Myristylation of rotavirus proteins

Development of porcine rotavirus vp6 protein based ELISA for differentiation of this virus and other viruses

Background

The context and purpose of the study included 1) bacterial expression of viral protein 6 (VP6) of porcine rotavirus (PRV) and generation of rabbit polyclonal antiserum to the VP6 protein; 3) establishment of a discrimination ELISA to distinguish PRV from a panel of other porcine viruses.

Results

The VP6 gene of PRV isolate DN30209 amplified by reverse transcription-PCR was 1356 bp containing a complete open reading frame (ORF) encoding 397 amino acids. Sequence comparison and phylogenetic analysis indicated that PRV DN30209 may belong to group A of rotavirus. Bacterially expressed VP6 was expressed in E.coli and anti-VP6 antibody was capable of distinguishing PRV from Porcine transmissible gastroenteritis virus, Porcine epidemic diarrhea virus, Porcine circovirus type II, Porcine reproductive and respiratory syndrome virus, Porcine pseudorabies virus and Porcine parvovirus.

Conclusions

PRV VP6 expressed in E. coli can be used to generate antibodies in rabbit; anti-VP6 serum antibody can be used as good diagnostic reagents for detection of PRV.

Viruses exploiting peroxisomes

Viruses that are of great importance for global public health, including HIV, influenza and rotavirus, appear to exploit a remarkable organelle, the peroxisome, during intracellular replication in human cells. Peroxisomes are sites of lipid biosynthesis and catabolism, reactive oxygen metabolism, and other metabolic pathways. Viral proteins are targeted to peroxisomes (the spike protein of rotavirus) or interact with peroxisomal proteins (HIV's Nef and influenza's NS1) or use the peroxisomal membrane for RNA replication. The Nef interaction correlates strongly with the crucial Nef function of CD4 downregulation. Viral exploitation of peroxisomal lipid metabolism appears likely. Mostly, functional significance and mechanisms remain to be elucidated. Recently, peroxisomes were discovered to play a crucial role in the innate immune response by signaling the presence of intracellular virus, leading to the first rapid antiviral response. This review unearths, interprets and connects old data, in the hopes of stimulating new and promising research.

Caveolar endocytosis of simian virus 40 is followed by brefeldin A-sensitive transport to the endoplasmic reticulum, where the virus disassembles

Simian virus 40 (SV40) enters cells by atypical endocytosis mediated by caveolae that transports the virus to the endoplasmic reticulum (ER) instead of to the endosomal-lysosomal compartment, which is the usual destination for viruses and other cargo that enter by endocytosis. We show here that SV4O is transported to the ER via an intermediate compartment that contains beta-COP, which is best known as a component of the COPI coatamer complexes that are required for the retrograde retrieval pathway from the Golgi to the ER. Additionally, transport of SV40 to the ER, as well as infection, is sensitive to brefeldin A. This drug acts by specifically inhibiting the ARF1 GTPase, which is known to regulate assembly of COPI coat complexes on Golgi cisternae. Moreover, some beta-COP colocalizes with intracellular caveolin-1, which was previously shown to be present on a new organelle (termed the caveosome) that is an intermediate in the transport of SV40 to the ER (L. Pelkmans, J. Kartenbeck, and A. Helenius, Nat. Cell Biol. 3:473-483, 2001). We also show that the internal SV40 capsid proteins VP2 and VP3 become accessible to immunostaining starting at about 5 h. Most of that immunostaining overlays the ER, with some appearing outside of the ER. In contrast, immunostaining with anti-SV40 antisera remains confined to the ER.

