Host plant reactions, physical properties and serology of three isolates of Andean potato latent virus from Peru

Three isolates of Andean potato latent virus (APLV) (Caj, Hu, Ay) each infected twenty-seven species of plants in the families Amaranthaceae, Chenopodiaceae, Cucurbitaceae and Solanaceae but differed somewhat in the symptoms they induced. Nicotiana bigelovii and N. clevelandii proved the most useful diagnostic hosts. Symptoms were sometimes produced by all three isolates in cultivated and wild potatoes. In sap from systemically infected N. bigelovii and N. clevelandii leaves, all three isolates remained infective when diluted to 10^-6 and when stored at room temperature for at least 3 wk. The thermal inactivation points were 65–70 °C for Hu and Ay, but 75–80 °C for Caj. All three isolates differed serologically from Col, the original isolate of APLV, forming spurs in gel diffusion tests. No serological difference was found between Hu and Ay, but both formed spurs in reciprocal reactions with Caj. The data from light absorption, particle morphology and protein molecular weight for Caj, Hu and Ay are similar to those reported for other tymoviruses. APLV was found widespread in Andean countries.     

Tests for transmission of four potato viruses through potato true seed

The Andean potato calico strain of tobacco ringspot virus (TRSV-Ca) was detected in 2–9% of potato seedlings grown from true seed from plants of cv. Cara and clone G5998(6) infected with TRSV-Ca. Similarly, a potato isolate of the oca strain of arracacha virus B (AVB-O) was detected in 4–12% of progeny seedlings of cv. Cara and clone D42/8 infected with AVB-O. Potato virus T (PVT) passed through 33–59% of seed from PVT-infected cv. Cara, but only 0–2% infection was detected in seedlings from seed of PVT-infected clone D42/8. By contrast, no infection was detected in seedlings grown from seed from plants of G5998(6), D42/8 or cv. Cara infected with Andean potato latent virus strains Hu (APLV-Hu) or Caj (APLV-Caj), although both strains passed through seed of Nicotiana clevelandii. AVB-O, PVT and TRSV-Ca were detected in all tests of pollen from flowers of infected potato plants, but APLV-Hu and APLV-Caj were detected less frequently. AVB-O and PVT were transmitted through 2% and 8% respectively, of seed from healthy potato plants pollinated with pollen from infected plants. However, no transmission through seed was detected when pollen from TRSV-Ca infected plants was used. None of the four viruses were transmitted to healthy potato plants pollinated with pollen from infected plants. APLV-Hu caused exceptionally severe symptoms in the cv. Cara plants used for seed production, but the Bolivian strain of PVT induced only mild symptoms rather than the severe systemic necrosis previously reported for the type of strain of PVT in this cultivar. No symptoms developed in potato seedlings infected with TRSV-Ca, AVB-O or PVT through the seed.     

A new plant virus from the high jungle of the Eastern Andes; Solanum apical leaf curling virus (SALCV)

A previously undescribed plant virus, Solanum apical leaf curling virus (SALCV), was found in cultivated potato and indigenous wild solanaceous plants in an area of high jungle near San Ramon, Peru. Symptoms in potato consisting of red, purple or pink discoloration, curling, crinkling and dwarfing of apical leaves develop soon after infection. Symptoms from tuber-borne infection may also include dwarfing and stunting, dormancy may be prolonged and sprouts may be filiform producing small plants with very thin stems. The virus is transmissible by grafting, but was not transmitted through seed, by aphids or leafhoppers tested, nor by mechanical inoculation of sap. Infected Datura tatula and D. stramonium, the most useful indicator hosts, developed yellowing of the small veins of newly formed leaves followed by distortion, dwarfing, and cupping of subsequently formed leaves. Tomato, Solanum nigrum, Nicandra physalodes and Nicotiana benthamiana were also infected experimentally. N. physalodes, Solanum basendopogon, D. tatula and Physalis peruviana were naturally infected in the field. Antiserum produced in rabbits was suitable for ELISA which detected SALCV in a range of graft-inoculated and naturally infected plants. Most virus particles in purified preparations and those trapped on antiserum sensitised grids treated with infective sap were c. 52 times 17 nm and consisted of three quasi-isometric units in a straight chain. This particle morphology although novel, suggests possible affinities with geminiviruses.     

