Characterization of epitopes recognized by monoclonal antibodies to aphid transmissible and non-transmissible strains of turnip mosaic virus

Summary Fourteen monoclonal antibodies (MAbs) were prepared against two strains of turnip mosaic virus (TuMV) differing in aphid transmissibility. Serological specificity of fourteen MAbs against the two strains was tested by indirect ELISA. Three MAbs were able to distinguish aphid transmissible TuMV strain 1 from non-aphid transmissible strain 31 while four MAbs reacted only with strain 31. No cross-reactivity between the two strains was found using these specific MAbs. Based upon the ability of Mab to inhibit the reaction of other MAbs, antibody competition test indicated that fourteen MAbs recognized six different epitopes on the virus particle; MAbs specific to strain 1 recognized two epitopes while MAbs specific to strain 31 also recognized two epitopes. The remaining two epitopes are common. Since the six amino acid differences between the coat proteins of the two strains were found at the N-terminal regions, MAbs specific to strain 1 or 31 bound to the different epitopes on the N-terminal regions in coat proteins of the two strains.     

Novel monoclonal antibodies against Menangle virus nucleocapsid protein

Menangle virus (MenV) is a member of the family Paramyxoviridae isolated in Australia that causes a reproductive disease of pigs. There is a need for specific immunoassays for virus detection to facilitate the diagnosis of MenV infection. Three novel monoclonal antibodies (MAbs) of the IgG1 subtype were generated by immunizing mice with recombinant yeast-expressed MenV nucleocapsid (N) protein self-assembled to nucleocapsid-like structures. One MAb was cross-reactive with recombinant N protein of Tioman virus. The epitopes of MAbs were mapped using a series of truncated MenV N proteins lacking the 29–119 carboxy-terminal amino acid (aa) residues. The epitopes of two MAbs were mapped to aa 430–460 of the MenV N protein, whilst the epitope of one MAb was mapped to residues 460–490. All three MAbs specifically recognized MenV, as indicated by immunohistochemical staining of brain tissue isolated from a field case (a stillborn piglet) of MenV infection. The MAbs against MenV N protein may be a useful tool for immunohistological diagnosis of MenV infection.     

A single amino acid substitution at N-terminal region of coat protein of turnip mosaic virus alters antigenicity and aphid transmissibility

Summary The antigenic activity of the N-terminal region of coat protein of turnip mosaic virus (TuMV) aphid transmissible strain 1 and non-transmissible strain 31 was examined by using a panel of monoclonal antibodies (MAbs) raised against the two virus strains as well as antisera raised against several synthetic peptides from the N-terminal region of the protein. The reactivity of these antibodies was tested in ELISA and in a biosensor system (BIAcore Pharmacia) using virus particles, dissociated coat protein and synthetic peptides as antigens. Substitution of a single amino acid at position 8 in the coat protein of TuMV strain 1 abolished any cross-reactivity between MAbs to strain 1 and the substituted peptide (strain 31) in ELISA although some cross-reactivity was apparent in BIAcore inhibition experiments. In reciprocal tests with MAbs to strain 31 no cross-reactivity with the heterologous peptide was detected in either type of assay. The amino acid residue present at position 8 appears to play a critical role in the binding capacity of MAbs specific for the N-terminal region of TuMV. Antiserum to a synthetic peptide corresponding to residues 1–14 of the protein of TuMV strain 1 was found to react strongly with dissociated coat protein and intact virus particles and was able to inhibit the aphid transmission of the virus. Antiserum to the corresponding peptide of strain 31 did not have this capacity.     

