Assessment of prey overlap between a native (<i>Polistes humilis</i>) and an introduced (<i>Vespula germanica</i>) social wasp using morphology and phylogenetic analyses of 16S rDNA

Kasper, Marta; Reeson, Andrew; Cooper, Steven J.; Perry, Kym D.; Austin, Andrew D.

doi:10.1111/j.1365-294x.2004.02193.x

Cited by 72 publications

(80 citation statements)

References 68 publications

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“…For vouchers, we sequenced the 16S and COI genes as described for diet items. Phylogenetic analyses were used to confirm molecular identifications, adapting the methods of Kasper et al (22). [2005][2006][2007] in HAVO and HALE, we sampled arthropod densities before and after the removal of V. pensylvanica colonies at removal and control sites.…”

Section: Methodsmentioning

confidence: 99%

“…Diet samples were PCR-amplified using LRN13398 and LRJ12887 primers (22) to amplify 500 -650 bp of the mitochondrial 16S rDNA gene. For reaction conditions, refer to SI.…”

Section: Methodsmentioning

confidence: 99%

“…We used molecular analyses to identify masticated diet items collected from Ϸ50 returning foragers at each of 10 colonies (5 in HAVO and 5 in HALE). We identified diet items by sequencing the 16S rDNA and COI genes following Kasper et al (22) and Magnacca and Danforth (23). We extracted DNA from 93% of samples (n ϭ 465), 90% of which were identified at least to the family level using a combination of BLAST searches, comparisons with voucher specimens collected on site, and phylogenetic analyses.…”

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confidence: 99%

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Life history plasticity magnifies the ecological effects of a social wasp invasion

Wilson

Mullen

Holway

2009

Proc. Natl. Acad. Sci. U.S.A.

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An unresolved question in ecology concerns why the ecological effects of invasions vary in magnitude. Many introduced species fail to interact strongly with the recipient biota, whereas others profoundly disrupt the ecosystems they invade through predation, competition, and other mechanisms. In the context of ecological impacts, research on biological invasions seldom considers phenotypic or microevolutionary changes that occur following introduction. Here, we show how plasticity in key life history traits (colony size and longevity), together with omnivory, magnifies the predatory impacts of an invasive social wasp (Vespula pensylvanica) on a largely endemic arthropod fauna in Hawaii. Using a combination of molecular, experimental, and behavioral approaches, we demonstrate (i) that yellowjackets consume an astonishing diversity of arthropod resources and depress prey populations in invaded Hawaiian ecosystems and (ii) that their impact as predators in this region increases when they shift from small annual colonies to large perennial colonies. Such trait plasticity may influence invasion success and the degree of disruption that invaded ecosystems experience. Moreover, postintroduction phenotypic changes may help invaders to compensate for reductions in adaptive potential resulting from founder events and small population sizes. The dynamic nature of biological invasions necessitates a more quantitative understanding of how postintroduction changes in invader traits affect invasion processes.biological invasions ͉ predation S pecies introductions disrupt ecosystems and can threaten biodiversity (1-3). Predicting the magnitude of these effects, however, has proved difficult (4), in part because invaders and members of the recipient biota may undergo microevolutionary changes or display phenotypic plasticity following introduction events (5-7). For invaders, postintroduction modifications in behavior, morphology, or life history traits may influence invasion success and alter the capacity of these species to disrupt the ecosystems they invade. In this way, trait plasticity may permit individuals to compensate for reduced genetic diversity (8) and the subsequent loss of adaptive potential that is assumed to result from translocation to new environments (9).Trait plasticity may be especially important for invasive social insects, because small behavioral changes at the individual level can scale up to produce dramatic and unexpected changes at the colony level (e.g., the formation of supercolonies) (10). In this sense, the phenotypic envelope of the social superorganism can encompass a larger set of potential morphotypes compared with that of a typical solitary organism. Here, we quantify the ecological effects of trait plasticity in an omnivorous social insect invader (the western yellowjacket, Vespula pensylvanica) that is shaping Hawaiian arthropod assemblages through top-down effects on multiple trophic levels. In part because Hawaii lacks native eusocial insects (11), yellowjacket invasions pose a potentially ...

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Section: Methodsmentioning

confidence: 99%

“…Diet samples were PCR-amplified using LRN13398 and LRJ12887 primers (22) to amplify 500 -650 bp of the mitochondrial 16S rDNA gene. For reaction conditions, refer to SI.…”

Section: Methodsmentioning

confidence: 99%

mentioning

confidence: 99%

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Life history plasticity magnifies the ecological effects of a social wasp invasion

Wilson

Mullen

Holway

2009

Proc. Natl. Acad. Sci. U.S.A.

