Comparison of capsids and nucleocapsids from cowpea mosaic virus-infected cowpea protoplasts and seedlings

The first crystal structure of a macromolecular assembly under high pressure: CpMV at 330 MPa

The structure of cubic Cowpea mosaic virus crystals, compressed at 330 MPa in a diamond anvil cell, was refined at 2.8 A from data collected using ultrashort-wavelength (0.331 A) synchrotron radiation. With respect to the structure at atmospheric pressure, order is increased with lower Debye Waller factors and a larger number of ordered water molecules. Hydrogen-bond lengths are on average shorter and the cavity volume is strongly reduced. A tentative mechanistic explanation is given for the coexistence of disordered and ordered cubic crystals in crystallization drops and for the disorder-order transition observed in disordered crystals submitted to high pressure. Based on such explanation, it can be concluded that pressure would in general improve, albeit to a variable extent, the order in macromolecular crystals.

Evidence for assembly-dependent folding of protein and RNA in an icosahedral virus

Ordered nucleic acid in an icosahedral virus was first visualized in the X-ray structure of the Picorna-like plant virus, Bean pod mottle virus (BPMV). Virus particles containing the 3500 nucleotide segment of the BPMV bipartite RNA genome (middle component) had nearly 20% of the genome ordered. Here we report the refined structures of the middle component, bottom component (particles containing the 5800 nucleotide segment of the genome), and top component (empty particles of BPMV capsid protein). The bottom component particles contain ordered RNA in the same location as middle component. Although the ordered RNA density in both nucleoprotein particles is the average of the contents of 60 icosahedral asymmetric units, both nucleoprotein components show that the base density for the first two nucleotides is predominantly purine, while the next five appear to be predominantly pyrimidine. The empty capsid demonstrates that RNA dictates the order of the N-terminal 19 residues of the large subunit because these residues are invisible in the top component.

Structural fingerprinting: subgrouping of comoviruses by structural studies of red clover mottle virus to 2.4-A resolution and comparisons with other comoviruses

Red clover mottle virus (RCMV) is a member of the comoviruses, a group of picornavirus-like plant viruses. The X-ray structure of RCMV strain S has been determined and refined to 2.4 A. The overall structure of RCMV is similar to that of two other comoviruses, Cowpea mosaic virus (CPMV) and Bean pod mottle virus (BPMV). The sequence of the coat proteins of RCMV strain O were modeled into the capsid structure of strain S without causing any distortion, confirming the close resemblance between the two strains. By comparing the RCMV structure with that of other comoviruses, a structural fingerprint at the N terminus of the small subunit was identified which allowed subgrouping of comoviruses into CPMV-like and BPMV-like viruses.

The refined crystal structure of cowpea mosaic virus at 2.8 A resolution

Comoviruses are a group of plant viruses in the picornavirus superfamily. The type member of comoviruses, cowpea mosaic virus (CPMV), was crystallized in the cubic space group I23, a = 317 A and the hexagonal space group P6(1)22, a = 451 A, c = 1038 A. Structures of three closely similar nucleoprotein particles were determined in the cubic form. The roughly 300-A capsid was similar to the picornavirus capsid displaying a pseudo T = 3 (P = 3) surface lattice. The three beta-sandwich domains adopt two orientations, one with the long axis radial and the other two with the long axes tangential in reference to the capsid sphere. T = 3 viruses display one or the other of these two orientations. The CPMV capsid was permeable to cesium ions, leading to a disturbance of the beta-annulus inside a channel-like structure, suggesting an ion channel. The hexagonal crystal form diffracted X rays to 3 A resolution, despite the large unit cell. The large ( approximately 200 A) solvent channels in the lattice allow exchange of CPMV cognate Fab fragments. As an initial step in the structure determination of the CPMV/Fab complex, the P6(1)22 crystal structure was solved by molecular replacement with the CPMV model determined in the cubic cell.

The cleavable carboxyl-terminus of the small coat protein of cowpea mosaic virus is involved in RNA encapsidation

The site of cleavage of the small coat protein of cowpea mosaic virus has been precisely mapped and the proteolysis has been shown to result in the loss of 24 amino acids from the carboxyl-terminus of the protein. A series of premature termination and deletion mutants was constructed to investigate the role or roles of these carboxyl-terminal amino acids in the viral replication cycle. Mutants containing premature termination codons at or downstream of the cleavage site were viable but reverted to wild-type after a single passage through cowpea plants, indicating that the carboxyl-terminal amino acids are important. Mutants with the equivalent deletions were genetically stable and shown to be debilitated with respect to virus accumulation. The specific infectivity of preparations of a deletion mutant (DM4) lacking all 24 amino acids was 6-fold less than that of a wild-type preparation. This was shown to be a result of DM4 preparations containing a much increased percentage (73%) of empty (RNA-free) particles, a finding that implicates the cleavable carboxyl-terminal residues in the packaging of the virion RNAs.

