Protein bound to the genome RNAs of cowpea mosaic virus

Cowpea Mosaic Virus Outperforms Other Members of the Secoviridae as In Situ Vaccine for Cancer Immunotherapy

In situ vaccination for cancer immunotherapy uses intratumoral administration of small molecules, proteins, nanoparticles, or viruses that activate pathogen recognition receptors (PRRs) to reprogram the tumor microenvironment and prime systemic antitumor immunity. Cowpea mosaic virus (CPMV) is a plant virus that─while noninfectious toward mammals─activates mammalian PRRs. Application of CPMV as in situ vaccine (ISV) results in a potent and durable efficacy in tumor mouse models and canine patients; data indicate that CPMV outperforms small molecule PRR agonists and other nonrelated plant viruses and virus-like particles (VLPs). In this work, we set out to compare the potency of CPMV versus other plant viruses from the Secoviridae. We developed protocols to produce and isolate cowpea severe mosaic virus (CPSMV) and tobacco ring spot virus (TRSV) from plants. CPSMV, like CPMV, is a comovirus with genome and protein homology, while TRSV lacks homology and is from the genus nepovirus. When applied as ISV in a mouse model of dermal melanoma (using B16F10 cells and C57Bl6J mice), CPMV outperformed CPSMV and TRSV─again highlighting the unique potency of CPMV. Mechanistically, the increased potency is related to increased signaling through toll-like receptors (TLRs)─in particular, CPMV signals through TLR2, 4, and 7. Using knockout (KO) mouse models, we demonstrate here that all three plant viruses signal through the adaptor molecule MyD88─with CPSMV and TRSV predominantly activating TLR2 and 4. CPMV induced significantly more interferon β (IFNβ) compared to TRSV and CPSMV; therefore, IFNβ released upon signaling through TLR7 may be a differentiator for the observed potency of CPMV-ISV. Additionally, CPMV induced a different temporal pattern of intratumoral cytokine generation characterized by significantly increased inflammatory cytokines 4 days after the second of 2 weekly treatments, as if CPMV induced a "memory response". This higher, longer-lasting induction of cytokines may be another key differentiator that explains the unique potency of CPMV-ISV.

Structures of the compact helical core domains of feline calicivirus and murine norovirus VPg proteins

We report the solution structures of the VPg proteins from feline calicivirus (FCV) and murine norovirus (MNV), which have been determined by nuclear magnetic resonance spectroscopy. In both cases, the core of the protein adopts a compact helical structure flanked by flexible N and C termini. Remarkably, while the core of FCV VPg contains a well-defined three-helix bundle, the MNV VPg core has just the first two of these secondary structure elements. In both cases, the VPg cores are stabilized by networks of hydrophobic and salt bridge interactions. The Tyr residue in VPg that is nucleotidylated by the viral NS7 polymerase (Y24 in FCV, Y26 in MNV) occurs in a conserved position within the first helix of the core. Intriguingly, given its structure, VPg would appear to be unable to bind to the viral polymerase so as to place this Tyr in the active site without a major conformation change to VPg or the polymerase. However, mutations that destabilized the VPg core either had no effect on or reduced both the ability of the protein to be nucleotidylated and virus infectivity and did not reveal a clear structure-activity relationship. The precise role of the calicivirus VPg core in virus replication remains to be determined, but knowledge of its structure will facilitate future investigations.

Inhibition of cleavage of a plant viral polyprotein by an inhibitor activity present in wheat germ and cowpea embryos

In rabbit reticulocyte lysate, the bottom component RNA of cowpea mosaic virus directs the synthesis of a 200,000-molecular-weight precursor protein (200K protein) that is cleaved during synthesis by a reticulocyte enzyme to form a 32K protein and a 170K protein. Cleavage of the 200K protein was found to be effectively inhibited by inhibitor activity in wheat germ and cowpea embryo extracts. The inhibitor was nondialyzable, precipitatable by ammonium sulfate, and partially stable at high temperatures. The activity appeared to be specific in that it caused no inhibition of the secondary cleavage reactions (cleavage of the 170K protein) at concentrations that were sufficient to cause complete inhibition of the primary cleavage reaction (cleavage of the 200K protein).