Properties of a resistance-breaking strain of potato virus X

During indexing of a potato germplasm collection from Bolivia, a strain of potato virus X (PVX), X_HB, which failed to cause local lesions in inoculated leaves of Gomphrena globosa was found in 7% of the clones. X_HB was transmitted by inoculation of sap to 56 species from 11 families out of 64 species from 12 families tested. It was best propagated in Nicotiana glutinosa or N. debneyi; Montia perfolia and Petunia hybrida were useful as local lesion hosts. Inoculated leaves of G. globosa plants kept at 10°, 14°, 18°, 22°, or 26 °C after inoculation were always infected symptomlessly. X_HB caused a mild mosaic, systemic chlorotic blotching or symptomless infection in 16 wild potato species and eight Andean potato cultivars, systemic necrotic symptoms in clone A6 and cultivar Mi Peru, and bright yellow leaf markings in cultivar Renacimiento. It caused necrotic local lesions in inoculated leaves of British potato cultivars with the PVX hypersensitivity gene Nb but then invaded the plants systemically without causing further necrosis; with gene Nx systemic invasion occurred but no necrotic symptoms developed. These reactions resemble those of PVX strain group four. X_HB differed from other known strains of PVX in readily infecting PVX-immune clones 44/1016/10, G. 4298.69 and USDA 41956, cultivars Saphir and Saco, and Solanum acaule PI 230554. X_HB had slightly flexuous filamentous particles with a normal length of 516 nm. It was transmitted readily by plant contact and it partially protected G. globosa leaves from infection with X_CP, a group two strain of PVX. Sap from infected N. glutinosa was infective after dilution to 10^--⁶ but not 10^--⁷ after 10 min at 75° but not 80 °C and after 1 yr at 20 °C. X_HB was readily purified from infected N. debneyi leaves by precipitation with polyethylene glycol followed by differential centrifugation. Microprecipitin tests showed that X_HB and X_CP are closely related serologically.     

Host range, purification and properties of potato virus T

Potato virus T (PVT) infected nine species of tuber-bearing Solanum, most of them symptomlessly, and as a rule was transmitted through the tubers to progeny plants: two genotypes of S. tuberosum ssp. andigena were not infected. The virus was also transmitted by inoculation with sap to 37 other species in eight plant families. Chenopodium amaranticolor is useful as an indicator host, C quinoa as a source of virus for purification, and Phaseolus vulgaris as a local-lesion assay host; the systemic symptoms in Datura stramonium, Nicotiana debneyi and in these three species are useful for diagnosis. Attempts to transmit PVT by aphids failed, but the virus was transmitted through seed to progeny seedlings of four solanaceous species, and from pollen to seed of S. demissum. PVT was purified by clarifying sap with n-butanol or bentonite, followed by precipitation with polyethylene glycol, differential centrifugation and sedimentation in a sucrose density gradient. Purified preparations had an E260/E280 ratio of 1.18 and contained a single infective component with a sedimentation coefficient of 99 S. This component consisted of flexuous filamentous particles of about 640 times 12 nm that showed a characteristic substructure when stained with uranyl acetate. The virus particles contained a single species of infective single-stranded RNA, of molecular weight 2–2 times 106 daltons, and a single species of polypeptide of molecular weight about 27 000 daltons. PVT is serologically related to apple stem grooving virus but not to four other common potato viruses with flexuous filamentous particles. Apple stem grooving virus and PVT cause similar symptoms in several hosts, but also differ somewhat in host range and symptomatology. Apple stem grooving virus did not infect potato, caused additional symptoms in C. quinoa also infected with PVT, and its particles did not show the structural features specific to PVT. The two viruses are considered to be distinct. The cryptogram of PVT is R/1:2–2/(5): E/E: S/C.     

