Begomoviruses Associated with Bean Golden Mosaic Disease in Nicaragua.

Begomovirus spp. cause substantial losses in bean crops in tropical and subtropical regions of the Americas. The predominant Begomovirus sp. in Central America associated with golden mosaic symptoms in bean is Bean golden yellow mosaic virus (BGYMV). However, Calopogonium golden mosaic virus was previously found to infect bean crops in the northern region of Costa Rica. The objective of this research was to identify Begomovirus spp. that infect bean plants in different geographical regions of Nicaragua. In all, 126 samples of young bean leaves with symptoms of golden mosaic were collected from eight different regions of Nicaragua. Using DNA hybridization with specific probes, 120 samples tested positive for BGYMV, 14 samples tested positive for Squash yellow mild mottle virus, and 7 samples tested positive for Calopogonium golden mosaic virus. Sequence analysis of polymerase chain reaction-amplified products from three samples (MA-9 Managua, BE-8 Rivas, and SO-9 Granada) also indicated that the symptoms of golden mosaic in bean are associated with viral sequences from three different Begomovirus spp. Management of bean golden mosaic disease must take into account that BGYMV is the predominant virus (95% of the samples) and that 12% of the samples exhibited possible mixed infections or recombination events in the south and central geographical regions of Nicaragua.

Use of Tomato leaf curl virus (TYLCV) truncated Rep gene sequence to engineer TYLCV resistance in tomato plants.

Tomato yellow leaf curl disease causes severe losses in tomato production throughout Mediterranean countries including Tunisia. In order to generate engineered resistance to this disease, an intron-hairpin RNA construct harboring a Tomato yellow leaf curl Sardinia virus (TYLCSV) truncated replication-associated protein (Rep) gene was used to transform genotype of tomato plants. Prepared transgenic plants were agro-inoculated with Tunisian infectious strain of TYLCSV and screened for the resistance to infection. The infected transgenic plants were divided into 3 different groups according to their specific symptoms. Only one of them contained transgenic plants fully resistant to the tomato yellow leaf curl disease.

Evaluation of two gene-silencing constructs for resistance to tomato yellow leaf curl viruses in Nicotiana benthamiana plants.

Infiltration of Agrobacterium tumefaciens into intact plant leaves of N. benthamiana was used to test the efficiency of two virus-based silencing constructs conferring resistance to the closely related begomoviruses. The constructs contained the most conserved sequences of the coat protein (CP) gene and replication-associated protein (Rep) gene of Tomato yellow leaf curl Sardinia virus (Sicily strain) (TYLCSV-[Sic]). Both constructs formed a hairpin structure that enhanced the post-transcriptional gene-silencing mechanism. When agro-infiltrated plants were challenged separately with infectious viruses TYLCSV-[Sic] and Tomato yellow leaf curl virus (TYLCV), the plants showed resistance to TYLCSV-[Sic], but not to the related TYLCV.

Post-transcriptional gene silencing in controlling viruses of the Tomato yellow leaf curl virus complex.

Tomato yellow leaf curl disease (TYLCD) is caused by a group of geminiviruses that belong to the Tomato yellow leaf curl virus (TYLCV) complex and are transmitted by the whitefly (Bemisia tabaci Genn.). The disease causes great yield losses in many countries throughout the Mediterranean region and the Middle East. In this study, the efficacy of post-transcriptional gene silencing (PTGS) to control the disease caused by TYLCV complex was investigated. Non-coding conserved regions from the genome of TYLCV, Tomato yellow leaf curl virus-mild, tomato yellow leaf curl Sardinia virus, tomato yellow leaf curl Malaga virus, and tomato yellow leaf curl Sardinia virus-Spain [2] were selected and used to design a construct that can trigger broad resistance against different viruses that cause tomato yellow leaf curl disease. The silencing construct was cloned into an Agrobacterium-binary vector in sense and antisense orientation and used in transient assay to infiltrate tomato and Nicotiana benthamiana plants. A high level of resistance was obtained when plants were agro-infiltrated with an infectious clone of the Egyptian isolate of TYLCV (TYLCV-[EG]) or challenge inoculated with TYLCV, TYLCV-Mld, and TYLCSV-ES[2] using whitefly-mediated transmission 16-20 days post infiltration with the silencing construct. Results of the polymerase chain reaction showed that the resistance was effective against all three viruses. Furthermore, dot blot hybridization and PCR failed to detect viral DNA in symptomless, silenced plants. A positive correlation between resistance and the accumulation of TYLCV-specific siRNAs was observed in silenced plants. Together, these data provide compelling evidence that PTGS can be used to engineer geminivirus-resistant plants.

