Your search keyword '"Moyer, Richard W."' showing total 24 results

1. NAD+-dependent DNA Ligase Encoded by a Eukaryotic Virus*

Author

Sriskanda, Verl, Moyer, Richard W., and Shuman, Stewart

Abstract

We report the production, purification, and characterization of an NAD+-dependent DNA ligase encoded by the Amsacta mooreientomopoxvirus (AmEPV), the first example of an NAD+ligase from a source other than eubacteria. AmEPV ligase lacks the zinc-binding tetracysteine domain and the BRCT domain that are present in all eubacterial NAD+ligases. Nonetheless, the monomeric 532-amino acid AmEPV ligase catalyzed strand joining on a singly nicked DNA in the presence of a divalent cation and NAD+. Neither ATP, dATP, nor any other nucleoside triphosphate could substitute for NAD+. Structure probing by limited proteolysis showed that AmEPV ligase is punctuated by a surface-accessible loop between the nucleotidyltransferase domain, which is common to all ligases, and the N-terminal domain Ia, which is unique to the NAD+ligases. Deletion of domain Ia of AmEPV ligase abolished the sealing of 3′-OH/5′-PO4nicks and the reaction with NAD+to form ligase-adenylate, but had no effect on phosphodiester formation at a pre-adenylated nick. Alanine substitutions at residues within domain Ia either reduced (Tyr39, Tyr40, Asp48, and Asp52) or abolished (Tyr51) sealing of a 5′-PO4nick and adenylyl transfer from NAD+without affecting ligation of DNA-adenylate. We conclude that: (i) NAD+-dependent ligases exist in the eukaryotic domain of the phylogenetic tree; and (ii) ligase structural domain Ia is a determinant of cofactor specificity and is likely to interact directly with the nicotinamide mononucleotide moiety of NAD+.

Published

2001

2. The Serpins Are an Expanding Superfamily of Structurally Similar but Functionally Diverse Proteins

Author

Silverman, Gary A., Bird, Phillip I., Carrell, Robin W., Church, Frank C., Coughlin, Paul B., Gettins, Peter G.W., Irving, James A, Lomas, David A., Luke, Cliff J., Moyer, Richard W., Pemberton, Philip A., Remold-O'Donnell, Eileen, Salvesen, Guy S., Travis, James, and Whisstock, James C.

Published

2001

3. Complete Genomic Sequence of the Amsacta mooreiEntomopoxvirus: Analysis and Comparison with Other Poxviruses

Author

Bawden, Alison L., Glassberg, Kathryn J., Diggans, James, Shaw, Regina, Farmerie, William, and Moyer, Richard W.

Abstract

The genome of the genus B entomopoxvirus from Amsacta moorei(AmEPV) was sequenced and found to contain 232,392 bases with 279 unique open reading frames (ORFs) of greater than 60 amino acids. The central core of the viral chromosome is flanked by 9.4-kb inverted terminal repeats (ITRs), each of which contains 13 ORFs, raising the total number of ORFs within the viral chromosome to 292. ORFs with no known homology to other poxvirus genes were shown to constitute 33.6% of the viral genome. Approximately 28.6% of the AmEPV genome encodes homologs of the mammalian poxvirus colinear core genes, which are found dispersed throughout the AmEPV chromosome. There is also no significant gene order conservation between AmEPV and the orthopteran genus B poxvirus of Melanoplus sanguinipes(MsEPV). Novel AmEPV genes include those encoding a putative ABC transporter and a Kunitz-motif protease inhibitor. The most unusual feature of the AmEPV genome relates to the viral encoded poly(A) polymerase. In all other poxviruses this heterodimeric enzyme consists of a single large and a single small subunit. However, AmEPV appears to encode one large and two distinct small poly(A) polymerase subunits. AmEPV is one of the few entomopoxviruses which can be grown and manipulated in cell culture. The complete genomic sequence of AmEPV paves the way for an understanding and comparison of the molecular properties and pathogenesis between the entomopoxviruses of insects and the more intensively studied vertebrate poxviruses.

Published

2000

4. The Cowpox Virus Serpin SPI-3 Complexes with and Inhibits Urokinase-Type and Tissue-Type Plasminogen Activators and Plasmin

Author

Turner, Peter C., Baquero, M.Teresa, Yuan, Shala, Thoennes, Sudha R., and Moyer, Richard W.