Purification of potato virus X and preparation of its antiserum

Potato virus X (PVX) isolated from the potato leaf and tuber samples which were collected from various fields in Damavand and Ardabil. The initial isolations of the virus were made from potato by mechanical inoculation on Gomphrena globosa L. and Chenopodium spp. that produce local lesion, and then it causes mosaic on Nicotiana spp. and Datura stramonium L. An isolate of the virus inoculated to Nicotiana glutinosa L. and it was maintained throughout the work. Sap from infected N. glutinosa was ineffective after dilution to 10-6, 10 minutes at 70 degrees and 10 weeks at room temperature. The virus was readily purified from infected leaves and the best protocol was Moreira & Jones 1980 than the other 2 methods of Fribourg 1975 and Shepard & Shalla 1972. Antisera were prepared against native, degraded proteins and micro precipitin test showed that both antisera had a 1/512 titer. Precipitin lines with D - Protein antiserum was better of the native protein antiserum in agar double diffusion test than treated with SDS. The isolate of the virus was not transmitted by none of 2 species of Cuscuta but transmitted from infected leaves to healthy plants with sap inoculation without using Carburandum. This isolate showed positive reaction with gamaglubulin in kate received from CIP centre.     

Occurrence, Distribution and Relative Importance of Viruses Infecting Hot Pepper and Tomato in the Major Growing Areas of Ethiopia

Hot pepper and tomato fields in the main growing areas in the Rift Valley and the west of Ethiopia were surveyed for virus infections in 1994. A total of 286 samples from hot pepper and 222 samples from tomato plants and associated Datura stramonium L. and Nicandra physalodes Gaertn. weeds with symptoms suggestive of virus infections were collected and analysed using electron microscopy, serology and test plant reactions. Potato virus Y (PVY), Ethiopian pepper mottle virus (EPMV), pepper veinal mottle virus (PVMV) and tomato mosaic virus (ToMV) were detected in hot pepper samples while tomato samples were shown to be infected with tomato mild mottle virus (TMMV), PVY and ToMV. The most widespread and predominant viruses which also occurred frequently in mixed infections were PVY and EPMV in hot pepper and PVY and TMMV in tomato. TMMV was also found in many samples of D. stramonium and N. physalodes. ToMV was identified in only few samples from both crops in the Rift Valley by its characteristic particle morphology, serological properties and symptomatology. PVMV was found in hot pepper samples only from western Ethiopia, but no natural infection of tomato with this virus was revealed. This is the first report on the natural occurrence of TMMV in tomato, D. stramonium and N. physalodes, as well as of ToMV in hot pepper and tomato in Ethiopia.     

Comparison of transmission efficiency of various isolates of Potato virus Y among three aphid vectors

Potato virus Y (PVY) strains are transmitted by different aphid species in a non‐persistent, non‐circulative manner. Green peach aphid (GPA), Myzus persicae Sulzer, is the most efficient vector in laboratory studies, but potato aphid (PA), Macrosiphum euphorbiae Thomas (both Hemiptera: Aphididae, Macrosiphini), and bird cherry‐oat aphid (BCOA), Rhopalosiphum padi L. (Hemiptera: Aphididae, Aphidini), also contribute to PVY transmission. Studies were conducted with GPA, PA, and BCOA to assess PVY transmission efficiency for various isolates of the same strain. Treatments included three PVY strains (PVY^O, PVY^N:O, PVY^NTN) and two isolates of each strain (Oz and NY090031 for PVY^O; Alt and NY090004 for PVY^N:O; N4 and NY090029 for PVY^NTN), using each of three aphid species as well as a sham inoculation. Virus‐free tissue‐cultured plantlets of potato cv. Russet Burbank were used as virus source and recipient plants. Five weeks post inoculation, recipient plants were tested with quantitative DAS‐ELISA to assess infection percentage and virus titer. ELISA‐positive recipient plants were assayed with RT‐PCR to confirm presence of the expected strains. Transmission efficiency (percentage infection of plants) was highest for GPA, intermediate for BCOA, and lowest for PA. For all aphid species, transmission efficiency did not differ significantly between isolates within each strain. No correlations were found among source plant titer, infection percentage, and recipient plant titer. For both GPA and BCOA, isolates of PVY^NTN were transmitted with greatest efficiency followed by isolates of PVY^O and PVY^N:O, which might help explain the increasing prevalence of necrotic strains in potato‐growing regions. Bird cherry‐oat aphid transmitted PVY with higher efficiency than previously reported, suggesting that this species is more important to PVY epidemiology than has been considered.     

