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Exploiting the Ecological Interaction of the Green Peach Aphid on Peach Trees

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Exploiting the Ecological Interaction of the Green Peach Aphid on Peach Trees I -. Iii 12. 8 ~ 12.8 1.0 W ~ I~ 1.0 W ~ I~ Ii: .~ wlji w 2.2 w 2.2 a:.: a:.: I w I.i£ w W I::.... ~ I:: ~ ... M .... M 1.1 ....k 1.1 '"lill .... - 111111.25 1111,1.4 111111.6 111111.25 111111.4 111111.6 . ' MICROCOPY RESOLUTION TEST CHART MICROCOPY RESOLUTION TEST CHART NATIONAL BUREAU Of STANOARDS-1963-A NATIONAL BUREAU Of STANDARDS-1963-A , . ST \ I ~ Un;l.d S'"., i{ AAll Dep.artment of ~ Agriculture Exploiting the Ecological Science anci Education Interaction of the Green Administration Technical Bulletin Peach Aphid on Peach Number 1640 Trees i::' e -0 a::::>- ..-- a co :.:J I- ..--m .~ C,;3 ..Q 0 0 ::J 0.... CL. LW rl tI) Q c.:J OJ :::> OJ oj c.o c:J.: c: => c:r:: tI) 0 -1 Abstract' Contents Page George Tamaki. Exploiting the Ecological Interaction of the Introduction _____ ~______ ___ ___ ___ __ ____ ____ ______ ___ 1 Green Peach Aphid on Peach Trees. U.S. Department of Distribution and damage _____________________ ~ ___ _ __ _ 1 Agriculture Technical Bulletin No. 1640,6 p., 1981 General life cycle __________________________________ _ Ecological life cycle interactions_____ _____ _______ ___ ___ 1 An alternative or noninsecticide control program was Autumn ____________________,_________ " _ _________ 2 developed, which resulted from an intense ecological and Winter_______________________________ , __________ ,_ 4 biological investigation of the green peach aphid (GPA), Spring,, _____________ • _________________________ 4 Myzus persicae (Sulzer), in peach orchards. The GPA Alate viviparae and disruption of emigration_ _____ _ ___ __ _ 5 displayed a complex life cycle with many tenuous ecological Explosive GPA population on cover interactions, which were broken or disrupted with the most vegetation of the orchard- ______________________ ,_ ___ 5 suitable technolor:i'::al tools available. Conclusion __ • ______ " __' ___ __ __ ___________ , _ __ __ _ 5 Literature cited __ ____ __ __ __ __ __ __ __ _ __ ____ " _ ___ 6 Keywords: Green peach aphid, Myzus persicae, peach trees, integrated pest management, biological control, cultural control, weed control. Issued June 1981 Exploiting the Ecological Interaction of the Green Peach Aphid on Peach Trees By George TamakP Introduction In addition to its wide host-plant range and worldwide distribution, the GPA is an important pest because it can injure The green peach aphid (GPA), Myzus persicae (Sulzer), is a cultivated plants in a variety of ways. It is capable of causing major agricultl "31 pest; therefore, considerable insecticide direct injury by extracting sap from the plant. With its high pressures have been applied on the population, and reports of reproductive rate and rapid development, it is not unusual to insecticide resistance are common (1,2,3,5).2 The need for find hundreds or thousands of aphids per plant. With these the development of alternative methods of GPA control IS very high numbers, plants may soon be extensively injured or even apparent, but it is not a simple matter of plugging new killed. A few individuals feeding on leaf and flower buds or technological advances in insect control, such as insect young fruit (22) can also deform ornamentals and fruits. pheromones, insect growth regulators, or other new third generation insecticides or techniques, into the system. Only one viruliferous G PA is needed to transmit virus diseases to plants. The GPA is known as the most important insect One approach to insect control is to search for the weakness or vector of plant diseases (9) because it transmits over 100 the fragility of bonds in any of the ecological interactions in the different plant virus diseases (23). I n the Western States, two of insect life cycle, then exploit or attempt to break the weak link the more important diseases transmitted by the GPA are in the ecological interaction with the most suitable techno­ potato leafroll virus and the yellows virus diseases on sugar­ logical tools. As past failures in insect control verity, killing beets. techniques utilized without knowledge of the biologicai and ecological interactions of the pest rarely succeed. The major General Life Cycle reason for such failure is the resilience of insect populations Another interesting aspect of the GPA is its complex life cycle to adapt to our ingenuity to kill them. Populations of insects with five distinct morphological forms (ovipara, male, fundatrix, such as the GPA have continually bounced back after being aptera virginopara, and alate virginopara) and two different decimated by insecticides because of their high reproductive behavioral forms (gynopara and hiemalis) (fig.1). potential, short developmental period, physiological resistance mechanisms, and the suppression of their natural enemies; The different morphological forms can be divided into sexual however, emphasis is given at times to integration of available and asexual groups. The sexual forms are present