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“…There is an urgent need to develop strategies for assessing these important different issues. Paralleling the situation in the field of invasion biology (see Lawson Handley et al 2011), despite continuous advances in methodology (Harwood and Obrycki 2005;Kasper et al 2004), molecular techniques are seldom used in the field of ERA to answer biological control questions such as those concerning trophic interactions. This review evaluates the use of immunological, chemical and molecular approaches to determine levels of intraguild predation by BCAs, in the field.…”

Section: Introductionmentioning

confidence: 99%

Detecting arthropod intraguild predation in the field

et al. 2011

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The process of biological control carries a distinct risk that an alien biological control agent (BCA) will become established as an invasive alien species with an associated threat to the local ecosystem biodiversity. It is imperative that a wide-ranging environmental risk assessment (ERA) is performed before the release of any BCA. This should include considering various potential but difficult to observe ecological interactions between the BCA and members of the native community, including disruption of intraguild relationships. Detection of intraguild predation (IGP) events involving predatory arthropods in the field can be done by analyzing their gut contents. Polymerase chain reaction (PCR) is a sensitive and specific tool to identify target prey DNA within a predator's gut. This paper reviews the efficiency of a DNA based approach for detecting IGP in the field, compared with detection by the use of monoclonal antibodies or gas chromatography. Prey specificity, detection times after prey consumption, capacity for quantification, multiple prey targeting and the time and costs involved in developing and using the different methods are considered.

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“…Life history and environmental traits related to invasion, highlighting the suggested differences between invasive and native insects that were found through an extensive literature review. Parasitoids more likely to establish than predators (Kimberling 2004) A, C Taxon Diptera and Lepidoptera fastest to disperse, Coleoptera slowest (Paynter and Bellgard 2011) Invasive species predominantly Hemiptera (56.4 %), Lepidoptera (14.9 %), and Hymenoptera (12.9 %) (Matosevic and Zivkovic 2013); Invasive species predominantly Homoptera (39 %), Coleoptera (19 %), Lepidoptera (13 %), and Hymentoptera (13 %) (Mattson et al 2007); Invasive species predominantly Coleoptera, Sternorrhyncha, and Psocoptera (Kenis et al 2007); Homoptera and Lepidoptera most likely to establish (Peacock and Worner 2008) C Feeding method Miners, borers, and leaf-rollers disperse faster than external feeders, and root-, rosette-, and seed-feeders (Paynter and Bellgard 2011) Internal feeders more likely to establish than external feeders (Kimberling 2004) Insects that use single host species are more likely to establish than those that use multiple hosts (Mondor et al 2007) C Diet breadth Diet breadth or Host specificity Invasive insects have a wide diet breadth (generalist) compared to natives (Moller 1996, Cervo et al 2000, Kasper et al 2004, Kimberling 2004, Moeser and Vidal 2005, Snyder and Evans 2006, Mondor et al 2006, Ward and Masters 2007…”

Section: Analogous Insect and Plant Invasiveness Traitsmentioning

confidence: 99%

Traits related to biological invasion: A note on the applicability of risk assessment tools across taxa

Emiljanowicz¹,

Hager²,

Newman³

2017

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Biological invasions are occurring frequently and with great impact to agricultural production and other ecosystem services. In response to this, the Australian Weed Risk Assessment (AWRA) was created to assess the potential 'weediness' of plants based on answers to questions related to biogeography, undesirable attributes, and biology or ecology. This basic model has been expanded and adapted for use on other taxa, often without adequate validation. Since invasive insect crop pests are a major economic cost to agricultural production, there is interest in using an expanded model for insects. Here, we review traits related to invasiveness of insects based on a systematic review of the literature. We then compare the identified invasive traits of insects with those identified for plants in the AWRA. Using insects as a case study, we illustrate that although there is some overlap in invasive traits, there are many unique traits related to invasion for both insects and plants. For insects, these traits relate largely to social behaviour. This lack of congruence may also be the case for other taxa. To increase predictive power, a taxon-specific risk assessment tool and deliberate verification are required.

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Assessment of prey overlap between a native (Polistes humilis) and an introduced (Vespula germanica) social wasp using morphology and phylogenetic analyses of 16S rDNA

Cited by 72 publications

References 68 publications

Life history plasticity magnifies the ecological effects of a social wasp invasion

Life history plasticity magnifies the ecological effects of a social wasp invasion

Detecting arthropod intraguild predation in the field

Traits related to biological invasion: A note on the applicability of risk assessment tools across taxa

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