, it was observed by us and also reported by others that the HCMV A143Q protease loses activity rapidly in the absence of DTT (26) and that DTT prevented the loss of activity. It is clear that the cysteine residues need to be reduced for maximal activity. Therefore, during experiments of extended duration, DTT was supplied exogenously at 1-10 mM. However, for experiments with short incubation time, the DTT at 8-12 µM carried over from the enzyme stock was adequate.


Figure 2: Purification of the HCMV protease catalytic domain A143Q from the E. coli lysate. LaneM, molecular mass markers. Lanes1 and 2, total lysates from uninduced(-) and induced (+) E. coli grown at 37 °C; lane3, the soluble fraction of induced E. coli lysate; lanes4 and 5, Q- and S-Sepharose pool containing the A143Q protease.



The same expression phagemid pMGH4 was used to express the HCMV assembly protein precursor in E. coli. The recombinant assembly protein precursor was soluble in the lysate. Purification included Q-Sepharose, hydroxylapatite column chromatography, and salt precipitations, and yielded assembly protein precursor with sufficient purity for enzymatic studies. During purification, it was observed that assembly protein precursor requires 5-10 mM DTT to maintain its solubility. Amino-terminal sequencing confirmed the 45-kDa assembly protein precursor identity and showed that its initiation methionine was removed. The enzymatic activity of purified A143Q was initially demonstrated using the assembly protein precursor. As shown in Fig. 3, 2.5 µg (1.08 µM) of substrate could be completely processed within 10 min by 0.5 µg (0.29 µM) of purified A143Q protease. In the assay buffer, 6 mM DTT was included to optimize the A143Q protease activity and to keep the assembly protein precursor soluble. Cleavage of the assembly protein precursor by the A143Q protease was quantitated by densitometric tracing of the full-length 45-kDa and processed 40-kDa protein bands on Coomassie Blue-stained gels after SDS-PAGE electrophoresis. The K(m) and k were determined to be 3.0 ± 1.0 µM and 13.3 ± 1.6 min, respectively. The large deviation in K(m) was mostly due to the experimental limit inherent to this discontinuous gel-based assay. The concentration range of substrate was also limited since the K(m) was so low. In vitro proteolytic processing of the HCMV assembly protein precursor at the M-site by a recombinant mutant V141A single-chain and wild-type two-chain HCMV protease was also recently reported by Holwerda et al.(27) . The processing of protein substrate was, however, only about 50% complete in the presence of 20% glycerol and 10 mM DTT after a 19-h incubation. The authors suggest that the incomplete turnover is due to a time-dependent loss of protease activity. The HCMV A143Q is significantly more stable than the mutant V141A and wild-type enzyme as observed both under assay conditions and during storage.


Figure 3: Time course of assembly protein precursor cleavage by the purified HCMV A143Q protease. Cleavage were carried out by mixing 2.5 µg of purified assembly protein precursor and 0.5 µg of purified A143Q protease in a final volume of 60 µl of 10 mM HEPES, pH 7.0, and 6 mM DTT, and incubated at 37 °C. LaneM, molecular mass markers. Lane1, substrate alone incubated for 90 min; lane2, cleavage reaction stopped immediately by boiling after mixing substrate with protease; lanes3-13, time points incubated for 1, 2, 3, 4, 5, 10, 15, 20, 30, 60, and 90 min, respectively. Samples were boiled in reducing sample buffer, and subjected to 16% SDS-PAGE and staining. Molecular mass of markers is indicated in kDa.