Identification of a type 1 peroxisomal targeting signal in a viral protein and demonstration of its targeting to the organelle

Peroxisomes are unimembrane, respiratory organelles of the cell. Transport of cellular proteins to the peroxisomal matrix requires a type 1 peroxisomal targeting signal (PTS1) which essentially constitutes a tripeptide from the consensus sequence S/T/A/G/C/N-K/R/H-L/I/V/M/A/F/Y. Although PTS-containing proteins have been identified in eukaryotes, prokaryotes, and parasites, viral proteins with such signals have not been identified so far. We report here the first instance of a virus, the rotavirus, which causes infantile diarrhea worldwide, containing a functional C-terminal PTS1 in one of its proteins (VP4). Analysis of 153 rotavirus VP4-deduced amino acid sequences identified five groups of conserved C-terminal PTS1 tripeptide sequences (SKL, CKL, GKL, CRL, and CRI), of which CRL is represented in approximately 62% of the sequences. Infection of cells by a CRL-containing representative rotavirus (SA11 strain) and confocal immunofluorescence analysis revealed colocalization of VP4 with peroxisomal markers and morphological changes of peroxisomes. Further, transient cellular expression of green fluorescent protein (GFP)-fused VP4CRL resulted in transport of VP4 to peroxisomes, whereas the chimera lacking the PTS1 signal, GFP-VP4DeltaCRL, resulted in diffuse cytoplasmic staining, suggesting a CRL-dependent targeting of the protein. The present study therefore demonstrates hitherto unreported organelle involvement, specifically of the peroxisomes, in rotaviral infections as demonstrated by using the SA11 strain of rotavirus and opens a new line of investigation toward understanding viral pathogenesis and disease mechanisms.

Human group C rotavirus: completion of the genome sequence and gene coding assignments of a non-cultivatable rotavirus

Genome segments 1 and 2 of human group C rotavirus 'Bristol' strain were sequenced and their gene-protein coding properties assigned. This work completed the genome sequence of a human group C rotavirus (17,910 bp) and allowed the full gene-protein coding assignment of the 11 segments of dsRNA. Gene 1 is 3309 bp in size and contains a single ORF of 3272 nucleotides, encoding a protein of 1090 amino acids in length with a predicted molecular mass of 125 kDa. Comparison of the translated sequence with cognate published mammalian group A, B and C rotavirus sequences showed 45.2, 26.4 and 92.6% identity, respectively. The sequence contains conserved amino acid motifs including the classic RNA-dependent RNA polymerase motif GDD, indicating that segment 1 encodes the group C rotavirus polymerase protein. Gene 2 is 2736 bp in size and contains a single ORF of 2655 nucleotides encoding a protein of 884 amino acids in length with a calculated molecular mass of 102 kDa. Database searches showed highest homology with VP2, the main structural component of the 'core' from group A rotaviruses (46% identity). Alignment of the human group C and A rotavirus VP2 proteins revealed several characteristics common to nucleic acid binding proteins. However, these features were not shared with group B rotavirus VP2.

Interaction of polyomavirus internal protein VP2 with the major capsid protein VP1 and implications for participation of VP2 in viral entry

A complex of the polyomavirus internal protein VP2/VP3 with the pentameric major capsid protein VP1 has been prepared by co-expression in Escherichia coli. A C-terminal segment of VP2/VP3 is required for tight association, and a crystal structure of this segment, complexed with a VP1 pentamer, has been determined at 2.2 A resolution. The structure shows specific contacts between a single copy of the internal protein and a pentamer of VP1. These interactions were not detected in the previously described structure of the virion, but the location of VP2 in the recombinant complex is consistent with features in the virion electron-density map. The C-terminus of VP2/VP3 inserts in an unusual, hairpin-like manner into the axial cavity of the VP1 pentamer, where it is anchored strongly by hydrophobic interactions. The remainder of the internal protein appears to have significant flexibility. This structure restricts possible models for exposure of the internal proteins during viral entry.

