G. H. Duncan scite author profile

Closteroviruses possess exceptionally long filamentous virus particles that mediate protection and active transport of the genomic RNA within infected plants. These virions are composed of a long ''body'' and short ''tail'' whose principal components are the major and minor capsid proteins, respectively. Here we use biochemical, genetic, and ultrastructural analyses to dissect the molecular composition and architecture of particles of beet yellows virus, a closterovirus. We demonstrate that the virion tails encapsidate the 5-terminal, Ϸ650-nt-long, part of the viral RNA. In addition to the minor capsid protein, the viral Hsp70-homolog, 64-kDa protein, and 20-kDa protein are also incorporated into the virion tail. Atomic force microscopy of virions revealed that the tail possesses a striking, segmented morphology with the tip segment probably being built of 20-kDa protein.The unexpectedly complex structure of closterovirus virions has important mechanistic and functional implications that may also apply to other virus families.atomic force microscopy ͉ closterovirus ͉ RNA encapsidation ͉ virion structure ͉ virus transport

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Effect of humidity on infection of rose petals by dry-inoculated conidia of Botrytis cinerea

Williamson¹,

Duncan²,

Harrison³

et al. 1995

Mycological Research

102

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Analysis of the N Gene Hypersensitive Response Induced by a Fluorescently Tagged Tobacco Mosaic Virus

Wright¹,

Duncan²,

Pradel³

et al. 2000

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The hypersensitive response (HR) triggered on Nicotiana edwardsonii by tobacco mosaic virus was studied using a modified viral genome that directed expression of the green fluorescent protein. Inoculated plants were initially incubated at 32°C to inhibit the N gene-mediated HR. Transfer to 20°C initiated the HR, and fluorescent infection foci were monitored for early HR-associated events. Membrane damage, which preceded visible cell collapse by more than 3 h, was accompanied by a transient restriction of the xylem within infection sites. Following cell collapse and the rapid desiccation of tissue undergoing the HR, isolated, infected cells were detected at the margin of necrotic lesions. These virus-infected cells were able to reinitiate infection on transfer to 32°C, however, if maintained at 20°C they eventually died. The results indicate that the tobacco mosaic virus-induced HR is a two-phase process with an early stage culminating in rapid cell collapse and tissue desiccation followed by a more extended period during which the remaining infected cells are eliminated.

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Effects of environment on the composition of epicuticular wax from kale and swede

Shepherd¹,

Robertson²,

Griffiths³

et al. 1995

Phytochemistry

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G. H. Duncan

Complex molecular architecture of beet yellows virus particles

Effect of humidity on infection of rose petals by dry-inoculated conidia of Botrytis cinerea

Analysis of the N Gene Hypersensitive Response Induced by a Fluorescently Tagged Tobacco Mosaic Virus

Effects of environment on the composition of epicuticular wax from kale and swede

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