J. S. Hu

The P0 gene of Sugarcane yellow leaf virus encodes an RNA silencing suppressor with unique activities.

The Sugarcane yellow leaf virus (SCYLV) P0, a member of the highly heterologous proteins of poleroviruses, is a suppressor of posttranscriptional gene silencing (PTGS) and has additional activities not seen in other P0 proteins. The P0 protein in previously tested poleroviruses (Beet western yellows virus and Cucurbit aphid-borne yellows virus), suppresses local, but not systemic, PTGS induced by both sense GFP and inverted repeat GF using its F-box-like domain to mediate destabilization of the Argonaute1 protein. We now report that the SCYLV P0 protein not only suppressed local PTGS induced by sense GFP and inverted repeat GF in Nicotiana benthamiana, but also triggered a dosage dependent cell death phenotype in infiltrated leaves and suppressed systemic sense GFP-PTGS. Deletion of the first 15 N-terminal amino acid residues of SCYLV P0 abolished suppression of both local and systemic PTGS and the induction of cell death. In contrast, only systemic PTGS and cell death were lost when the 15 C-terminal amino acid residues were deleted. We conclude that the 15 C-terminal amino acid residue region of SCYLV P0 is necessary for suppressing systemic PTGS and inducing cell death, but is not required for suppression of local PTGS.

Transmission of Pineapple Mealybug Wilt-Associated Virus by Two Species of Mealybug (Dysmicoccus spp.).

ABSTRACT Closterovirus-like particles associated with mealybug wilt of pineapple were acquired and transmitted by the pink pineapple mealybug, Dysmicoccus brevipes, and the gray pineapple mealybug, D. neobrevipes. Mealybugs acquired pineapple mealybug wilt-associated virus (PMWaV) from infected pineapple plants or detached leaves. The virus was detected in plants by tissue blot immunoassay and confirmed by immunosorbent electron microscopy. Plants exposed to mealybugs reared on PMWaV-free pineapple tissue remained uninfected. The presence of ants was correlated with an increased rate of virus spread when caged with D. brevipes. All stages of D. neobrevipes acquired PMWaV, although vector efficiency decreased significantly in older adult females. The probability of a single third-instar immature transmitting the virus was 0.04. Both species of mealybug acquired and transmitted PMWaV from infected pineapple material that had been clonally propagated for decades, and both species acquired PMWaV from sources previously infected with the virus by the other mealybug species.

Comparison of dot blot, ELISA, and RT-PCR assays for detection of two cucumber mosaic virus isolates infecting banana in Hawaii

The coat protein genes of two cucumber mosaic virus (CMV) isolates infecting banana plants in Hawaii were cloned and sequenced. Based on nucleotide and amino acid sequence comparisons, both isolates belong to CMV subgroup I. One isolate (CMV-Hawaii), which is common in banana plants in the state of Hawaii and induces mild mosaic symptoms, shares 99% sequence identity (both nucleotide and amino acid sequences) with CMV-C strain. Another isolate (CMV-Oahu), which was found only at two banana farms in the state of Hawaii, induces severe mosaic and leaf distortion symptoms. CMV-Oahu shares 91% and 93% nucleotide and amino acid sequence identity, respectively, with both CMV-C and CMV-Hawaii. A reverse transcription-polymerase chain reaction (RT-PCR) assay was developed for detection of both CMV subgroups from banana samples. The RT-PCR product (∼750 bp) was also labeled as a probe to detect CMV in dot blot hybridization tests. PCR is a more sensitive assay than either dot blot or ELISA. The dot blot assay was 100 times more sensitive than ELISA. The distribution of CMV within banana plants was uneven. CMV concentrations were higher in younger leaves than in older ones. The CMV-Oahu isolate was not detected in banana by ELISA using antibodies to both CMV subgroups I and II, but was positive in dot blot and RT-PCR tests.

