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Shivendra Singh 《Journal of Applied Entomology》2003,127(9-10):540-547
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S. M. Zia Hasan Firose Hossain Zannati Ferdous Zaoti Faruk Hasan Asadul Islam Khalekuzzaman 《Archives Of Phytopathology And Plant Protection》2018,51(5-6):252-266
A sensitive and specific assay was developed to detect and biological control of bacterial leaf spot of pumpkin, Xanthomonas cucurbitae was identified on the basis of the morphological, biochemical and molecular assay. The antibiotic sensitivity of the isolate showed that, Carbenicillin revealed highest antibacterial activity with 29 ± 0.00 mm zone of inhibition against isolated bacterial strain. Isolated bacterial strains from soil were also identified by biochemical and molecular characterisation. By analysing morphological and biochemical characteristics and 16S rDNA of three bacterial strains isolated from soil was matched 96% with Bacillus subtilis, 98% with Bacillus brevis and 97% with Pseudomonas fluorescens strain. They were subjected to the antagonistic activity against Xanthomonas cucurbitae by disc diffusion method. Among them, B. subtilis showed significant positive antagonistic activity with 17.0 ± 0.28 mm zone of inhibition against Xanthomonas cucurbitae. The presence of DNA sequence related to the hrpD gene successfully amplified in some isolates of Xanthomonas cucurbitae. 相似文献
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瓜实蝇Zelugodacus cucurbitae和南亚果实蝇Zelugodacus tau是两种主要以葫芦科植物为寄主的瓜类实蝇,主要分布于我国南部和中部地区。在实际研究中发现南亚果实蝇和瓜实蝇分类地位、寄主范围和生活史相近,但分布区域可能存在差异。因此,采用性诱剂诱集法在全国14个省(自治区)对这两种实蝇的分布进行调查,结果显示南亚果实蝇在我国整个南部地区均有分布,瓜实蝇在我国的分布范围较小,主要分布于北纬25°以南。结合气候数据发现两种实蝇的分布范围基本上和各地年平均气温一致,瓜实蝇主要在年平均温度20℃以上的区域分布,南亚果实蝇则在年平均温度为15℃以上的区域均有分布。这种地理分布的差异可能是两种实蝇对气候环境和寄主植物适应能力不同所致。 相似文献
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利用害虫对不同颜色的趋性进行害虫防治, 如利用黄板对实蝇的监测和防治已有很长的历史, 然而尚未见把颜色量化进行实蝇对颜色偏嗜性研究的报道。为探明对瓜实蝇Bactrocera cucurbitae最具吸引力的颜色及其虚拟波长, 本试验应用Dan Bruton的虚拟波长与RGB值的函数关系, 把RGB值转换为虚拟波长; 选择RGB值[(0, 213, 255), (0, 255, 146), (54, 255, 0), (129, 255, 0), (195, 255, 0), (255, 255, 0), (255, 190, 0)和 (255, 119, 0)]的颜色进行打印, 这些颜色对应的虚拟波长分别是480, 500, 520, 540, 560, 580, 560和600 nm; 在八面体内进行瓜实蝇对8种颜色的偏嗜性试验。结果表明: 波长在520~560 nm 之间对应的颜色对瓜实蝇的吸引率高于其他虚拟波长对应的颜色, 而540 nm (黄绿色, RGB值为 129, 255, 0)对应的颜色纸对瓜实蝇的吸引率最大。此外田间颜色偏嗜性试验也证实了黄绿色对瓜实蝇有最强的引诱作用。结果说明, 黄绿色(虚拟波长540 nm)是吸引瓜实蝇的关键颜色, 黄绿色粘虫板可作为监测与防治瓜实蝇的一种有效方法。 相似文献
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瓜实蝇是热带和亚热带地区最重要的经济害虫之一。本研究拟对卵巢发育进行分级,以判断田间捕获的瓜实蝇是否达到性成熟。室内饲养瓜实蝇成虫,对开始羽化至羽化后80 d的不同日龄成虫卵巢进行解剖,并记录了卵巢长度、卵巢宽度、卵巢指数(卵巢长度×卵巢宽度)和所含卵粒数。将瓜实蝇卵巢发育过程分为4期6个级别,分别为卵黄发生前期(Ⅰ级和Ⅱ级)、卵黄发生期(Ⅲ级和Ⅳ级)、抱卵期(Ⅴ级)、经产期(Ⅵ级)。随着卵巢的发育,Ⅰ~Ⅴ级卵巢长度和宽度迅速增长,卵巢发育成熟开始产卵以后,Ⅵ级卵巢长度和宽度逐渐减小。Ⅰ级和Ⅱ级卵巢长度与宽度大致相等,以后各期卵巢长度均大于宽度。Ⅲ级和Ⅳ级可见清晰的卵室,卵母细胞迅速增长,卵黄逐渐沉积。Ⅴ级可见清晰的卵粒,整个卵巢呈圆柱状。Ⅵ级开始排出卵子,所含卵粒数显著少于Ⅴ级;虽然此级卵巢长度大于Ⅳ级,但卵巢宽度、卵巢指数与Ⅳ级基本一致;Ⅵ级卵巢可见黄体,可结合黄体判定卵巢所处发育级别。本研究对评估粘虫板捕获的瓜实蝇雌虫生理日龄结构有潜在应用价值。 相似文献
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E. B. Jang 《Journal of Applied Entomology》2011,135(6):456-466