Myristoylation

N-myristoylation is an acylation process absolutely specific to the N-terminal amino acid glycine in proteins. This maturation process concerns about a hundred proteins in lower and higher eukaryotes involved in oncogenesis, in secondary cellular signalling, in infectivity of retroviruses and, marginally, of other virus types. Thy cytosolic enzyme responsible for this activity, N-myristoyltransferase (NMT), studied since 1987, has been purified from different sources. However, the studies of the specificities of the various NMTs have not progressed in detail except for those relating to the yeast cytosolic enzyme. Still to be explained are differences in species specificity and between various putative isoenzymes, also whether the data obtained from the yeast enzyme can be transposed to other NMTs. The present review discusses data on the various addressing processes subsequent to myristoylation, a patchwork of pathways that suggests myristoylation is only the first step of the mechanisms by which a protein associates with the membrane. Concerning the enzyme itself, there are evidences that NMT is also present in the endoplasmic reticulum and that its substrate specificity is different from that of the cytosolic enzyme(s). These differences have major implications for their differential inhibition and for their respective roles in several pathologies. For instance, the NMTs from mammalians are clearly different from those found in several microorganisms, which raises the question whether the NMT may be a new targets for fungicides. Finally, since myristoylation has a central role in virus maturation and oncogenesis, specific NMT inhibitors might lead to potent antivirus and anticancer agents.

The structure of simian virus 40 refined at 3.1 A resolution

BACKGROUND

The structure of simian virus 40 (SV40), previously determined at 3.8 degree resolution, shows how its pentameric VP1 assembly units are tied together by extended C-terminal arms. In order to define more precisely the possible assembly mechanisms, we have refined the structure at 3.1 degree resolution.

RESULTS

New data from a high-intensity synchrotron source have been used for phase extension by electron-density averaging and refinement, exploiting only the strict 5-fold non-crystallographic symmetry for the real-space averaging steps. The accurate model enables us to study important structural features of the virus particle in detail. The remarkably invariant core of the VP1 pentamer bears the docking sites for the C-terminal arms from other pentamers. These contacts are the principal way in which pentameric assembly units are linked together in the capsid. Only at the interface between five-coordinated and six-coordinated pentamers do the pentamer cores appear to interact strongly. There are two cation-binding sites per VP1 monomer, seen in a soaking experiment with gadolinium nitrate. These sites are quite close to each other at the interfaces between pentamers.

CONCLUSION

We propose that the contact between five-coordinated and six-coordinated pentamers may help to generate a six-pentamer nucleus, with which further pentamers can assemble to generate the complete particle. Calcium ions probably stabilize the structure of the assembled particle, rather than direct its assembly.

Interactions among the major and minor coat proteins of polyomavirus

Murine polyomavirus contains two related minor coat proteins, VP2 and VP3, in addition to the major coat protein, VP1. The sequence of VP3 is identical to that of the carboxy-terminal two-thirds of VP2. VP2 may serve a role in uncoating of the virus, and both minor coat proteins may be important for viral assembly. In this study, we show that VP3 and a series of deletion mutants of VP3 can be expressed in Escherichia coli as fusion proteins to glutathione S-transferase and partially solubilized with a mild detergent. Using an in vitro binding assay, we demonstrate that a 42-amino-acid fragment near the carboxy terminus of VP3 (residues 140 to 181) is sufficient for binding to purified VP1 pentamers. This binding interaction is rapid, saturable, and specific for the common carboxy terminus of VP2 and VP3. The VP1-VP3 complex can be coimmunoprecipitated with an antibody specific to VP1, and a purified VP3 fragment can selectively extract VP1 from a crude cell lysate. The stoichiometry of the binding reaction suggests that each VP1 pentamer in the virus binds either one VP2 or one VP3, with the VP1-VP2/3 complex stabilized by hydrophobic interactions. These results, taken together with studies from other laboratories on the expression of polyomavirus capsid proteins in mouse and insect cells (S. E. Delos, L. Montross, R. B. Moreland, and R. L. Garcea, Virology, 194:393-398, 1993; J. Forstova, N. Krauzewicz, S. Wallace, A. J. Street, S. M. Dilworth, S. Beard, and B. E. Griffin, J. Virol. 67:1405-1413, 1993), support the idea that a VP1-VP2/3 complex forms in the cytoplasm and, after translocation into the nucleus, acts as the unit for viral assembly.