In order to develop a sensitive continuous peptide-based assay for the HCMV protease, three peptide substrates (Table 1) mimicking the maturation cleavage site of the full-length HCMV protease were made. Various synthetic peptides were previously used by other groups to measure the HCMV protease activity(25, 26, 27, 28, 29) . The sequence of the peptide substrate A6376 was the same as the one used by Burck et al.(26) . This peptide sequence differs from the native M-site sequence at P6, P2`, and P6` positions. These changes were maintained in A6376 for its ease of synthesis and higher solubility as compared with its native sequence. After cleavage of A6376 peptide by the HCMV protease, the amino-terminal peptide product was readily resolved by reverse-phase HPLC. Cleavage at the A/S scissile bond within the A6376 peptide was confirmed by the same retention time observed by HPLC analysis of the synthetic peptide containing only P6 to P1 residues. The terminal sequences of the A6376 peptide were also modified to produce the resonance energy transfer fluorogenic peptides PK03 and AM1013. The carboxyl-terminal glycine in PK03 and lysine in AM1013 was chosen solely for synthetic reasons. We chose anthranilic acid and nitrotyrosine as the donor and acceptor pair mainly because they showed the sufficient quenching efficiency needed for long range resonance energy transfer over 10-16 amino acids(24) . With 10 amino acids corresponding to roughly 30 Å distance between the two chromophores, only 25% of the initial fluorescence (or 75% quenching efficiency) was observed with PK03 and AM1013. After cleavage of these fluorogenic peptide substrates, the fluorescence of the anthranilic acid increases roughly 4-fold. Part of the starting fluorescence is due to free anthranilic acid contaminating the peptide sample (data not shown). However, the incomplete quenching of the anthranilic acid by the nitrotyrosine is compensated for by the very high quantum yield of anthranilic acid. Reliable initial rates were generated by turning over as little as 100 nM, or equivalent to 0.5% of the fluorogenic substrate during the reaction. There is no measurable rate of substrate hydrolysis in the absence of HCMV protease. The values of k/K(m) for these substrates and assembly protein precursor are shown in Table 2. The fluorogenic peptides have larger k/K(m) values than the A6376 peptide presumably due to the removal of the K(m)-increasing arginine at the amino terminus rather than the addition of the nitrotyrosine and anthranilic acid moieties. This presumption is supported by AM1013 where the positions of the two moieties are switched with little effect on k/K(m). From this data, we see that PK03 is a better substrate than A6376 by a factor of 4.3-fold. This continuous fluorescent assay is very sensitive and able to detect the HCMV protease activity in nanomolar concentration over a short reaction time.



After obtaining the k and K(m) values of purified HCMV A143Q protease for different substrates, we examined if the natural protein substrate would be turned over with a much higher k than the peptide substrate due to possible conformational changes occurring around the catalytic residues upon substrate binding. We were also interested in establishing that protease activity measured with synthetic peptides reflects its proteolytic activity in cleaving its in vivo protein substrate. Data presented in Table 2show that the k values are all very similar; regardless of the substrate used. This suggests that the geometric arrangements of catalytic residues in the Michaelis complexes formed with different substrates are very similar. Different K(m) values indicate that the HCMV protease has a binding affinity toward its in vivo protein substrate at least 45-fold stronger than for synthetic peptide substrates presumably due to the larger surface binding areas as compared with peptides. The binding of the HCMV protease to residues outside of the M-site of the assembly protein precursor, however, does not cause significant change in k. Based on the similar k values in this comparative analysis, activity measured with the synthetic peptides does reflect its proteolytic activity in cleaving its in vivo protein substrate.

In order to establish that the mutant HCMV A143Q protease has the same activity as the wild-type enzyme, a comparison of the enzymatic activity of the HCMV A143Q mutant protease was made against the activities previously reported by various other groups (25, 26, 27, 28, 29) for the wild-type counterpart (Table 3). This analysis clearly demonstrates that mutant A143Q protease has very similar activity against peptide substrate when compared with the wild-type HCMV protease. In one case, when identical synthetic peptide was used as the substrate for both enzymes, the A143Q protease has k and K(m) values of 18.5 min and 476 µM (or k/K(m) of 0.038 µMmin) at 25 °C as compared with 16.0 min and 586 µM (or k/K(m) of 0.027 µMmin) for the refolded wild-type enzyme at 37 °C(26) . The slight differences in data generated with two enzyme forms are likely due to different temperatures used for cleavage reactions. It was observed that HCMV protease had maximal activity at 27 °C (data not shown). Based on such analysis presented in Table 3, we conclude that the mutant A143Q protease possesses the same, or similar, enzymatic activity as its wild-type counterpart against synthetic peptide substrates. We have not compared the activity of the mutant A143Q and wild-type protease against the natural protein substrate directly due to difficulty inherent in the gel-based assay and the reported instability of the wild-type enzyme. The discontinuous gel-based assay may also lack the sensitivity and accuracy to detect potential subtle differences between the two enzymes. However, since the protease activity measured with the A143Q against the synthetic peptides does reflect its proteolytic activity in cleaving in vivo protein substrate as discussed in the previous section, it can be inferred that the mutant A143Q protease also has the same, or similar, activity against its in vivo substrate as compared with the wild-type enzyme. This argument is strengthened by the fact that (i) alanine 143 of the HCMV protease lies in a variable region and close to a six-amino acid insertion present only in HCMV and Epstein-Barr virus proteases, but not HSV-1 and varicella-zoster virus proteases, and (ii) that alanine 143 may reside in a flexible loop and thus becomes accessible to proteolytic attack and is unlikely to serve any significant role in substrate binding or catalysis.