Abstract

The orthopoxvirus serpin SPI-3 is N-glycosylated and suppresses fusion between infected cells. Although SPI-3 contains motifs conserved in inhibitory serpins, no proteinase inhibition by SPI-3 has been demonstrated, and mutations within the serpin reactive center loop (RCL) do not affect the ability to regulate cell fusion. We demonstrate here that SPI-3 protein expressed by transcription/translation in vitrois able to form SDS-stable complexes with the serine proteinases plasmin, urokinase-type plasminogen activator (uPA), and tissue-type plasminogen activator (tPA), consistent with inhibitory activity of the serpin. Weaker complexes were noted with factor Xa and thrombin. Mutation of Arg-340/Ser-341 at the predicted P1/P1′ sites within the RCL prevented the formation of complexes between SPI-3 and plasmin, uPA, or tPA, suggesting that the arginine at the P1 position was required for complex formation. SPI-3 protein lacking the N-terminal signal peptide was purified by means of an N-terminal His10-tag and gave complete inhibition in vitroof plasmin, uPA, and tPA and partial inhibition of factor Xa. SPI-3 is therefore a bifunctional protein that acts as a proteinase inhibitor and suppresses infected cell–cell fusion. As a proteinase inhibitor, SPI-3 has similar specificity to the leporipoxvirus SERP1 protein of myxoma virus, although the two serpins are less than 30% identical overall. The inhibition constants of SPI-3 for plasmin, uPA, and tPA were determined to be 0.64, 0.51, and 1.9 nM, respectively, very similar to the corresponding Kivalues of SERP1.

Published

2000

5. The Cowpox Virus SPI-3 and Myxoma Virus SERP1 Serpins Are Not Functionally Interchangeable despite Their Similar Proteinase Inhibition Profiles in Vitro

Author

Wang, Yun Xiang, Turner, Peter C., Ness, Traci L., Moon, Kristin B., Schoeb, Trenton R., and Moyer, Richard W.

Abstract

The myxoma virus (MYX) serpin SERP1 is a secreted glycoprotein with anti-inflammatory activity that is required for full MYX virulence in vivo.The cowpox virus (CPV) serpin SPI-3 (vaccinia virus ORF K2L) is a nonsecreted glycoprotein that blocks cell–cell fusion, independent of serpin activity, and is not required for virulence of vaccinia virus or CPV in mice. Although SPI-3 has only 29% overall identity to SERP1, both serpins have arginine at the P1 position in the reactive center loop, and SPI-3 has a proteinase inhibitory profile strikingly similar to that of SERP1 [Turner, P. C., Baquero, M. T., Yuan, S., Thoennes, S. R., and Moyer, R. W. (2000) Virology272, 267–280]. To determine whether SPI-3 and SERP1 were functionally equivalent, a CPV variant was constructed where the SPI-3 gene was deleted and replaced with the SERP1 gene regulated by the SPI-3 promoter. Cells infected with CPVΔSPI-3::SERP1 secrete SERP1 and show extensive fusion, suggesting that SERP1 is unable to functionally substitute for SPI-3 in fusion inhibition. In the reciprocal experiment, both copies of SERP1 were deleted from MYX and replaced with SPI-3 under the control of the SERP1 promoter. Cells infected with the MYXΔSERP1::SPI-3 recombinant unexpectedly secreted SPI-3, suggesting either that the cellular secretory pathway is enhanced by MYX or that CPV encodes a protein that prevents SPI-3 secretion. MYXΔSERP1::SPI-3 was as attenuated in rabbits as MYXΔSERP1::lacZ, indicating that SPI-3 cannot substitute for SERP1 in MYX pathogenesis.

Published

2000

6. Granzyme B Short-Circuits the Need for Caspase 8 Activity during Granule-Mediated Cytotoxic T-Lymphocyte Killing by Directly Cleaving Bid

Author

Barry, Michele, Heibein, Jeffrey A., Pinkoski, Michael J., Lee, Siow-Fong, Moyer, Richard W., Green, Douglas R., and Bleackley, R. Chris

Abstract

ABSTRACTCytotoxic T lymphocytes (CTL) can trigger an apoptotic signal through the Fas receptor or by the exocytosis of granzyme B and perforin. Caspase activation is an important component of both pathways. Granzyme B, a serine proteinase contained in granules, has been shown to proteolytically process and activate members of the caspase family in vitro. In order to gain an understanding of the contributions of caspases 8 and 3 during granule-induced apoptosis in intact cells, we have used target cells that either stably express the rabbitpox virus-encoded caspase inhibitor SPI-2 or are devoid of caspase 3. The overexpression of SPI-2 in target cells significantly inhibited DNA fragmentation, phosphatidylserine externalization, and mitochondrial disruption during Fas-mediated cell death. In contrast, SPI-2 expression in target cells provided no protection against granzyme-mediated apoptosis, mitochondrial collapse, or cytolysis, leading us to conclude that SPI-2-inhibited caspases are not an essential requirement for the granzyme pathway. Caspase 3-deficient MCF-7 cells were found to be resistant to CTL-mediated DNA fragmentation but not to CTL-mediated cytolysis and loss of the mitochondrial inner membrane potential. Furthermore, we demonstrate that granzyme B directly cleaves the proapoptotic molecule Bid, bypassing the need for caspase 8 activation of Bid. These results provide evidence for a two-pronged strategy for mediating target cell destruction and provide evidence of a direct link between granzyme B activity, Bid cleavage, and caspase 3 activation in whole cells.