Expression of Middle-Component RNA of Cowpea Mosaic Virus: In Vitro Generation of a Precursor to Both Capsid Proteins by a Bottom-Component RNA-Encoded Protease from Infected Cells

The expression of the middle-component (M) RNA of cowpea mosaic virus was studied by means of in vitro translation. In both the wheat germ extract and the rabbit reticulocyte lysate, M RNA was translated into two overlapping polypeptides of 95 and 105 kilodaltons. Incubation of these polypeptides with 30,000 x g supernatant fractions from cowpea mesophyll protoplasts inoculated with complete virus or with separate bottom (B) components alone resulted in extensive processing, yielding polypeptides of 60, 58, 48, and 47 kilodaltons. Similar proteolytic activity was found associated with the in vitro translation products from the bottom-component RNA, demonstrating that the protease present in infected cells is encoded by B RNA. Using antisera raised against the separate capsid proteins VP23 and VP37, it was shown that the 60-kilodalton cleavage product is the precursor to both capsid proteins. Cleavage of nascent 95- and 105- kilodalton polypeptides by the in vivo protease demonstrated that this capsid protein precursor is located C terminally within both polypeptides and that the synthesis of these two overlapping polypeptides is the result of two initiation sites on middle-component RNA. In addition, a second virus-induced proteolytic activity, capable of releasing VP23 from the 95- and 105-kilodalton polypeptides, was detected in leaves of infected plants, but not in infected mesophyll protoplasts. A model for the expression of the middle-component RNA is presented.

Evidence That the 32,000-Dalton Protein Encoded by Bottom-Component RNA of Cowpea Mosaic Virus is a Proteolytic Processing Enzyme

Translation of middle-component RNA of cowpea mosaic virus in vitro produced two polypeptides of 95 and 105 kilodaltons (95K and 105K, respectively) with overlapping amino acid sequences, which were specifically cleaved by a protease encoded by the bottom-component RNA. The proteolytic cleavage was studied by the addition of antibodies raised against various bottom-component RNA-encoded proteins to extracts prepared from bottom-component RNA-inoculated cowpea protoplasts. Since antiserum to the 32K polypeptide efficiently inhibited the proteolytic activity of such extracts, although antiserum to VPg or to the 170K polypeptide did not, evidence was obtained which indicates that the 32K polypeptide represents the protease involved. Fractionation of proteolytically active extract by glycerol gradient centrifugation demonstrated that 32K polypeptides do not exist as free proteins but are aggregated to the bottom-component RNA-encoded 170K, 84K, 60K, or 58K polypeptides. Maximal proteolytic activity was observed for 32K polypeptides associated with 170K polypeptides, suggesting that the activity was unstable and confined to newly synthesized molecules.

Multimeric forms of satellite of tobacco ringspot virus RNA

An approximately 350-nucleotide residue RNA replicates in association with tobacco ringspot virus (TobRV) and becomes encapsidated in TobRV coat protein. Here we show by electrophoretic analyses that this small satellite RNA, RNA S, is the most abundant and most rapidly migrating of a series of at least ten encapsidated RNAs with RNA S sequences. A largely double-stranded RNA fraction from infected tissue, when denatured, gave a similar series of up to 12 zones that contained both RNA S sequences and sequences that hybridized to RNA S. Analysis of the mobilities suggests a weight increment between each zone corresponding approximately to the size of RNA S. Thus the more slowly migrating zones appear to contain covalent multimers of RNA S or, for tissue RNA, both multimers of RNA S and multimers of the complement of RNA S sequences. Neither terminal structure of TobRV genomic RNAs was found in the satellite RNA. RNA S lacks detectable polyadenylate or oligoadenylate. Covalently linked protein was not detected in RNA S or its more slowly migrating forms, and satellite RNA biological activity, unlike that of the TobRV RNAs, was not protease sensitive. Polynucleotide kinase catalyzed the phosphorylation of satellite RNAs, indicating free 5'-hydroxyl groups.