Characterization of a polyhistidine-tagged form of human myristoyl-CoA: protein N-myristoyltransferase produced in Escherichia coli

The enzyme myristoyl-CoA:protein N-myristoyltransferase is responsible for the attachment of a myristoyl group to the N-terminal glycine of a number of cell, viral and fungal proteins. In order to overcome the difficulties of purification of this enzyme from tissue sources, we have produced an N-terminally polyhistidine-tagged version of the enzyme and expressed this in Escherichia coli. The resulting enzyme has a molecular mass of 53 kDa and is fully active showing the expected specificity for myristic acid and causing the N-terminal myristoylation of both synthetic peptide and protein substrates in vitro. The enzyme exhibits a broad pH optimum peaking at a pH of 8.0 and has a Km for myristoyl-CoA of 7.6 microM. The two synthetic peptide substrates based on the N-terminal sequence of the catalytic subunit of protein kinase A (GNAAAARR) and of p60src (GSSKSKPKDPSQRRRY) have different kinetic parameters with Km values of 115.2 microM and 44.2 microM and Vmax values of 95 and 120 nmol.min-1.mg-1, respectively. The expressed enzyme is partially inhibited (50%) by iodoacetamide at 5 mM and fully inhibited by diethylpyrocarbonate at 10 mM. This latter inhibition can be prevented by including histidine in the incubation of the enzyme and inhibitor. Antisera raised to synthetic peptides based on sequences derived from the N- and C- terminus of the human enzyme reacted with the expressed protein on Western blots, but only the N-terminal sequence reacted with the native protein suggesting that the C-terminus may be not be accessible. The enzyme can catalyse the removal of a myristoyl group from myristoylated peptides but does so only in the presence of added coenzyme A.

Rearrangement of the VP6 gene of a group A rotavirus in combination with a point mutation affecting trimer stability

A group A rotavirus isolated from a lamb with diarrhea in Qinhai province, China, was serially passaged in fetal calf kidney cells. In passage 96, rearrangements of RNA segments 5 and 6 of the viral genome were found. Here we report the nucleotide and predicted amino acid sequences of normal and rearranged RNA 6, coding for the major inner capsid protein VP6. In comparison with the normal gene (N6), the rearranged RNA 6 (R6) contained the normal open reading frame followed by a 473-nucleotide (nt) duplication of the gene beginning 23 nt after the termination codon. The duplicated region starts at nt 768 and runs through to the 3' end of the gene. In accordance with the nucleotide sequence of the rearranged RNA 6, a normal-length VP6 product was found in cells infected with the mutant. However, a single-amino-acid change from proline to glutamine at position 309 slightly affected the electrophoretic mobility of the VP6 monomer of the R6 mutant and reduced the stability of VP6 trimers on gels and at low pH values compared with the normal gene product. The degree of relatedness of VP6 of the Chinese lamb rotavirus Lp14 to those of other group A rotaviruses was determined.

Purification and partial sequencing of myristoyl-CoA:protein N-myristoyltransferase from bovine brain

The enzyme myristoyl-CoA:protein N-myristoyltransferase (NMT; EC 2.3.1.97) catalyses the transfer of myristic acid to the N-terminal glycine residue of cell and viral proteins. In this report the purification and partial sequencing of this enzyme from bovine brain is described. Using a combination of ammonium sulphate precipitation, chromatography on DEAE-Sepharose and affinity chromatography on CoA-agarose the enzyme was purified some 40-fold. Size-exclusion chromatography of this material in the presence of myristoyl-CoA yielded two peaks of enzyme activity with apparent molecular masses of 66 kDa and 43 kDa. Chromatography of the CoA-affinity-purified material on MONO-S followed by size-exclusion chromatography in the presence of myristoyl-CoA resulted in the isolation of the large form of the enzyme purified 3000-fold. Analysis by SDS/PAGE of this material showed a major 60 kDa silver-stained band. Similar analysis of the 43 kDa enzyme fraction from the same separation showed that this fraction contained several proteins including a major component with an apparent molecular mass of 49 kDa. Attempts at N-terminal sequencing of the 66 kDa form of the enzyme were unsuccessful and therefore this material was digested with trypsin and the resulting peptides separated by reverse-phase h.p.l.c. N-terminal protein sequencing of these peptides yielded sequences which show sequence similarity to those of yeast N-myristoyl-transferase.