Many factors affected the activity of this protease. Both the k and the K(m) were affected by changes in the glycerol, Me(2)SO, and buffer concentrations. Increasing concentrations of glycerol enhance the formation of peptide cleavage products by 20-fold (Fig. 4). Moreover, this increase in activity can be even greater than the observed 20-fold enhancement since the amounts of product turned over at higher concentrations of glycerol do not represent initial rates of product formation. In the absence of glycerol, increasing concentrations of Me(2)SO in the reaction mixture up to 25% enhance the activity (Fig. 5). However, in the presence of 50% glycerol the addition of Me(2)SO is harmful to activity. An increase in the concentration of NaCl also decreases the A143Q protease activity. This NaCl-inhibition can be fit to an IC of 25 mM, and such inhibition is likely due to ionic strength since many divalent cation salts also inhibit A143Q activity (data not shown). The effect of ionic strength on k and K(m) for A6376 is demonstrated in Fig. 6, where these values were determined in 10 and 100 mM MOPS, pH 7.2, in the presence of 50% glycerol. These data are presented as a double reciprocal plot, but the k and K(m) were determined by fitting the data to the nonlinear form of the Michaelis-Menten equation as described under ``Experimental Procedures.'' At 10 mM MOPS, the k was 5.57 min, and the K(m) was 152 µM. At 100 mM MOPS, the k was 9.2 min, and the K(m) was 1500 µM. The measured values of k for this experiment are low since 4% Me(2)SO was included in the assay. Increases in Me(2)SO concentration seem to have a detrimental effect on k. The effect of the MOPS concentration is largely on K(m) rather than k, and this is reflected in the 6.2-fold difference in the k/K(m) value.


Figure 4: Effect of glycerol on the HCMV A143Q protease activity. HCMV A143Q protease was assayed at 30 °C for 15 min in 10 mM MOPS, pH 7.2, 8 µM DTT with increasing concentrations of glycerol. Activity was determined with A6376 peptide by the HPLC-based assay. The percent activity was calculated from the maximal activity, which measured the amount of product formed over the 15-min incubation.




Figure 5: Effect of Me(2)SO on the HCMV A143Q protease activity. HCMV A143Q protease was assayed at 30 °C in 50 mM MOPS, pH 7.2, 10 µM DTT in the presence or absence of 50% glycerol with increasing concentrations of Me(2)SO. Activity was determined with A6376 by the HPLC-based assay. Relative activities versus Me(2)SO concentrations are plotted, and 100% activity represents the maximal activity calculated from the amount of product formed during a 15-min incubation. Maximal activity in 50% glycerol was 7-fold greater than in its absence at this buffer concentration.




Figure 6: Effect of buffer concentration on k and K for A6376. HCMV A143Q protease activity was measured by the HPLC assay at 30 °C for 15 min in 10 or 100 mM MOPS, pH 7.2, 8 µM DTT, 50% glycerol, and 4% Me(2)SO. The concentration range of A6376 was 50-400 µM and 100-2000 µM; the concentration of HCMV protease was 0.16 and 1.1 µM for the 10 mM MOPS and 100 mM MOPS data sets, respectively. The data are shown as a double-reciprocal plot where V(0) represents the amount of product formed per minute during a 15-min incubation.



