Life cycle of a non-diapausing population of the two-spotted spider mite,Tetranychus urticae Koch in a pear orchard

The life cycle of a non-diapausing T. urticae population was studied in a pear orchard in the southern part of Okayama Prefecture, western Honshû, Japan. The mites overwintered only on biennial weeds in the orchard without entering diapause, started to increase in number in early spring on them and then moved to other weeds as they emerged. The occurrence of the mites on pear began in early May several weeks after the unfolding of pear leaves and the population on pear was initiated by the migrants from the weeds around the base of pear trees. The population on pear showed two distinct peak occurrences, one in June and the other in mid-autumn. After pear leaves dropped in late autumn, the mites returned to biennial weeds for overwintering.     

Seasonal susceptibility of 'Bartlett' pears to codling moth (Lepidoptera: Tortricidae) infestation and notes on diapause induction

Seasonal susceptibility of 'Bartlett' pear, Pyrus communis L., to codling moth, Cydia pomonella (L.), infestation, successful completion of larval development after infestation, and the induction of C. pomonella diapause was studied from 1992 through 1995. The seasonal variation in C. pomonella infestation and larval survival were effected by changes in fruit maturity. In late May through mid-June, pears were hard and were not as successfully infested by C. pomonella and produced less larvae compared with fruit later in the season. In late June to mid-July, pears became more suitable for infestation and a greater percentage of the larvae completed their development. In late July through mid-August, pears were susceptible to infestation, but the larvae were less likely to successfully complete development than in the late June to mid-July period due to pear tissue breakdown. From mid-August through September, pears are unsuitable for infestation, and few larvae were produced. When fruit were infested with neonate larvae in late May and mature larvae emerged from the fruit in July, a low percentage of the larvae entered diapause. However, when fruit were infested with neonate larvae in early July and mature larvae emerged from the fruit in early August, the majority of the larvae entered diapause. When fruit were infested with neonate larvae in late July through September and mature larvae emerged from the fruit after mid-August, nearly all C. pomonella larvae had entered diapause.     

Overwintering phenology of a predacious mite, Typhlodromus vulgaris (Acari: Phytoseiidae), on Japanese pear trees, observed with Phyto traps

Phyto traps were attached to twigs, main branches and trunks of Japanese pear trees in central Japan in autumn of 2004, to evaluate the effectiveness of the trap as a tool to study overwintering phenology of arboreal phytoseiid mites. A subset of the traps was inspected and replaced at two-weeks intervals (“short-term Phyto trap”), in order to evaluate movement of phytoseiid mites on the trees in a short-term. The remaining traps were left undisturbed and collected monthly from January to May 2005 (“long-term Phyto trap”), to know what species overwinter in the traps and when they leave them. Most phytoseiid mites were collected in the traps on twigs. The most abundant phytoseiid species was Typhlodromus vulgaris Ehara. In the short-term traps on twigs, adult females and males of T. vulgaris were collected until mid-November 2004, when the pear trees became completely defoliated, but few mites were collected from December to April. On the other hand, adult females of T. vulgaris were abundant in the long-term traps on twigs sampled from January to April, but other stages of mites were never collected. These results indicate that T. vulgaris had moved to the long-term traps by late November, and that only adult females had overwintered in the traps. These females began to move and reproduce in early May. By that time immature developmental stages of T. vulgaris were also recorded in the short- and long-term Phyto traps. Our results confirmed that the Phyto trap was a useful tool for estimating overwintering phenology of phytoseiid mites on trees.     