Published

2000

7. Granzyme B Short-Circuits the Need for Caspase 8 Activity during Granule-Mediated Cytotoxic T-Lymphocyte Killing by Directly Cleaving Bid

Author

Barry, Michele, Heibein, Jeffrey A., Pinkoski, Michael J., Lee, Siow-Fong, Moyer, Richard W., Green, Douglas R., and Bleackley, R. Chris

Abstract

Cytotoxic T lymphocytes (CTL) can trigger an apoptotic signal through the Fas receptor or by the exocytosis of granzyme B and perforin. Caspase activation is an important component of both pathways. Granzyme B, a serine proteinase contained in granules, has been shown to proteolytically process and activate members of the caspase family in vitro. In order to gain an understanding of the contributions of caspases 8 and 3 during granule-induced apoptosis in intact cells, we have used target cells that either stably express the rabbitpox virus-encoded caspase inhibitor SPI-2 or are devoid of caspase 3. The overexpression of SPI-2 in target cells significantly inhibited DNA fragmentation, phosphatidylserine externalization, and mitochondrial disruption during Fas-mediated cell death. In contrast, SPI-2 expression in target cells provided no protection against granzyme-mediated apoptosis, mitochondrial collapse, or cytolysis, leading us to conclude that SPI-2-inhibited caspases are not an essential requirement for the granzyme pathway. Caspase 3-deficient MCF-7 cells were found to be resistant to CTL-mediated DNA fragmentation but not to CTL-mediated cytolysis and loss of the mitochondrial inner membrane potential. Furthermore, we demonstrate that granzyme B directly cleaves the proapoptotic molecule Bid, bypassing the need for caspase 8 activation of Bid. These results provide evidence for a two-pronged strategy for mediating target cell destruction and provide evidence of a direct link between granzyme B activity, Bid cleavage, and caspase 3 activation in whole cells.

Published

2000

8. Myxoma Virus Serp2 Is a Weak Inhibitor of Granzyme B and Interleukin-1ß-Converting Enzyme In Vitro and Unlike CrmA Cannot Block Apoptosis in Cowpox Virus-Infected Cells

Author

Turner, Peter C., Sancho, M. Carmen, Thoennes, S. R., Caputo, A., Bleackley, R. C., and Moyer, Richard W.

Abstract

ABSTRACTThe Serp2 protein encoded by the leporipoxvirus myxoma virus is essential for full virulence (F. Messud-Petit, J. Gelfi, M. Delverdier, M. F. Amardeilh, R. Py, G. Sutter, and S. Bertagnoli, J. Virol. 72:7830–7839, 1998) and, like crmA of cowpox virus (CPV), is reported to inhibit the interleukin-1ß-converting enzyme (ICE, caspase-1) (F. Petit, S. Bertagnoli, J. Gelfi, F. Fassy, C. Boucraut-Baralon, and A. Milon, J. Virol. 70:5860–5866, 1996). Serp2 and CrmA both contain Asp at the P1 position within the serpin reactive site loop and yet are only 35% identical overall. Serp2 protein was cleaved by ICE but, unlike CrmA, did not form a stable complex with ICE that was detectable by native gel electrophoresis. Attempts to covalently cross-link ICE-serpin inhibitory complexes were successful with CrmA, but no complex between ICE and Serp2 was visible after cross-linking. Purified His10-tagged Serp2 protein was a relatively poor inhibitor of ICE, with aKiof 80 nM compared to 4 pM for CrmA. Serp2 protein resembled CrmA in that a stable complex with the serine proteinase granzyme B was detectable after sodium dodecyl sulfate-polyacrylamide gel electrophoresis. However, Serp2 was less effective at inhibiting granzyme B activity (Ki= 420 nM) than CrmA (Ki= 100 nM). Finally, Serp2 was tested for the ability to replace CrmA and inhibit apoptosis in LLC-PK1 cells infected with a CPV recombinant deleted for CrmA but expressing Serp2. Unlike wild-type-CPV-infected cells, apoptosis was readily observed in cells infected with the recombinant virus, as indicated by the induction of both nuclear fragmentation and caspase-mediated cleavage of DEVD-AMC [acetyl-Asp-Glu-Val-Asp-(amino-4-methyl coumarin)]. These results indicate that Serp2 is unable to functionally substitute for CrmA within the context of CPV and that the inhibition spectra for Serp2 and CrmA are distinct.

Published

1999

9. SPI-1-Dependent Host Range of Rabbitpox Virus and Complex Formation with Cathepsin G Is Associated with Serpin Motifs

Author

Moon, Kristin B., Turner, Peter C., and Moyer, Richard W.