Mitochondria/nuclear signaling of alternative oxidase gene expression occurs through distinct pathways involving organic acids and reactive oxygen species.

Cultured cells of tobacco (Nicotiana tabacum L. cv Petit Havana) were used to investigate signals regulating the expression of the "model" nuclear gene encoding the alternative oxidase (AOX) (AOX1), the terminal oxidase of the mitochondrial alternative respiratory pathway. Several conditions shown to induce AOX1 mRNA accumulation also result in an increase in cellular citrate concentrations, suggesting that citrate and/or other tricarboxylic acid (TCA) cycle intermediates may be important signal metabolites. In addition, mitochondrial reactive oxygen species (ROS) production has recently been shown to be a factor mediating mitochondria-to-nucleus signaling for the expression of AOX1. We found that the exogenously supplied TCA cycle organic acids citrate, malate and 2-oxoglutarate caused rapid and dramatic increases in the steady-state level of AOX1 mRNA at low, near physiological concentrations (0.1 mM). Furthermore, an increase in AOX1 induced by the addition of organic acids occurs independently of mitochondrial ROS formation. Our results demonstrate that two separate pathways for mitochondria-to-nucleus signaling of AOX1 may exist, one involving ROS and the other organic acids.

PCR and DNA Hybridization Methods for Specific Detection of Bean-Infecting Begomoviruses in the Americas and Caribbean.

Begomoviruses are a major problem for common bean production in the tropics and subtropics of the Americas and the Caribbean. Multiplex polymerase chain reaction (PCR) primer pairs and nucleic acid hybridization probes have been developed to differentiate five bean-infecting begomoviruses and were used to assay reference and field-collected bean samples from Florida, Mexico, Central America, the Caribbean, and Brazil. Bean golden mosaic virus was found in Brazil, Bean calico mosaic virus in Mexico, and Bean golden yellow mosaic virus in Central America, the Caribbean, and Florida. Bean dwarf mosaic virus was not detected in any of the field samples. Tomato yellow leaf curl virus was found only in tomato samples from the Caribbean. These detection methods will provide tools to assist in the understanding of the epidemiology and diversity of geminiviruses as well as to facilitate resistance breeding, cultivar selection, and development of strategies for control.

First Report of Tomato yellow leaf curl virus Associated with Beans, Phaseolus vulgaris, in Cuba.

Beans with yellow mosaic and/or leaf crumple symptoms were collected in three fields in the southern area of the province of Havana, Cuba in December 2001 and February 2002. DNA was extracted from the fresh bean leaves of 25 samples (1). Dot blot hybridization was performed at high stringency with a specific probe for Tomato yellow leaf curl virus (TYLCV). The specific probe was prepared by alkaline phosphatase labeling of the polymerase chain reaction (PCR) fragment amplified with primer pair, PTYIRv21/PTYIRc287, containing the intergenic region (IR) of TYLCV, and chemiluminescent hybridization was completed as described by the manufacturer (AlkPhos Direct Labeling and Detection Systems, Amersham Pharmacia Biotech Inc., Piscataway, NJ). Four of the samples had positive hybridization signals. PCR was performed with overlapping primers for TYLCV (2) with the DNA extract from sample 01-44, which gave a positive hybridization signal with the TYLCV probe, and a 2.8-kb fragment was obtained. This fragment was cloned in pGem T-Easy (pBeTY44) and partially sequenced. Greater than 96% nt identity was obtained for the 591 nt of the IR and 504 nt of the N-terminus of the Rep gene with TYLCV (GenBank Accession No. AF260331). Also, PCR was completed on 11 of the 25 samples with the degenerate primer pair PAL1v1978/PAR1c715 for DNA-A (3). Eight samples gave fragment sizes of 1.4 kb and one sample gave a fragment of 1.3 kb. The 1.3-kb fragment from sample number 01-50 was cloned in pGem T-Easy (pBeBG50) and partially sequenced. Pairwise nucleotide comparisons with Bean golden yellow mosaic virus (BGYMV, GenBank Accession No. M91604) were 95% for 719 nt of the N-terminus of the Rep gene. These results are consistent with the association of both TYLCV and BGYMV in beans and have important implications for future disease management strategies. References: (1) G. P. Accotto et al. Eur. J. Plant. Pathol. 106:179, 2000. (2) M. K. Nakhla et al. Plant Dis. 78:926, 1994. (3) M. Rojas et al. Plant Dis. 77:340, 1993.