Trapping trials were conducted in two locations on the island of Hawaii with plastic‐matrix formulations of methyl eugenol (ME) (1‐2‐dimethoxy‐4‐allylbenzene) and cuelure (CL) [4‐(p‐acetoxyphenyl)‐2‐butanone] in traps with or without a toxicant (2, 2‐dichlorovinyl dimethyl phosphate, DDVP) against wild fly populations of oriental fruit fly, Bactrocera dorsalis (Hendel) and melon fly, Bactrocera cucurbitae (Coquillett) respectively. Both 5 g disks and 10 g cones of ME and 2 g plugs of CL caught flies for >9 months which varied relative to the population fluctuations. In all of these trials a one‐way entrance design trap caught more flies than the toxicant‐baited trap. The similar‐sized entrance holes (0.70 cm) of the latter may have slowed the dispersal of the toxicant vapour, thus causing flies to be repelled or killed outside the entrance to the trap when DDVP vapour was evolving at a maximum rate. The effect decreased as the toxicant aged. One‐way entrance traps are appropriate where toxicant traps are not allowed (e.g. organic farms), present a health hazard (e.g. yards with children), or would need to be replaced more frequently than lures. The results of these studies are discussed in relation to areawide fruit fly suppression programs where large populations of these flies are persistent, as well as to detection programs in areas where fruit flies have not established. 相似文献
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【背景】瓜实蝇是重要的瓜果害虫,研究其在田间的时空分布可为进一步探讨成虫在栖息地的迁移规律奠定基础。【方法】试验于2013年9月17日~11月8日在广州市白云区广东省农业科学院试验基地进行。试验地面积约6900 m2,其中,苦瓜地面积为34 m×19 m。以黄绿色粘板进行诱捕取样,点算粘板上瓜实蝇雌、雄成虫个体数,以地学统计学方法研究瓜实蝇成虫的时空分布动态。【结果】瓜实蝇成虫密度有2个峰;其半变异函数多为高斯模型,在调查范围内空间格局为聚集分布,变程范围为9.648~65.580 m,空间异质性是由空间自相关引起。【结论与意义】运用Kriging插值法,由软件Surfer10.0绘制的密度等值线图清楚地反映出瓜实蝇成虫主要分布于苦瓜地内,呈现出瓜实蝇成虫被苦瓜吸引,并迅速繁殖及之后向瓜地外扩散的变动特征。 相似文献
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The melon fruit fly, Zeugodacus cucurbitae (Coquillett), is an important polyphagous pest that damages to various agricultural crops, whose distribution has become global as a result of human activity. In this study, we investigated the fecundity, pre-oviposition and oviposition periods, and the longevity of adult Z. cucurbitae at various constant temperatures ranging from 15 to 35.2°C. One newly emerged one virgin female and two males of Z. cucurbitae were used, and the longevity of both sexes and the fecundity of the females were examined daily. The longevity of female Z. cucurbitae ranged from 183.8 days at 15.0°C to 30.8 days at 35.2°C, and the maximum fecundity per female was 1204 eggs at 24.5°C. The lower development threshold (LDT) and thermal constant (K) of females were estimated as 14.8°C and 781.13 degree-days, respectively. Female reproduction was modeled using a two-phase oviposition model. Oviposition was estimated using females in the oviposition phase, which had a complete pre-oviposition phase. The oviposition model consisted of two reproductive components (total fecundity and age-specific cumulative oviposition rate during oviposition) and a survival component (age-specific survival rate). The daily egg production of Z. cucurbitae was estimated in relation to adult age and temperature. 相似文献
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T. Miyatake 《Population Ecology》2002,44(3):0201-0207