Myristoylation is important at multiple stages in poliovirus assembly

The N-terminal glycine of the VP4 capsid subunit of poliovirus is covalently modified with myristic acid (C14 saturated fatty acid). To investigate the function of VP4 myristoylation in poliovirus replication, amino acid substitutions were placed within the myristoylation consensus sequence at the alanine residue (4003A) adjacent to the N-terminal glycine by using site-directed mutagenesis methods. Mutants which replace the alanine residue with a small hydrophobic residue such as leucine, valine, or glycine displayed normal levels of myristoylation and normal growth kinetics. Replacement with the polar amino acid histidine (4003A.H) also resulted in a level of myristoylation comparable to that of the wild type. However, replacement of the alanine residue with aspartic acid (4003A.D) caused a dramatic reduction (about 40 to 60%) in myristoylation levels of the VP4 precursors (P1 and VP0). In contrast, no differences in modification levels were found in either VP0 and VP4 proteins isolated from mature mutant virions, indicating that myristoylation is required for assembly of the infectious virion. The myristoylation levels of the VP0 proteins found in capsid assembly intermediates indicate that there is a strong but not absolute preference for myristoyl-modified subunits during pentamer formation. Complete myristoylation was observed in mature virions but not in assembly intermediates, indicating that there is a selection for myristoyl-modified subunits during stable RNA encapsidation to form the mature virus particle. In addition, even though mutant infectious virions are fully modified, the severe reduction in specific infectivity of both 4003A.D and 4003A.H purified viruses indicates that the amino acid residue adjacent to the N-terminal glycine apparently has an additional role early during viral infection and that mutations at this position induce pleiotropic effects.

Rotavirus NS26 is modified by addition of single O-linked residues of N-acetylglucosamine

We studied the post-translational modification of NS26, the protein product of rotavirus gene 11 segment. Based on the presence of a putative N-glycosylation site and the high content of serine and threonine residues in gene 11 amino acid sequence we investigated whether NS26 is modified by carbohydrate addition. Specific antibodies raised against the gene 11 product expressed in Escherichia coli recognized in infected cells two polypeptides with apparent molecular weight of 26,000 (26-kDa polypeptide) and 28,000 (28-kDa polypeptide). Pulse-chase experiments demonstrated that the 26-kDa product was processed to the 28-kDa polypeptide. Both polypeptides were metabolically labeled with [3H]glucosamine, indicating the presence of a carbohydrate moiety on the protein. NS26 was found to be resistant to endo-beta-N-acetylglucosaminidase H and endo-beta-N-acetylglucosaminidase F/peptide:N-glycosidase F treatment, but sensitive to removal by alkali-induced beta-elimination, suggesting that the saccharide chain was attached to the protein via an O-glycosidic linkage. Chromatographic analysis of total acid hydrolysates of [3H]glucosamine-labeled NS26-bound carbohydrate indicated the presence of N-acetylglucosamine. In addition, mild alkaline treatment of NS26 in the presence of NaB3H4 identified the O-linked carbohydrate moiety as N-acetylglucosamine. Taken together, these data demonstrate that NS26 is processed to a 28-kDa polypeptide by addition of O-linked monosaccharide residues of N-acetylglucosamine.