in the pest-control techniques or agents as the ideal approach before autumn. The oviparae (female) are wingless and develop on enough ecological and biological information are available. peach leaves, where they reach adulthood. They mate with Therefore, we often match our strongest tools against the winged males that arrive from the summer host plants. The insects' ability to survive and reproduce. In the long term, we oviparae then lay overwintering eggs behind the peach buds. will achieve more success by exploiting insect weaknesses with strategy than by attacking them head on. In spring, when the eggs hatch, a third distinct form develops, which is called the fundatrix (stem mother). The fundatrices are In this article, control of the GPA will be restricted to the peach asexual and wingless. The progenies of the fundatrices are orchards, which contain the primary host and overwintering wingless and asexual (aptera virginopara), but their fragile, soft source of the GPA. The status of the GPA as a pest and its appearance makes them morphologically distinct from the generalized life cycle in the Yakima Valley will be reviewed for a sturdy-bodied stem mother. Later, winged asexuals (alate more meaningful discussion of the ecologiCal interactions of virginopara) are produced, which represent the fifth the GPA in the peach orchards. distinct form. Distribution and Damage In autumn, with shorter photoperiords and cooler tempera­ tures, the gynoparae (winged asexual aphids), physiologically The GPA ranks as one of the most important agricultural insect different from the summer winged forms, emigrate to peach pests in the world because of its worldwide distribution and the trees. These winged gynoparae give birth to the oviparae on type of damage inflicted on so many crops. The GPA is found peach leaves. The other physiological form is the hiemalis in almost every country in the wor~d, from tropical to temperate (specialized aptera viviparae), which overwinters on secon­ zones, including Alaska. The host range of the GPA includes dary host plant (6). In Yakima Valley, these hiemalis overwinter over 875 plant species; many of the vegetable, ornamentals, in protective microhabitat sites in deep drainage ditches fed by and field crops grown throughout the world are included on warm ul1derground springs (24). this list (4,8). Ecological Life Cycle Interactions 1Research entomologist, U.S. Department of Agriculture, Science and Education Administration-Agricultural Research, Yakima Agricultural A generalized life cycle can be used to describe the seasonal Research Laboratory, Yakima, Wash. 98902. activity of the different life stages and morphological forms of 21talic numbers in parentheses refer to Literature Cited, p. 6. the GPA (fig. 1); however, such an illustration is limited because 1 it does not present any of the ecological interactions of the Not until about the first part of October do the aphids begin to GPA. The ensuing discussion will concern the ecological life build up noticeably. but the population quickly peaks about cycle interactions of the GPA on their primary host, peaches, mid-October, with as many ae 80 winged aphids and 600 and subsequent development of an integrateu pest manage­ sexual females on a single leaf (13). The extremely rapid ment (IPM) program. buildup of the GPA in a very short period is attributed to the continuous arrival of the winged asexuals and their high Autumn reproductive rate. In most instances, large populations of aphids attract many natural enemies; however, in the fall, In mid-September in Yakima, the winged gynoparae of the instead of a multitude of different predator species attacking GPA begin to settle on the peach leaves, where they feed and the GPA, the predaceous syrphid larva are predominant. Most give birth to wingless sexual oviparae (fig.2). other predator species, such as coccinellid beetles, are either SPRING HIE"ALI' P'UHOATRICES Primary host Secondary host APTERAE EMIGRANTS EMIGRANTS SUMMER APTERAE Secondary host .YNOII'ARA! III ALii Hf~flfAL" / / / / AUTUMN 1 / Primary h o.f OVIPARAI Secondary h 0 at HIE"ALIS WINTER I ••• Hf.IIALIl Figure 1.-Life cycle of the green peach aphid. 2 AUTUMN SECONDARY HOST PRIMARY HOST- PEACH TREES MA LES --------------------~~~---, syrphld ' ..... predoflon " .... Mati~O OVERWINTERING EGGS o "RAE Lost to spider predetlon Qvlparae r.turnlng to t rl. S LOll 10 glocorld predation / GROUND / / / / / // / / / " SEPTEMBER OCTOBER I NOVE M BER I Figure 2.-Ecological interaction of the life cycle of the green peach aphid in autumn. inactive or in diapause because of the cool temperatures in Masking tape was placed around the trunks of the trees, and a late September and October. Apparently, these cool fall double ring of sticky material was placed on the tape to enable temperatures do not affect the syrphids because the adult flies us to distinguish the direction of the aphids' movement. Many continue to lay eggs in aphid colonies on peach leaves, and aphids were caught returning to the trees. A more interesting the emerging larvae feed on the aphids.
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