In summary, we have demonstrate that (i) by one single amino acid substitution, the A143Q mutant can be purified from E. coli as a stable single-chain 29-kDa protein, (ii) purified A143Q protease can recognize and cleave its in vivo protein substrate efficiently and is sufficient in cleaving the assembly protein precursor in vitro without other cellular or viral factors, (iii) a sensitive, continuous peptide-based fluorescent assay has been developed for the HCMV protease to detect activity in nM concentration of enzyme (Fig. 7), and activity detected with peptide substrates has k values similar to that measured with the protein substrate, and (iv) A143Q mutant enzyme has the same, or similar, activity as the wild-type enzyme.


Figure 7: Progress curve of product formation for PK03 in the RET-fluorogenic assay. This time course was collected at 25 °C in 25 mM MOPS pH 7.2, 1 mM DTT, 50% glycerol, and 2% Me(2)SO. The concentrations of PK03 and HCMV A143Q protease were 20 and 0.67 µM, respectively. For clarity, only 5% of the collected data points are shown. The data were fit to a single exponential equation with k = 0.11 min. The value k/K was calculated as described under ``Experimental Procedures.''



The HCMV protease has recently been demonstrated by Holwerda et al.(27) to be a serine protease, and Ser-132 was identified as the active site nucleophile based on the irreversible modification by the serine protease inhibitor diisopropyl fluorophosphate. Similar irreversible modification of the HSV-1 protease at Ser-129 by diisopropyl fluorophosphate was reported by DiIanni et al.(29) . And, mutation of the equivalent Ser residue in the simian CMV protease to Ala also eliminated the enzyme activity(28) . Since HSV and CMV are members of the Herpesviridae family, and their proteases share sequence homology, it suggests that both HCMV and HSV-1 protease could belong to the serine protease class. Inhibition of the HCMV protease by N-ethylmaleimide and iodoacetamide, at high inhibitor/enzyme molar ratio, was also documented (26) and confirmed in this laboratory (data not shown). However, this inhibition may be due to nonspecific alkylation of Cys residues leading to inactivation of the enzyme.

Interestingly, the recently determined human rhinovirus 3C protease structure reveals that its three-dimensional structure possesses a trypsin-like polypeptide fold, and its catalytic residues Cys-146, His-40, and Glu-71 have an overall geometry similar to that of the Ser-His-Asp catalytic triad found in trypsin-like serine proteases (30) . The human rhinovirus protease structure demonstrates that this trypsin-like viral protease has a cysteine in place of serine to serve as an active site nucleophile. For the HCMV protease, His-63 and Glu-122 were recently identified as two other residues in the active site triad(31) . The different spacing of the HCMV protease active site residues: His-63, Glu-122, and Ser-132 and the lack of sequence homology with other known serine proteases together suggest that herpes proteases belong to a new class of serine proteases and their structures may be completely different from any solved serine protease structure. The structure solution of the HCMV A143Q protease is currently being pursued. Three-dimensional structure of the HCMV protease will undoubtedly reveal if the Ser-132 is indeed the active site residue and its geometric arrangement within the catalytic triad of this new class of viral protease.


FOOTNOTES

*
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§
To whom correspondence and reprint requests should be addressed: Molecular Biology/Biochemistry Group, Agouron Pharmaceuticals, Inc., 3565 General Atomics Ct., San Diego, CA 92121. Tel.: 619-622-3121; Fax: 619-622-3299.

(^1)
The abbreviations used are: HSV-1 herpes simplex virus type-1; CMV, cytomegalovirus; HCMV, human cytomegalovirus; ORF, open reading frame; DTT, dithiothreitol; PAGE, polyacrylamide gel electrophoresis; Mes, 2-[N-morpholino]ethanesulfonic acid; HPLC, high performance liquid chromatography; MOPS, 3-[N-morpholino]propanesulfonic acid; RET, resonance energy transfer.


ACKNOWLEDGEMENTS

We thank Karen Fan for the gift of HCMV-infected culture cells. We also thank Zdenek Hostomsky and Howard Tenenbaum for E. coli cultures grown in the fermenter and Anthony Welch for helpful discussion.


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