Molecular characterization of a novel bipartite begomovirus isolated from Lycianthes biflora in China.

A bipartite begomovirus isolate GD was isolated from Lycianthes biflora plants showing yellow mosaic symptoms in Nanxiong, Guangdong Province, China. The apparently full-length DNA-A and DNA-B viral components were cloned after enrichment of circular DNA by rolling circle amplification, restriction digestion, cloning, and DNA sequencing. The DNA-A component (2752nt, KT582302) shares highest (80.2%) nucleotide (nt) sequence identity with tomato leaf curl Sulawesi virus [Indonesia-Sulawesi-Langowan F101-2006] (ToLCSuV- [ID-Sul -LanF09-06], FJ237618), reported in Indonesia as causing yellow leaf curl disease of chilli pepper. The DNA-B component (2704nt, KT582303) shares highest (76.3%) nt sequence identity with pepper yellow leaf curl Indonesia virus-[Indonesia-tomato2-2005] (PepYLCIV-[ID-Tom2-05 AB213599) reported in Indonesia, and associated with yellow leaf curl disease in tomato. Based on the ICTV guidelines for begomoviral species demarcation, the virus is a new, previously undescribed bipartite begomovirus species for which the name "Lycianthes yellow mosaic virus" is proposed.

Identification and molecular characterization of two begomoviruses from Pouzolzia zeylanica (L.) Benn. exhibiting yellow mosaic symptoms in adjacent regions of China and Vietnam.

Two monopartite begomoviruses were isolated from Pouzolzia zeylanica (L.) Benn. plants showing yellow mosaic symptoms in Gaoyao, Guangdong Province, China (GD1) and in Phu Tho, Vietnam (VN), respectively. A comparison of the complete genome sequence of GD1 (2,739 nucleotides [nt]) with VN (2,741 nt) indicated that they shared 86.2 % nt sequence identity. GD1 and VN shared the highest nucleotide sequence identity at 86.7 % and 91.4 % respectively, with isolate TY01 of pouzolzia golden mosaic virus (PGMV-TY01), another begomovirus isolated from P. zeylanica. Phylogenetic analysis revealed that GD1, VN, and PGMV-TY01 were members of a distinct begomovirus clade. Based on the ICTV guidelines for begomoviral species demarcation, GD1 belongs to a new begomovirus species, for which the name Pouzolzia yellow mosaic virus is proposed. Likewise, VN represents a previously unreported strain of PGMV. Recombination analysis predicted that VN was a recombinant between PGMV-TY01 and ageratum yellow vein China virus isolate G13 (AYVCNV-G13), and that PGMV-TY01 and VN were likely the parents of GD1 through recombination with allamanda leaf curl virus isolate G10 (AlLCV-G10), a begomovirus endemic to Guangdong Province of China.

First Report of Sweet potato leaf curl Georgia virus Infecting Tall Morning Glory (Ipomoea purpurea) in China.