Abstract

ABSTRACTSerpins are a superfamily of serine proteinase inhibitors which function to regulate a number of key biological processes including fibrinolysis, inflammation, and cell migration. Poxviruses are the only viruses known to encode functional serpins. While some poxvirus serpins regulate inflammation (myxoma virus SERP1 and cowpox virus [CPV] crmA/SPI-2) or apoptosis (myxoma virus SERP2 and CPV crmA/SPI-2), the function of other poxvirus serpins remains unknown. The rabbitpox virus (RPV) SPI-1 protein is 47% identical to crmA and shares all of the serpin structural motifs. However, no serpin-like activity has been demonstrated for SPI-1 to date. Earlier we showed that RPV with the SPI-1 gene deleted, unlike wild-type virus, fails to grow on A549 or PK15 cells (A. Ali, P. C. Turner, M. A. Brooks, and R. W. Moyer, Virology 202:306–314, 1994). Here we demonstrate that in the absence of a functional SPI-1 protein, infected nonpermissive cells which exhibit the morphological features of apoptosis fail to activate terminal caspases or cleave the death substrates PARP or lamin A. We show that SPI-1 forms a stable complex in vitro with cathepsin G, a member of the chymotrypsin family of serine proteinases, consistent with serpin activity. SPI-1 reactive-site loop (RSL) mutations of the critical P1 and P14 residues abolish this activity. Viruses containing the SPI-1 RSL P1 or P14 mutations also fail to grow on A549 or PK15 cells. These results suggest that the full virus host range depends on the serpin activity of SPI-1 and that in restrictive cells SPI-1 inhibits a proteinase with chymotrypsin-like activity and may function to inhibit a caspase-independent pathway of apoptosis.

Published

1999

10. The Effects of Serpin Gene Mutations on the Distinctive Pathobiology of Cowpox and Rabbitpox Virus Following Intranasal Inoculation of Balb/c Mice

Author

Thompson, James P., Turner, Peter C., Ali, Ahmad N., Crenshaw, Barbara C., and Moyer, Richard W.

Abstract

Intranasal infection of Balb/c mice with 10⁶ plaque forming units (PFU) of wild-type cowpox virus (CPV) and rabbitpox virus (RPV) induced strikingly different pulmonary pathology despite nearly identical clinical signs of illness and LD₅₀. Intranasal infection with CPV induced severe peribronchial, peribronchiolar, and perivascular hemorrhage with a mixed inflammatory cell infiltrate, bronchial and bronchiolar epithelial cell hyperplasia with intracytoplasmic acidophilic inclusion bodies, and alveolar hemorrhage and edema. In contrast, infection with RPV induced a mixed peribronchial and peribronchiolar inflammatory cell infiltrate, multifocal areas of bronchiolar epithelial cell coagulation necrosis, alveolar edema, and a conspicuous absence of pulmonary hemorrhage. Viremia was not detected following CPV infection and only 1 of 11 mice had brain-associated virus at death. Mice infected with RPV exhibited a viremia 2-3 days after infection and all mice bed virus associated with the brain at death. Mice infected with viruses containing certain serine protease inhibitor (SPI) gene mutations (CPV ΔSPI-1, CPV ΔSPI-3, and RPV SPI-1^-) exhibited no difference in clinical disease manifestation when compared with those infected with wild-type viruses. However, inactivation of the SPI-2 gene in either CPV or RPV resulted in disease attenuation and alteration of pulmonary pathology. Mice infected with the CPV ΔSPI-2 mutant showed decreased pulmonary hemorrhage, reduced inflammation, and an absence of alveolar edema, while mice infected with the RPV ΔSPI-2 mutant had a marked increase in intrapulmonary inflammatory cells and only a transient viremia. Copyright 1993, 1999 Academic Press

Published

1993

11. Identification of an AmsactaSpheroidin-like Protein within the Occlusion Bodies of ChoristoneuraEntomopoxviruses

Author

Hall, Richard L. and Moyer, Richard W.