Mammalian reoviruses contain a myristoylated structural protein

The structural protein mu 1 of mammalian reoviruses was noted to have a potential N-myristoylation sequence at the amino terminus of its deduced amino acid sequence. Virions labeled with [3H]myristic acid were used to demonstrate that mu 1 is modified by an amide-linked myristoyl group. A myristoylated peptide having a relative molecular weight (Mr) of approximately 4,000 was also shown to be a structural component of virions and was concluded to represent the 4.2-kDa amino-terminal fragment of mu 1 which is generated by the same proteolytic cleavage that yields the carboxy-terminal fragment and major outer capsid protein mu 1C. The myristoylated 4,000-Mr peptide was found to be present in reovirus intermediate subviral particles but to be absent from cores, indicating that it is a component of the outer capsid. A distinct large myristoylated fragment of the intact mu 1 protein was also identified in intermediate subviral particles, but no myristoylated mu-region proteins were identified in cores, consistent with the location of mu 1 in the outer capsid. Similarities between amino-terminal regions of the reovirus mu 1 protein and the poliovirus capsid polyprotein were noted. By analogy with other viruses that contain N-myristoylated structural proteins (particularly picornaviruses), we suggest that the myristoyl group attached to mu 1 and its amino-terminal fragments has an essential role in the assembly and structure of the reovirus outer capsid and in the process of reovirus entry into cells.

Myristylation and polylysine-mediated activation of the protein kinase domain of the large subunit of herpes simplex virus type 2 ribonucleotide reductase (ICP10)

The amino-terminal domain of the large subunit of herpes simplex virus type 2 (HSV-2) ribonucleotide reductase (ICP10) was previously shown to possess protein kinase (PK) activity that localizes to the cytosolic, cytoskeletal, and plasma membrane fractions. Further studies of the PK domain using computer-assisted sequence analysis have identified a single transmembrane segment and fatty acid incorporation findings indicate that ICP10 is myristylated. Myristylation does not depend on a viral enzyme, since myristic acid is incorporated into ICP10 precipitated from cells transfected with an ICP10 expression vector. It is also incorporated into the 57-kDa protein expressed by the amino-terminal PK expression vector. The myristyl moiety is linked through an amide bond. The basic protein polylysine stimulates the kinase activity and alters its divalent cation requirements resulting in 20- to 40-fold stimulation in the presence of 0.1 mM Mn2+. The PK activity is inhibited by antibody to synthetic peptides corresponding to residues 355-369 and 13-26, respectively, located within, and amino-terminal to, the predicted PK catalytic domain.

Intracellular RNA synthesis directed by temperature-sensitive mutants of simian rotavirus SA11

The kinetics of intracellular synthesis of single-stranded (ss) RNA and double-stranded (ds) RNA directed by prototype temperature-sensitive (ts) mutants representing the 10 mutant groups of rotavirus SA11 were examined. Cells were infected with individual mutants or wild type under one-step growth conditions and maintained at permissive temperature (31 degrees) or nonpermissive temperature (39 degrees). At various times postinfection, infected cells were pulse-labeled, ssRNA and dsRNA were purified, RNA species were resolved by electrophoresis and autoradiography, and RNA synthesis was quantitated by computer-assisted densitometry. The mutants representing all groups synthesized significantly less ssRNA and dsRNA at both 31 degrees and 39 degrees, when compared to wild type. When the ratio of synthesis at 39 degrees/31 degrees was determined for ssRNA and dsRNA of each mutant, three RNA synthesis phenotypes were evident. The tsB(339), tsC(606), and tsE(1400) mutants synthesized both ssRNA and dsRNA in a temperature-dependent manner. The group G mutant, tsG(2130), synthesized ssRNA in temperature-independent fashion but was temperature-dependent for the synthesis of dsRNA. The remaining mutants, tsA(778), tsD(975), tsF(2124), tsH(2384), tsI(2403), and tsJ(2131), synthesized both ssRNA and dsRNA in a temperature-independent fashion. The RNA synthesis phenotypes of the ts mutants are discussed in terms of what is known of the function(s) of the protein species to which ts lesions have been assigned.