Aphid transmission of a potyvirus depends on suitability of the helper component and the N terminus of the coat protein

Summary. The present study investigates the specificity of potyviruses for aphid species. Two potyviruses differing in their host range were used: Zucchini yellow mosaic virus (ZYMV) mainly infecting cucurbits and Turnip mosaic virus (TuMV) mainly infecting crucifers. Two sets of aphids species were used as vectors, one polyphagous (Myzus persicae and Aphis gossypii) and the other from crucifers (Brevicoryne brassicae and Lipaphis erysimi). Evidence is provided that the specificity between a vector and a potyvirus depends either on the affinity between the aphid species and the helper component (HC) protein used or on the affinity between the HC and the virions. The difference between the two potyviruses cannot be attributed to the DAG domain which is unaltered in both N termini of the CP. Therefore, a ZYMV full length clone served to exchange a fragment encoding for the N terminus of the ZYMV CP by that of TuMV. This partial exchange in the ZYMV CP, allowed the TuMV HC to transmit the chimeric virus but not the wild type ZYMV. The significance of the N terminus context of the CP in the specificity for the HC is discussed.     

Sequence analysis shows that ribgrass mosaic virus Shanghai isolate (RMV-Sh) is closely related to Youcai mosaic virus

Summary.  The complete nucleotide sequence of an isolate of Ribgrass mosaic virus (RMV-Sh) from Brassica chinensis (Qingcai) in Shanghai, China was determined. The genome consisted of 6301 nucleotides and its genomic organization was similar to those of other crucifer-tobamoviruses. Comparisons of the nucleotide and predicted amino acid sequences and phylogenetic analyses showed that RMV-Sh had very high homology (> 95% identical nucleotides and 97.7–99.6% identical amino acids) to a sequence of Youcai mosaic virus (YMV = Chinese rape mosaic or Oilseed rape mosaic virus), despite differences in host range or symptoms and this strongly suggests that these isolates should be regarded as belonging to the same species. Only coat protein sequences have been reported for other RMV isolates but it seems likely that the distinction between RMV and YoMV will be difficult to maintain. Accepted December 18, 2000 Received October 5, 2000     

A novel natural mutation in HC-Pro responsible for mild symptomatology of Zucchini yellow mosaic virus (ZYMV, Potyvirus) in cucurbits

A natural mild isolate of Zucchini yellow mosaic virus was found to contain a mutation in the helper component (HC-Pro) within a conserved motif, “CDNQLD”, located 12 residues downstream from the “FRNK” motif involved in symptom severity. Introducing the mutation in an infectious cDNA clone of ZYMV resulted in an almost complete absence of symptoms, although viral accumulation was only partially reduced. The FRNK(X)₁₂CDNQLD sequence might be part of a larger motif that is conserved in potyviruses and plays a role in symptomatology and/or silencing inhibition.     

Characterisation and epitope analysis of monoclonal antibodies to virions of clover yellow vein and Johnsongrass mosaic potyviruses