Characterization of the coat protein gene of mite-transmitted blackcurrant reversion associated nepovirus

The nucleotide sequence of the 3' terminal 3105 nucleotides (nt) of RNA2 of blackcurrant reversion associated virus (BRAV), the first mite-transmitted member of the nepovirus group, has been determined. The sequence contains an open reading frame of 1744 nt in the virus-sense strand, a 3' untranslated region of 1360 nt and a 3' poly(A) tail. Analysis of the amino-terminal residues of purified coat protein (CP) suggests that the CP gene is located between nts 1361 and 2959 (from the 3' terminus) in the RNA2, and that Asp/Ser is the proteolytic cleavage site of CP in the RNA2 encoded polyprotein. The predicted translation product from the CP gene is a polypeptide of 533 amino acids with a calculated Mr of 57 561. The amino acid sequence of BRAV CP showed highest similarity to blueberry leaf mottle virus (BLMV), and tomato ringspot virus (ToRSV), two members of the proposed sub-group three of nepoviruses possessing large RNA2 components. Nucleic and amino acid sequence comparisons between BRAV CP and the CPs of other nepoviruses indicate that specific conserved nepovirus CP domains occur in the BRAV CP thus confirming that BRAV is a member of the subgroup three of nepoviruses. reserved.

Nucleotide sequence and genetic map of cowpea severe mosaic virus RNA 2 and comparisons with RNA 2 of other comoviruses

We report the nucleotide sequence of cowpea severe mosaic comovirus (CPSMV) genomic RNA 2. The molecule is composed of 3732 nucleotide (nt) residues, exclusive of the polyadenylate at the 3' end. Only one of the six reading frame registers has a long open reading frame, from nt 255 to nt 3260 in the polarity of encapsidated RNA and corresponding to a polyprotein of 1002 amino acid residues (aa). As has been reported for other comoviruses, a second in-frame AUG, at nt position 531, apparently also initiates translation, at least in vitro. Multiple alignments of the deduced CPSMV polyprotein aa sequence with those of bean pod mottle comovirus (BPMV), cowpea mosaic comovirus (CPMV), and red clover mottle comovirus (RCMV) were consistent with a similar size for each of the three genes: the putative movement protein, beginning at the second in-frame AUG, the large coat protein (L), and the small coat protein. Identical nucleotide sequences in the terminal noncoding regions of RNA 2 of the four viruses are limited to 9 nt at the 5' end and the 3' polyadenylate. However, extensive similarities in sequence and potential structure were found. For all three genes and the 5' untranslated region, CPSMV and BPMV are more similar to each other than either is to CPMV or RCMV, the last two being similar to each other. Observed similarities predict that both cleavage sites in the CPSMV RNA 2 polyprotein are at glutamine-serine dipeptides. A sequence of 16 aa at the amino terminus of L, determined by automated Edman degradation, matched a region of the deduced aa sequence in the polyprotein and is consistent with cleavage at the predicted glutamine-serine dipeptide.

Ubiquitinated conjugates are found in preparations of several plant viruses

Recently D.D. Dunigan, R.G. Dietzgen, J.E. Schoelz, and M. Zaitlin (Virology 165, 310-312, 1988) demonstrated that a small proportion of the subunits of tobacco mosaic virus particles were conjugated with the small protein ubiquitin. We have now detected ubiquitinated conjugates in immunoblots of virion preparations of several other plant viruses, using anti-human ubiquitin antiserum. Based on their polyacrylamide gel migrations, plant virus-associated ubiquitin-immunoreactive proteins were considered to be possible virus structural protein-ubiquitin conjugates of the following viruses: barley stripe mosaic, brome mosaic, cowpea mosaic (two proteins), cowpea severe mosaic (two proteins), and satellite panicum mosaic. Ubiquitinated conjugates were not detected in immunoblots of preparations of cucumber mosaic virus and Cymbidium mosaic virus. The significance of ubiquitinated viral proteins remains to be determined.

RNA and capsid accumulation in cowpea protoplasts that are resistant to cowpea mosaic virus strain SB

Leaf protoplasts from the Arlington line of cowpea (Vigna unguiculata) support only a limited increase of cowpea mosaic virus strain SB (CPMV-SB), whereas cowpea severe mosaic virus, another member of the comovirus group, replicates efficiently in Arlington cowpea protoplasts. CPMV-SB replicates efficiently in protoplasts of cowpea line Blackeye 5. Some characteristics of the virus-specific resistance of Arlington protoplasts to CPMV-SB are reported. Differences between progeny CPMV-SB from Arlington and Blackeye 5 protoplasts were not detected. Inoculation with CPMV-SB RNA, rather than virions, did not make Arlington protoplasts fully susceptible. These results favor, for likely involvement in the CPMV-SB restriction phenomenon, events in the virus life cycle that occur after exposure of virion RNA to the cytoplasm and before assembly of particles is completed. The accumulation of CPMV-SB RNAs of both polarities was found to be depressed in inoculated Arlington protoplasts. However, (+)RNA (virion RNA polarity) accumulated to no lesser extent, per unit of (-)RNA, in Arlington protoplasts than in Blackeye 5 protoplasts. Capsid antigen accumulation, per unit of (+)RNA, was reduced in Arlington protoplasts as compared to Blackeye 5 protoplasts. A working hypothesis consistent with the above and other observations is that Arlington protoplasts have an inhibitory substance that interferes with the production or/and function of CPMV-SB specified proteins.