Evidence for a 58-kilodalton polypeptide as precursor of the coat protein of cauliflower mosaic virus

Purified cauliflower mosaic virus subjected to agarose gel electrophoresis separated into two zones, slow and fast, with the latter consisting of less than 5-10% of the total. When these two types of virions were excised from gels and subjected to analysis in dodecyl sulfate impregnated gels, the fast component consisted mainly of the 58- and 44-kilodalton (kd) phosphorylated forms of the coat protein whereas the slow component contained only lower molecular weight forms of the same protein. Pulse labeling experiments with 32P (as orthophosphate) or tritiated thymidine showed the fast electrophoretic form of the virus to become labeled more rapidly than the slow form. With long labeling periods the slow form accumulated more label than the fast form suggesting a precursor-product relationship between the fast and slow electrophoretic forms. With [32P]orthophosphate or [35S]methionine labeling, the 58-kd phosphorylated protein showed a much higher relative level of labeling than that obtained with protein stains such as Coomassie blue. With longer labeling periods greater amounts of activity appeared in the 44-kd and lower molecular weight forms of the coat protein. These results supported previous results suggesting that the 58-kd protein is the primary translation product of the coat protein gene and that this is the form used in encapsidation to produce mature virions.

Nucleotidylylation of the VPg protein of a human norovirus by its proteinase-polymerase precursor protein

Caliciviruses have a positive strand RNA genome covalently-linked at the 5'-end to a small protein, VPg. This study examined the biochemical modification of VPg by the ProPol form of the polymerase of human norovirus strain MD145 (GII.4). Recombinant norovirus VPg was shown to be nucleotidylylated in the presence of Mn2+ by MD145 ProPol. Phosphodiesterase I treatment of the nucleotidylylated VPg released the incorporated UMP, which was consistent with linkage of RNA to VPg via a phosphodiester bond. Mutagenesis analysis of VPg identified Tyrosine 27 as the target amino acid for this linkage, and suggested that VPg conformation was important for the reaction. Nucleotidylylation was inefficient in the presence of Mg2+; however the addition of full- and subgenomic-length MD145 RNA transcripts led to a marked enhancement of the nucleotidylylation efficiency in the presence of this divalent cation. Furthermore, evidence was found for the presence of an RNA element near the 3'-end of the polyadenylated genome that enhanced the efficiency of nucleotidylylation in the presence of Mg2+.

A multiple alignment of the capsid protein sequences of nepoviruses and comoviruses suggests a common structure

The amino acid sequences of the regions encoding the structural proteins of eleven nepoviruses and five comoviruses, two genera of the family Comoviridae, have been aligned. The properties predicted by computer analysis (three-dimensional-3D-structure, hydrophobicity) are also correlated along this alignment, and aligned to the experimentally determined 3D structure of two comoviruses. It can thus be assumed that the 3D structure of the unique nepovirus coat protein matches that of the bipartite protomer found in the comovirus particles. In this model, the spatial locations of two amino-acid motifs characteristic of nepoviruses are in close vicinity, at the external surface of the virion. The coat proteins of nepoviruses and comoviruses may thus share a common evolutionary origin. A phylogenetic analysis was made using the multiple alignment, allowing a better understanding of the molecular relationships between these two groups of viruses.

Improvements of the infectivity of in vitro transcripts from cloned cowpea mosaic virus cDNA: impact of terminal nucleotide sequences

Full-length DNA copies of both B- and M-RNA of cowpea mosaic virus (CPMV) were constructed downstream from a T7 promoter. By removal of nucleotides from the promoter sequence, B- and M-RNA-like transcripts with varying numbers of additional nonviral sequences at the 5' end were obtained upon transcription with T7 RNA polymerase. The infectivity of the transcripts in cowpea protoplasts was greatly affected by only a few extra nonviral nucleotides at the 5' end. The addition of about 400 nonviral nucleotides at the 3' end did not have any effect. Using the most infectious transcripts, in 40% of the cowpea protoplasts replication and expression of B-RNA like transcripts were observed and in 10% of the protoplasts both B- and M-RNA-like transcripts multiplied. Moreover, cowpea plants could also be infected with these transcripts. Sequence analysis showed that the 5' terminus of the M-RNA transcripts and the 3' terminus of the B-RNA transcripts were completely restored during replication in plants, including a poly(A) tail of variable length. Swapping experiments have been used to identify an influential point mutation in the coding region for the viral polymerase of a noninfectious B transcript. This experiment demonstrates the potential of the optimized infection system for future analysis of virus-encoded functions.