Performance of a pyrethroid-resistant strain of the predator mite Typhlodromus pyri (Acari: Phytoseiidae) under different insecticide regimes

An organophosphate pyrethroid-resistant strain of Typhlodromus pyri Scheuten imported from New Zealand was reared on potted apple trees in an outdoor insectary. From 1988 to 1995, the population was selected one to three times per year with a dilute solution (1.7 ppm) of the pyrethroid cypermethrin. Petri dish bioassays with cypermethrin in 1995 indicated that the insectary-reared T. pyri had an LC50 of 81 ppm versus 0.006 ppm for native T. pyri taken from a research orchard. The bioassays suggested that recommended orchard rates of cypermethrin would cause heavy mortality in native populations of T. pyri but only moderate losses in the imported New Zealand strain. Bioassays in 1996 with the organophosphate insecticide dimethoate indicated both New Zealand and native T. pyri were susceptible and that recommended orchard rates of dimethoate likely would cause high mortality of T. pyri in apple orchards. These findings from bioassays were supported by data from orchard trials. In June and July 1993, insectary-reared New Zealand T. pyri were placed on five apple trees in each of eight 38-tree plots in the research orchard. In late August 1994, New Zealand T. pyri from orchard trees that had been sprayed twice by airblast sprayer with the full recommended rate of 50 g (AI)/ha (83 ppm) cypermethrin were placed on the other 33 trees in each of six plots. In the summers of 1994-1996, plots were treated with one of the following insecticide regimes: (1) conventional integrated pest management (IPM) (registered neurotoxic insecticides considered harmless or slightly toxic to T. pyri); (2) advanced IPM (use of newer, more selective insecticides); (3) pyrethroid (at least one full-rate application of cypermethrin); (4) dimethoate; and (5) dimethoate plus pyrethroid. Densities of European red mite, Panonychus ulmi (Koch), were highest in all plots treated with dimethoate and in pyrethroid plots not yet inoculated with New Zealand T. pyri. Densities of apple rust mite, Aculus schlechtendali (Nalepa), and of the stigmaeid predator Zetzellia mali (Ewing) were highest in plots treated with dimethoate and were nearly absent in the IPM plots. Densities of T. pyri were high enough for effective biocontrol in the IPM plots and in the pyrethroid plots 1-2 yr after release of the New Zealand strain, provided pyrethroid was applied just before the resistant strain was released in the orchard. A recurring theme of this study was the generally negative association between densities of phytophagous mites and those of T. pyri, suggesting the ability of this predator to suppress their prey. In contrast, the positive association between phytophagous mites and Z. mali suggests the inability of this predator to regulate their prey at least under the conditions of this study.     

Cross-correlation analysis of fluctuations in local populations of pear psyllids and anthocorid bugs

1. To test whether predatory anthocorids migrate into pear orchards when populations of pear psyllids are building up, a cross-correlation analysis was carried out on their population numbers. Predator and prey population sizes were assessed weekly in 3 consecutive years (1991–93) by sampling pear leaves for eggs and nymphs of psyllids and pear tree branches for adult psyllids, as well as adults and nymphs of predatory anthocorids. The time-series consisted of numbers (per leaf or branch) averaged over preselected pear trees in an orchard and, in addition, over other trees selected along the hedgerows flanking the orchard. 2. The fluctuations in populations of adult and juvenile anthocorids showed strong cross-correlations with those of the eggs and nymphs of pear psyllids, but less correlation with adults of pear psyllids, as expected based on their increased ability to escape from predation. The psyllids always appeared first on the pear trees, resulting in positive phase shifts. The first peak of adult anthocorids on pear trees was always later than the first peak in the hedgerows, and the first peak of nymphal anthocorids on pear trees was always later than the first peak of adults on these pear trees. In each of the 3 years, anthocorids were rarely observed in the pear orchard during the first part of the growing season (April–June), but during the second half of the growing season (July–August) there was a strong numerical response of the anthocorid populations to increasing population densities of pear psyllids. 3. These results provide support for the hypothesis that the numerical response of the predators to prey density is caused initially by migration of anthocorids into the pear orchard and then by a reproductive response. The migrants originate from the hedgerows and other trees elsewhere, where they feed on aphids during the first part of the growing season.     