Use of Clq enzyme-linked immunosorbent assay to detect plant viruses and their serologically different strains

Clq was prepared from bovine serum using a simple method involving repeated dialysis at low ionic strength in the presence of chelating agents (yield c. 3 mg/100 ml serum). It was viable when stored at -18°C for up to 2 months, and at 4°C for at least 10 wk in a storage buffer containing 10% sucrose. When used in Clq ELISA this test was as sensitive as the direct double antibody sandwich form of ELISA (direct ELISA) in detecting purified potato virus Y (PVY), with a limit of detection in both methods of c. 15 ng/ml, and slightly more sensitive in detecting purified cocksfoot mild mosaic virus (CMMV), with limits of detection of c. 15 ng/ml and c. 15–60 ng/ml respectively. Using an antiserum to one strain of each virus, Clq ELISA readily detected strains of PVY, CMMV, Andean potato latent virus (APLV) and barley yellow dwarf virus (BYDV). This included detection of APLV-Hu by APLV-Caj antibodies and CMMV(G) by PMV(S) antibodies, neither of which system gives detection in direct ELISA. Clq ELISA was therefore less specific than direct ELISA in detecting serologically different virus strains. Virus detection by Clq ELISA was inhibited when sap of tobacco, Nicotiana clevelandii and Setaria italica was used at low dilution. Inhibition by N. clevelandii sap was alleviated by using increased concentrations of virus specific antibody to detect APLV and plum pox virus. Also, extracting APLV infective N. clevelandii or CMMV infective S. italica saps in a minimum of buffer, centrifuging at low speed and diluting the supernatant before testing, partially overcame the inhibition. The inhibitory substance(s) in sap may act by preventing the binding of Clq to virus-antibody aggregates. Sap of wheat, oat and barley did not appear to have an inhibitory effect and BYDV was readily detected in naturally infected field grown plants of these species.     

Identification and molecular analysis of transgenic potato chromosomes transferred to tomato through microprotoplast fusion

 Results are reported on the integration sites and copy number of alien marker genes neomycin phosphotransferase II (nptII) and β-glucuronidase (uidA), introduced into diploid potato Solanum tuberosum through transformation by Agrobacterium tumefaciens. Also, the transgenic potato chromosomes 3 and 5 harbouring the nptII and uidA genes, which were transferred to tomato (wild species Lycopersicon peruvianum) by microprotoplast fusion, as revealed by genomic in situ hybridization (GISH), were identified by RFLP analysis using chromosome-specific markers. The data revealed three integration sites in the donor potato genome, each containing the uidA gene, and two also harbouring the nptII gene. Analysis of monosomic-addition hybrid plants obtained after microprotoplast fusion showed that each of these three integration sites is located on a different potato chromosome. The microprotoplast hybrid plants contained only the chromosomes that carried the selectable gene nptII. The data on sexual transmission of the donor potato chromosome carrying the uidA and nptII genes were obtained by analysing the first backcross progeny (BC₁) derived from crossing a monosomic-addition hybrid plant to tomato (L. peruvianum). The glucuronidase (GUS) assay and PCR analysis using primers for the uidA gene indicated the presence of the potato chromosome in GUS-positive and its absence in GUS-negative BC₁ plants. RFLP analysis confirmed sexual transmission of the potato chromosome carrying the nptII and uidA genes to the BC₁ plants. A few BC₁ plants contained the nptII and uidA genes in the absence of the potato additional chromosome, indicating that the marker genes were integrated into the tomato genome. The potential applications of the transfer of alien chromosomes and genes by microprotoplast fusion technique are discussed. Recieved: 1 September 1996 / Accepted: 20 September 1996     