High-level synthesis of cowpea mosaic virus RNA polymerase and protease in Escherichia coli

An expression system for the production of polymerase proteins of cowpea mosaic virus (CPMV) in Escherichia coli cells is described. High-level synthesis of proteins containing protease and polymerase moieties (110-kDa protein) and polymerase alone (87-kDa protein) were obtained from cells containing different plasmid constructions. Precursor and processed forms of CPMV proteins were detected by immunoblotting with antisera directed against 170-kDa precursor polyprotein and 24-kDa viral protease. Crude lysates and supernatant fractions of the lysates from E. coli cells harboring the various plasmid constructions were analysed for poly(A)-oligo(U) polymerase activity and found to be negative for CPMV activity under conditions where similar expression systems for the production of poliovirus RNA polymerase activity were positive. Thus, conditions for CPMV RNA replication may indeed be different from those for poliovirus even though the genomic organization of these viruses is similar.

Mapping of the tobacco vein mottling virus VPg cistron

The location of the cistron encoding the genome-linked protein (VPg) in the potyvirus tobacco vein mottling virus (TVMV) was investigated. Precipitation of 125I-labeled VPg with anti-tobacco etch virus 49K nuclear inclusion protein antiserum (which reacts with the NIa nuclear inclusion protein of TVMV) indicated that the TVMV VPg is immunologically related to NIa. Lysyl residues were found to be present at positions 2, 11, and 16 of the amino-terminal region of the VPg. A search of the TVMV polyprotein sequence for this distribution of lysyl residues revealed a unique location beginning at amino acid residue 1801, the proposed amino-terminus of the NIa protein.

Two viral proteins involved in the proteolytic processing of the cowpea mosaic virus polyproteins

A series of specific deletion mutants derived from a full-length cDNA clone of cowpea mosaic virus (CPMV) B RNA was constructed with the aim to study the role of viral proteins in the proteolytic processing of the primary translation products. For the same purpose cDNA clones were constructed having sequences derived from both M and B RNA of CPMV. In vitro transcripts prepared from these clones with T7 RNA polymerase, were efficiently translated in rabbit reticulocyte lysates. The translation products obtained were processed in the lysate by specific proteolytic cleavages into smaller products, which made it possible to study subsequently the effect of the various mutations on this process. The results obtained indicate that the B RNA-encoded 24K polypeptide represents a protease responsible for all cleavages in the polyproteins produced by both CPMV B and M RNA. For efficient cleavage of the glutamine-methionine site in the M RNA encoded polyprotein the presence of a second B RNA encoded protein, the 32K polypeptide, is essential, although the 32K polypeptide itself does not have proteolytic activity. A number of cleavage-site mutants were constructed in which the coding sequence for the glutamine-glycine cleavage site between the two capsid proteins was changed. Subsequent in vitro transcription and translation of these cleavage site mutants show that a correct dipeptide sequence is a prerequisite for efficient cleavage but that the folding of the polypeptide chain also plays an important role in the formation of a cleavage site.

Proteolytic activity of the cowpea mosaic virus encoded 24K protein synthesized in Escherichia coli

The function of the 24-kilodalton (24K) protein encoded by cowpea mosaic virus (CPMV) has been studied by constructing a bacterial expression plasmid that contained a cloned chimeric segment consisting of partial DNA copies of CPMV M-RNA (including sequences coding for both capsid proteins) and B-RNA (including sequences coding for the 24K protein). Viral sequences were transcribed from the phage T7 promoter phi 10 of plasmid pT7-6 using T7-RNA polymerase expressed from plasmid pGP1-2 present in the same cells. Upon inducing the synthesis of T7-RNA polymerase several new polypeptides that contained CPMV-specific sequences were expressed, as demonstrated by immunoprecipitation and immunoblotting. Furthermore a proteolytic activity was detected in induced cells which cleaved the viral protein sequences specifically at two glutamine-glycine sites. One of the cleavage products represented capsid protein VP23. The proteolytic activity was absent when an 87-bp deletion was introduced in the coding region for the 24K protein, indicating that this protein represented the protease involved in the proteolytic processing at those specific sites.