北京梨园绿盲蝽及其天敌的种群动态

【目的】调查研究梨园绿盲蝽Apolygus lucorum (Meyer-Dür)及其天敌的种群动态, 为梨园绿盲蝽的预测预报和科学防治提供理论依据。【方法】2012-2013年利用色板诱集法和目测法, 对北京市农林科学院林业果树研究所梨园的绿盲蝽及其天敌的种群动态进行了系统调查和分析。【结果】绿板调查结果显示, 绿盲蝽在梨园的发生有2个高峰期, 第1个峰值远高于第2个峰值, 主要发生高峰期为5月下旬至6月中旬。目测调查结果显示, 2012年, 绿盲蝽有两个发生高峰期, 5月中旬达到第1个峰值, 5月下旬达到第2个峰值; 2013年, 绿盲蝽仅有5月下旬一个发生高峰期。2012和2013年天敌主要发生高峰期均为6月上旬至下旬。梨园调查到的天敌主要为捕食类天敌, 包括蜘蛛和天敌昆虫, 其中天敌昆虫有7种隶属3目3科。天敌的优势种类为蜘蛛、 龟纹瓢虫、 异色瓢虫、 中华草蛉。【结论】天敌的发生与绿盲蝽有明显的时间和数量跟随关系。     

Life-cycle variation inPanonychus akitanus Ehara (Acarina:Tetranychidae)

The life history ofPanonychus akitanus Ehara was studied in two Hokkaido populations on dwarf bamboos. The Sapporo population overwintered both as egg and female adult onSasa senanensis, and the Tomakomai population overwintered as egg onSasa apoiensis. Mites of the Sapporo population produced four or five generations from late April to late November or early December. The eggs that had overwintered began to hatch in mid-May, and this hatching period overlapped with that of eggs laid in late April by females that had overwintered. Therefore, mites with different overwintering stages would interbreed. Most eggs that had overwintered in the Tomakomai population hatched in mid-May, and about four generations were produced before early December, when only eggs were found. The density of mites per leaf of the Sapporo population reached a maximum in early May on old leaves and in late June on new leaves, and thereafter gradually decreased. The Tomakomai population initially decreased in density after hatching in the spring, but rapidly dispersed to new leaves, reached a peak in early September, and then gradually decreased. The maximal density was about 10 times higher and the distribution was less clumped (lower values of the aggregation index,m/m) than that of the Sapporo population. This was probably because the Sapporo mites could utilize only the underside of sporadically distributed leaves which were curled by spiders, whereas the Tomakomai mites inhabited any part of the leaf undersurface of the hairy host plant. Predators observed were phytoseiid mites and larvae of gall midges. The predatory effect on the Sapporo population was not clear. In the Tomakomai population, the number of gall midges correlated with the number of spider mites better than that of phytoseiid mites.     

Plantago asiatica groundcover supports Amblyseius tsugawai (Acari: Phytoseiidae) populations in apple orchards

Amblyseius tsugawai Ehara (Acari: Phytoseiidae) is a major predator of spider mites in orchards in Japan. To support populations in apple orchards in Akita Prefecture, northern Japan, we investigated whether it can use Plantago asiatica L. as a food resource. In laboratory tests, survival did not differ significantly between female adults given water only and those given a piece of P. asiatica leaf and water. However, A. tsugawai reproduces by feeding on P. asiatica pollen, and significantly more mites were reared on P. asiatica pollen than on tea pollen, which is commonly used for rearing phytoseiid mites. In orchards in 2013, female adults were observed on leaves of P. asiatica from late May; numbers peaked in mid-June and gradually decreased until late July. Most adults were found along veins on the hidden sides of the leaves. Female adults were also collected in Phyto traps attached to plants between late May and early August. Pollen production of P. asiatica peaked from mid-June to early July, when numbers of adults peaked on the plants. These results suggest that conservation of P. asiatica in apple orchards would sustain A. tsugawai populations.     

