Relevant bibliographies by topics / Bactrocera jarvisi

Academic literature on the topic 'Bactrocera jarvisi'

Author: Grafiati
Published: 10 December 2022
Last updated: 28 January 2023

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Journal articles on the topic "Bactrocera jarvisi"

1

Park, Soo Jean, Stefano G. De Faveri, Jodie Cheesman, Benjamin L. Hanssen, Donald N. S. Cameron, Ian M. Jamie, and Phillip W. Taylor. "Zingerone in the Flower of Passiflora maliformis Attracts an Australian Fruit Fly, Bactrocera jarvisi (Tryon)." Molecules 25, no. 12 (June 22, 2020): 2877. http://dx.doi.org/10.3390/molecules25122877.

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Passiflora maliformis is an introduced plant in Australia but its flowers are known to attract the native Jarvis’s fruit fly, Bactrocera jarvisi (Tryon). The present study identifies and quantifies likely attractant(s) of male B. jarvisi in P. maliformis flowers. The chemical compositions of the inner and outer coronal filaments, anther, stigma, ovary, sepal, and petal of P. maliformis were separately extracted with ethanol and analyzed using gas chromatography-mass spectrometry (GC-MS). Polyisoprenoid lipid precursors, fatty acids and their derivatives, and phenylpropanoids were detected in P. maliformis flowers. Phenylpropanoids included raspberry ketone, cuelure, zingerone, and zingerol, although compositions varied markedly amongst the flower parts. P. maliformis flowers were open for less than one day, and the amounts of some of the compounds decreased throughout the day. The attraction of male B. jarvisi to P. maliformis flowers is most readily explained by the presence of zingerone in these flowers.
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Cruickshank, Leanne, Andrew J. Jessup, and David J. Cruickshank. "Interspecific crosses of Bactrocera tryoni (Froggatt) and Bactrocera jarvisi (Tryon) (Diptera: Tephritidae) in the laboratory." Australian Journal of Entomology 40, no. 3 (July 13, 2001): 278–80. http://dx.doi.org/10.1046/j.1440-6055.2001.00223.x.

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3

Morrow, Jennifer L., Markus Riegler, A. Gilchrist, Deborah CA Shearman, and Marianne Frommer. "Comprehensive transcriptome analysis of early male and female Bactrocera jarvisi embryos." BMC Genetics 15, Suppl 2 (2014): S7. http://dx.doi.org/10.1186/1471-2156-15-s2-s7.

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4

Sherwin, William B., Marianne Frommer, John A. Sved, Kathryn A. Raphael, John G. Oakeshott, Deborah C. A. Shearman, and A. Stuart Gilchrist. "Tracking invasion and invasiveness in Queensland fruit flies: From classical genetics to ‘omics’." Current Zoology 61, no. 3 (June 1, 2015): 477–87. http://dx.doi.org/10.1093/czoolo/61.3.477.

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Abstract Three Australian tephritid fruit flies (Bactrocera tryoni - Q-fly, Bactrocera neohumeralis - NEO, and Bactrocera jarvisi - JAR) are promising models for genetic studies of pest status and invasiveness. The long history of ecological and physiological studies of the three species has been augmented by the development of a range of genetic and genomic tools, including the capacity for forced multigeneration crosses between the three species followed by selection experiments, a draft genome for Q-fly, and tissue- and stage-specific transcriptomes. The Q-fly and NEO species pair is of particular interest. The distribution of NEO is contained entirely within the wider distribution of Q-fly and the two species are ecologically extremely similar, with no known differences in pheromones, temperature tolerance, or host-fruit utilisation. However there are three clear differences between them: humeral callus colour, complete pre-mating isolation based on mating time-of-day, and invasiveness. NEO is much less invasive, whereas in historical times Q-fly has invaded southeastern Australia and areas of Western Australia and the Northern Territory. In southeastern fruit-growing regions, microsatellites suggest that some of these outbreaks might derive from genetically differentiated populations overwintering in or near the invaded area. Q-fly and NEO show very limited genome differentiation, so comparative genomic analyses and QTL mapping should be able to identify the regions of the genome controlling mating time and invasiveness, to assess the genetic bases for the invasive strains of Q-fly, and to facilitate a variety of improvements to current sterile insect control strategies for that species.
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5

Wee, Suk-Ling, Thelma Peek, and Anthony R. Clarke. "The responsiveness of Bactrocera jarvisi (Diptera: Tephritidae) to two naturally occurring phenylbutaonids, zingerone and raspberry ketone." Journal of Insect Physiology 109 (August 2018): 41–46. http://dx.doi.org/10.1016/j.jinsphys.2018.06.004.