Identification and characterization of a protein covalently bound to DNA of minute virus of mice

We identified a protein which is covalently linked to a fraction of the DNA synthesized in cells infected with minute virus of mice. This protein is specifically bound to the 5' terminus of the extended terminal conformers of the minute virus of mice replicative-form DNA species and of a variable fraction of single-stranded viral DNA. The chemical stability of the protein-DNA linkage is characteristic of a phosphodiester bond between a tyrosine residue in the protein and the 5' end of the DNA. The terminal protein (TP) bound on all DNA forms has a relative molecular weight of 60,000; it is also seen free in extracts from infected cells. Immunologic comparison of the TP with the other known viral proteins suggests that the TP is not related to the capsid proteins or NS-1.

Cleavage of a viral polyprotein by a cellular proteolytic activity

The 200,000-dalton polyprotein encoded by the bottom component RNA of cowpea mosaic virus was synthesized in rabbit reticulocyte lysates, and this in vitro-synthesized protein was isolated from the lysate reaction mixture by sucrose density gradient centrifugation. Incubation of the isolated polyprotein with buffer caused no change in the protein, but incubation with reticulocyte lysates or with fractionated lysate proteins resulted in cleavage of the protein into the expected cleavage products (32,000- and 170,000-dalton proteins). This finding indicated that reticulocytes contain a proteolytic activity that is needed for the primary cleavage reaction. A cleavage assay in which we used partially purified preparations showed that cleavage was an ATP-dependent reaction.

An absolute requirement for the 5' cap structure for mRNA translation in sea urchin eggs

Translation of a variety of RNAs was studied in a cell-free translation system derived from sea urchin eggs. While RNAs such as globin or tobacco mosaic virus are efficiently translated, viral RNAs which do not contain the 5' cap structure, such as cow pea mosaic virus (CPMV) and poliovirus, are not translated. Mixing experiments with reticulocyte lysates indicated that the lack of translation of uncapped viral RNAs is not due to the presence of a potent inhibitor or the absence of an activating agent. RNA competition experiments between capped and uncapped RNAs indicated that uncapped RNAs do not interact with the sea urchin egg initiation machinery. Proteolytic removal of the 5' viral protein did not allow the translation of CPMV RNA. However, chemical decapping of vesicular stomatitis virus mRNA completely inhibited the translation of this mRNA in the sea urchin cell-free system. We conclude that the sea urchin egg lacks the initiation pathway used to initiate uncapped mRNAs in mammalian cells and thus has an absolute requirement for the 5' cap structure for initiation. In addition we discuss the implications of these findings for the control of protein synthesis after fertilization of the sea urchin egg.

Identification of a protein bound to the termini of bacteriophage PRD1 DNA

Lipid-containing bacteriophage PRD1 has a double-stranded DNA genome of about 14,500 nucleotide base pairs. The phage can infect Escherichia coli and Salmonella typhimurium as well as other gram-negative bacteria harboring an appropriate plasmid. [35S]methionine label is incorporated into the DNA band early in infection. The label remains associated with DNA through phenol extraction and boiling with sodium dodecyl sulfate. Nuclease treatment of the genome released a protein which migrated as an early phage-specific protein (P8). This protein is also necessary for phage DNA replication. By restriction enzyme analysis it was shown that protein was associated with the terminal restriction fragments. Extracts of infected cells catalyzed the labeling of protein P8 with [alpha-32P]dGTP.

