Intra-specific variation for host plant use in Helicoverpa armigera (Hübner) (Lepidoptera: Noctuidae): Implications for management

The polyphagous moth Helicoverpa armigera (Hubner) is one of the world's most important agricultural pests. A number of existing approaches and future designs for management of H. armigera rely on the assumption that moths do not exhibit either genetically and/or non-genetically based variation for host plant utilization. We review recent empirical evidence demonstrating that both these forms of variation influence host plant use in this moth. The significance of this variation in H. armigera in relation to current and future pest management strategies is examined. We provide recommendations on future research needs and directions for sustainable management of H. armigera, under a framework that includes consideration of intra.-specific variation for host use relevant in this and other similar pest species. (C) 2004 Elsevier Ltd. All rights reserved.

Foraging behaviour of Helicoverpa armigera first instar larvae on crop plants of different developmental stages

Understanding how insect pests forage on their food plants can help optimize management strategies. Helicoverpa armigera (Hubner) (Lep., Noctuidae) is a major polyphagous pest of agricultural crops worldwide. The immature stages feed and forage on crops at all stages of plant development, damaging fruiting and non-fruiting structures, yet very little is known about the influence of host type or stage on the location and behaviour of larvae. Through semi-continuous observation, we evaluated the foraging (movement and feeding) behaviours of H. armigera first instar larvae as well as the proportion of time spent at key locations on mungbean [Vigna radiata (L.) Wilczek] and pigeon pea [Cajanus cajan (L.) Millspaugh] of differing developmental stages: seedling- and mature (flowering/pod fill)-stage plants. Both host type and age affected the behaviour of larvae. Larvae spent more time in the upper parts of mature plants than on seedlings and tended to stay at the top of mature plants if they moved there. This difference was greater in pigeon pea than in mungbean. The proportion of time allocated to feeding on different parts of a plant differed with host and age. More feeding occurred in the top of mature pigeon pea plants but did not differ between mature and seedling mungbean plants. The duration of key behaviours did not differ between plant ages in either crop type and was similar between hosts although resting bouts were substantially longer on mungbeans. Thus a polyphagous species such as H. armigera does not forage in equivalent ways on different hosts in the first instar stage.

Host recognition by a polyphagous lepidopteran (Helicoverpa armigera): primary host plants, host produced volatiles and neurosensory stimulation

An important question in the host-finding behaviour of a polyphagous insect is whether the insect recognizes a suite or template of chemicals that are common to many plants? To answer this question, headspace volatiles of a subset of commonly used host plants (pigeon pea, tobacco, cotton and bean) and nonhost plants (lantana and oleander) of Helicoverpa armigera Hubner (Lepidoptera: Noctuidae) are screened by gas chromatography (GC) linked to a mated female H. armigera electroantennograph (EAG). In the present study, pigeon pea is postulated to be a primary host plant of the insect, for comparison of the EAG responses across the test plants. EAG responses for pigeon pea volatiles are also compared between females of different physiological status (virgin and mated females) and the sexes. Eight electrophysiologically active compounds in pigeon pea headspace are identified in relatively high concentrations using GC linked to mass spectrometry (GC-MS). These comprised three green leaf volatiles [(2E)-hexenal, (3Z)-hexenylacetate and (3Z)-hexenyl-2-methylbutyrate] and five monoterpenes (alpha-pinene,beta-myrcene, limonene, E-beta-ocimene and linalool). Other tested host plants have a smaller subset of these electrophysiologically active compounds and even the nonhost plants contain some of these compounds, all at relatively lower concentrations than pigeon pea. The physiological status or sex of the moths has no effect on the responses for these identified compounds. The present study demonstrates how some host plants can be primary targets for moths that are searching for hosts whereas the other host plants are incidental or secondary targets.

Predicting population dynamics of weed biological control agents: science or gazing into crystal balls?