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6

Gamage, T. V., P. Sanguansri, P. Swiergon, M. Eelkema, P. Wyatt, P. Leach, D. L. J. Alexander, and K. Knoerzer. "Continuous combined microwave and hot air treatment of apples for fruit fly (Bactrocera tryoni and B. jarvisi) disinfestation." Innovative Food Science & Emerging Technologies 29 (May 2015): 261–70. http://dx.doi.org/10.1016/j.ifset.2015.02.009.

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7

Siderhurst, Matthew S., Soo J. Park, Ian M. Jamie, and Stefano G. De Faveri. "Electroantennogram responses of six Bactrocera and Zeugodacus species to raspberry ketone analogues." Environmental Chemistry 14, no. 6 (2017): 378. http://dx.doi.org/10.1071/en17091.

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Environmental contextQueensland fruit fly is a major pest of fruits and vegetables in eastern Australia, sometimes causing complete loss of unprotected crops. Odours that attract fruit flies can help control these pests and this study investigated how six fruit fly species smell these chemicals. The strength of fly responses to tested odours gives insight into the way flies smell and provides information for making better attractants, potentially reducing insecticide use. AbstractThe Queensland fruit fly (Bactrocera tryoni, Q-fly) is a major horticultural pest in eastern Australia. The deployment of male lures comprises an important component of several detection and control strategies for this pest. A novel fluorinated analogue of raspberry ketone (RK), raspberry ketone trifluoroacetate (RKTA), has been developed with the aim of further improving Q-fly control. RKTA elicited strong electroantennogram (EAG) responses from Q-flies whereas cuelure (CL) and melolure (ML) responses were not significantly greater than a negative control. Further experimentation showed that RKTA also elicited EAG response from five other fruit fly species, included flies known to be strongly attracted to CL (B. neohumeralis, B. kraussi and B. frauenfeldi), weakly attracted to CL (B. jarvisi), or non-responsive to CL (Zeugodacus cucumis), whereas seven other compounds, RK, CL, ML, raspberry ketone difluoroacetate, raspberry ketone monofluoroacetate, anisyl acetone and trimethylsilyl raspberry ketone, elicited only weak responses comparable with a negative control. However, fly EAG responses to RKTA are likely due at least in part to trifluoroethanoic acid, which is a hydrolysis product of RKTA and elicited strong EAG responses from all six species when tested alone. Furthermore, whereas ethanoic acid, methanoic acid and trifluoroethanoic acid all elicited strong EAG responses in Q-flies, the only corresponding RK ester to elicit an EAG response was RKTA, suggesting that RKTA hydrolyses quickly, whereas CL and ML do not. This is in contrast to the idea that CL readily hydrolyses on contact with atmospheric moisture, an assertion that has been made in the literature repeatedly.
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8

Peng, R. K., and K. Christian. "Effective control of Jarvis's fruit fly,Bactrocera jarvisi(Diptera: Tephritidae), by the weaver ant,Oecophylla smaragdina(Hymenoptera: Formicidae), in mango orchards in the Northern Territory of Australia." International Journal of Pest Management 52, no. 4 (October 2006): 275–82. http://dx.doi.org/10.1080/09670870600795989.

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9

"Bactrocera jarvisi (Jarvis' fruit fly)." CABI Compendium CABI Compendium (January 7, 2022). http://dx.doi.org/10.1079/cabicompendium.8715.

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This datasheet on Bactrocera jarvisi covers Identity, Overview, Distribution, Dispersal, Hosts/Species Affected, Diagnosis, Biology & Ecology, Natural Enemies, Impacts, Prevention/Control, Further Information.
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10

"Bactrocera jarvisi (Jarvis' fruit fly)." PlantwisePlus Knowledge Bank Species Pages (January 7, 2022). http://dx.doi.org/10.1079/pwkb.species.8715.

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