Calopogonium golden mosaic virus Identified in Phaseolus vulgaris from Western and Northern Regions of Costa Rica.

Bean golden yellow mosaic virus (BGYMV, GenBank Accession No. M91604) is reported to be the main bean-infecting (Phaseolus vulgaris) begomovirus in Central America (1,2). Another begomovirus, Bean calico mosaic virus (BCaMV, GenBank Accession No. AF110189), is known to infect P. vulgaris in central Mexico. Bean samples with the viral symptom of foliar chlorosis were collected in different regions of Costa Rica from 1994 to 2001. Total nucleic acids were extracted and tested using polymerase chain reaction (PCR) with degenerate primer pair PBL1v2039/PCRc2 for DNA-B, which can give a different fragment size for some begomoviruses (4). PCR fragments were obtained from 119 bean samples. Fifty samples from the central valley produced 600-bp PCR fragments, which is typical for BGYMV (4), and one sample produced two fragments (500 and 600 bp). One sample from western Costa Rica had a 550-bp fragment, and 69 samples from the western and northern regions produced 500-bp fragments. One of the latter samples (No. 01-1152) was selected for PCR with degenerate primer pairs PAL1v1978/PAR1c715 for DNA-A and PBL1v2039/PBR1v800 for DNA-B (4). The amplified PCR fragments were 1.35 and 1.4 kb for DNA-A and DNA-B, respectively. These are expected sizes for a Western Hemisphere begomovirus. The DNA-A fragment was cloned and sequenced (GenBank Accession No. AF439402). Sequence comparisons indicated that this uncharacterized begomovirus (No. 01-1152) had 98, 97, and 93% nucleotide identities with the rep gene, common region, and coat protein gene promoter of Calopogonium golden mosaic virus (CalGMV, GenBank Accession Nos. AF439748 and AF439749, respectively) (3). CalGMV had been isolated from a weed, Calopogonium sp., collected in 1991 near Quepos in the west and Tilaran in the north of Costa Rica (3). Phylogenetic analysis of the viral sequence of the begomovirus associated with No. 01-1152 placed it in the Squash leaf curl virus clade (1). BCaMV is also in this phylogenetic clade, but sequence comparisons between CalGMV and BCaMV had <90% nucleotide identity, and so are distinct species. CalGMV is the begomovirus associated with No. 01-1152, and this is an example of the movement of a weed-infecting begomovirus into an agricultural crop. Since this Calopogonium sp. is widespread in Central America, it is important to determine if CalGMV is present in beans in other regions. The data also indicate that BGYMV and CalGMV infect beans in two geographically distinct regions of Costa Rica. References: (1) J. C. Faria et al. Phytopathology 84:321, 1994. (2) W. McLaughlin et al. Plant Dis. 78:1220, 1994. (3) M. R. Rojas et al. Annu. Rep. Bean Improv. Coop. 35:150, 1992. (4) M. R. Rojas et al. Plant Dis. 77:340, 1993.

First Report and Partial Molecular Characterization of a New Begomovirus Associated with Pigeon Pea in Puerto Rico.

