Integrated Metabonomic−Proteomic Analysis of an Insect−Bacterial Symbiotic System

Wang, Yulan; Carolan, James C.; Hao, Fuhua; Nicholson, Jeremy K.; Wilkinson, T. L.; Douglas, Angela E.

doi:10.1021/pr9007392

Cited by 35 publications

(23 citation statements)

References 55 publications

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“…Consistent with the holobiont theory of evolution (Zilber-Rosenberg et al, 2008) this implies that aphids acquire resistance to natural enemies by picking up bacterial symbionts, rather than having changes in the aphids' genes. A truly transdisciplinary analysis performed by experts from a Department of Entomology, a Department of Biology, two laboratories of Magnetic Resonance and Atomic and Molecular Physics, an Institute of Physics and Mathematics, a School of Biology and Environmental Science, a Department of Biomolecular Medicine, and a Department of Surgery and Cancer, deepened our understanding of the interaction between aphids and B. aphidicola by uncovering the central role of amino acid metabolism in the aphid – Buchnera symbiosis (Wang et al, 2010). …”

Section: Case Study 2: Species Interactions In Aphidsmentioning

confidence: 99%

Metaorganisms as the new frontier

Bosch

McFall‐Ngai

2011

Zoology

358

267

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Summary Because it appears that almost all organisms are part of an interdependent meta-organism, an understanding of the underlying host-microbe species associations, and of its evolution and molecular underpinnings, has become the new frontier in zoology. The availability of novel highthroughput sequencing methods together with the conceptual understanding that advances mostly originate at the intersection of traditional disciplinary boundaries, enable biologists to dissect the mechanisms that control the interdependent associations of species. In this perspective article, we outline some of the issues in interspecies interactions, present two case studies illuminating the necessity of interfacial research when addressing complex and fundamental zoological problems, and show that an interdisciplinary approach that seeks to understand co-evolved multi-species relationships will connect genomes, phenotypes, ecosystems and the evolutionary forces that have shaped them. We hope that this article inspires other collaborations of a similar nature on the diverse landscape commonly referred to as “zoology”.

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Section: Case Study 2: Species Interactions In Aphidsmentioning

confidence: 99%

Metaorganisms as the new frontier

Bosch

McFall‐Ngai

2011

Zoology

358

267

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“…Although many applications are currently only represented by relatively few studies, entometabolomics has contributed to the understanding of such topics as hypoxia (Coquin et al., ; Feala et al., ), insect–bacterial symbiosis (Wang et al., ), behavioural ecology (Lenz et al., ), parasitism (Thompson et al., ), development (Phalaraksh et al., ; Wu et al., ), infectious diseases (Aliferis et al., ), the effects of commercial pesticides (Derecka et al., ), and temperature‐dependent stresses (Michaud & Denlinger, ; Michaud et al., ; Koštál et al., ,b) (Table ). Simultaneously, metabolomic investigations have indirectly generated information about insect life histories; particularly work focusing on plant‐insect interactions (Hunt et al., , ; Faria et al., ; Gattolin et al., ; Jansen et al., ; Leiss et al., ).…”

Section: Current Approaches To Entometabolomicsmentioning

confidence: 99%

“…Metabolomics has been applied to a number of insect study systems in an effective manner, generating new insights into the mechanisms underlying aspects of biology including behaviour (Lenz et al., ), infection (Chambers et al., ), temperature stress responses (Malmendal et al., ; Li et al., ; Colinet et al., ), CO 2 sedation (Colinet & Renault, ), and bacteria–insect symbiosis (Wang et al., ). We are sure that this list of topics will expand in the near future.…”