Summary Mouse monoclonal antibodies (MAbs) against the Australian B strain of clover yellow vein (C1YVV-B) and the JG strain of Johnsongrass mosaic (JGMV) potyviruses were produced, characterised and the epitopes with which they reacted were deduced. Using intact particles of C1YVV a total of ten MAbs were obtained which reacted strongly with C1YVV-B in an enzyme-linked immunosorbent assay and Western blots. Four of these MAbs (1, 2, 4, and 13) were found to be ClYVV-specific, as they reacted with all five C1YVV strains from Australia and the U.S.A. but not with 11 strains of bean yellow mosaic (BYMV), pea mosaic (PMV), and white lupin mosaic (WLMV) viruses which, together with C1YVV, form the BYMV subgroup of potyviruses. These MAbs failed to react with eight other potyvirus species, including six which infect legumes like the viruses in the BYMV subgroup. The C1YVV MAb 10 was found to be BYMV subgroup-specific. It reacted strongly with 15 of the 16 strains of viruses in the subgroup and gave no reaction with eight other potyviruses. The other five C1YVV MAbs reacted with varying degrees of specificity with the BYMV subgroup viruses and also with other potyviruses. Eight of the C1YVV MAbs (1, 2, 4, 5, 13, 17, 21, and 22) reacted with the intact coat proteins only and not with the truncated (minus amino terminus) coat protein of C1YVV suggesting that the epitopes for these MAbs are located in the surface-exposed, amino-terminal region of the C1YVV coat protein. Comparison of published coat protein sequences of BYMV and C1YVV isolates indicated that the epitopes for the four ClYVV-specific MAbs may be in the amino-terminal region spanning amino acid residues 18 to 30, whereas those for the other four MAbs may be located in the first 17 amino-terminal amino acid residue region. The epitopes that reacted with BYMV subgroup-specific MAb 10 and MAb 30 which reacted with 20 of the 24 potyvirus isolates, are probably located in the core region of C1YVV coat protein as these MAbs reacted with the intact as well as truncated coat protein of C1YVV. Analysis, in Western blot immunoassay, of 17 MAbs raised against virions of JGMV revealed that only two MAbs (1–25 and 4–30) were JGMV-specific, whereas others displayed varying degrees of specificity to different potyviruses. When these MAbs were screened against the intact and truncated (minus 67 amino-terminal amino acid residues) coat proteins of JGMV, the two JGMV-specific MAbs reacted only with the intact coat protein, whereas the other MAbs reacted with the intact as well as with truncated coat proteins, in Western blots. These results suggest that the epitopes for the two JGMV-specific MAbs are located in the surface-exposed amino-terminal 67 amino acid residue region and those for the cross-reactive MAbs are contained in the conserved core region of the JGMV coat protein. Screening of potyvirus MAbs against intact and truncated coat proteins thus appears to be a simple procedure to select virus-specific MAbs to potyviruses.     

Identification of type-specific and cross-reactive neutralizing conformational epitopes on the major capsid protein of human papillomavirus type 31

Summary. The majority of the neutralizing epitopes of papillomaviruses (PV) are conformation-specific and have not been fully characterised. Studies have, to date, been limited to a few HPV types only. We analysed the epitopes on the major capsid protein (L1) of Human papillomavirus (HPV) type 31 using monoclonal antibodies (MAbs) generated against HPV-31 virus-like particles (VLPs). The type-specific MAbs against HPV-31 were all found to be neutralizing and recognized conformation-dependent epitopes. Two other MAbs directed against a conformational epitope were found to be cross-reactive with other HPV types, and one of them was found to be cross-neutralizing. Cross-reactive antibodies were further investigated using wild-type HPV-16 L1 VLPs and two mutants. The results obtained suggested the existence of a cross-neutralizing conformational epitope at the N-terminal part of the FG loop of the major capsid protein, and the other four cross-reactive MAbs recognized epitopes also located at the N-terminal part of the FG loop.     

Molecular characterisation of a complex mixture of viruses in garlic with mosaic symptoms in China

Summary.  Degenerate primers were used to detect and amplify cDNA of viruses of the genera Carlavirus, Allexivirus and Potyvirus from garlic plants with mosaic symptoms growing in Zhejiang province, China. Plants contained a complex mixture of viruses and strains. Three distinct stains of Garlic latent virus were detected; the most frequent one was completely sequenced and partial sequences were obtained for the other two. The complete sequence (8363 nt) was 76.4% identical to a Korean isolate. Two allexiviruses were detected and completely sequenced. One (8319 nt) was identified as Garlic virus X and comparisons showed that a published Korean isolate (which had 90.2% identical nucleotides) had an N-terminal deletion in the serine-rich ORF4. The other isolate (8451 nt), tentatively named Garlic virus E, appeared to be a new member of the genus. Phylogenetic analyses of the different viral proteins and distinctive conserved sequence motifs within the genus are discussed. This is the first report of allexiviruses from China. Using potyvirus primers, three distinct isolates of Onion yellow dwarf virus and one of Leek yellow stripe virus were detected and the 3′-terminal sequences of their genomes were determined. In a coat protein phylogenetic analysis, the new isolates were most closely related to other published isolates from Japan and China. Accepted June 1, 2001 Received February 20, 2001     

