A new serine-protease fold revealed by the crystal structure of human cytomegalovirus protease

Tong, Liang; Qian, Chungeng; Massariol, Marie-Josée; Bonneau, Pierre; Cordingley, Michael G.; Lagacé, Lisette

doi:10.1038/383272a0

Cited by 162 publications

(131 citation statements)

References 19 publications

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“…It has also been suggested that without R-site cleavage, conformation of the pPR sequence destined to form the carboxyl terminus of assemblin would be different (14) and possibly unable to participate in the interactions and changes, which accompany dimerization and activation. Thus, one explanation of our finding is that imidazole rescue of I-site cleavage works only when the active site residues are in the relative orientation they assume in the activated assemblin dimer, which may be different in the precursor.…”

Section: Discussionmentioning

confidence: 99%

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Chemical Rescue of I-site Cleavage in Living Cells and in Vitro Discriminates between the Cytomegalovirus Protease, Assemblin, and Its Precursor, pUL80a

McCartney¹,

Brignole

Kolegraff

et al. 2005

Journal of Biological Chemistry

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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 ϳ11%/h in bacteria and ϳ30%/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.As an essential step in their maturation, herpes group viruses package their DNA genome into preformed capsids (1-7). For this to occur, internal proteins of the nascent capsid must be eliminated through a process catalyzed by a virus-encoded maturational protease (8 -10). In the absence of this enzyme, the capsids produced are devoid of viral DNA and unable to mature into infectious virus. The enzyme required for this step is a serine protease but is distinguished from other members of its family by an atypical catalytic triad (Ser-His-His instead of SerHis-Asp/Glu) (11-14), an unusually slow cleavage rate (15-18), and a requirement to dimerize for activity (19 -22). These deviations from the more typical serine proteases increase interest in the relationships between its enzymatic mechanism and biological function.Like its homologs in other herpesviruses, the cytomegalovirus (CMV) 4 protease is autoproteolytically derived from a precursor by sequential cleavage at its maturational (M) site and then its release (R) site to yield a mature form, called assemblin (10,23,24). Among the CMV-type herpesviruses (members of the ␤-herpesvirus family, Ref. 25), the assemblin homolog is additionally cleaved at an internal (I) site (15, 26) (e.g. see Fig. 1D), converting it to a two-chain form that remains active (27)(28)(29). Although these self-processing steps are coupled with capsid maturation, little is understood about their regulation.To further investigate this enzyme and the relationship of its selfprocessing to capsid assembly and maturation, we considered creating a mutant controlled by a rationally designed small-molecule switch. Such "chemical rescue" mutants have an inactivating amino acid substitution that can be functionally compensated by an exogenous compound (30, 31). Given that two cat...

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Section: Discussionmentioning

confidence: 99%

“…The crystal structure of assemblin places the I site within an unstructured loop in the vicinity of the active site (11)(12)(13)(14). Extension of the loop toward the interior of the protease would situate the I site in proximity to the catalytic residues.…”

Section: Discussionmentioning

confidence: 99%

Chemical Rescue of I-site Cleavage in Living Cells and in Vitro Discriminates between the Cytomegalovirus Protease, Assemblin, and Its Precursor, pUL80a

McCartney¹,

Brignole

Kolegraff

et al. 2005

Journal of Biological Chemistry

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“…This could lead to a tighter packing of the protease molecules. Second, sodium sulfate caused a small change in the organization of the HCMV protease dimer in these crystals (Tong et al, 1996). This might also have an impact on the crystal packing, as evidenced by the fact that crystal form D has the shortest c-axis length.…”

Section: Discussionmentioning

confidence: 99%

“…The amino-acid sequences of herpesvirus proteases have no detectable homology to other serine proteases or hydrolases. The crystal structure of HCMV protease has recently been determined in our laboratory by the seleno-methionyl multiple-wavelength anomalous diffraction (MAD) technique (Tong et al, 1996), and in other laboratories by the heavy-atom isomorphous replacement technique (Qiu et al, 1996;Shieh et al, 1996;Chen et al, 1996). It showed that HCMV protease possesses a new polypeptide backbone fold; confirmed that Ser132 and His63 are in close proximity in space; and identified His157 as the possible third member of the catalytic triad.…”

Section: Introductionmentioning

confidence: 93%

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Experiences from the Structure Determination of Human Cytomegalovirus Protease

Tong

Qian²,

Davidson³

et al. 1997

Acta Cryst D

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Several obstacles were encountered and overcome during the structure determination of human cytomegalovirus protease. Dehydration of crystals, by exposing them to higher concentrations of the precipitant, reduced the mosaicity of the crystals and may have also resolved their microscopic twinning. The initial phase information was obtained with the selenomethionyl multiple-wavelength anomalous diffraction technique. However, site-specific mutagenesis was required to introduce extra Met residues into the protease. The phase information had to be improved by non-crystallographic symmetry averaging, initially among three 'crystal forms'. A change in the composition of the artificial mother liquor led to a significant improvement, from 3.0 and 2.0A resolution, in the diffraction quality of the crystals. The experiences reported here may prove useful to structure determination of other proteins.

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Metallionen als Coinhibitoren von Serin-Proteasen: ein neuer Ansatz bei der Suche nach hochaffinen und spezifischen Liganden

Schirmeister

1998

Angewandte Chemie

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A new serine-protease fold revealed by the crystal structure of human cytomegalovirus protease

Cited by 162 publications

References 19 publications

Chemical Rescue of I-site Cleavage in Living Cells and in Vitro Discriminates between the Cytomegalovirus Protease, Assemblin, and Its Precursor, pUL80a

Chemical Rescue of I-site Cleavage in Living Cells and in Vitro Discriminates between the Cytomegalovirus Protease, Assemblin, and Its Precursor, pUL80a

Experiences from the Structure Determination of Human Cytomegalovirus Protease

Metallionen als Coinhibitoren von Serin-Proteasen: ein neuer Ansatz bei der Suche nach hochaffinen und spezifischen Liganden

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