Various factors can influence the population dynamics of phytophages post introduction, of which climate is fundamental. Here we present an approach, using a mechanistic modelling package (CLIMEX), that at least enables one to make predictions of likely dynamics based on climate alone. As biological control programs will have minimal funding for basic work (particularly on population dynamics), we show how predictions can be made using a species geographical distribution, relative abundance across its range, seasonal phenology and laboratory rearing data. Many of these data sets are more likely to be available than long-term population data, and some can be incorporated into the exploratory phase of a biocontrol program. Although models are likely to be more robust the more information is available, useful models can be developed using information on species distribution alone. The fitted model estimates a species average response to climate, and can be used to predict likely geographical distribution if introduced, where the agent is likely to be more abundant (i.e. good locations) and more importantly for interpretation of release success, the likely variation in abundance over time due to intra- and inter-year climate variability. The latter will be useful in predicting both the seasonal and long-term impacts of the potential biocontrol agent on the target weed. We believe this tool may not only aid in the agent selection process, but also in the design of release strategies, and for interpretation of post-introduction dynamics and impacts. More importantly we are making testable predictions. If biological control is to become more of a science making and testing such hypothesis will be a key component.

Understanding Heliothine (Lepidoptera: Heliothinae) pests: What is a host plant?

Heliothine moths (Lepidoptera: Heliothinae) include some of the world's most devastating pest species. Whereas the majority of nonpest heliothinae specialize on a single plant family, genus, or species, pest species are highly polyphagous, with populations often escalating in size as they move from one crop species to another. Here, we examine the current literature on heliothine host-selection behavior with the aim of providing a knowledge base for research scientists and pest managers. We review the host relations of pest heliothines, with a particular focus on Helicoverpa armigera (Hubner), the most economically damaging of all heliothine species. We then consider the important question of what constitutes a host plant in these moths, and some of the problems that arise when trying to determine host plant status from empirical studies on host use. The top six host plant families in the two main Australian pest species (H. armigera and Helicoverpa punctigera Wallengren) are the same and the top three (Asteraceae, Fabaceae, and Malvaceae) are ranked the same (in terms of the number of host species on which eggs or larvae have been identified), suggesting that these species may use similar cues to identify their hosts. In contrast, for the two key pest heliothines in the Americas, the Fabaceae contains approximate to 1/3 of hosts for both. For Helicoverpa zea (Boddie), the remaining hosts are more evenly distributed, with Solanaceae next, followed by Poaceae, Asteraceae, Malvaceae, and Rosaceae. For Heliothis virescens (F.), the next highest five families are Malvaceae, Asteraceae, Solanaceae, Convolvulaceae, and Scrophulariaceae. Again there is considerable overlap in host use at generic and even species level. H. armigera is the most widely distributed and recorded from 68 plant families worldwide, but only 14 families are recorded as a containing a host in all geographic areas. A few crop hosts are used throughout the range as expected, but in some cases there are anomalies, perhaps because host plant relation studies are not comparable. Studies on the attraction of heliothines to plant odors are examined in the context of our current understanding of insect olfaction, with the aim of better understanding the connection between odor perception and host choice. Finally, we discuss research into sustainable management of pest heliothines using knowledge of heliothine behavior and ecology. A coordinated international research effort is needed to advance our knowledge on host relations in widely distributed polyphagous species instead of the localized, piecemeal approaches to understanding these insects that has been the norm to date.

Forecasting Helicoverpa populations in Australia: A comparison of regression based models and a bio-climatic based modeling approach

Long-term forecasts of pest pressure are central to the effective management of many agricultural insect pests. In the eastern cropping regions of Australia, serious infestations of Helicoverpa punctigera (Wallengren) and H. armigera (Hübner)(Lepidoptera: Noctuidae) are experienced annually. Regression analyses of a long series of light-trap catches of adult moths were used to describe the seasonal dynamics of both species. The size of the spring generation in eastern cropping zones could be related to rainfall in putative source areas in inland Australia. Subsequent generations could be related to the abundance of various crops in agricultural areas, rainfall and the magnitude of the spring population peak. As rainfall figured prominently as a predictor variable, and can itself be predicted using the Southern Oscillation Index (SOI), trap catches were also related to this variable. The geographic distribution of each species was modelled in relation to climate and CLIMEX was used to predict temporal variation in abundance at given putative source sites in inland Australia using historical meteorological data. These predictions were then correlated with subsequent pest abundance data in a major cropping region. The regression-based and bioclimatic-based approaches to predicting pest abundance are compared and their utility in predicting and interpreting pest dynamics are discussed.