A universal PCR primer to detect members of the Potyviridae and its use to examine the taxonomic status of several members of the family

Summary.  A universal primer (Sprimer: 5^′-GGX AAY AAY AGY GGX CAZ CC-3^′, X = A, G, C or T; Y = T or C; Z = A or G), designed from the consensus sequences that code for the conserved sequence GNNSGQP in the NIb region of members of the family Potyviridae, was used to amplify by RT-PCR the 3′-terminal genome regions from infected plant samples representing 21 different viruses in the family. Sequencing of some of the fragments (c. 1.7 kb) showed that the type strain (ATTC PV-107) of Oat necrotic mottle virus is not a distinct species in the genus Rymovirus, but is synonymous with Brome streak mosaic virus (genus Tritimovirus) and that Celery mosaic virus is a distinct member of the genus Potyvirus not closely related to any other sequenced species. Potyviruses infecting crops in China were also investigated, showing that viruses on cowpea and maize in Hangzhou, Zhejiang province were respectively Bean common mosaic virus and Sugarcane mosaic virus and that one on garlic in Nanjing, Jiangsu province was Onion yellow dwarf virus. Fragments were also sequenced from Chinese isolates of Lettuce mosaic virus and Soybean mosaic virus (from Hangzhou), Turnip mosaic virus (2 different isolates from Zhejiang province) and RNA1 of Wheat yellow mosaic virus (from Rongcheng, Shandong province). Received June 30, 2000 Accepted September 28, 2000     

The genome organisation and taxonomy of Sugarcane striate mosaic associated virus

Summary.  Sugarcane striate mosaic associated virus (SCSMaV) has slightly flexuous 950 nm × 15 nm filamentous particles and is associated with sugarcane striate mosaic disease in central Queensland, Australia. We report the full sequence of its RNA genome, which comprises 5 open reading frames representing the polymerase, movement function proteins encoded in a triple gene block and coat protein. Phylogenetic analyses based on either the full nucleotide sequence, the polymerase protein, or the coat protein all placed SCSMaV in an intermediate position between the genera Foveavirus and Carlavirus, but outside both genera. In addition, the absence of a sixth open reading frame excludes it from the genus Carlavirus, and the coat protein is approximately half the size of the type member for the genus Foveavirus. Although SCSMaV was most closely allied to Cherry green ring mottle virus by genome analysis, the two viruses are morphologically and biologically dissimilar. SCSMaV may therefore represent a new plant virus taxon. Received January 30, 2001/Accepted May 29, 2001     

Complete nucleotide sequence of Sesbania mosaic virus: a new virus species of the genus Sobemovirus

Summary.  The complete nucleotide sequence of the Sesbania mosaic virus (SeMV) genomic RNA was determined by sequencing overlapping cDNA clones. The SeMV genome is 4149 nucleotides in length and encodes four potential overlapping open reading frames (ORFs). Comparison of the nucleotide sequence and the deduced amino acid sequence of the four ORFs of SeMV with that of other sobemoviruses revealed that SeMV was closest to southern bean mosaic virus Arkansas isolate (SBMV-Ark, 73% identity). The 5′ non-coding regions of SeMV, SBMV and southern cowpea mosaic virus (SCPMV) are nearly identical. However ORF1 of SeMV which encodes for a putative movement protein of M_r 18370 has only 34% identity with SBMV-Ark. ORF 2 encodes a polyprotein containing the serine protease, genome linked viral protein (VPg) and RNA dependent RNA polymerase domains and shows 78% identity with SBMV-Ark. The N-terminal amino acid sequence of VPg was found to be TLPPELSIIEIP, which mapped to the region 326–337 of ORF2 product and the cleavage site between the protease domain and VPg was identified to be E³²⁵-T³²⁶. The cleavage site between VPg and RNA dependent RNA polymerase was predicted to be E⁴⁴⁵-T⁴⁴⁶ based on the amino acid sequence analysis of the polyprotein from different sobemoviruses. ORF3 is nested within ORF2 in a − 1 reading frame. The potential ribosomal frame shift signal and the downstream stem-loop structure found in other sobemoviruses are also conserved in SeMV RNA sequence, indicating that ORF3 might be expressed via − 1 frame shifting mechanism. ORF4 encodes the coat protein of SeMV, which shows 76 and 66% identity with SBMV-Ark and SCPMV, respectively. Thus the comparison of the non-coding regions and the ORFs of SeMV with other sobemoviruses clearly revealed that it is not a strain of SBMV. Phylogenetic analysis of six different sobemoviruses, including SeMV, suggests that recombination event is not frequent in this group and that SeMV is a distinct member of the genus sobemovirus. The analysis also shows sobemoviruses infecting monocotyledons and dicotyledons fall into two distinct clusters. Received April 20, 2000 Accepted August 28, 2000     

