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Storey Storey (1938)
Investigations of the mechanism of the transmission of plant viruses by insect vectorsProc. roy. Soc. B., 125
M. Watson, F. Roberts (1939)
A Comparative Study of the Transmission of Hyoscyamus Virus 3, Potato Virus Y and Cucumber Virus 1 by the Vectors Myzus persicae (Sulz), M. circumflexus (Buckton), and Macrosiphum gei (Koch)Proceedings of The Royal Society B: Biological Sciences, 127
Sylvester Sylvester (1949)
Transmission of sugar‐beet yellow‐net virus by the green peach aphidPhytopathology, 39
H. Storey (1938)
Investigations of the Mechanism of the Transmission of Plant Viruses by Insect Vectors. II. The Part Played by Puncture in TransmissionProceedings of The Royal Society B: Biological Sciences, 125
B. Kassanis (1949)
The transmission of sugar-beet yellows virus by mechanical inoculation.The Annals of applied biology, 36 2
H. Storey, A. Bottomley (1928)
THE ROSETTE DISEASE OF PEANUTS (ARACHIS HYPOGAEA L.)Annals of Applied Biology, 15
H. Storey, A. Bottomley (1925)
Transmission of a Rosette Disease of the Ground NutNature, 116
Hille Hille, Lambers Lambers (1948)
On Palestine aphidsTrans. R. ent. Soc. Lond., 99
M. Watson (1936)
Factors Affecting the Amount of Infection Obtained by Aphis Transmission of the Virus Hy. IIIPhilosophical Transactions of the Royal Society B, 226
A. Posnette. (1947)
Use of Seeds in the Insect Transmission of Some Plant VirusesNature, 159
Storey Storey, Ryland Ryland (1950)
Virus diseases of groundnutsAnn. Rep. E. Afr. Agric. For. Res. Org., 1949
The rosette virus was transmitted to groundnut plants, if previously etiolated, bymechanical inoculation of juice with ‘Celite’ addition; but only a small proportion of the inoculations succeeded. Aphis craccivora (Koch), the known vector, transmitted the virus by feeding on germinating groundnut seeds; and from this fact we developed an experimental technique that is convenient and flexible. Different races of this species appeared to vary in inherent efficiency in transmission, and one failed ever to transmit. Within races that could transmit, all larval forms and alate and apterous adults might transmit; but alatae were sometimes significantly more efficient than apterae, and at other times the converse held. A field experiment showed that wingless forms, moving over the soil surface, might play a predominant part in secondary spread around a rosetted plant. Comparative tests with groups of I, 2, 3 and 4 infective aphids supported the hypothesis that infections by this vector are individual and independent. Single aphids, tested for 24 hr. on 10 successive days without access to an outside source of virus, might infect on any day up to the tenth. Similar results were obtained in a succession of I hr. tests on a single day. In the infected seed the virus rapidly became available to feeding aphids; previously non‐infective aphids acquired the virus by feeding on a seed during the third day from the first exposure of this seed to infective aphids.
Annals of Applied Biology – Wiley
Published: Sep 1, 1955
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