Pigeon pea (Cajanus cajan (L.) Millsp.) is an important edible legume crop in Puerto Rico. In late fall 1997, symptoms of a golden mosaic virus were observed in a pigeon pea planting in the municipality of Villalba. The symptoms resembled those incited by the Rhynchosia mosaic virus, a whitefly-transmitted virus, in pigeon pea (1). Tests with the 3F7 antigeminivirus antibody from Agdia (Elkhart, IN) confirmed the presence of a begomovirus in these symptomatic pigeon peas. Extraction of DNA from dried symptomatic foliar tissue was accomplished by the methods described in Rojas et al. (2), and subsequent viral DNA amplification was accomplished with the coat protein (CP) gene polymerase chain reaction primer pair AV494-AC1048 (3). A 550-bp fragment was cloned and sequenced (GenBank Accession No. AY028308). For sequence analysis, the BLAST program at the National Institutes of Health was used. The first match was 91% with the CP gene sequence (Accession No. AF070924) of a begomovirus from Clitoria falcata from Puerto Rico. The next three matches were approximately 86% with a begomovirus (accession no. AF058024) from Macroptilium lathyroides from Puerto Rico, Dicliptera yellow mottle virus (Accession No. AF139168) from Florida, and Tobacco apical stunt virus (Accession No. AF076855) from Mexico. On the basis of sequence analysis of this conserved region of the CP gene, it is concluded that the virus described in this report is a new virus, and thus named Pigeon pea golden mosaic virus. The only sequence for a begomovirus from a Rhynchosia sp. in GenBank is Rhynchosia golden mosaic virus from Honduras (accession no. AF239671). On the basis of sequence comparisons, the virus from pigeon pea is not an isolate of the Honduran Rhynchosia golden mosaic virus. References: (1) J. Bird et al. 1975. Pages 3-25 in: Tropical Diseases of Legumes. J. Bird and K. Maramorosch, eds. Academic Press, NY. (2) M. R. Rojas et al. Plant Dis. 77:340, 1993. (3) S. D. Wyatt and J. K. Brown. Phytopathology. 86:1288, 1996.

A New Tomato-Infecting Begomovirus in Barbados.

In September 1998, tomato plants in Barbados exhibited symptoms of severe leaf curling without marginal chlorosis. These symptoms were often associated with an increase in whitefly (Bemisia tabaci) populations. DNA was extracted from leaf tissue from symptomatic tomato plants. Polymerase chain reaction (PCR) was performed with DNA-A degenerate primer pair PAC1v1978/PAV1c715, which amplifies part of the rep gene, the cp gene, and the common region (CR), and with DNA-B primer pair PBC1v2039/PBV1c800, which amplifies part of the bc1 and bv1 genes and the CR (2). The amplified PCR fragments of DNA-A and DNA-B were 1.3 and 1.4 kb, respectively, which are the expected sizes from bipartite, whitefly-transmitted geminiviruses of the Western Hemisphere (2). DNA sequence of the cloned fragments of DNA-A and DNA-B are available as GenBank No. AF213013 and AF213014, respectively. The 181 nucleotides of the CR of DNA-A had a nucleotide identity of 96% with the CR of DNA-B, which indicates that this is a bipartite begomovirus. Pairwise comparisons using DNASTAR (DNASTAR, Madison, WI) of the sequenced part of DNA-A was most similar to Cabbage leaf curl virus (CaLCuV, 69%, U65529) and Squash leaf curl virus extended host range isolate (SqLCV-E, 64%, M38183), and <59% to 13 other bipartite Western Hemisphere geminiviruses and Tomato yellow leaf curl virus from Israel (X15656). Pairwise comparisons of the DNA-B fragment sequence was 59 and 55% similar to CaLCuV (U65530) and SqLCV-E (M38182), respectively. Phylogenetic analysis of DNA-A of the major groups of Western Hemisphere begomoviruses placed the Barbados tomato-infecting geminivirus in the cluster with CaLCuV and SqLCV-E (1), while DNA-B analysis placed it with CaLCuV. The DNA-A amplified fragment was used as a probe at high stringency with the dot blot hybridization assay using the Genius II labeling and detection kit (Boeringer Mannheim) to detect this geminivirus in tomato and several other plant species, which had typical geminiviral symptoms. Strong hybridization signals were obtained for all 23 tomato plants with symptoms, weak signals were observed for two of three muskmelon and two of seven watermelon plants, all with leaf curling symptoms. No hybridization signals were observed for peppers with leaf curling symptoms and two weed species, Macroptilium lathyroides and Rhynchosia minima, with golden mosaic symptoms or with the symptomless plant species used as negative controls. The weak signals observed from watermelon and muskmelon samples indicated the presence of low virus titer or geminiviruses distinct from this tomato virus. The presence of viral DNA in these two plant species was confirmed by PCR with degenerate primers described above. Resulting database searches of sequences in the GenBank revealed that the Barbados tomato virus appears to be a previously unreported virus. This new virus is given the provisional name Tomato leaf curl Barbados virus (ToLCBBV). References: (1) J. C. Faria et al. Phytopathology 84:321, 1994. (2) M. R. Rojas et al. Plant Dis. 77:340, 1993.