Abstract

Like baculoviruses, a characteristic feature of entomopoxviruses is the amalgamation of virions within environmentally stable occlusion bodies. It is this occluded form of the virus that is primarily responsible for dissemination to other insects. While the major protein (polyhedrin) of baculovirus occlusions is quite similar between viruses, it has been reported that the major occlusion body protein (spheroidin) of two group B entomopoxviruses, Amsacta moorei(AmEPV) and Choristoneura biennis(CbEPV) is quite different both in terms of amine acid sequence and coding capacity of the corresponding spheroidin genes (115 and 47 kDa for AmEPV and CbEPV, respectively). We report the discovery of a AmEPV spheroidin gene homolog in both CbEPV and a second Choristoneuravirus, Choristoneura fumiferana(CfEPV). Antibodies directed against the AmEPV 115-kDa spheroidin reacted with the major protein of ∼115 kDa found within the occlusion body preparation from both Choristoneuraviruses. Direct protein microsequencing of small portions of the 115-kDa protein from CbEPV has resulted in peptide sequences identical to those of corresponding regions of the AmEPV spheroidin gene. We suggest that it is this Choristoneuragene which encodes spheroidin. All attempts, however, to find a homolog of the previously reported CbEPV spheroidin gene within AmEPV have been unsuccessful. We also show this newly identified Choristoneurahomolog of the AmEPV spheroidin gene as well as the AmEPV spheroidin gene itself are both located at the 3′ end of an NPH I gene and are highly homologous in all three viruses, indicating that this region of the genome in the three viruses is co-linear. These results and others suggest that while the insect viruses lack the traditional central core of conserved genes observed for the vertebrate poxviruses, the insect poxviruses may have also evolved an alternative central core of conserved genes, unique to the invertebrate poxviruses.

Published

1993

12. CrmA/SPI-2 Inhibition of an Endogenous ICE-related Protease Responsible for Lamin A Cleavage and Apoptotic Nuclear Fragmentation*

Author

Takahashi, Atsushi, Musy, Pierre-Yves, Martins, Luis M., Poirier, Guy G., Moyer, Richard W., and Earnshaw, William C.

Abstract

CrmA, a poxvirus gene product with a serpin-like structure, blocks a variety of apoptotic death events in cultured cells. Based on the ability of CrmA to inhibit the interleukin-1β converting enzyme in vitro, it has been speculated that interleukin-1β converting enzyme-related proteases (caspases) essential for apoptosis are the cellular targets of CrmA. Here we found that rabbitpox virus CrmA/SPI-2 inhibits the cleavage of lamin A mediated by a caspase in our cell-free system of apoptosis. In the presence of CrmA/SPI-2, nuclear apoptosis in vitrowas blocked at an intermediate stage after collapse of the chromatin against the nuclear periphery and before nuclear shrinkage and disintegration into apoptotic body-like fragments. Using N-(acetyltyrosinylvalinyl-Nϵ-biotinyllysyl) aspartic acid [(2,6-dimethylbenzoyl)oxy] methyl ketone, which derivatizes the active forms of caspases, we could show that one of five caspases active in the extracts is inhibited both by CrmA/SPI-2 and by a peptide spanning the lamin A apoptotic cleavage site. These results reveal that CrmA/SPI-2 can inhibit a caspase responsible both for lamin A cleavage and for the nuclear disintegration characteristic of apoptosis.

Published

1996

13. The T1/35kDa Family of Poxvirus-Secreted Proteins Bind Chemokines and Modulate Leukocyte Influx into Virus-Infected Tissues

Author

Graham, Kathryn A, Lalani, Alshad S, Macen, Joanne L, Ness, Traci L, Barry, Michele, Liu, Li-Ying, Lucas, Alexandra, Clark-Lewis, Ian, Moyer, Richard W, and Mcfadden, Grant

Abstract

Immunomodulatory proteins encoded by the larger DNA viruses interact with a wide spectrum of immune effector molecules that regulate the antiviral response in the infected host. Here we show that certain poxviruses, including myxoma virus, Shope fibroma virus, rabbitpox virus, vaccinia virus (strain Lister), cowpox virus, and raccoonpox virus, express a new family of secreted proteins which interact with members of both the CC and CXC superfamilies of chemokines. However, swinepox virus and vaccinia virus (strain WR) do not express this activity. Using a recombinant poxviruses, the myxoma M-T1 and rabbitpox virus 35kDa secreted proteins were identified as prototypic members of this family of chemokine binding proteins. Members of this T1/35kDa family of poxvirus-secreted proteins share multiple stretches of identical sequence motifs, including eight conserved cysteine residues, but are otherwise unrelated to any cellular genes in the database. The affinity of the CC chemokine RANTES interaction with M-T1 was assessed by Scatchard analysis and yielded aKdof approximately 73 nM.In rabbits infected with a mutant rabbitpox virus, in which the 35kDa gene is deleted, there was an increased number of extravasating leukocytes in the deep dermis during the early phases of infection. These observations suggest that members of the T1/35kDa class of secreted viral proteins bind multiple members of the chemokine superfamilyin vitroand modulate the influx of inflammatory cells into virus-infected tissuesin vivo.

Published

1997

14. DNA Sequence Analysis of Conserved and Unique Regions of Swinepox Virus: Identification of Genetic Elements Supporting Phenotypic Observations Including a Novel G Protein-Coupled Receptor Homologue

Author

Massung, Robert F., Jayarama, V., and Moyer, Richard W.