Quantitative studies on the uptake and retention of potato leafroll virus by aphids in laboratory and field conditions

Enzyme-linked immunosorbent assay (ELISA) was adapted for the efficient detection and assay of potato leafroll virus (PLRV) in aphids. Best results were obtained when aphids were extracted in 0.05 M phosphate buffer, pH 7.0, and the extracts incubated at 37 °C for 1 h before starting the assay. Using batches of 20 green peach aphids (Myzus persicae), about 0.01 ng PLRV/aphid could be detected. The virus could also be detected in single aphids allowed a 1-day acquisition access period on infected potato leaves. The PLRV content of aphids depended on the age of potato source-plants and the position of source leaves on them. It increased with increase in acquisition access period up to 7 days but differed considerably between individual aphids. A maximum of 7 ng PLRV/aphid was recorded but aphids more usually accumulated about 0.2 ng PLRV per day. When aphids were allowed acquisition access periods of 1–3 days, and then caged singly on Physalis floridana seedlings for 3 days, the PLRV content of each aphid, measured subsequently, was not strongly correlated with the infection of P. floridana. The concentration of PLRV in leaf extracts differed only slightly when potato plants were kept at 15, 20, 25 or 30 °C for 1 or 2 wk, but the virus content of aphids kept on leaves at the different temperatures decreased with increase of temperature. PLRV was transmitted readily to P. floridana at all temperatures, but by a slightly smaller proportion of aphids, and after a longer latent period, at 15 °C than at 30 °C. The PLRV content of M. persicae fed on infected potato leaves decreased with increasing time after transfer to turnip (immune to PLRV). The decrease occurred in two phases, the first rapid and the second very slow. In the first phase the decrease was faster, briefer and greater at 25 and 30 °C than at 15 and 20 °C. No evidence was obtained that PLRV multiplies in M. persicae. These results are compatible with a model in which much of the PLRV in aphids during the second phase is in the haemocoele, and transmission is mainly limited by the rate of passage of virus particles from haemolymph to saliva. The potato aphid, Macrosiphum euphorbiae, transmitted PLRV much less efficiently than M. persicae. Its inefficiency as a vector could not be ascribed to failure to acquire or retain PLRV, or to the degradation of virus particles in the aphid. Probably only few PLRV particles pass from the haemolymph to saliva in this species. The virus content of M. euphorbiae collected from PLRV-infected potato plants in the field increased from early June to early July, and then decreased. PLRV was detected both in spring migrants collected from the plants and in summer migrants caught in yellow water-traps. PLRV was also detected in M. persicae collected from infected plants in July and August, and in trapped summer migrants, but their PLRV content was less than that of M. euphorbiae, and in some instances was too small for unequivocal detection.     

Comparison of resistance to potyviruses within Solanaceae: infection of potatoes with tobacco etch potyvirus and peppers with potato A and Y potyviruses