First Report and Characterization of Rhynchosia golden mosaic virus in Honduras.

Rhynchosia minima was suspected to be a weed host of Bean golden yellow mosaic virus (BGYMV, previously designated Bean golden mosaic virus type II). Leaf tissue that exhibited yellow mosaic foliar symptoms characteristic of a geminivirus infection was collected in the Comayagua Valley in Honduras in July 1999. Extraction of viral DNA from the symptomatic leaves was accomplished with the DNeasy Plant Mini Kit (Qiagen Inc., Valencia, CA). Subsequent viral DNA amplification was accomplished with degenerative primers for the cp gene (AV494/AC1048) (4). The 570-bp fragment was cloned into the pGEM T-Easy vector (Promega Corp., Madison, WI) producing the recombinant plasmid pRhyb5. The viral insert was sequenced, and from this sequence, specific primers (RHc549 and RHv29) were designed to amplify the remaining part of DNA-A. The 2.1-kb-amplified polymerase chain reaction (PCR) fragment was cloned into the pGEM T-Easy vector producing the recombinant plasmid (pRhya-sp), and the viral insert was sequenced. Nucleotide sequence comparison (GAP program, Wisconsin Package Version 10.0, Genetics Computer Group, Madison, WI) of the complete 2,624-bp DNA-A (GenBank accession no. AF239671) to geminiviruses representing the major phylogenetic clusters (1) showed nucleotide identities ranging from 63 to 82%. Sequence comparisons for the common region and rep, trap, ren, and cp genes with the most closely related geminivirus, Pepper hausteco virus (PHV, X70418), gave 76, 82, 79, 81, and 82% nucleotide identities, respectively. There is a direct repeat (TATCGGT) of 7 nt 5' (viral sense polarity) of the conserved TATA box, and this repeat is most analogous to that in PHV (1). Specific primers were designed in the complementary sense (RGBc2414, BGBc2553) from the common region DNA-A sequence and used with a degenerative viral sense primer for the DNA-B (PBC1v2039) (3) to amplify a 647-bp fragment. Sequence comparison for the common region (134 nt from the rep gene start codon toward the 3' end) from the DNA-B sequence had 88% nt identity to the DNA-A sequence, thus indicating that this geminivirus is bipartite. These sequence analyses indicated that this geminivirus isolated from R. minima is distinct from previously described geminiviruses, and we propose the name Rhynchosia golden mosaic virus (RGMV). From rep gene sequence alignments, RGMV has an apparent genome recombination between Old and New World geminiviruses (Tomato yellow leaf curl virus and Bean dwarf mosaic virus) as previously noted for PHV (2). Our results indicate that RGMV is a distinct geminivirus from BGYMV, and, thus, additional studies are needed to establish the importance of R. minima as a reservoir for vegetable-infecting geminiviruses. This study is the first report of another virus in the PHV phylogenetic cluster and is thus of importance in the understanding of recombinant viruses and their phylogenetic relationship to other characterized geminiviruses. References: (1) J. C. Faria et al. Phytopathology 84:321, 1994. (2) M. Padidam et al. Virology 265:218, 1999. (3) M. R. Rojas et al. Plant Dis. 77:340, 1993. (4) S. Wyatt and J. K. Brown. Phytopathology 86:1288, 1996.