The mechanism by which a clock gene pleiotropically controlling life history and behavioral traits causes reproductive isolation is explained using a model species, the melon fly, Bactrocera cucurbitae (Coquillett) (Diptera: Tephritidae). Melon flies mate once a day, at dusk. The population selected for life history traits exhibits correlated responses in the time of mating during the day. For example, the fly populations selected for faster (slower) development have an earlier (later) time of mating. A circadian rhythm controls the time of mating. The circadian periods in constant darkness were about 22 h in lines selected for a short developmental period and about 31 h in lines selected for a long developmental period. The data on crosses between the selected lines indicated that the developmental period is controlled by a polygene, whereas the circadian period may be controlled by a single clock gene. These results suggest a clock gene pleiotropically controls developmental and circadian periods in the melon fly. Reproductive isolation may often evolve as an indirect (pleiotropic) consequence of adaptation to different environments or habitats. For example, niches that are temporally or seasonally offset can select organisms with different developmental characteristics. These developmental differences can inadvertently cause reproductive isolation by a variety of means including shifts in mating activity patterns. The difference in time of mating between populations selected for developmental period translated into significant prezygotic isolation, as measured by mate choice tests. If the mating time between populations differed more than 1 h, the isolation index was significantly higher than zero. These findings indicate that premating isolation can be established by a pleiotropic effect of a clock gene. There are many examples in which the difference in timing of reproduction prevents gene flow between populations, such as the egg spawning time in marine organisms, the flowering time in angiosperms, and the time of mating in insects. In such organisms, if genetic correlations between circadian rhythm and reproductive traits exist, multifarious divergent selection for life history traits would often accelerate the evolution of reproductive isolation through clock genes. Natural populations may diverge in reproduction time through drift, direct natural selection for time of reproduction, or as a by-product effect of genetic correlations. In any case, clock genes are keys in reproductive isolation. Received: January 31, 2002 / Accepted: July 29, 2002 Acknowledgments I am grateful to Tetsuo Arai, Akira Matsumoto, Takashi Matsuyama, Toru Shimizu, Aya Takahashi, Teiichi Tanimura, Tetsuya Toyosato, and Yasuhiko Watari for useful discussion, and to the responsible editor and two anonymous reviewers for helpful suggestions. I also thank Yoshihiko Chiba, Norio Ishida, Emi Koyama, Kazuhiko Sakai, and Takaomi Sakai for useful information. My work on speciation has been supported by a Grant-in-Aid for Scientific Research (KAKENHI 14340244) from the Ministry of Education, Culture, Sports, Science and Technology of Japan. 相似文献