Direct and feeding‐induced interactions between two rice planthoppers, <i>Sogatella furcifera</i> and <i>Nilaparvata lugens</i>: effects on dispersal capability and performance

Matsumura, Masaya; Suzuki, Yoshito

doi:10.1046/j.1365-2311.2003.00498.x

Cited by 35 publications

(34 citation statements)

References 36 publications

(45 reference statements)

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“…For example, the waxy hairs of T. longula nymphs may act to exclude the nymphs of M. scutellaris from feeding areas (Figure 4). Despite this, the insects do share some of the food resource, particularly the upper portion of the petiole as a substrate to oviposit (Sosa et al 2004(Sosa et al , 2005; Remes Lenicov and Hernández 2010); consequently exploitative competition and/or plant-mediated interaction seem to be expected (Kaplan and Denno 2007), as they were recorded on the rice planthoppers N. lugens and Sogatella furcifera (Matsumura and Suzuki 2003). Finally, there is no evidence of enemy-mediated interactions because they do not share oophagous parasitoids in their native range (Triapistyn, Sosa, and Hernández 2010;Triapitsyn and Hernández 2011).…”

Section: Discussionmentioning

confidence: 99%

Feeding behavior and spatial distribution of two planthoppers,Megamelusscutellaris(Delphacidae) andTaosalongula(Dictyopharidae), on water hyacinth

Hernández

Brentassi

Sosa

et al. 2011

Biocontrol Science and Technology

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Megamelus scutellaris Berg (Delphacidae) and Taosa (Cuernavaca) longula Remes Lenicov (Dictyopharidae) are specialist planthoppers that feed and reproduce on the invasive aquatic weed, Eichhornia crassipes (Martius) Solms-Laubach (Pontederiaceae). They overlap geographically in several regions of South America and may, therefore, interact and compete for food and microhabitat. Preliminary observations indicated that both species do not feed on the same part of the plant. We hypothesized that they partition the resource; hence, we studied (1) the feeding mechanism at the tissue level and (2) the spatial distribution of both species on the water hyacinth plant. Salivary sheaths were detected through histological sections of plant tissues using light microscopy. The location of either planthopper species on the plant was recorded when in the presence or absence of the other species. Both species produced true salivary sheaths, mostly branched (M. scutellaris: 82%; T. longula: 84%), ending in phloem (M. scutellaris: 56%; T. longula: 52%), and xylem tissues (M. scutellaris: 24%; T. longula: 28%). They resided on different parts of the water hyacinth plant even when they did not coexist; nymphs of T. longula occurred primarily on the back side of the leaf laminas, while nymphs of M. scutellaris occupied the basal zone of the petioles. This study shows that these planthoppers complement each other and could be used in combination as control agents for water hyacinth. Further experimental studies and field observations are necessary to quantify interactions.

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Section: Discussionmentioning

confidence: 99%

Feeding behavior and spatial distribution of two planthoppers,Megamelusscutellaris(Delphacidae) andTaosalongula(Dictyopharidae), on water hyacinth

Hernández

Brentassi

Sosa

et al. 2011

Biocontrol Science and Technology

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“…While there is a growing body of literature pertaining to induced responses to insects in rice (Karban and Chen 2007), most of this research has involved piercing-sucking insect pests or indirect resistance (Xu et al 2002;Matsumura and Suzuki 2003;Zhou et al 2003;Lou et al 2005). Rice thus remains relatively under-utilized for the study of direct induced resistance to chewing insects.…”

Section: Discussionmentioning

confidence: 99%

“…What research that has been done has primarily focused on indirect induced resistance and/or induced responses to feeding by sucking insects (Bentur and Kalode 1996;Seino et al 1996;Matsumura and Suzuki 2003;Xu et al 2002Xu et al , 2003Kanno et al 2005;Lou et al 2005;Senthil-Nathan et al 2009). Recently, however, Stout et al (2009) demonstrated direct induced resistance in rice to a chewing insect, the fall armyworm (Spodoptera frugiperda J.E.…”

Section: Introductionmentioning

confidence: 99%

Herbivore- and Elicitor-Induced Resistance in Rice to the Rice Water Weevil (Lissorhoptrus oryzophilus Kuschel) in the Laboratory and Field