The alternative oxidase lowers mitochondrial reactive oxygen production in plant cells.

Besides the cytochrome c pathway, plant mitochondria have an alternative respiratory pathway that is comprised of a single homodimeric protein, alternative oxidase (AOX). Transgenic cultured tobacco cells with altered levels of AOX were used to test the hypothesis that the alternative pathway in plant mitochondria functions as a mechanism to decrease the formation of reactive oxygen species (ROS) produced during respiratory electron transport. Using the ROS-sensitive probe 2',7'-dichlorofluorescein diacetate, we found that antisense suppression of AOX resulted in cells with a significantly higher level of ROS compared with wild-type cells, whereas the overexpression of AOX resulted in cells with lower ROS abundance. Laser-scanning confocal microscopy showed that the difference in ROS abundance among wild-type and AOX transgenic cells was caused by changes in mitochondrial-specific ROS formation. Mitochondrial ROS production was exacerbated by the use of antimycin A, which inhibited normal cytochrome electron transport. In addition, cells overexpressing AOX were found to have consistently lower expression of genes encoding ROS-scavenging enzymes, including the superoxide dismutase genes SodA and SodB, as well as glutathione peroxidase. Also, the abundance of mRNAs encoding salicylic acid-binding catalase and a pathogenesis-related protein were significantly higher in cells deficient in AOX. These results are evidence that AOX plays a role in lowering mitochondrial ROS formation in plant cells.

trans-Dominant Inhibition of Geminiviral DNA Replication by Bean Golden Mosaic Geminivirus rep Gene Mutants.

ABSTRACT Geminiviruses are a group of single-stranded DNA viruses that cause major losses on a number of important crops throughout the world. Bean golden mosaic virus (BGMV) is a typical bipartite, whitefly-transmitted geminivirus that causes a severe disease on beans (Phaseolus vulgaris) in the Western Hemisphere. The lack of natural resistance to geminiviruses has led to attempts to engineer resistance, particularly through the use of pathogen-derived resistance strategies. The rep gene contains several conserved domains including nucleoside triphosphate (NTP)-binding and DNA-nicking domains and is the only geminiviral gene necessary for replication. Previous analysis by our group and others has demonstrated that the NTP-binding and DNA-nicking domains are necessary for geminiviral DNA replication. The ability of the rep gene and rep gene mutants to interfere with geminiviral DNA replication, when expressed in trans, was examined using a transient assay in a tobacco suspension cell culture system. Wild-type (wt) and mutant rep genes were cloned into plasmids under the control of the cauliflower mosaic virus 35S promoter for in planta expression and coinoculated into tobacco cells with infectious clones of various geminiviruses. The wt rep gene from BGMV-GA was able to support replication of BGMV-GA DNA-B. Several different rep gene mutants, with function-abolishing mutations in the NTP-binding or DNA-nicking domains, were potent trans-dominant inhibitors of geminiviral DNA replication.

Variability in Geminivirus Isolates Associated with Phaseolus spp. in Brazil.

ABSTRACT Bean golden mosaic geminivirus (BGMV) is the single most devastating virus of common beans in the tropical and subtropical Americas and the Caribbean Basin. The BGMV from Brazil, named BGMV-BZ, is considered distinct from BGMV-PR isolates from Puerto Rico, Guatemala, and the Dominican Republic because of DNA sequence data, the ability to form pseudorecombinants, and mechanical transmissibility properties. In bean-growing areas of Brazil, samples were collected from beans, lima beans, and the weed Leonurus sibiricus displaying typical symptoms of infection by geminiviruses. Viral DNA fragments comprising part of the rep gene, the common region, and part of the cp gene were amplified by polymerase chain reaction, cloned, and sequenced. The bean samples had geminivirus with sequences nearly identical to that of BGMV-BZ collected in Goiânia, state of Goiás, in 1986. The sample from lima bean contained a new species of geminivirus that induces symptoms similar to those induced by BGMV-BZ and was named lima bean golden mosaic virus (LBGMV-BR). While all sequences from bean samples clustered with BGMV-BZ, the sequence from the lima bean isolate stood alone. A mixed infection with abutilon mosaic geminivirus was also found in a single sample from the state of São Paulo. DNA sequence comparisons indicate that the virus isolate from L. sibiricus represents a new geminivirus species, designated here as leonurus mosaic virus.