Helicoverpa armigera (Hubner): can wheat stubble protect cotton plants against attack?

When investigating strategies for Helicoverpa armigera (Hubner) control, it is important to understand oviposition behaviour. Cotton (Gossypium hirsutum) was sown into standing wheat (Triticum astivum L.) stubble in a closed arena to investigate the effect of stubble on H. armigera moth behaviour and oviposition. Infrared cameras were used to track moths and determine whether stubble acted as a physical barrier or provided camouflage to cotton plants, thereby reducing oviposition. Searching activity was observed to peak shortly before dawn (03:00 and 04:00 h) and remained high until just after dawn (4 h window). Moths spent more time resting on cotton plants than spiralling above them, and the least time flying across the arena. While female moths spent more time searching for cotton plants growing in wheat stubble, the difference in oviposition was not significant. As similar numbers of eggs were laid on cotton plants with stubble (3.5/plant SE +/- 0.87) and without stubble (2.5/plant SE +/- 0.91), wheat stubble does not appear to provide camouflage to cotton plants. There was no significant difference in the location of eggs deposited on cotton plants with and without stubble, although more eggs were laid on the tops of cotton leaves in wheat stubble. As the spatial and temporal distribution of eggs laid on the cotton plant is a crucial component of population stability, eggs laid on the upper side of leaves on cotton plants may be more prone to fatalities caused by environmental factors such as wind and rain. Therefore, although stubble did not influence the number of eggs laid, it did affect their distribution on the plant, which may result in increased mortality of eggs on cotton plants sown into standing wheat stubble.

Host location behaviour in the desert caterpillar, Heliothis punctifera

The host location behaviour of foraging caterpillars has received little attention, despite the wealth of theoretical and empirical studies that have been directed at this behavioural trait in adult Lepidoptera. Here, we study caterpillars of the moth Heliothis punctifera Walker (Lepidoptera: Noctuidae), which inhabits the arid inland desert areas of Australia. Caterpillars of this species consume many flowerheads before completing development and can be observed moving across the sand in search of new hosts. Consequently, if host location behaviour favours attraction to certain plant species, it might be expected to influence the distribution and abundance of caterpillars in the field. We present field data showing that H. punctifera caterpillars are unevenly distributed throughout mixed patches of two of its host species, with a higher abundance on Senecio gregorii F. Muell., the annual yellow top, compared to Myriocephalus stuartii (F. Muell. & Sond.) Benth., the poached egg daisy (both Asteraceae). Using laboratory studies, we test whether this distribution may, in part, be due to host location behaviour of caterpillars. Our results show that caterpillars exhibit a preference for locating S. gregorii in their pre- and post-contact foraging behaviour. In addition, our results provide evidence that feeding history plays a role in host location behaviour in this insect. We propose that key features of the desert environment and the ecology of H. punctifera would favour adaptations to host location behaviour by immatures.

Evaluación comparativa de cuatro insecticidas y una mezcla lannate + decis para el control de larvas de heliothis spp Keiferia lycopercicella y adultos de Bemisia tabaci en el cultivo de tomate