Orientation of the Cleavage Map of the 200-Kilodalton Polypeptide Encoded by the Bottom-Component RNA of Cowpea Mosaic Virus

The genomic organization of the bottom-component RNA of cowpea mosaic virus was studied. In vivo, this RNA encodes at least eight different polypeptides of 170, 110, 87, 84, 60, 58, 32, and 4 kilodaltons (K), the last polypeptide representing the genome-bound protein VPg. In rabbit reticulocyte lysates, bottom-component RNA is translated into a 200K polypeptide which is then processed to give the 32 and 170K polypeptides also found in vivo. By pulse-labeling the 200K primary translation product, we now show that the 32 and 170K polypeptides are derived from the NH 2 -terminal and COOH-terminal parts of this polypeptide, respectively. Comparison of the proteolytic peptide patterns of 170K polypeptides synthesized in vitro and pulse-labeled at either the NH 2 -terminal or the COOH-terminal end with the patterns of the 170 and 110K polypeptides found in vivo demonstrates that the order within the 200K primary translation product of cowpea mosaic virus bottom-component RNA is as follows: NH 2 -32K polypeptide-58K polypeptide-VPg-24K polypeptide-87K polypeptide-COOH.

The H protein isolated from tobacco mosaic virus reassociates with virions reconstituted in vitro

Virions of two strains of tobacco mosaic virus (U1 and Cc) have associated with them a small amount of a minor protein called H protein (A. Asselin and M. Zaitlin, 1978, Virology 91, 173-181), now known to be related to the viral coat protein (C.W. Collmer, V.M. Vogt, and M. Zaitlin, 1983, Virology 126, 429-448.). In the present study, a quantification technique involving disruption of virions followed by direct analysis of the component parts on SDS polyacrylamide gels was used to confirm an average of one molecule of H protein per virion for U1 TMV. H protein was separated from coat protein and purified by electrofocusing in a flatbed of granulated gel under stringent dissociating conditions. When assayed in the presence of urea, H protein has a pI of approximately 5.4, coat protein has a pI of approximately 4.9. Proteinase K-treated TMV RNA and H-protein-free TMV coat protein were reconstituted in vitro with or without H protein and the resulting virions were analyzed. A small amount of H protein reassociated with virions reconstituted in vitro (less than 10% of the amount found in native virions) and became resistant to degradation by trypsin, but such virions were no different from virions reconstituted without H protein in terms of yield of reconstituted particles or infectivity. In mixed reconstitution experiments with RNA and coat protein from strains U1 and Cc in all four possible combinations and with U1 H protein, the H protein always associated with the U1 coat protein. This demonstrated U1-H protein affinity for a specific coat protein rather than a specific RNA. It is unlikely that H protein functions in the early stages of viral infection, although the possibility of its having some other role in the life cycle of TMV remains.

Cowpea Mosaic Virus-Encoded Protease Does Not Recognize Primary Translation Products of M RNAs from Other Comoviruses

The protease encoded by the large (B) RNA segment of cowpea mosaic virus was tested for its ability to recognize the in vitro translation products of the small (M) RNA segment from the comoviruses squash mosaic virus, red clover mottle virus, and cowpea severe mosaic virus (CPsMV, strains Dg and Ark), and from the nepovirus tomato black ring virus. Like M RNA from cowpea mosaic virus, the M RNAs from squash mosaic virus, red clover mottle virus, CPsMV-Dg, and CPsMV-Ark were all translated into two large polypeptides with apparent molecular weights which were different for each virus and even for the two CPsMV strains. Neither the in vitro products from squash mosaic virus, red clover mottle virus, and CPsMV M RNAs nor the in vitro product from tomato black ring virus RNA-2 were processed by the cowpea mosaic virus-encoded protease, indicating that the activity of this enzyme is highly specific.

The location of the first AUG codons in cowpea mosaic virus RNAs

We have made use of the known sequence of the 5' ends of both CPMV RNAs to synthesise an oligodeoxynucleotide which can prime second-strand DNA synthesis on full-length cDNA copies of both RNAs. By priming synthesis in the presence of dideoxynucleoside triphosphates, we have determined the positions of the first AUG codons in each RNA. These occur at positions 115 and 207 on M and B RNA respectively. By using a cloned double-stranded DNA fragment derived from near the 5' end of M RNA as a primer additional sequence from the 5' terminal region of M RNA has been obtained.