Section: Conclusion and Recommendationsmentioning

confidence: 99%

Entometabolomics: applications of modern analytical techniques to insect studies

Snart

Hardy

2015

Entomologia Exp Applicata

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Metabolomic analyses can reveal associations between an organism's metabolome and further aspects of its phenotypic state, an attractive prospect for many life‐sciences researchers. The metabolomic approach has been employed in some, but not many, insect study systems, starting in 1990 with the evaluation of the metabolic effects of parasitism on moth larvae. Metabolomics has now been applied to a variety of aspects of insect biology, including behaviour, infection, temperature stress responses, 2 sedation, and bacteria–insect symbiosis. From a technical and reporting standpoint, these studies have adopted a range of approaches utilising established experimental methodologies. Here, we review current literature and evaluate the metabolomic approaches typically utilised by entomologists. We suggest that improvements can be made in several areas, including sampling procedures, the reduction in sampling and equipment variation, the use of sample extracts, statistical analyses, confirmation, and metabolite identification. Overall, it is clear that metabolomics can identify correlations between phenotypic states and underlying cellular metabolism that previous, more targeted, approaches are incapable of measuring. The unique combination of untargeted global analyses with high‐resolution quantitative analyses results in a tool with great potential for future entomological investigations.

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“…In the present study, we coupled two-dimensional (2-D) fluorescence difference gel electrophoresis (DIGE), one of the most widely used platforms for quantitative proteomics (68), and tandem mass spectrometry with genetic analyses to quantitatively compare the proteomes of S. graminum genotypes that differ in the ability to transmit CYDV-RPV. The recently published genome sequence of the aphid species A. pisum has provided additional resources for protein discovery in our S. graminum genotypes and has propelled proteomics to the forefront of biological discovery technologies for S. graminum and other aphid species (10,14,25,26,50,51,74).…”

mentioning

confidence: 99%

Genetics Coupled to Quantitative Intact Proteomics Links Heritable Aphid and Endosymbiont Protein Expression to Circulative Polerovirus Transmission

Cilia

Tamborindeguy

Fish

et al. 2011

J Virol

103

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Yellow dwarf viruses in the family Luteoviridae, which are the causal agents of yellow dwarf disease in cereal crops, are each transmitted most efficiently by different species of aphids in a circulative manner that requires the virus to interact with a multitude of aphid proteins. Aphid proteins differentially expressed in F2 Schizaphis graminum genotypes segregating for the ability to transmit Cereal yellow dwarf virus-RPV (CYDV-RPV) were identified using two-dimensional difference gel electrophoresis (DIGE) coupled to either matrix-assisted laser desorption ionization-tandem mass spectrometry or online nanoscale liquid chromatography coupled to electrospray tandem mass spectrometry. A total of 50 protein spots, containing aphid proteins and proteins from the aphid's obligate and maternally inherited bacterial endosymbiont, Buchnera, were identified as differentially expressed between transmission-competent and refractive aphids. Surprisingly, in virus transmission-competent F2 genotypes, the isoelectric points of the Buchnera proteins did not match those in the maternal Buchnera proteome as expected, but instead they aligned with the Buchnera proteome of the transmission-competent paternal parent. Among the aphid proteins identified, many were involved in energy metabolism, membrane trafficking, lipid signaling, and the cytoskeleton. At least eight aphid proteins were expressed as heritable, isoelectric point isoform pairs, one derived from each parental lineage. In the F2 genotypes, the expression of aphid protein isoforms derived from the competent parental lineage aligned with the virus transmission phenotype with high precision. Thus, these isoforms are candidate biomarkers for CYDV-RPV transmission in S. graminum. Our combined genetic and DIGE approach also made it possible to predict where several of the proteins may be expressed in refractive aphids with different barriers to transmission. Twelve proteins were predicted to act in the hindgut of the aphid, while six proteins were predicted to be associated with the accessory salivary glands or hemolymph. Knowledge of the proteins that regulate virus transmission and their predicted locations will aid in understanding the biochemical mechanisms regulating circulative virus transmission in aphids, as well as in identifying new targets to block transmission.

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Integrated Metabonomic−Proteomic Analysis of an Insect−Bacterial Symbiotic System

Cited by 35 publications

References 55 publications

Metaorganisms as the new frontier

Metaorganisms as the new frontier

Entometabolomics: applications of modern analytical techniques to insect studies

Genetics Coupled to Quantitative Intact Proteomics Links Heritable Aphid and Endosymbiont Protein Expression to Circulative Polerovirus Transmission

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