In September 2013, tall morning glory (Ipomoea purpurea) plants showing vein yellowing and leaf curl symptoms typical of a begomovirus infection were observed in Jingzhou, Hubei Province, China. Total nucleic acids were extracted from a symptomatic plant using cetyltrimethylammonium bromide (CTAB). Rolling circle amplification (RCA) was conducted using TempliPhi kit (GE Healthcare) to recover the genome of a putative begomovirus. Digestion of the RCA product with PstI yielded a ~2.8 kbp DNA fragment suggestive of a monomerized begomoviral genome. The fragment was cloned and sequenced and the sequence was deposited in GenBank under accession no. KF769447. SDTv1.0 (species demarcation tool) analysis revealed that the putative begomovirus showed 98.5 and 92.0% nucleotide sequence identity with Sweet potato leaf curl Georgia virus (SPLCGV)-[China:Hebei:2011] (GenBank Accession No. JX448368) and SPLCGV-[US:Geo:16] (AF326775), respectively. The virus contained six ORFs, which encoded proteins showing 96.5 to 100% and 90.6 to 95.6% amino acid sequence identity with their counterparts of SPLCGV-[China:Hebei:2011] and SPLCGV-[US:Geo:16], respectively. Thus, the virus should be considered as an isolate of SPLCGV-[China:Hebei:2011]. Tall glory morning in a nearby field (which covers an area of 3 square kilometers) was surveyed and 70 to 100% of plants were found showing symptoms reminiscent of begomoviral infection. Total nucleic acid was extracted from 13 randomly selected (10 symptomatic and 3 healthy) plants and used as templates for PCR with a pair of specific primers (5'-CGCAGCCTTTCCACACTATC-3'/5'-AAAACAGTTTGGGCTCGGTC-3') designed according to the sequence described above. Positive results were obtained for all of the symptomatic, but none of the healthy-looking tall morning glory plants. SPLCGV (genus Begomovirus, family Geminiviridae) was reported to infect sweet potato (I. batatas) in the United States (4), India (2), and China (3). To our knowledge, this is the first report of SPLCGV infecting tall morning glory in China. Also, it is the first report of a geminivirus in Hubei, a province of central China. Whereas the finding of SPLCGV in sweet potato (3) may be a result of vegetative propagation of this crop, the detection of SPLCGV in tall morning glory, an annual plant, raises the possibility that this virus is transmissible and is spreading in China. References: (1) B. Muhire et al. Arch. Virol. 158:1411, 2013. (2) G. Prasanth and V. Hegde. Plant Dis. 92:311, 2008. (3) Y. Qin et al. Plant Dis. 97:1388, 2013. (4) R. A. Valverde and D. L. Gutierrez. Rev. Mex. Fitopatol. 21:128, 2003.

First Report of Wild tomato mosaic virus Infecting Tobacco (Nicotiana tabacum) in China.

Wild tomato mosaic virus (WTMV), a potyvirus, has been reported in Laichau, Vietnam, infecting Solanum torvum (wild tomato) in 2008 (3), and Kanchanaburi, Thailand, infecting Capsicum spp. in 2013 (KF250353). In mid-May 2013, Nicotiana tabacum showing yellowing, mosaic, and/or ringspot symptoms were found in natural tobacco fields of Nanxiong, Guangdong Province, China. Total RNA was extracted from symptomatic leaves and reverse transcribed with M4T (5'-GTTTTCCCAGTCACGAC (T)15-3') as the 3' anchoring primer (1). The cDNA was used as template in a PCR assay using primers M4: 5'-GTTTTCCCAGTCACGAC-3' and Sprimer: 5'-GGXAAYAAYAGYGGXCAZCC-3', which amplifies a region comprising part of the NIb protein gene, the entire coat protein (CP) gene and the 3' nontranslated region (UTR) of a potyvirus (1). A ~1,700-bp product was amplified from the cDNA derived from three of the five diseased plants. The product (KF639967) showed 87% and 84% nucleotide sequence identities with those of WTMV isolates KAN and Laichau, respectively. The CP deduced from the sequence of the product shared 87% and 86% nucleotide and 94% and 93% amino acid sequence identities with those of WTMV isolates KAN and Laichau, respectively. The 3'-UTR of the putative virus shared 93% and 92% nucleotide sequence identities to those of WTMV isolates KAN and Laichau, respectively. Thus, according to the molecular criteria for potyvirus species demarcation (2), the virus we identified should be an isolate of WTMV (isolate GD1). One of the diseased samples was homogenized in 0.1 mol/liter phosphate buffer (pH 7.0) and used to inoculate the potyvirus to healthy, two to four leaf-stage Capsicum annuum L., N. tabacum, and N. benthamiana. The inoculated, as well as mock-treated plants, which were inoculated only with phosphate buffer, were grown in soil under 12 h day/12 h night at 25°C. All inoculated N. tabacum and N. benthamiana plants developed yellowing and mosaic symptoms by 14 days post inoculation (dpi). For N. benthamiana, the symptom became very severe by 21 dpi and some diseased plants died prematurely. About 10% of inoculated C. annuum L. developed very mild veinal chlorosis 18 dpi. Cloning and sequencing experiments showed that all the symptomatic plants tested were WTMV positive, but Cucumber mosaic virus, Tobacco mosaic virus, and Tobacco etch virus negative. To our knowledge, this is the first report of WTMV in China. Also, it is the first report that WTMV infects Nicotiana spp. Although further experiments are needed to definitively attribute the disease observed in the field to WTMV, our results indicate that WTMV, which forms a monophyletic clade with a number of other potyviruses infecting Solanaceae species in phylogenetic analysis, is widely distributed, or is spreading in Southeast Asia. It may pose a threat to Solanaceae species cultivation in this region. References: (1) Chen et al. Arch. Virol. 146:757, 2001. (2) Adams et al. Arch. Virol. 150:459, 2005. (3) Ha et al. Arch. Virol. 153:25, 2008.