Three epitopes located on the coat protein amino terminus of viruses in the bean common mosaic potyvirus subgroup

Summary.  Twenty-seven of 29 strains of viruses in the bean common mosaic virus (BCMV) subgroup of legume-infecting potyviruses reacted strongly with one or more of the monoclonal antibodies (MAbs) which are known to be specific for epitopes located along the 50 amino acids which constitute the N-terminal end of the viral coat protein. Approximately one half of the virus strains reacted with the N-terminal epitope specific (NTES) MAb 4G12 which is specific for epitope E/B4, while the other half reacted with NTES MAbs 4 A1 or 4F9 which are specific for epitope E/B3. All but two strains contained at least one of these epitopes while no strain contained both. Competitive assays using five sequential, non-overlapping, synthetic, 10mer peptides indicated that the amino acids critical for epitope E/B3 reaction were located at positions 5, 7, and 10 from the N-terminal end of the coat protein. By deduction we postulate that the amino acids critical for epitope E/B4 are located at positions 10, 16, and 17. Because epitope E/B3 requires isoleucine at position 10 for expression whereas epitope E/B4 requires valine to be expressed, no one strain can express both epitopes. Two viruses in our tests (azuki mosaic and Dendrobium mosaic viruses) had deletions in this portion of their sequence explaining their failure to react MAbs specific for either epitope. The critical amino acids for a third epitope, E/B3A, were located at positions 16 and 17. We found no correlation between any of the three N-terminal epitopes defined in this study and the presence or absence of any biological property that we could accurately measure: i.e., symptomatology, host range, or pathotype. However, when coat protein sequences were aligned according to epitope type E/B3 or E/B4, we found that sequences within groups had high levels of identity while between group identities were low. We also found that sequences in the 3′-end non-coding region exhibited similar relationships within and between epitope groups. Two strains of BCMV (NL-4 and RU-1) were found to possess coat protein sequences typical of epitope E/B4 but 3′-NCR sequences typical of epitope E/B3. These data suggest that both strains may be the result of natural recombinants between the two epitope groups. Received May 18, 1998 Accepted October 26, 1998     

Characterisation of several heterogeneous species of defective RNAs derived from RNA 3 of cucumber mosaic virus

Summary. Preparations of double-stranded RNAs (dsRNAs) extracted from Nicotiana tabacum cv Xanthi plants infected with a subgroup IB isolate of Cucumber mosaic virus (CMV) were found to contain a heterogeneous population of defective RNAs (D-RNAs) derived from RNA 3. Characterised D-RNAs ranged in size from 1.5 to 1.9 kb and were derived either by a single in-frame deletion within the 3a or 3b genes or by means of double in-frame deletions within both genes. Also, northern blot hybridisation showed two other types of RNA derived from RNA 3: (a) RNA species of ca. 0.7 kb containing the 3′-terminus but lacking the 5′-terminus, which could be 3′-coterminal subgenomic of D-RNAs derived from the 3b gene and (b) RNA species of unknown origin of ca. 0.8 kb containing the 5′-terminus but lacking the 3′-terminus.     