Seasonal phenology of Bactrocera minax (Diptera: Tephritidae) in western Bhutan

The Chinese citrus fruit fly, Bactrocera (Tetradacus) minax (Enderlein), is one of the major citrus pests in Bhutan and can cause >50% mandarin (Citrus reticulata Blanco) fruit drop. As part of the development of a management strategy for the fly in mandarin orchards, population monitoring and experimental manipulations were carried out to determine: (i) adult emergence period; (ii) adult phenology patterns; (iii) period of crop susceptibility; and (iv) period from fruit drop to pupation. In western Bhutan, adult flies emerge from the overwintering pupal stage in late April/early May. Most flies are mature by the end of May and it is inferred that mating occurs at this time: from the beginning of June males rapidly disappear from the population and by mid- to late June are rare or absent from traps. Mature females are present in the mandarin crop at the beginning of June, but very little oviposition occurs until mid-June, while most damage has occurred by mid-July. Initiation of oviposition into mandarins is almost certainly linked to crop phenology. Adult flies disappear from the orchard system during August. After fruit drop, larvae were recorded leaving the fruit to pupate within 13 days. The use of early to mid-season protein bait sprays and/or targeted use of systemic insecticides during the one month oviposition period, plus the removal of fallen fruit once every 10 days, are recommended as control strategies.     

SEASONAL PERFORMANCE AFFECTING POPULATION DYNAMICS OF CITRUS RED MITE, FANONYCHUS CITRI (MCGREGOR) (ACARI: TETRANYCHIDAE), ON PEAR

Abstract The population of the citrus red mite, Panonychus citri (McGregor), does not increase on pear from spring to mid-summer but thereafter increases abruptly. To elucidate this phenomenon, we compared the performance of the mites on pear leaves with that on citrus leaves, at different time throughout the pear-growing season. No significant difference was detected between the oviposition rate on pear and that on citrus throughout the season. However, the survival rate of ovipositing females that had fed on pear and the hatch rate of eggs laid by those females were significantly lower than those for females that had fed on citrus, until August. However, no significant difference was observed thereafter. The results showed that the decline of the population of citrus red mite before autumn is due to the high mortality of adult females that had fed on pear leaves and the low hatch rate of the eggs produced by those females.     

柑桔全爪螨（蜱螨亚纲：叶螨科）在梨树上季节性发生影响种群动态

柑桔全爪螨为害梨树时春夏种群密度极低但随后却突然爆发,形成一年之中只有秋季一个高峰期之发生规律,这与其在柑桔上一年之中两个发生高峰期的发生特点形成鲜明对照。为阐明柑桔全爪螨在梨树直的这种季节消长规律之成因,本采用对比研究方法分析研究了该螨在梨叶和柑桔叶一年之中的产卵率,成活率以及卵的孵化率等生态学习性。结果表明产卵率在梨叶与柑桔叶之间全年均无显差异;然而其在梨叶上的成活率以及卵的孵化率在八月之产明显低于其在柑桔叶上之值,且差异显或极显,但八月之后以上各项指标在梨叶和柑桔叶上均无显差异。     

Seasonal occurrence of specialist and generalist insect predators of spider mites and their response to volatiles from spider-mite-infested plants in Japanese pear orchards

In two adjacent Japanese pear orchards (orchards 1 and 2), we studied the seasonal occurrence of the Kanzawa spider mite, Tetranychus kanzawai, and its predators. Also the response of these predators to the volatiles from kidney bean plants infested with T. kanzawai was investigated using trap boxes in orchard 1. The mite density in orchard 1 was unimodal, with one peak at the end of August. In this orchard, population development of the specialist insect predators, Scolothrips takahashii, Oligota kashmirica benefica and Stethorus japonicus, was almost synchronized with that of the spider mites. These predators disappeared when the density of their prey became very low in mid-September. Both S. takahashii and O. kashmirica benefica abruptly increased in number in orchard 2 when the spider mite population in orchard 1 decreased. These results suggested that some of the predators migrated from orchard 1 to orchard 2. In this period, predator-traps with T. kanzawai-infested bean plants attracted significantly more S. takahashii than traps with uninfested plants. Very few individuals of S. japonicus and O. kashimirica benefica were found in the traps, despite their abundance in orchard 1. The generalist insect predator, Orius sp., was attracted to the traps throughout the experimental period irrespective of the density of spider mites, although this predator was never observed inside the orchards.     