Expression of the Bottom-Component RNA of Cowpea Mosaic Virus: Evidence that the 60-Kilodalton VPg Precursor Is Cleaved into Single VPg and a 58-Kilodalton Polypeptide

In cowpea protoplasts infected with cowpea mosaic virus, a bottom-component (B) RNA-encoded 60-kilodalton (60K) polypeptide is synthesized, which is membrane-bound and represents the direct precursor to the genome-bound protein VPg. The relationship between this VPg precursor and other B-RNA-encoded polypeptides was studied. Digestion of the B-RNA-encoded 170K and 84K polypeptides with Staphylococcus aureus protease V8 and subsequent analysis of the generated peptides with antiserum against VPg showed that a VPg sequence resides internally in these polypeptides. Furthermore, a new B-RNA-encoded polypeptide was detected, with a size of 58K, which differed from the 60K polypeptide only in the lack of VPg sequences. A model is presented in which the 60K VPg precursor is generated from the 200K primary translation product from B RNA and further processed to a 58K polypeptide and single VPg.

Transfection of Escherichia coli spheroplasts with a bacteriophage Mu DNA-protein complex

We disrupted bacteriophage Mu particles by freeze-thaw treatment and recovered the DNA by CsCl density gradient centrifugation. This CsCl-purified DNA had a buoyant density which was indistinguishable from that of phenol-extracted Mu DNA. It was, however, 10(3) times more infective than phenol-extracted DNA for spheroplasts of exoV endI Escherichia coli. Infectivity was destroyed by proteinase K as well as by pancreatic DNase, indicating that the infective form was a DNA-protein complex. The infective properties of the complex demonstrated that the protein protects. Mu DNA against degradation by exonuclease V and that it serves at least one other function in bacteriophage Mu infection. The infectivity of the CsCl-purified DNA was due to a small class of highly infective molecules which sedimented 1.2. times faster than phenol-extracted Mu DNA on neutral sucrose gradients. This change in sedimentation rate is best explained by the formation of protein-linked circular monomers or linear dimers of Mu DNA. In vitro labeling of the DNA-protein complex, followed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, showed that the CsCl-purified DNA contained a noncovalently associated 65,000-dalton polypeptide. A 65,000-dalton protein was also found to be a minor component of the bacteriophage Mu particle. No protein was found in phenol-extracted Mu DNA. These results suggest that the 65,000-dalton protein is necessary for successful phage infection and is normally injected into the host cell with the Mu genome.

Antibodies Against the Genome-Linked Protein VPg of Cowpea Mosaic Virus Recognize a 60,000-Dalton Precursor Polypeptide

We have prepared a rabbit antiserum specifically directed against the genome-linked protein (VPg) of cowpea mosaic virus by injecting an hydrolysate of purified virion RNA. Using this antiserum as a probe in combination with “Western” (protein) blots of subcellular fractions of cowpea mosaic virus-infected cowpea ( Vigna unguiculata ) cells, we have detected a bottom component RNA-encoded, 60,000-dalton polypeptide which is membrane bound and presumably represents the immediate precursor of VPg.

Two forms of VPg on poliovirus RNAs

The protein (VPg) linked to the 5' termini of poliovirus RNAs resolved into two species when subjected to non-equilibrium electrofocusing. The differently charged forms of VPg were not due to protein phosphorylation nor to variability of the number of phosphate residues associated with the nucleotide moiety remaining after RNase digestion of the nucleoprotein. Single-stranded viral RNA isolated from mature virions contained predominantly the more basic form of VPg, whereas unpackaged single-stranded RNa remaining in cells at the end of the virus replication cycle contained predominantly the more acidic form of VPg. Replicative-form (RF) molecules also contained both species of VPg, with the more acidic form representing the major species. Both plus and minus RNA strands in RF had similar VPg compositions; however, there appeared to be a strongly selective loss of VPg from only the minus strand in RF, particularly at late times postinfection.