Molecular characterization of a novel monopartite begomovirus isolated from Pouzolzia zeylanica in China.

The complete genome sequence of a monopartite begomovirus isolate TY01 was obtained from diseased Pouzolzia zeylanica plants exhibiting golden mosaic symptoms in Baise, Guangxi Province, China. It consisted of 2723 nucleotides (nt) and encoded two ORFs (CP and AV2) in the virion-sense DNA and five ORFs (AC1-AC5) in the complementary-sense DNA. Compared with the DNA-A sequences of other begomoviruses, it has the highest (78.5 %) nucleotide sequence identity with ageratum yellow vein virus (AYVV) isolate AFSP6D from Thailand, which is less than the 89 % identity in the complete genome that has been defined as the threshold value for demarcation of species in the genus Begomovirus, family Geminiviridae. Phylogenetic analysis showed that TY01 was grouped in a separate clade from the other 28 begomovirus isolates. These results indicate that isolate TY01 is a member of a novel Begomovirus species, for which the name "Pouzolzia golden mosaic virus" (PGMV) is proposed.

First Report of Bacterial Wilt Caused by Ralstonia solanacearum on Ageratum conyzoides in China.

Ageratum conyzoides L. is believed to act as reservoir host for many plant diseases. In June 2011, a 30% incidence of bacterial wilt on A. conyzoides was observed in a field of Rhizoma kaempferiae in Yangchun city of Guangdong province. The initial symptoms were wilting of the apical leaves during the day, which recovered at night. After 4 to 6 days, the leaves became totally necrotic. The basal stems of the diseased plants were blackened and the vascular tissue turned brown. To investigate the disease etiology before understanding the disease link between A. conyzoides and R. kaempferiae, 10 plants with typical wilting symptoms were collected from the field. A total of 10 bacterial isolates were isolated from the vascular tissue of each diseased plant on tripheny tetrazolium chloride (TZC) medium. After incubation at 30°C for 2 days, the plates had large, irregular round, fluidal, white colonies with a pink center. Thirty healthy A. conyzoides plants at the four- to six-leaf growth stage were inoculated by injuring the roots and soaking them in a bacterial suspension (1 × 108 cfu/ml) for 20 min with the 10 bacterial isolates separately, and planted in 10-cm pots with sterile gardening soil in a glasshouse (28 to 35°C). Sterile water was used as a negative control. Five days after inoculation, a few leaves of the inoculated plants began to exhibit wilting. The inoculated plants eventually showed the same symptoms as those in the field. The same bacterium was reisolated from inoculated plants. The 30 negative control plants did not have wilt symptoms. With the same inoculation procedure, the bacterium also caused wilting on tomato (25 of 30), pepper (10 of 30), eggplant (2 of 30), ginger (11 of 15), and R. kaempferiae (8 of 15). Using the universal bacterial 16S rDNA primer set 27f/1541R (3), approximately 1,400 bp-fragments were amplified from the 10 isolates, respectively. The sequences for the 10 fragments (GenBank Accession Nos. JX294065 to JX294074) were identical and had 100% sequence identity with 16S rDNA of R. solanacearum GMI1000 (AL646052). The 10 isolates were able to oxidize disaccharides (lactose, maltose, and cellobiose) and hexose alcohols (mannitol, dulcitol, and sorbitol). According to Hayward's classification, all isolates were biovar 3 (2). Based on the pathogenicity tests, carbohydrate utilization, and near full-length 16S rDNA sequences, the bacterial isolates from the diseased A. conyzoides belonged to race 4 and biovar 3 of R. solanacearum. Furthermore, the specific 280-bp and 140-bp fragments were respectively amplified from all 10 isolates by using the multiplex PCR (1). In addition, specific 165-bp fragments were amplified from all the isolates using the specific primers AKIF/AKIR (3), which indicates the bacterium belongs to R. solanacearum Phylotype I. To our knowledge, this is the first report of a disease caused by R. solanacearum on A. conyzoides in China. References: (1) M. Fegan and P. Prior. Page 449 in: Bacterial Wilt Disease and the Ralstonia solanacearum Species Complex. C. Allen et al., eds. The American Phytopathological Society. St. Paul, MN, 2005. (2) A. C. Hayward. J. Appl. Bacteriol. 27:265, 1964. (3) M. Horita et al. J. Gen. Plant Pathol. 70:278, 2004.

