A single residue in the 126-kDa protein of pepper mild mottle virus controls the severity of symptoms on infected green bell pepper plants.

Infectious cDNA clones originally derived from a mild strain of Pepper mild mottle virus were constructed by replacing residue 649, a critical point for attenuation of this virus, with all possible amino acids. All clones were infectious to pepper plants and induced a variety of symptoms, including no visible symptoms. The results of this study showed that a single amino acid mutation at residue 649 could control the function of the 126- and 183-kDa proteins, replicases with multiple roles in the life cycle of this virus.

Molecular analysis of coat protein coding region of tobacco stunt virus shows that it is a strain of Lettuce big-vein virus in the genus Varicosavirus.

To evaluate the relationship between tobacco stunt virus (TStV) and Lettuce big-vein virus (LBVV), we determined nucleotide sequences of the coat protein (CP) coding region of five TStV and three LBVV isolates and compared them with those of one Japanese and four Spanish isolates of LBVV. CP coding regions were identical in size and the nucleotide and amino acid sequence identities between TStV and LBVV were 95.6-96.5% and 97.2-98.7%, respectively. Phylogenetic analysis of nucleotide sequences indicated that TStV was very closely related to LBVV and a strain of LBVV rather than a distinct species.

Supravesical hernia: CT diagnosis.

We report two cases of surgically proven supravesical hernia, one an internal supravesical hernia and the other an external supravesical hernia. Abdominal computed tomography showed the relation of the incarcerated intestine anterior to and compressing the urinary bladder. Although neither case was diagnosable preoperatively, we believe that the preoperative diagnosis of supravesical hernia by abdominal computed tomography is possible.

Aphid transmission studies using helper component proteins of potato virus Y expressed from a vector derived from potato virus X.

The genes encoding the helper component (HC) proteins of two strains of Potato virus Y (PVY) were cloned and the proteins expressed from a vector derived from Potato virus X (PVX). The expressed HC contained six N-terminal histidine residues to facilitate purification by metal affinity chromatography. Approximately 2-4 microg/g of purified HC was obtained from leaves of Nicotiana benthamiana plants systemically infected by recombinant PVX. Preparations of the HC protein derived from PVY ordinary strain (PVY(o)) assisted aphid transmission of purified particles of PVY(o) and PVY strain C (PVY(c); a naturally occurring non-aphid transmissible strain of PVY which contains a defective HC), as well as Potato aucuba mosaic virus. The HC derived from PVY(c) contained the Glu-Ile-Thr-Cys (EITC) motif, and mutation of Glu (E) to Lys (K) enabled the mutant PVX-expressed preparations to assist virus transmission by aphids. Expression of HC protein from the PVX vector produced biologically active protein. This approach should facilitate further studies to elucidate more precisely the molecular mechanism of virus transmission by aphids.

Molecular characterization of a new potyvirus infecting sunflower.

We have sequenced 1873 nucleotides from the 3'-end region of a sunflower potyvirus genome including the 3'-NIb protein coding region (813 nucleotides), the entire coat protein coding region (807 nucleotides) and 3'-NCR (253 nucleotides), excluding the poly (A) tail. Amino acids identity of the whole CP between the sunflower virus and Potyvirus members ranged from 49.5% (SCMV) to 81.5% (PVY-NsNr), and the core ranged from 55% (TVMV) to 87% (PVY-NsNr; PepMoV). The 3'-NCR nucleotides showed 38.7% homology to PeSMV and 61% to PepMoV-C. The sequence of 3' end region and analysis of phylogenetic relationships suggest this sunflower virus could belong to PVY subgroup and the name of "sunflower chlorotic mottle virus" (SuCMoV) is proposed. This is the first report on the partial nucleotide sequence of a potyvirus infecting sunflower.

Biological, serological, and molecular variabilities of clover yellow vein virus.

ABSTRACT A comparative study was made on the host reactions, serological properties, and nucleotide sequences of the coat protein (CP) gene of 10 clover yellow vein virus (C1YVV) isolates and one bean yellow mosaic virus (BYMV) isolate collected from different host plant species and locations in Japan. Two strains of C1YVV isolates, grouped on the basis of host reactions on Chenopodium amaranticolor, C. quinoa, Nicotianaclevelandii, N. benthamiana, Vicia faba, and Trifolium repens, corresponded to two serotypes determined by double-antibody sandwich- and triple-antibody sandwich-enzyme-linked immunosorbent assay using three polyclonal and nine monoclonal antibodies. These results were also confirmed by nucleotide sequence analysis of the CP gene. The CP gene of C1YVV isolates of strain 1, including the Australian isolate C1YVV-B, had 93 to 98% nucleotide identities and 97 to 99.6% amino acid identities. The CP of C1YVV isolates of strain 2, including the New Zealand isolate C1YVV-NZ, had 92 to 98% nucleotide identities and 95 to 98% amino acid identities. The nucleotide identities and the amino acid identities between the two C1YVV strains were 82 to 84%, and 90 to 94%, respectively. When compared with the CP sequences of 12 C1YVV isolates, the CP sequence of the BYMV isolate had 71 to 73% nucleotide identity and 73 to 77% amino acid identity. Amino acid sequence differences among C1YVV isolates from strains 1 and 2 were located mostly at the N-terminal regions of the CP. Our results indicated that the C1YVV isolates studied could be separated into two strains on the basis of host reactions, serology, and the nucleotide sequence of the CP gene.