Identification of an epitope on the dengue virus membrane (M) protein defined by cross-protective monoclonal antibodies: design of an improved epitope sequence based on common determinants present in both envelope (E and M) proteins

Summary.  The protective capacity of monoclonal antibodies (MAbs) generated to the dengue-2 virus envelope (E) and premembrane (prM) proteins was tested in vivo. Two anti-E MAbs, 2C5.1 and 4G2 and two anti-prM MAbs, 2A4.1 and 2H2 provided cross-protection against all four dengue virus serotypes. Overlapping sets of synthetic peptides spanning amino-acid sequence 301–401 (domain III) of the E protein and the entire prM protein were then used to locate their epitopes. The anti-E MAbs strongly reacted with the peptide sequence 349-GRLITVNPIVT-359 (E349–359) from domain III and the immunodominant epitope, 274-SGNLLFTGHL-283 (E274–283) from the hinge region between domains I and II. The anti-prM MAbs strongly reacted with the sequence, 40-PGFTVMAAIL-49 (M40–49) from the first membrane-spanning domain of the M protein. These anti-prM MAbs also reacted with peptides E274–283 and E349–359, while the anti-E MAbs reacted with a peptide sequence, 1-FHLTTRNGEP-10 from the prM protein and these cross-reactions with both proteins were confirmed using immunoblot assays. MAbs 2C5.1, 4G2 and 2H2 more strongly reacted with an MEH1 peptide GLFTPNLITI, which was designed as an antigenic hybrid between these E and prM peptide sequences, than with any of these natural peptide sequences. These peptide sequence will now be tested for their ability to generate cross-protective antibodies against each dengue virus serotype when delivered with appropriate T-helper epitopes. Accepted August 13, 1999     

Characterisation of a potyvirus and a potexvirus from Chinese scallion

Summary.  Molecular analyses of viruses infecting Chinese scallion (Allium chinense G. Don) showed that the plants did not contain any of the poty-, carla- or allexiviruses that are common in garlic plants in China. The complete sequences of a potyvirus and a potexvirus were determined and these were shown to represent different viruses from any in the databases. They could be transmitted mechanically to scallion but not to other Allium species (including garlic) or to Narcissus. The potyvirus, tentatively named Scallion mosaic virus, has a distant relationship (c. 62% nucleotide identity over the entire genome) to Turnip mosaic virus and Japanese yam mosaic virus, with which it grouped in phylogenetic analyses. Its genome is 9324 nts long, encoding a 341.3 kDa polyprotein of 3001 amino acids. The potexvirus, tentatively named Scallion virus X, has a genome 6987 nts long and its organisation was similar to that of the other potexviruses but with only 46.3–63.2% nucleotides identical to them. It is most closely related to Narcissus mosaic virus but phylogenetic analyses indicate that it should be considered a distinct species. Neither of the viruses have been detected in garlic, although the two host plants are closely related. Received September 28, 2001 Accepted December 20, 2001     

Variation in the coat protein sequence of British isolates of <Emphasis Type="Italic">Turnip yellow mosaic virus</Emphasis> and comparison with previously published isolates

Summary. Isolates of Turnip yellow mosaic virus (TYMV) were collected from wild cabbage (Brassica oleracea) on a 400 m stretch of Dorset coastline. The coat protein genes of four isolates showed high homology in nucleotide sequence (0.970–1.000, mean 0.987). Lower levels of homology where found to previously published sequences of Australian isolates [10] (0.725–0.775, mean 0.741). The amino acid composition of the Dorset isolates showed high levels of homology (0.964–1.000, mean 0.986). Numerous amino acid substitutions occurred between the Dorset and Australian isolates (0.705–0.819, mean 0.742). Comparison with other isolates showed large genetic distances between the Dorset isolates and both European and Australian isolates.     