Abstract

Swinepox virus (SPV) contains a double-stranded cross-linked linear DNA genome of approximately 175 kilobase pairs with terminal inverted repetitions (TIRs) of 4.3 kb. The nucleotide sequence was determined for fragments from several regions of the genome including a 2.85-kb fragment from the central potentially conserved portion and two fragments within the presumed variable near-terminal regions which tend to be unique to a given poxvirus. The core sequence contains one partial and two complete open reading frames that are highly conserved and colinear with three contiguous ORFs within the HindIII D fragment of vaccinia virus (VV). The two near-terminal fragments, encompassing 14.2 and 3.6 kb, are respectively located 2.1 kb internal to the left and right cross-linked termini of the DNA and span the TIR junctions. The sequences encode 25 open reading frames including numerous proteins predicted to be membrane-bound or secreted in infected cells. Several ORFs unique to SPV were identified that may be involved in cell attachment, immune modulation, and pathogenesis including a novel poxvirus G protein-coupled receptor. In addition, several polypeptides encoded within the near-terminal regions of vaccinia virus DNA that function as host range or virulence factors are lacking within this region of swinepox virus including the VV growth factor, complement-binding protein, and ORFs C7L and K1L, associated with host range. The lack of these functional homologues could explain the characteristic attenuated phenotype and limited host range of SPV.

Published

1993

15. The SPI-1 Gene of Rabbitpox Virus Determines Host Range and Is Required for Hemorrhagic Pock Formation

Author

Ali, Ahmad N., Turner, Peter C., Brooks, Michael A., and Moyer, Richard W.

Abstract

Wild-type rabbitpox virus (RPV) and cowpox virus (CPV) produce red hemorrhagic lesions or pocks upon infection of the chicken chorioallantoic membrane (CAM) of 11-day-old embryonated chicken eggs. However, white, nonhemorrhagic pock variants arise spontaneously within wild-type (wt) populations of either virus at a frequency of about 1%, reflective of complex deletions/rearrangements in the termini of the viral DNA. A subpopulation of the RPV white-pock mutants fail to plaque on pig kidney (PK-15) cells and are referred to as host-range (hr) mutants. In the case of CPV, white-pock formation has been linked to mutations in the SPI-2 (crmA) gene. We show that five spontaneous RPV white-pock host-range mutants (RPVµhr8sm, RPVµhr23, RPµhr28, RPVµhr30, and RPµhr31) each contain a SPI-2 (crmA) gene end express the crmA protein but lack instead a functional SPI-1 gene. Two other spontaneous RPV white-pock mutants, RPVµ9 and RPVµ12, which plaque on PK-15 cells (nonhost-range mutants) contain and express a SPI-1 gene but lack instead a functional SPI-2 gene. Targeted disruption of either the SPI-1 or SPI-2 genes of wtRPV, but only the SPI-2 gene of wtCPV, generates mutants which produce white pocks. The RPVΔSPI-1 mutant fails to plaque on PK-15 or human A549 cells, whereas the RPVΔSPI-2 mutant has a normal host range. No changes in host range compared to wtCPV for either the CPVΔSPI-1 or CPVΔPI-2 mutants were noted. These differences in phenotypes observed between the two viruses may be reflective of either small sequence variations between the highly conserved SPI-1 or SPI-2 genes or the aggregate phenotypes provided by the other remaining genes. Copyright 1994, 1999 Academic Press

Published

1994

16. Functional Comparisons among Members of the Poxvirus T1/35kDa Family of Soluble CC-Chemokine Inhibitor Glycoproteins

Author

Lalani, Alshad S., Ness, Traci L., Singh, Rajkumari, Harrison, Jeffrey K., Seet, Bruce T., Kelvin, David J., McFadden, Grant, and Moyer, Richard W.

Abstract

Many poxviruses express a 35–40-kDa secreted protein, termed “T1” (for leporipoxviruses) or “35kDa” (for orthopoxviruses), that binds CC-chemokines with high affinity but is unrelated to any known cellular proteins. Many previously identified poxvirus cytokine-binding proteins display strict species ligand-binding specificity. Because the T1 and 35kDa proteins share only 40% amino acid identity, we compared the abilities of purified myxoma virus-T1 (M-T1) and vaccinia virus (strain Lister)- and rabbitpox virus-35kDa proteins to inhibit human CC-chemokinesin vitro.All three proteins were equally effective in preventing several human CC-chemokines from binding to target chemokine receptors and blocking subsequent intracellular calcium release. The inhibitory affinities were comparable (Ki= 0.07–1.02 nM). These proteins also displayed similar abilities to inhibit (IC50= 6.3–10.5 nM) human macrophage inflammatory protein-1α-mediated chemotaxis of human monocytes. None of the viral proteins blocked interleukin-8-mediated calcium flux or chemotaxis of human neutrophils, confirming that the biological specificity of the T1/35kDa family is targeted inhibition of CC-chemokines. Despite the significant sequence divergence between the leporipoxvirus T1 and orthopoxvirus 35kDa proteins, our data suggest that their CC-chemokine binding and inhibitory properties appear to be species nonspecific and that the critical motifs most likely reside within the limited regions of conservation.