The reaction of several cultivated potato varieties (Solarium tuberosum L.) to three strains of tobacco etch potyvirus (TEV-F, TEV-Mex21 and TEV-ATCC) and the reaction of several pepper lines (Capsicum annuum L. and C. chinense L.) to two strains of potato Y potyvirus (PVY^O and PVY^N) and one strain of potato A potyvirus (PVA-M) was tested. The potato varieties included in this study carried resistance genes against PVY, PVA and potato V potyvirus, but all were susceptible to TEV and developed mottle and mosaic symptoms. TEV was readily transmitted by mechanical inoculation from tobacco and potato to potato, whereas transmission from pepper to potato occurred infrequently. TEV was transmitted through potato tubers, and from pepper to potato plants by aphids. Lack of detectable systemic infection following graft-inoculation indicated extreme resistance to PVY^O and PVA in several pepper lines. No pepper line was systemically infected with PVY^N following mechanical inoculation (graft-inoculation was not carried out with PVY^N). The development of necrotic lesions following mechanical and graft-inoculation indicated hypersensitive response to PVY^O in several pepper lines which resembled the resistance responses to these potyvirus strains in potato. Results of this study together with previous work indicate that C. annuum cv. Avelar is resistant to four potyviruses [PVY, PVA, pepper mottle potyvirus (PepMoV) and some isolates of TEV]; C. annuum cv. Criollo de Morelos and C. chinense PI 152225 and PI 159236 are resistant to three potyviruses (PVY, PepMoV and PVA; and PVY, PepMoV and TEV, respectively); C. annuum 9093–1 and 92016–1 are resistant to PVY and PepMoV; and C. annuum cv. Jupiter and C. annuum cv. RNaky are resistant to PVY^N and PVA.     

Ecological studies on potato mop-top virus in Scotland

Plants with symptoms of potato mop-top virus (PMTV) occurred in many commercial seed stocks of Arran Pilot and Red Craig's Royal potato in Scotland, but their incidence rarely exceeded 5%. In nuclear stocks of seed potatoes, most varieties examined in 1967 and 1968 were infected at one or more locality, but infected plants did not occur in all clones or at all stages of propagation of any one variety. infection of nuclear stocks resulted both from propagation on virus-infested land and from unwitting selection of infected plants to start new clones. PMTV was detected in farm soils ranging from light sands to heavy loams, in five Scottish counties. Soil was infested throughout the ploughed layer but the severity of infestation varied greatly within any one field; some sites of former potato clamps were heavily infested. PMTV was detected in field soil 12 years after potatoes were grown. In glasshouse tests many British crop and wild plants were colonized by Spongospora subterranea. Within some families all species tested were moderate to good hosts. (Solanaceae, Chenopodiaceae and Cruciferae), in others, species differed greatly in susceptibility (Compositae and Umbelliferae), and in a few, species were poor hosts or were not infected (Caryophyllaceae and Gramineae). Of the British crop and weed species that were moderate to good zoosporangial hosts of S. subterranea, only Solanum nigrum, potato, spinach and sugar beet were hosts of vector-borne PMTV. Potato probably survives between potato crops mainly in the resting spores of S. subterranea. PMTV was probably first brought to Europe with potatoes from South or Central America.     

The role of flying aphid vectors in the transmission of cucumber mosaic virus and potato virus Y to peppers in Israel

More than 44 species of aphids were trapped by suction during the spring seasons of 1981, 1982 and 1983 over a pepper field at Bet Dagan, Israel. Nineteen species transmitted cucumber mosaic virus (CMV), while seven transmitted potato virus Y (PVY) at least once. Over 80% of the CMV and of the PVY infection among test plants (Capsicum annuum cv. Weindale) exposed to trapped aphids was caused by Aphis citricola and two or three other Aphis species, Myzus persicae and Macrosiphum euphorbiae. Landing rate was determined by comparing the proportion of each species found on green tiles or pepper plants with that found in suction traps. A. citricola was the most common but was found in a much lower proportion on plants than either in flight or on green tiles. Aphis spp. and M. persicae were more than 2–5 times more frequent (relative to other species) on green tiles than in flight. M. persicae and M. euphorbiae, which colonise peppers, were found on peppers at a proportion several times higher than either on green tiles or in the air. The relative importance of the different vector species was calculated by multiplying abundance by the proportion of transmitters and the landing rate. A. citricola and Aphis spp. were responsible for more than 50% of the total transmission of either CMV in 1981 and 1982 and of PVY in 1981. Peaks of CMV infection of bait plants coincided with peaks of transmitters of A. citricola and Aphis spp. caught in suction traps. The significance of these findings in primary infection of peppers with CMV and PVY is discussed.     