Phylloplane fungi: an extrinsic factor of tetranychid population growth?

In a study on leaf-inhabiting tetranychid mites (Tetranychus urticae Koch–TSSM and Panonychus ulmi (Koch)–ERM) we investigated the effects of an extrinsic factor on the mites environment, namely phylloplane fungi. In a research orchard four trees were selected and treated with an aerosol application of a phylloplane fungus (Alternaria alternata) in a tap-water emulsion. Applications were made immediately after each sampling, with the exception of the last sample date. Two tap water controls for each treated tree were also sampled: a nearest neighbour (< 3 m from the treated trees) and a distant neighbour (> 30 m from the treated trees with other apple trees in between). Due to possible migration from the treated trees to near neighbours, the distant control best reflected normal orchard conditions. Eight samples were taken throughout the 1994 growing season; however, appreciable mite populations were only observed on the last four sample dates. On the treated trees, the ERM maintained a steady low population (less than ten per leaf) whereas the TSSM showed a population outbreak (up to 44 mites per leaf). Conversely, on the distant trees, the TSSM maintained a low population (less than ten per leaf) while the ERM showed an outbreak (up to 33 per leaf). Observing on a leaf by leaf basis, when tetranychids were present on a leaf, either one species dominated or the other, suggesting mutual competitive exclusion, the outcome of which was reversed to favour TSSM on trees that received an application of fungus. We concluded that the application of additional or supplemental amounts of A. alternata to apple leaves enhanced the population growth of TSSM compared to that of ERM. Possible mechanisms are discussed. This revised version was published online in November 2006 with corrections to the Cover Date.     

湖北老河口梨小食心虫成虫发生规律及综合防治效果

【目的】为了寻找湖北省老河口梨小食心虫Grapholita molesta(Busck)的最佳防治时期,推广使用无公害防控技术,减少化学药剂的使用。【方法】分别调查了梨小食心虫在梨园及桃园的发生规律,释放赤眼蜂的生物防治效果,糖醋酒液、三角形诱捕器、黄板的物理防治效果,以及性信息素迷向防治效果。【结果】结果表明,桃园梨小食心虫最佳防治时期在4月中下旬,梨园梨小食心虫最佳防治时期在5月下旬、6月上旬、8月中旬前。防治效果上,释放赤眼蜂生物防治措施、配比为红糖∶白酒∶食用醋:水=3∶1∶3∶80的糖醋酒液诱捕器的物理防治措施、迷向丝及迷向素的迷向措施均有替代化学防治措施的潜力。【结论】综合防治能够有效控制梨园梨小食心虫发生量,减少化学防治频次,为建立稳定的梨园生态系统及生产无公害水果提供了帮助。     

The life-history and bionomics of Epitrimerus piri (Acarina: Eriophyidae) on pear

The majority of Epitrimerus piri on pear, cv. Williams' Bon Chretien, moved from their hibernation sites in small permanently dormant buds on spurs and under loose bark to fruit buds between the stages of green cluster and petal fall. Peak numbers of mites occurred in mid-June on fruit and early August on leaves with the return to hibernation beginning in July. Development time from egg hatch to adult was 17–1, 6–9 and 4–8 days at 10, 16 and 22 °C, respectively. Mites were dispersed by wind. They were found only on species in the genera Pyrus, Cydonia and Pyronia. Mite feeding caused browning on the ventral, sides of leaves and russet on fruit which was confined to the calyx end on Williams'. Populations of over 2000 mites/leaf reduced the length and dry weight of new shoots on potted pears by 8 and 14% respectively.     