Published

1998

17. Characterization of a DNA Topoisomerase Encoded byAmsacta mooreiEntomopoxvirus

Author

Petersen, Birgitte ø., Hall, Richard L., Moyer, Richard W., and Shuman, Stewart

Abstract

We have identified anAmsacta mooreientomopoxvirus (AmEPV) gene encoding a DNA topoisomerase. The 333-amino acid AmEPV topoisomerase displays instructive sequence similarities to the previously identified topoisomerases encoded by five genera of vertebrate poxviruses. One hundred nine amino acids are identical or conserved among the six proteins. The gene encoding AmEPV topoisomerase was expressed in bacteria and the recombinant enzyme was partially purified. AmEPV topoisomerase is a monomeric enzyme that catalyzes the relaxation of supercoiled DNA. Like the vaccinia, Shope fibroma virus, and Orf virus enzymes, the AmEPV topoisomerase forms a covalent adduct with duplex DNA at the target sequence CCCTT↓. The kinetic and equilibrium parameters of the DNA cleavage reaction of AmEPV topoisomerase (kobs= 0.08 sec−1;Kcl= 0.22) are similar to those of the vaccinia virus enzyme.

Published

1997

18. Control of Apoptosis by Poxviruses

Author

Turner, Peter C. and Moyer, Richard W.

Abstract

Poxviruses express a variety of proteins which can function to inhibit apoptosis in infected cells, allowing virus replication to continue and conferring a broad host range. Some poxvirus antiapoptosis proteins act by sequestering or inactivating inducers of apoptosis such as dsRNA and superoxide anions. Others interfere with signaling by receptors including those belonging to the TNF receptor superfamily that would otherwise activate a proteolytic cascade that terminates with the cleavage of death substrates. The cowpox virus crmA protein directly inhibits cysteine proteinases within the cascade and can also block apoptosis triggered by the serine proteinase granzyme B. Finally there are poxvirus antiapoptosis proteins containing ankyrin repeat regions that are thought to interact with cellular proteins.

Published

1998

19. The Non-Permissive Infection of Insect (Gypsy Moth) LD-652 Cells by Vaccinia Virus

Author

Li, Yi, Yuan, Shala, and Moyer, Richard W.

Abstract

The members ofPoxviridaefamily are among the most complex of animal viruses and subfamily members infect both vertebrate (Chordopoxvirinae) and invertebrate (Entomopoxvirinae) hosts, respectively. Vaccinia virus (VV) is the most commonly studied vertebrate virus and the entomopoxvirus ofAmsacta moorei(AmEPV) is the prototypic insect virus. AmEPV, while not able to productively infect vertebrate cells, does enter vertebrate cells and expresses early genes after which the infection aborts although the cells survive (Y. Li, R. L. Hall, and R. W. Moyer.J.Virol.71(12), 95579562, 1997). We show here that a recombinant VV, containing thelacZgene regulated by the cowpox virus A-type inclusion (ATI) late promoter, likewise does not productively infect insect cells. Our results suggest that the recombinant VV enters insect cells, host protein synthesis is inhibited, early gene expression is normal, and viral DNA replication occurs as does late protein synthesis. However, little if any proteolytic processing of late viral proteins, typical of morphogenesis, is observed. Electron micrographs of infected cells suggest that while cytoplasmic virosomes (factories) are formed, there is little indication of further morphogenesis or any formation of mature virions. Therefore, while both orthopoxviruses and entomopoxviruses fail to replicate in heterologous hosts, the nature of abortive infections is quite different.

Published

1998

20. The nature of naturally occurring mutations in the hemagglutinin gene of vaccinia virus and the sequence of immediately adjacent genes

Author

Brown, Charles K., Bloom, David C., and Moyer, Richard W.