2010

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Feeding by herbivores can change plants in ways that make them more resistant to subsequent herbivory. Such induced responses are better-studied in a number of model dicots than in rice and other cereals. In a series of greenhouse and field experiments, we assessed the effects of prior herbivory by the fall armyworm, Spodoptera frugiperda (J.E. Smith) and of exogenous applications of jasmonic acid (JA) on the resistance of rice plants to the rice water weevil, Lissorhoptrus oryzophilus (Kuschel), the major pest of rice in the United States. Prior feeding by S. frugiperda and treatment of plants with exogenous JA resulted in increases in the resistance of plants to the weevil. Increases in resistance were manifested as reduced numbers of eggs and first-instars associated with armyworm-injured or JA-treated plants relative to control plants. In field experiments, there was a transient but significant reduction in the number of immature L. oryzophilus on JA-treated plants relative to untreated plants. To our knowledge, this is the first example of direct induced resistance in rice demonstrated in small-plot field experiments. We discuss the potential for the use of elicitor induced resistance in rice.

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“…Denno et al 2001;Matsumura and Suzuki 2003;Poniatowski and Fartmann 2011c) between populations with different colonisation histories, we studied 43 populations of M. roeselii. Only populations with high abundances were chosen as these are more likely to produce macropters (Higaki and Ando 2003;Fartmann 2009, 2011b, c).…”

Section: Colonisation History and Dispersal Capabilitymentioning

confidence: 99%

“…The clear association between macroptery and dispersal in M. roeselii (Simmons and Thomas 2004;Gardiner 2009;Hochkirch and Damerau 2009) allowed us to use the proportion of long-winged individuals as a reliable index of dispersal capability (cf. Denno et al 2001;Matsumura and Suzuki 2003;Poniatowski and Fartmann 2011c). M. roeselii is an ideal model organism for studying dispersal strategies because dispersing males are easy to detect, regardless of their wing morph, due to their noisy song (Hochkirch and Damerau 2009).…”

Section: Introductionmentioning

confidence: 99%

The role of macropters during range expansion of a wing-dimorphic insect species

2011

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Marked changes in distribution in consequence of global warming have been observed not only for highly mobile insect taxa, which are capable of flight, but also for wing-dimorphic species with predominantly short-winged individuals. In the special case of wing-dimorphic species, it is likely that the rarer long-winged (macropterous) morph plays an important role in the dispersal process, but little is known about how and to what extent it is involved. The aim of our study was to provide more information on the mechanisms behind dispersal processes in wing-dimorphic insects at expanding range margins. As solitary individuals are believed to play an important role in the range expansion of wing-dimorphic species (potential dispersers), we recorded the number of long-winged and short-winged solitary males at the local range margin of our model organism Metrioptera roeselii (Orthoptera: Tettigoniidae) in NW Germany. To investigate differences in dispersal capability (% macropters) between populations with different colonisation histories, we studied 43 populations of M. roeselii. Our results show that about 2/3 of the solitary males were long-winged and these long-winged individuals were significantly more frequent in recently colonised areas. Moreover, M. roeselii had a significantly higher dispersal capability (% macropters) in high-density populations and in recently established populations at the expanding range margin compared to populations characterised by medium-or long-term establishment nearer to the range core. Our study is the first that quantifies the importance of macropters for the recent range expansion of a wing-dimorphic species and it provides for the first time detailed insights into the complex dispersal processes that take place at the expanding range margin. It is likely that density stress and a changed genetic predisposition to become macropterous, and thus a combination of both ecological and evolutionary effects, leads to a high percentage of macropters in recently colonised areas.

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Direct and feeding‐induced interactions between two rice planthoppers, Sogatella furcifera and Nilaparvata lugens: effects on dispersal capability and performance

Cited by 35 publications

References 36 publications

Feeding behavior and spatial distribution of two planthoppers,Megamelusscutellaris(Delphacidae) andTaosalongula(Dictyopharidae), on water hyacinth

Feeding behavior and spatial distribution of two planthoppers,Megamelusscutellaris(Delphacidae) andTaosalongula(Dictyopharidae), on water hyacinth

Herbivore- and Elicitor-Induced Resistance in Rice to the Rice Water Weevil (Lissorhoptrus oryzophilus Kuschel) in the Laboratory and Field

The role of macropters during range expansion of a wing-dimorphic insect species

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