First Report of Potato Blackleg Disease Caused by Pectobacterium atrosepticum in Guangdong China.

Potato (Solanum tuberosum L.) is an important crop in China. In 2013, diseased potatoes exhibiting blackleg and soft rot symptoms were found in the winter potato growing areas of Huizhou city, Guangdong Province, China, with an incidence of approximately 20%. Initially, the stem bases of infected plants blackened and this symptom spread upward. Later, foliage of the diseased plants became yellow and the stem rotted with vascular discoloration. Twenty diseased plants with typical black leg symptoms were collected from a 10-ha potato field with approximately 60,000 potato plants per hectare. A bacterium with small, irregular, round, fluidal, white colonies was isolated from the vascular tissue of all diseased plants on nutrient agar at 26°C for 2 days. Ten strains were randomly selected for pathogenicity assays. Potato plants (cv. Favorita) at the five- to six-leaf stage were inoculated by injecting their stems with 1 ml of each strain in a bacterial suspension (3 × 108 CFU/ml). The inoculated potato plants were incubated at 16 to 21°C and 65 to 85% humidity, and exhibited the same symptoms as the diseased potato plants in the field by 3 to 5 days post inoculation (dpi). The bacterium was reisolated from the diseased tissue (stem) of the inoculated potato plants and produced characteristic pits on crystal violet pectate medium (1). The bacterium utilized a-methyl glucoside, glucose, lactose, maltose, cellobiose, raffinose, melibiose, and citrate, but not d-arabitol, sorbitol, or malonate. The bacteria also gave a positive reaction for catalase and production of reducing substances from sucrose, but gave a negative reaction for oxidase, production of phosphatase, and indole. Using the universal bacterial 16S rDNA primer set, 27f/1541R (4), 1,400-bp fragments were amplified from the 10 strains. The sequences of the 10 fragments (GenBank Accessions KC695819 to KC695828) were identical and had 100% sequence identity with 16S rDNA of Pectobacterium atrosepticum CFBP 1526 (JN600332). Further, the 438-bp and 690-bp fragments were respectively amplified from all 10 strains with the P. atrosepticum-specific primers Y45/Y46 (3) and ECA1f/ECA2r (2). To our knowledge, this is the first report of potato blackleg disease caused by P. atrosepticum (formerly named as Erwinia carotovora subsp. atroseptica) in Guangdong Province, China. References: (1) D. Cupples et al. Phytopathology 64:468, 1974. (2) S. H. De Boer et al. Phytopathology 85:854, 1995. (3) D. Frenchon et al. Potato Research 41:63, 1995. (4) M. Horita et al. J. Gen. Plant Pathol. 70:278, 2004.