The coat protein gene of grapevine leafroll associated closterovirus-3: cloning, nucleotide sequencing and expression in transgenic plants

SummaryA lambda ZAP II cDNA library was constructed by cloning cDNA prepared from a high molecular weight double-stranded RNA (dsRNA, ca. 18 kb) isolated from grapevine leafroll associated closterovirus-3 (GLRaV-3) infected tissues. This cDNA library was immuno-screened with GLRaV-3 coat protein specific polyclonal and monoclonal antibodies and three immuno-positive clones were identified. Analysis of nucleotide sequences from these clones revealed an open reading frame (ORF) which was truncated at the 3′ end; the remainder of this ORF was obtained by sequencing a fourth clone that overlapped with one of the immunopositive clones. A total of 2028 bp was sequenced. The putative GLRaV-3 coat protein ORF, 939 bp, encodes a protein (referred to as p35) with a calculated Mr of 34 866. Multiple alignment of the p35 amino acid sequence with coat protein sequences from other clostero-viruses revealed that the consensus amino acid residues (R and D) of filamentous plant viruses are preserved in the expected locations. The GLRaV-3 coat protein gene was then engineered for sense and antisense expression in transgenic plants. Transgenic Nicotiana benthamiana plants that contain the sense GLRaV-3 coat protein gene produced a 35 kDa protein that reacted with GLRaV-3 antibody in Western blot.

Detection of Cymbidium mosaic virus, Odontoglossum ringspot virus, tomato spotted wilt virus, and potyviruses infecting orchids in Hawaii

Approximately 3,600 orchid plants representing 44 genera from three orchid collections, 22 commercial farms, and six nurseries on the islands of Oahu and Hawaii were tested for Cymbidium mosaic virus (CyMV), Odontoglossum ringspot virus (ORSV), tomato spotted wilt virus (TSWV), and potyviruses with enzyme-linked immunosorbent assay (ELISA). CyMV was detected in 59 samples and ORSV was detected in 23 samples, which represented 61 and 25% of the 44 genera surveyed, respectively. Double infection with both viruses occurred in 20 samples, representing 20% of the genera. CyMV and ORSV were detected in 29 and seven of the 31 sites surveyed, respectively

Use of a Tissue Blotting Immunoassay to Examine the Distribution of Pineapple Closterovirus in Hawaii

Specific monoclonal antibodies made to a pineapple closterovirus (PCV) were used in a tissue blotting immunoassay (TBIA) for the detection of PCV in pineapple. More than 2,000 samples were tested in 5 days by one person using this rapid and reliable assay. A survey was conducted using this assay to test more than 20,000 Hawaiian pineapple samples for the presence of PCV. PCV was detected in symptomless pineapple plants in the field and in the USDA pineapple germ plasm collection. Studies of the association of PCV with mealybug wilt of pineapple (MWP) suggest that PCV may be involved in MWP.

Diversity and mealybug transmissibility of ampeloviruses in Pineapple

Mealybug wilt of pineapple (MWP) is one of the most destructive diseases of pineapple (Ananas comosus) worldwide. At least one Ampelovirus species, Pineapple mealybug wilt associated virus-2 (PMWaV-2), and mealybug feeding are involved in the etiology of MWP. A previously undescribed Ampelovirus sharing highest homology with PMWaV-1 and a putative deletion mutant sharing highest homology with PMWaV-2 were detected with reverse transcription-polymerase chain reaction (RT-PCR) assays using degenerate primers. Results were verified with additional sequence information and by immunosorbent electron microscopy. Sequence homology between the virus tentatively designated PMWaV-3, and PMWaV-1 and PMWaV-2, decreases toward the N-terminal across the HSP70 homolog, small hydrophobic protein, and RNA-dependent RNA polymerase open reading frames (ORF). Putative PMWaV-3 could not be detected with four different monoclonal antibodies specific for PMWaV-1 and PMWaV-2. The potential deletion mutant spanning the N-terminal of the HSP70 region was obtained from a pineapple accession from Zaire maintained at the USDA-ARS National Clonal Germplasm Repository in Hawaii. Putative PMWaV-3, like PMWaV-1 and PMWaV-2, is transmissible separately or in combination with other PMWaVs by Dysmicoccus brevipes and D. neobrevipes mealybugs. Plants infected with PMWaV-3 that were continuously exposed to mealybugs did not develop symptoms of MWP in the absence of PMWaV-2. Specific RT-PCR assays were developed for detection of putative PMWaV-3 and the deletion mutant.