Abstract

The expression of the vaccinia IHD-J hemagglutinin (HA) gene is regulated by two promoters, an early/late and a second distinct late promoter. The first promoter results in transcripts that begin early and are synthesized throughout the infection. All transcripts from this promoter initiate at the same 5′ site. A second promoter is only active late in infection and initiates transcription some distance upstream of the first promoter. We have previously shown that the transcriptional start site controlled by this second, “late only” promoter lies within the coding sequence of an upstream reading frame (p 16-ORF), whereas the termination of early transcription of the HA gene utilizes a transcription termination signal (TTTTTNT) located just beyond the coding region of an immediately downstream reading frame (p 17-ORF). In order to assist our understanding of HA gene expression, we report here the sequence of these two ORFs adjacent to the HA gene. The HA-ORF itself consists of 945 bp, whereas the upstream p 16-ORF consists of 429 bp and the downstream p 17-ORF of 453 bp, sufficient to encode polypeptides of 16 and 17 kD, respectively. While many strains of vaccinia are HA+, rabbitpox virus and the variant of vaccinia IHD-J, designated IHD-W, are HA-. We report and compare here the HA gene sequences of wild-type rabbit poxvirus, two spontaneous HA+revertants of rabbit poxvirus, and the HA-vaccinia strain IHD-W to that of the previously sequenced (1) prototype HA+IHD-J strain of vaccinia. All differences were found to occur within the HA open reading frame. Vaccinia virus IHD-W contains a two nucleotide (CA) insertion, leading to the creation of a premature translation termination signal. The HA gene of rabbitpox virus contains several base changes, two deletions of three and six bases, and a single adenine nucleotide deletion within a seven-base adenine repeat, creating a nonfunctional frameshift. Reversion of the HA-rabbitpox virus to HA+variants is accompanied on both occasions by reinsertion of the single deleted adenine nucleotide.

Published

1991

21. Cytotoxic T Lymphocyte-assisted Suicide

Author

Atkinson, Eric A., Barry, Michele, Darmon, Alison J., Shostak, Irene, Turner, Peter C., Moyer, Richard W., and Bleackley, R. Chris

Abstract

Cytototoxic T lymphocyte-induced apoptosis can occur either through the directed exocytosis of granzyme B and perforin or via ligation of Fas. Both pathways involve the activation of a family of cysteine proteinases, the caspases, that cleave substrates at aspartic acid and are themselves activated by cleavage at internal aspartate residues. Fas recruits caspase 8, which initiates the death program through the subsequent activation of caspase 3. Granzyme B can process both caspase 8 and 3 in vitro, suggesting that both Fas and granzyme B access the apoptotic program in the same way. Here we demonstrate that although the two mechanisms are similar, the events that lead to activation of caspase 3 can be distinguished in vivoon the basis of their sensitivities to both pharmacological and virus-encoded caspase inhibitors. In cytotoxic T lymphocytes-mediated death the initial cleavage event on caspase 3 is insensitive to benzyloxycarbonyl-Val-Ala-Asp fluoromethyl ketone (zVAD-fmk) inhibition in both mouse and human systems. During Fas-mediated death, however, activation of caspase 3 is completely inhibited to zVAD-fmk. In addition, the viral serpin SPI-2, a homologue of cytokine response modifier A (crmA), is an effective inhibitor of the Fas but not the granzyme pathway. Our results demonstrate that whereas Fas-mediated activation of caspase 3 requires an upstream caspase activity that is zVAD-fmk-sensitive, the initial cleavage of caspase 3 during granule-mediated cell death is insensitive to zVAD-fmk, suggesting that caspase 3 is cleaved directly by granzyme Bin vivo.

Published

1998

22. PATTERNS OF RNA SYNTHESIS IN T5-INFECTED CELLS I. AS STUDIED BY THE TECHNIQUE OF DNA-RNA HYBRIDIZATION-COMPETITION*

Author

Moyer, Richard W. and Buchanan, John M.

Abstract

The RNA-labeling patterns obtained after T5 infection of Escherichia coliF agree with the patterns of protein labeling published by McCorquodale and Buchanan.1Three distinct classes of RNA formed sequentially during the period of viral development can be recognized by the DNA-RNA hybridization-competition technique. Class I RNA is formed within 5 minutes after the beginning of viral metabolism and corresponds to the RNA synthesized in response to infection with the 8 per cent segment of T5 DNA. Protein synthesis directed by this 8 per cent segment is required in some capacity for the cessation of class I synthesis and the beginning of the synthesis of class II at 4 to 5 min after infection. Class III RNA synthesis begins between 9 and 12 minutes. Its appearance is prevented when chloramphenicol is added immediately after complete expression of class I functions.

Published

1969

23. In VivoRepair of the Single-Strand Interruptions Contained in Bacteriophage T5 DNA

Author

Herman, Ronald C. and Moyer, Richard W.

Abstract

Bacteriophage T5 is known to contain several unique single-strand interruptions in only one strand of the duplex DNA. Analysis of labeled parental phage DNA from infected Escherichia colishows that these nicks are repaired in vivoto yield intact double-stranded molecules. Sealing begins at about 6 min after infection and is independent of DNA replication. Repair may be an ordered process that starts at a unique end of the molecule.

Published

1974

24. Palm Beach Party.

Author

Moyer, Richard W.

Subjects

PALM Beach Party (Poem), MOYER, Richard W.

Abstract

Presents the poem "Palm Beach Party," by Richard W. Moyer. First Line: a rumble of drum rhythm, Last Line: "Quit fucking my sister!"

Published

2006