Infection of potato plants with potato leafroll virus changes attraction and feeding behaviour of Myzus persicae

Potato leafroll virus (PLRV; genus Polerovirus, family Luteoviridae) is a persistently transmitted circulative virus that depends on aphids for spreading. The primary vector of PLRV is the aphid Myzus persicae (Sulzer) (Homoptera: Aphididae). Solanum tuberosum L. potato cv. Kardal (Solanaceae) has a certain degree of resistance to M. persicae: young leaves seem to be resistant, whereas senescent leaves are susceptible. In this study, we investigated whether PLRV‐infection of potato plants affected aphid behaviour. We found that M. persicae's ability to differentiate headspace volatiles emitted from PLRV‐infected and non‐infected potato plants depends on the age of the leaf. In young apical leaves, no difference in aphid attraction was found between PLRV‐infected and non‐infected leaves. In fact, hardly any aphids were attracted. On the contrary, in mature leaves, headspace volatiles from virus infected leaves attracted the aphids. We also studied the effect of PLRV‐infection on probing and feeding behaviour (plant penetration) of M. persicae using the electrical penetration graph technique (DC system). Several differences were observed between plant penetration in PLRV‐infected and non‐infected plants, but only after infected plants showed visual symptoms of PLRV infection. The effects of PLRV‐infection in plants on the behaviour of M. persicae, the vector of the virus, and the implications of these effects on the transmission of the virus are thoroughly discussed.     

Purification and properties of sweet potato mild mottle, a white-fly borne virus from sweet potato(Ipomoea batatas) in East Africa

A virus obtained from sweet potatoes in Kenya, Uganda and Tanzania was transmitted by inoculation of sap and by whiteflies (Bemisia tabaci). It infected forty-five of 119 plant species in fourteen of thirty-six plant families. It was propagated in Nicotiana glutinosa and N. tabacum, in which diagnostic symptoms of vein clearing, leaf curling and distortion developed. Cheno-podium quinoa was a good local lesion host. Different seedling lines of sweet potato differed greatly in their susceptibility to infection and in symptoms produced; some developed leaf mottling and were stunted, some were symptomless, and some appeared immune. The virus was transmitted by dodder (Cuscuta campestris) but not by aphids, or through seed of Ipomoea nil or N. clevelandii. Sweet potato sap contained strong inhibitors of infection, and a low concentration of virus. Virus-free cuttings of sweet potato were obtained by thermotherapy (4–5 wk at 35 °C), or by meristem-tip culture. The virus remained infective in sap of N. tabacum after dilution to 10-³, or after 10 min at 55 °C (but not 60 °C), 3 but not 7 days at 18 °C, or 42 but not 49 days at 2 °C. Infectivity was abolished by sonication or u.v. irradiation, by 2% formaldehyde or 2% tri-sodium orthophosphate, and was greatly decreased by 20 % CHC1₃ or 20 % ether. Purified virus preparations were obtained from N. tabacum by clarifying phosphate buffer extracts with n-butanol, virus precipitation with polyethylene glycol, and differential centrifugation. The virus sedimented as one band in density gradients, and produced a single sedimenting boundary in analytical centrifugation (s°20, w = 1555)- It contained one polypeptide species of mol wt 37700, and preliminary digestion experiments suggested a single-stranded RNA. Antisera prepared against the virus reacted specifically in precipitin tube tests with titres of 1/16384, but no serological relationships could be found between the virus and fourteen viruses of the potato virus Y group. Electron micrographs showed straight, filamentous particles c. 950 nm long when mounted in MgCl_a, but 800–900 nra long in EDTA. The present cryptogram is: (R/i):*/*:E/E:S/Al. This virus is probably the same as Sheffield's virus B.     