El presente estudio de realizó en la Estación experimental Raúl González del valla4e de Sebaco de la D.G:A-MIDINRA entre los meses de febrero y mayo de 1984: la variedad fue UC-82, para determinar en ella el efecto de cuatro insecticidas y una mezcla lannate +Decis en el control de plagas de tomate industrial. Se estudiaron los siguientes insecticidasdas de Elcar 20 PIB PM, Lannate 90 PM. Decis 2.5 EC Lannate 90 PM +Decis 2.5 Ec y cytrolane 250 E más un testigo (sin la aplicación de insecticida). Para el análisis estadístico de los dados se usó parcelas divididas con cinco repeticiones: Los resultados obtenidos revelaron diferencias significativas únicamente entre los diferentes insecticidas en relaciona con el testigo sobre el número de larvas de Heliothis Spp y Keiferia Lycopercicella encontrados en el follaje lo mismo que para el número de frutos dañados por estas mismas plagas: en el caso del porcentaje de frutos dañados por Heliothis spp y K lycopercicella se detectó diferencia significativa en los tratamientos Lannate +Decis (102 gr/mz+240 cc/mz) y Decis (540cc/mz)en relación con el testigo, siendo los otros tratamientos insecticidas significativamente iguales al testigo. Para B. tabaci los resultados no detectaron diferencia significativas entre los insecticidas y el testigo

Estudio del crecimiento de larvas de Heliothis zea (Boddie) criadas en dieta artificial

En el periodo de los meses Enero-Febrero de 1973, se llevo a cabo el estudio del crecimiento de larvas de Heliothis zea en dieta artificial, en el Laboratorio de Biología de la Universidad Nacional Autónoma de Nicaragua (con sede en el Departamento de Leon). Habiendose antes hecho pruebas preliminares en el Laboratorio de Biología de la Escuela Nacional de Agricultura y Ganadería (con sede en el Departamento de Managua). Los objetivos eran: a) determinar el numero de mudas; b) la duración de su ciclo larval y c) la curva de crecimiento de Heliothis zea. Para ello se trabajo en el Laboratorio, con crianza del insecto, haciendo uso de la dieta artificial de Shorey modificada. Los datos a tomar fueron: a) longitud del cuerpo en mms.; b) tiempo transcurrido al tiempo de la muda; c) largo de capsula cefálica; d) ancho de capsula cefálica. De los resultados obtenidos, se detectaron seis mudas en el desarrollo de su ciclo larval. La duración de su ciclo larval vario desde 13 días hasta 21 días, encontrándose un promedio de 16.07 días como resultado de 28 observaciones que se tomaron. En la duración de su estado pupal se obtuvo un promedio de 10.06 días, resultado obtenido de 18 observaciones los análisis se efectuaron en el Instituto Interamericano de Ciencias Agrícolas, obteniéndose los siguientes resultados: a) A medida que aumentaba la edad de la larva, los periodos entre muda son mas variables. b) Siendo la variación del tiempo y longitud del cuerpo, máxima en la sexta muda. c) Los tamaños de las larvas son bastantes constante durante las dos primeras mudas; y se incrementa la variabilidad en las cuatro ultimas. d) Se logro ajuste a la ecuación logística en promedio de 99.10% y con los parámetros B0, B1, B2, se hizo curvas de crecimiento promedio de larvas de Heliothis zea. e) Análisis de correlación fueron efectuados, para conocer el grado de asociación de las variables largo del cuerpo vs. ancho de capsula cefálicas, no encontrándose correlación alguna.

石榴棉铃虫Heliothis倪糯谤m(Hubner) 发生规律及其防治研究

:石榴棉铃虫 (Heliothisarmigera (Hubner) ,属鳞翅目 (Lepidoptera) ,夜蛾科 (Noctuidae) ,是棉花的主要害虫 ,但也是云南蒙自石榴的主要害虫之一。但其发生危害规律尚不清楚 ,致使防治效果不佳。于 1 998～ 1 999年对该虫发生规模及综合防治进行了研究 ,为寻求有效防治方法提供参考

Recuperación de cepas HD de Bacillus thuringiensis, su propagación en 14 medios de producción y la evaluación de la actividad tóxica contra Trichoplusia ni (Háber) y Heliothis virescens (Fabricius)

Tesis (Maestría en Ciencias con Especialidad en Microbiología) UANL

Selección y evaluación de cepas nativas de Bacillus thuringiensis contra Heliothis zea (Boddie) y Spodoptera exigua (Hübner) [por] Guillermo José Gutiérrez Castillo

Tesis (Maestro en Ciencias con especialidad en Microbiolo gia) U.A.N.L.