Interaction between potyvirus P3 and ribulose-1,5-bisphosphate carboxylase/oxygenase (RubisCO) of host plants

The P3 protein encoded by Shallot yellow stripe virus onion isolate (SYSV-O) interacted in the Yeast Two-hybrid (Y2H) system and in co-immunoprecipitation (Co-IP) assays with the large subunit of the ribulose-1,5-bisphosphate carboxylase/oxygenase (RubisCO) protein that is encoded by the rbcL gene of its onion host. Dissection analysis by Y2H showed that the main part of SYSV P3 (amino acids 1–390) and onion RbcL (amino acids 1–137) were responsible for the interaction. The P3 proteins encoded by Onion yellow dwarf virus (OYDV), Soybean mosaic virus Pinellia isolate (SMV-P), and Turnip mosaic virus (TuMV) also interacted with RbcL, suggesting that a P3/RbcL interaction might exist generally for potyviruses. An interaction between P3 of these potyviruses and the small subunit of RubisCO (RbcS) was also demonstrated. Moreover, the P3N-PIPO protein encoded by a newly identified open reading frame embedded within the P3 cistron also interacted with both RbcL and RbcS. It is possible that the potyvirus P3 protein affects the normal functions of RubisCO which thus contributes to symptom development.     

Molecular characterization and interviral relationships of a flexuous filamentous virus causing mosaic disease of sugarcane (Saccharum officinarum L.) in India

Summary.  A virus isolate causing mosaic disease of commercial sugarcane was purified to homogeneity. Electron microscopy revealed flexuous filamentous virus particles of ca 890 × 15 nm. The virus isolate reacted positively with heterologous antiserum to narcissus latent virus form UK, but failed to react with potyvirus group specific antiserum. N-terminal sequencing of the intact coat protein (CP) and the tryptic peptides indicated that the virus was probably a potyvirus but distinct from several reported potyviruses. Comparison of the 3′-terminal 1084 nucleotide sequence of the RNA genome of this virus revealed 93.6% sequence identity in the coat protein coding region with the recently described sugarcane streak mosaic virus (Pakistani isolate). The molecular weight of the coat protein (40 kDa) was higher than that deduced from the amino acid sequence (34 kDa). The apparent increase in size was shown to be due to glycosylation of the coat protein which has not been reported thus far in the family, Potyviridae. This is the first report on the molecular characterization of a virus causing mosaic disease of sugarcane in India and the results demonstrate that the virus is a strain of sugarcane streak mosaic virus, a member of the Tritimovirus genus of the Potyviridae. We have named it sugarcane streak mosaic virus – Andhra Pradesh isolate (SCSMV-AP). Received October 14, 1997 Accepted August 7, 1998     

The genomic sequence and biological properties of Pennisetum mosaic virus, a novel monocot-infecting potyvirus

The complete nucleotide sequences of two isolates of Pennisetum mosaic virus (PenMV) were determined. The viral genome comprised 9,611 nucleotides (nt) excluding the 3′-terminal poly(A) sequence, with the capacity of encoding a single polyprotein of 3,065 amino acids. The large open reading frame is flanked by a 172-nt 5′-untranslated region (UTR) and a 244-nt 3′-UTR. Sequence comparisons and phylogenetic analyses of the complete genome and polyproteins suggest that PenMV is closely related to other monocot potyviruses such as Maize dwarf mosaic virus, Sorghum mosaic virus and Sugarcane mosaic virus (SCMV), and thus represents a distinct potyvirus within the SCMV subgroup. The host range of PenMV is limited to Gramineae, and the virus naturally infects maize, sorghum and some wild grasses, causing mosaic symptoms on the leaves. This virus could be transmitted by both mechanical inoculation and by at least four species of aphids.