Acquisition and transmission of potato mop-to furovirus by a culture of Spongospora subterranea f.sp. subterranea derived from a single cystosorus

Potato mop-top virus (PMTV) was detected by ELISA in primary zoospores from four out of six isolates of Spongospora subterranea f.sp. subterranea. One virus-free isolate (N) of S. subterranea was used to acquire PMTV from potato roots and to transmit the virus to healthy plants. A mono-fungal culture of S. subterranea (isolate N) was derived by infecting tomato plant roots with a single cystosorus. The culture was used successfully to acquire PMTV from the roots of infected Nicotiana debneyi plants that had been manually inoculated with virus isolates, and subsequently to transmit the virus to healthy bait plants. These experiments confirm that S. subterranea is a vector of PMTV. Two PMTV isolates that had been maintained by manual inoculation for 19 and 21 passages were also acquired and transmitted by the fungus culture.     

Determination of the races of potato virus X and its host rang in Karaj, Damavand and Ardabil, Iran

Potato virus x (PVX) is found commonly in potato-growing areas, worldwide. It is an economically important virus which causes losses in tuber yield of approximate 5 to 15 percent. In a 2 year survey, potato leaf and tuber samples were collected from various fields in Damavand and Karaj. The initial isolations from potato were made by mechanical inoculation first to Gomphrena globosa L. and later to Dartura stramonium L. It was not transmitted by 2 species of Cuscuta but transmitted mechamically. The isolates were inoculated to Nicotiana glutinosa L. in which they were maintained throughout the work. Sap from infected N. glutinosa was ineffective after dilution to 10-6, after 10 minutes at 70 degrees C and after 10 weeks at room temperature. The virus had filamentous and slightly flexuous particles with a normal length of about 490-500 nm and 12 nm width. According to the symptoms, TIP results and serological comparisons, the compared isolates showed no difference and they belong to XN group. In order to estimate disease incidence, 773 tubers from Damavand area were tested and compared with that in Ardabil area. Disease incidence in Damavand ranged from 1.1-20.9 percent and was lower than disease incidence in Ardabil. In 8 genera of collected weeds from fields of potato and tomato samples by using test plants and serological methods, they didn't show existence of the potato virus x.     

Phytoaccumulation of Heavy Metals in Natural Vegetation at the Municipal Wastewater Site in Abbottabad,Pakistan

Heavy metal accumulation in crops and soils from wastewater irrigation poses a significant threat to the human health. A study was carried out to investigate the removal potential of heavy metals (HM) by native plant species, namely Cannabis sativa L., Chenopodium album L., Datura stramonium L., Sonchus asper L., Amaranthus viridus L., Oenothera rosea (LHer), Xanthium stramonium L., Polygonum macalosa L., Nasturtium officinale L. and Conyza canadensis L. growing at the municipal wastewater site in Abbottabad city, Pakistan. The HM concentrations varied among plants depending on the species. Metal concentrations across species varied in the order iron (Fe) > zinc (Zn) > chromium (Cr) > nickel (Ni) > cadmium (Cd). Majority of the species accumulated more HM in roots than shoots. Among species, the concentrations (both in roots and shoots) were in the order C. sativa > C. album > X. stramonium > C. canadensis > A. viridus > N. officinale > P. macalosa > D. stramonium > S. asper > O. rosea. No species was identified as a hyperaccumulator. All species exhibited a translocation factor (TF) less than 1. Species like C. sativa, C. album and X. stramonium gave higher (> 1) biological concentration factor (BCF) and biological accumulation coefficient (BAC) especially for Fe, Cr and Cd than other species. Higher accumulation of heavy metals in these plant species signifies the general application of these species for phytostabilization and phytoextraction of HM from polluted soils.     

High frequency of tetraploidy in Agrobacterium-mediated transformants regenerated from tuber discs of diploid potato lines

Summary Variations in the ploidy level of 69 transgenic potato (Solanum tuberosum L.) plants regenerated from the tuber discs of 17 diploid lines were studied: 24 plants (35%) were diploid, the other 45 plants (65%) were tetraploid. Seventy-eight control regenerants obtained without Agrobacterium inoculation showed a relatively low tendency to tetraploidization (35%). The results obtained suggested that chromosome doubling occurred frequently in diploid potato lines during the tissue culture process for regeneration. Putative somaclonal changes in in vitro-formed tuber proteins were detected in three out of six transformants by electrophoretic analysis.