桑蓟马在桑树中空间分布的研究

桑蓟马Pseudodendrothrips mori是桑树的一种主要害虫。它的寄生直接影响供桑叶的质量和产量。我们通过泰勒幂法则和Morisita的散度指标对桑树蓟马在植株和桑园内的空间分布进行检验,结果显示:P.mori种群在植株内和桑园里的分布都存在局部化。桑树中蓟马的分布在树内显示出幼虫蓟马位于低层(从上面叶子起5-10层),但成虫更喜欢上层(从上面叶子起1-5层)。同一植株叶子的不同方向上蓟马密度没有出现明显变化。桑园内蓟马主要分布在桑园东部、南部和北部的植株上,中部,西部植株上的蓟马密度较低。P.mori的成虫和幼虫在叶子上的分布呈现明显聚集化。     

浙江省余姚地区松褐天牛的生活世代

松褐天牛Monochamus alternatus Hope是松材线虫(Bursaphelenchus xylophilus)病的主要传播媒介,明确松褐天牛的发生世代及成虫羽化规律对于松材线虫病的防控有着重要意义。本研究利用"塑料薄膜包裹松树树干、定期解除包裹供天牛产卵"的方法,系统研究了余姚地区松褐天牛的产卵规律及成虫的羽化规律。研究结果表明,成虫产卵期为5月上旬至8月下旬,高峰期出现在6月下旬至8月中旬。松褐天牛在浙江余姚多数为1年1代,部分为2年1代,95%以上的成虫集中在产卵后的第2年羽化,少数在第3年羽化。成虫自5月上旬开始羽化,高峰期出现在5月中旬到6月中旬,7月中旬羽化基本结束。     

Species composition and arthropod pest feeding of phytoseiid mites in a Japanese pear greenhouse

A population survey of spider mites and phytoseiid mites was conducted on Japanese pear leaves in a greenhouse. For the survey, the method to estimate phytoseiid mite species composition using quantitative sequencing was modified to be applicable for phytoseiid mite species inhabiting in the greenhouse. Results show the dominant appearance of Neoseiulus californicus (McGregor), Neoseiulus womersleyi (Schicha), and Neoseiulus makuwa (Ehara) from the end of June to late September and their contribution in spider mite control. PCR-based method to detect the ribosomal internal transcribed spacer (ITS) sequences of spider mites from phytoseiid mites was developed. The method shows sensitivity to detect the ITS sequences of Tetranychus urticae Koch from single N. californicus adult at 168 h after ingestion of the spider mite. PCR-based method to detect the cytochrome c oxidase subunit I sequences of several arthropod pests belonging to Hemiptera, Thysanoptera, and Acari from phytoseiid mites was also developed. Results show that phytoseiid mites prey on Eriophyes chibaensis (Kadono) and Aphis gossypii (Glover), in addition to spider mites.     

Epiphytic fitness of a biological control agent of fire blight in apple and pear orchards under Mediterranean weather conditions

The behaviour of Pseudomonas fluorescens EPS62e was investigated in apple and pear orchards under Mediterranean climatic conditions. The trials studied the influence of weather conditions, plant host species, presence of indigenous microbial community and spread from treated to nontreated trees on colonization and survival. Population dynamics were assessed by real-time PCR and CFU-counting methods. With inoculated flowers, weather conditions were optimal for colonization, and EPS62e established high and stable population levels around 10(8) CFU per organ, according to both methods of analysis. The plant host species did not influence the colonization rate, and the biocontrol agent dominated the microbial communities of blossoms, representing up to 100% of the total cultivable population. With inoculated leaves, the EPS62e population decreased to nondetectable levels 30 days after treatment according to both methods used. EPS62e spread moderately in the orchard, being detected in nontreated flowers of trees 15-35 m from the inoculation site. The combined use of real-time PCR and CFU-counting methods of analysis permitted the identification of three physiological states for EPS62e in the field, which consisted of active colonization, survival and entry into a viable but nonculturable state, and cell death.     

Extraction of arbutin and its comparative content in branches,leaves, stems,and fruits of Japanese pear Pyrus pyrifolia cv. Kousui

Arbutin is a tyrosinase inhibitor and is extensively used as a human skin-whitening agent. This study investigated the optimum conditions for extracting arbutin by ultrasonic homogenization from discarded branches pruned from Japanese pear (Pyrus pyrifolia cv. Kousui) trees. The arbutin content was measured in the branches and also in the leaves, stems, fruit peel, and fruit flesh.