A New Geminivirus Associated with Tomato in the State of São Paulo, Brazil.

The apical growth of about 20% of young tomato plants in observed fields near Campinas, State of São Paulo, Brazil, had yellow streaking of veins. Leaf symptoms developed into patches of yellow mosaic and the leaves became wavy. The whitefly Bemisia tabaci Genn. transmitted a pathogen from the infected tomato plants to healthy tomato and potato plants, reproducing the original symptoms in tomato. The apical leaves of infected potatoes showed yellow or green mottle that developed into leaf distortion with yellow blotches, symptoms indistinguishable from potato-deforming mosaic disease (2). DNA was extracted from these tomato and potato plants (1). Using DNA from the infected tomato plant, polymerase chain reaction (PCR) with the degenerate primer pair PAC1v1978/ PAV1c715 (1), which amplifies part of the rep gene (AC1 ORF), the common region (CR), and part of the cp gene (AV1 ORF), and with the primer pair PBC1v2039/PBV1c800, which amplifies part of BC1 ORF, CR, and part of BV1 ORF, gave virus-specific DNA fragments of the sizes expected from a whitefly-transmitted geminivirus. These were cloned and the complete nucleotide (sequences for DNA-A (pToYA, GenBank accession no. U79998) and DNA-B (pToYB, GenBank accession no. U80042) fragments obtained. Nucleotide identity between the CRs (184 nucleotides) was 90%, strongly indicating that those fragments correspond to a bipartite subgroup III geminivirus. PCR with the DNA from infected potato gave the expected size fragment for DNA-A. The partial sequence of the rep gene was 100% identical to the homologous sequence from the PCR fragment from the infected tomato. A search in the GenBank, EMBL, DDBJ, and PDB databases, using the BLAST program, found no identical geminivirus. The highest identity for the CR was 75% to tomato mottle geminivirus-Florida (ToMoV) and 74% to bean golden mosaic virus-Brazil. For the rep gene, the highest identity was 73% to tomato yellow leaf curl virus-Israel, an Old World geminivi-rus, followed by 71% to tomato golden mosaic virus-Brazil (TGMV) and ToMoV. For the cp gene, the highest identity was 86% to TGMV, followed by 83% to squash leaf curl geminivirus. Therefore, we propose the name tomato yellow vein streak geminivirus (ToYVSV) for this distinct virus (2). References: (1) M. R. Rojas et al. Plant Dis. 77:340, 1993. (2) J. A. C. Souza-Dias et al. Summa Phytopathol. 22:57, 1996.

A New Geminivirus Associated with a Leaf Curl Disease of Tomato in Tanzania.

Leaf samples of tomato exhibiting yellow mottle, severe leaf curl, stunting, and upright stems were collected from Makutupora, Tanzania, in October 1994 by L. L. Black (AVRDC). Leaf tissue squashes on nylon membranes did not hybridize with DNA-A probes from tomato yellow leaf curl geminiviruses (TYLCVs) from Thailand (Thai) or Egypt (EG), an isolate of TYLCV-Isr (Israel). Polymerase chain reaction (PCR) with primer pair PAC1v1978/PAV1c715 (2), which specifically amplifies part of the rep (AC1) open reading frame (ORF), the intergenic region, and the cp (AV1) ORF of whitefly-transmitted geminiviruses, yielded a 1.5-kb fragment from a DNA extract of symptomatic tomato leaves. No virus-specific fragments were amplified from symptomless tomato leaves. The nucleotide sequence (GenBank accession no. U73478) of the PCR fragment (recombinant plasmid pAF1) was compared with the sequences of seven distinct subgroup III geminiviruses that infect tomato (1)-TYLCV-Isr, TYLCV-Sar (Sardinia), TYLCV-Thai, tomato leaf curl virus (TLCV)-;Aus (Australia), IndTLCV (India), TLCV-Ind (Bangalore I), and TLCV-Tai (Taiwan)-as well as three other subgroup III geminiviruses from the Old World: Indian cassava mosaic virus, African cassava mosaic virus, and mung bean yellow mosaic virus. Nucleotide sequence identities for the pairwise comparisons of the rep ORF (692 nucleotides) and the intergenic region (169 nucleotides) of this Tanzanian geminivirus with those of the 10 Old World geminiviruses showed low nucleotide identities, which were <79% for the rep ORF and <67% for the intergenic region. Since isolates of the same geminivirus usually have nucleotide sequence identities >90% (1), this Tanzanian geminivirus is considered to be different from all previously characterized Old World geminiviruses and is given the name TLCV-Tan. Further, tissue squash blots of samples previously collected from other areas in Tanzania gave strong positive reactions with the TYLCV-EG probe, so yet another geminivirus closely related to TYLCV-Isr may be present. References: (1) M. Padidam et al. J. Gen. Virol. 76:249, 1995. (2) M. R. Rojas et al. Plant Dis. 77:340, 1993.