Characterization of a Virus Infecting Citrus volkameriana with Citrus Leprosis-Like Symptoms

A Citrus volkameriana tree displaying symptoms similar to citrus leprosis on its leaves and bark was found in Hawaii. Citrus leprosis virus C (CiLV-C)-specific detection assays, however, were negative for all tissues tested. Short, bacilliform virus-like particles were observed by transmission electron microscopy in the cytoplasm of symptomatic leaves but not in healthy controls. Double-stranded (ds) RNAs ≈8 and 3 kbp in size were present in symptomatic leaf tissue but not in healthy controls. Excluding poly(A) tails, the largest molecule, RNA1, was 8,354 bp in length. The ≈3 kbp dsRNA band was found to be composed of two distinct molecules, RNA2 and RNA3, which were 3,169 and 3,113 bp, respectively. Phylogenetic analyses indicated that the RNA-dependent RNA polymerase (RdRp) domain located in RNA1 was most closely related to the RdRp domain of CiLV-C. A reverse-transcription polymerase chain reaction assay developed for the detection of this virus was used to screen nearby citrus trees as well as Hibiscus arnottianus plants with symptoms of hibiscus green spot, a disease associated with infection by Hibiscus green spot virus (HGSV). All nearby citrus trees tested negative with the assay; however, symptomatic H. arnottianus plants were positive. All three RNAs were present in symptomatic H. arnottianus and were >98% identical to the RNAs isolated from C. volkameriana. We contend that the virus described in this study is HGSV, and propose that it be the type member of a new virus genus, Higrevirus.

Closterovirus Infection and Mealybug Exposure Are Necessary for the Development of Mealybug Wilt of Pineapple Disease

ABSTRACT The roles of Pineapple mealybug wilt-associated viruses (PMWaVs) and mealybug (Dysmicoccus spp.) feeding in the etiology of mealybug wilt of pineapple (MWP) were evaluated. Container-grown pineapple (Ananas comosus) plants from five commercially grown Hawaiian proprietary selections and a field study utilizing a randomized complete block design were used to test four treatments for induction of MWP: PMWaV-1-free and PMWaV-1-infected plants maintained mealybug-free, and PMWaV-1-free and PMWaV-1-infected plants that received monthly applications of nonviruliferous mealybugs. A second PMWaV, PMWaV-2, was identified in some of the test plants during the course of these studies and was shown to be an integral factor in MWP etiology. Typical MWP symptoms developed only in plants infected with PMWaV-2 and exposed to mealybugs. MWP did not develop in PMWaV-1-free or PMWaV-1-infected plants that were exposed to mealybugs, or in mealy-bug-free plants infected with PMWaV-1, PMWaV-2, or both viruses. Plants from all five Hawaiian proprietary selections developed MWP when PMWaV-2 infected plants were exposed to mealybug feeding. A PMWaV-2-specific monoclonal antibody was produced that decorated the particles in immunosorbent electron microscopy and detected the virus in tissue blot immunoassays. PMWaV-2 was acquired and transmitted by pink and gray pineapple mealybugs (Dysmicoccus spp.) to pineapple plants, and these plants subsequently developed MWP symptoms while sustaining mealybug populations.

Transmission, movement and inactivation of cymbidium mosaic and odontoglossum ringspot viruses.

Transmission and movement studies were conducted on orchids mechanically inoculated with cymbidium mosaic virus (CyMV) or odontoglossum ringspot virus (ORSV). Transmission of CyMV and ORSV to University of Hawaii (UH) Dendrobium hybrids was efficient; both viruses were detected in inoculated leaves a minimum of 3 days after inoculation. Cymbidium mosaic virus moved systemically from inoculated leaves to roots (minimum 10 days after inoculation) and then to other leaves (minimum 20 days after inoculation). Thirty-two of 33 CyMV-inoculated orchid plants were systemically infected. Systemic movement of ORSV took about 7 mo and occurred in only one of 38 inoculated orchid plants. Seven chemicals were evaluated for inactivation of CyMV on pruning tools for disease control [...]