Polypeptide composition of rotavirus empty capsids and their possible use as a subunit vaccine

Two types of empty capsid particles that differed with respect to the presence of the two outer shell proteins were isolated from MA-104 cells infected with bovine rotavirus V1005. Three previously uncharacterized polypeptides, I, II, and III, migrating between VP2 and VP6, were detected in empty capsids but not in single- and double-shelled rotavirus particles. Peptide mapping revealed that all three proteins were related to VP2. Polypeptides I, II, and III could be generated by in vitro trypsin digestion of empty capsids not exposed to trypsin in the infection medium. Labeled polypeptides appeared in empty capsids before they were detected in intracellular single- or double-shelled rotavirus particles. Empty capsids were also observed in MA-104 cells infected with bovine rotaviruses UK and NCDV, simian rotavirus SA11, and human rotavirus KU. VP7-containing empty capsid is the minimal subunit vaccine for cows; we failed to induce a substantial neutralizing antibody increase with VP7 purified under denaturating or nondenaturating conditions or with synthetic peptides corresponding to two regions of VP7.

Rotavirus gene structure and function

Knowledge of the structure and function of the genes and proteins of the rotaviruses has expanded rapidly. Information obtained in the last 5 years has revealed unexpected and unique molecular properties of rotavirus proteins of general interest to virologists, biochemists, and cell biologists. Rotaviruses share some features of replication with reoviruses, yet antigenic and molecular properties of the outer capsid proteins, VP4 (a protein whose cleavage is required for infectivity, possibly by mediating fusion with the cell membrane) and VP7 (a glycoprotein), show more similarities with those of other viruses such as the orthomyxoviruses, paramyxoviruses, and alphaviruses. Rotavirus morphogenesis is a unique process, during which immature subviral particles bud through the membrane of the endoplasmic reticulum (ER). During this process, transiently enveloped particles form, the outer capsid proteins are assembled onto particles, and mature particles accumulate in the lumen of the ER. Two ER-specific viral glycoproteins are involved in virus maturation, and these glycoproteins have been shown to be useful models for studying protein targeting and retention in the ER and for studying mechanisms of virus budding. New ideas and approaches to understanding how each gene functions to replicate and assemble the segmented viral genome have emerged from knowledge of the primary structure of rotavirus genes and their proteins and from knowledge of the properties of domains on individual proteins. Localization of type-specific and cross-reactive neutralizing epitopes on the outer capsid proteins is becoming increasingly useful in dissecting the protective immune response, including evaluation of vaccine trials, with the practical possibility of enhancing the production of new, more effective vaccines. Finally, future analyses with recently characterized immunologic and gene probes and new animal models can be expected to provide a basic understanding of what regulates the primary interactions of these viruses with the gastrointestinal tract and the subsequent responses of infected hosts.

Fatty acid acylation of vaccinia virus proteins

Labeling of vaccinia virus-infected cells with [3H]myristic acid resulted in the incorporation of label into two viral proteins with apparent molecular weights of 35,000 and 25,000 (designated M35 and M25, respectively). M35 and M25 were expressed in infected cells after the onset of viral DNA replication, and both proteins were present in purified intracellular virus particles. Virion localization experiments determined M25 to be a constituent of the virion envelope, while M35 appeared to be peripherally associated with the virion core. M35 and M25 labeled by [3H]myristic acid were stable to treatment with neutral hydroxylamine, suggesting an amide-linked acylation of the proteins. Chromatographic identification of the protein-bound fatty acid moieties liberated after acid methanolysis of M25, isolated from infected cells labeled during a 4-h pulse, resulted in the recovery of 25% of the protein-bound fatty acid as myristate-associated label and 75% as palmitate, indicating that interconversion of myristate to palmitate had occurred during the labeling period. Similar analyses of M25 and M35, isolated from infected cells labeled during a 0.5-h pulse, determined that 46 and 43%, respectively, of the protein-bound label had been elongated to palmitate even during this brief labeling period. In contrast, M25 and M35 isolated from purified intracellular virions labeled continuously during 24 h of growth contained 75 and 70%, respectively, myristate-associated label, suggesting greater stability of these proteins or a favored interaction of the proteins containing myristate with the maturing or intracellular virion.