Mutational analysis of the putative nicking motif in the replication-associated protein (AC1) of bean golden mosaic geminivirus.

Geminiviruses are circular single-stranded DNA viruses that replicate by a rolling circle mechanism involving the viral-encoded AC1 protein. DNA nicking is necessary both for initiating replication of the covalently closed double-stranded DNA templates and for releasing unit-length monomers. The effects of mutations in a putative nicking motif (K101 A Y I D K106; E. V. Koonin and T. V. Ilyina, J. Gen. Virol. 73:2763-2766, 1992) of the AC1-derived protein for bean golden mosaic geminivirus isolate GA (BGMV-GA) were studied. The amino acids equivalent to Y103 and K106 of BGMV-GA are invariant in all whitefly-transmitted geminiviruses. Phaseolus vulgaris plant infectivity assays showed that the mutants K101-->H, K101-->A, and D105-->T produced symptoms, but mutants Y103-->A, Y103-->F, K106-->R, and K106-->H did not. A mutant with a stop codon in the N terminus of the AC4 open reading frame (ORF) produced the same symptoms as the wild-type BGMV-GA. Only those that were infectious replicated in NT-1 tobacco suspension cells. These results indicate that the Y103 and K106 residues are essential for replication, and that this putative DNA-nicking motif of the AC1 ORF may be functional in the rolling circle mechanism of replication for geminiviruses. The potential role of these mutants in the design of antiviral strategies is discussed.

Photosystem II Excitation Pressure and Photosynthetic Carbon Metabolism in Chlorella vulgaris.

Chlorella vulgaris grown at 5[deg]C/150 [mu]mol m-2 s-1 mimics cells grown under high irradiance (27[deg]C/2200 [mu]mol m-2 s-1). This has been rationalized through the suggestion that both populations of cells were exposed to comparable photosystem II (PSII) excitation pressures measured as the chlorophyll a fluorescence quenching parameter, 1 - qP (D.P. Maxwell, S. Falk, N.P.A. Huner [1995] Plant Physiol 107: 687-694). To assess the possible role(s) of feed-back mechanisms on PSII excitation pressure, stromal and cytosolic carbon metabolism were examined. Sucrose phosphate synthase and fructose-1,6-bisphosphatase activities as well as the ratios of fructose-1,6-bisphosphate/fructose-6-phosphate and sucrose/starch indicated that cells grown at 27[deg]C/2200 [mu]mol m-2 s-1 appeared to exhibit a restriction in starch metabolism. In contrast, cells grown at 5[deg]C/150 [mu]mol m-2 s-1 appeared to exhibit a restriction in the sucrose metabolism based on decreased cytosolic fructose-1,6- bisphosphatase and sucrose phosphate synthase activities as well as a low sucrose/starch ratio. These metabolic restrictions may feed-back on photosynthetic electron transport and, thus, contribute to the observed PSII excitation pressure. We conclude that, although PSII excitation pressure may reflect redox regulation of photosynthetic acclimation to light and temperature in C. vulgaris, it cannot be considered the primary redox signal. Alternative metabolic sensing/signaling mechanisms are discussed.