| 1. |
- Richards, Stephen, et al.
(författare)
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The genome of the model beetle and pest Tribolium castaneum.
- 2008
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Ingår i: Nature. - 1476-4687. ; 452:7190, s. 949-55
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Tidskriftsartikel (refereegranskat)abstract
- Tribolium castaneum is a representative of earth’s most numerous eukaryotic order, a powerful model organism for the study of generalized insect development, and also an important pest of stored agricultural products. We describe its genome sequence here. This omnivorous beetle has evolved an ability to interact with a diverse chemical environment as evidenced by large expansions in odorant and gustatory receptors, as well as p450 and other detoxification enzymes. Developmental patterns in Tribolium are more representative of other arthropods than those found in Drosophila, a fact represented in gene content and function. For one, Tribolium has retained more ancestral genes involved in cell-cell communication than Drosophila, and some are expressed in the growth zone crucial for axial elongation in short germ development. Systemic RNAi in T. castaneum appears to use mechanisms distinct from those found in C. elegans, but nevertheless offers similar power for the elucidation of gene function and identification of targets for selective insect control.
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| 2. |
- Gerardo, Nicole M, et al.
(författare)
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Immunity and other defenses in pea aphids, Acyrthosiphon pisum.
- 2010
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Ingår i: Genome Biology. - : Springer Science and Business Media LLC. - 1465-6906 .- 1474-760X. ; 11:2
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Tidskriftsartikel (refereegranskat)abstract
- BACKGROUND: Recent genomic analyses of arthropod defense mechanisms suggest conservation of key elements underlying responses to pathogens, parasites and stresses. At the center of pathogen-induced immune responses are signaling pathways triggered by the recognition of fungal, bacterial and viral signatures. These pathways result in the production of response molecules, such as antimicrobial peptides and lysozymes, which degrade or destroy invaders. Using the recently sequenced genome of the pea aphid (Acyrthosiphon pisum), we conducted the first extensive annotation of the immune and stress gene repertoire of a hemipterous insect, which is phylogenetically distantly related to previously characterized insects models.RESULTS: Strikingly, pea aphids appear to be missing genes present in insect genomes characterized to date and thought critical for recognition, signaling and killing of microbes. In line with results of gene annotation, experimental analyses designed to characterize immune response through the isolation of RNA transcripts and proteins from immune-challenged pea aphids uncovered few immune-related products. Gene expression studies, however, indicated some expression of immune and stress-related genes.CONCLUSIONS: The absence of genes suspected to be essential for the insect immune response suggests that the traditional view of insect immunity may not be as broadly applicable as once thought. The limitations of the aphid immune system may be representative of a broad range of insects, or may be aphid specific. We suggest that several aspects of the aphid life style, such as their association with microbial symbionts, could facilitate survival without strong immune protection.
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| 3. |
- Lindgren, Malin, 1975-
(författare)
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Molecular and functional characterization of the insect hemolymph clot
- 2008
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Doktorsavhandling (övrigt vetenskapligt/konstnärligt)abstract
- All metazoans possess an epithelial barrier that protects them from their environment and prevents loss off body fluid. Insects, which have an open circulatory system, depend on fast mechanism to seal wounds to avoid excessive loss of body fluids. As in vertebrates, and non-insect arthropods such as horseshoe crab and crustaceans, insects form a clot as the first response to tissue damage. Insect hemolymph coagulation has not been characterized extensively at the molecular level before, and the aim of my studies was to gain more knowledge on this topic. Morphological characterization of the Drosophila hemolymph clot showed that it resembles the clots previously described in other larger bodied insects, such as Galleria mellonella. The Drosophila clot is a fibrous network of cross-linked proteins and incorporated blood cells. The proteins building up the clot are soluble in the hemolymph or released from hemocytes upon activation. Since bacteria are caught in the clot matrix and thereby prevented from spreading it is likely that the clot serves as a first line of defense against microbial intruders. The bacteria are not killed by the clot. What actually kills the bacteria is not known at this point, although the phenoloxidase cascade does not seem to be of major importance since bacteria died in the absence of phenoloxidase. We identified and characterized a new clot protein which we named gp150 (Eig71Ee). Eig71Ee is an ecdysone-regulated mucin-like protein that is expressed in salivary glands, the perithophic membrane of the gut and in hemocytes, and can be labeled with the lectin peanut agglutinin (PNA). Eig71Ee was found to interact with another clot protein (Fondue), and the reaction was catalyzed by the enzyme transglutaminase. This is the first direct functional confirmation that transglutaminase acts in Drosophila coagulation. A protein fusion construct containing Fondue tagged with GFP was created. The fusion construct labeled the cuticle and the clot, and will be a valuable tool in future studies. Functional characterization of the previously identified clotting factor Hemolectin (Hml) revealed redundancy in the clotting mechanism. Loss of Hml had strong effects on larval hemolymph clotting ex vivo, but only minor effects, such as larges scabs, in vivo when larvae were wounded. An immunological role of Hml was demonstrated only after sensitizing the genetic background of Hml mutant flies confirming the difficulty of studying such processes in a living system. Hemolectin was previously considered to contain C-type lectin domains. We reassessed the domain structure and did not find any Ctype lectin domains; instead we found two discoidin domains which we propose are responsible for the protein’s lectin activity. We also showed that lepidopterans, such as Galleria mellonella and Ephestia kuehniella, use silk proteins to form clots. This finding suggests that the formation of a clot matrix evolved in insects by the co-option of proteins already participated in the formation of extracellular formations.
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| 4. |
- Richards, Stephen, et al.
(författare)
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Genome Sequence of the Pea Aphid Acyrthosiphon pisum
- 2010
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Ingår i: PLoS biology. - : Public Library of Science (PLoS). - 1544-9173 .- 1545-7885. ; 8:2, s. e1000313-
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Tidskriftsartikel (refereegranskat)abstract
- Aphids are important agricultural pests and also biological models for studies of insect-plant interactions, symbiosis, virus vectoring, and the developmental causes of extreme phenotypic plasticity. Here we present the 464 Mb draft genome assembly of the pea aphid Acyrthosiphon pisum. This first published whole genome sequence of a basal hemimetabolous insect provides an outgroup to the multiple published genomes of holometabolous insects. Pea aphids are host-plant specialists, they can reproduce both sexually and asexually, and they have coevolved with an obligate bacterial symbiont. Here we highlight findings from whole genome analysis that may be related to these unusual biological features. These findings include discovery of extensive gene duplication in more than 2000 gene families as well as loss of evolutionarily conserved genes. Gene family expansions relative to other published genomes include genes involved in chromatin modification, miRNA synthesis, and sugar transport. Gene losses include genes central to the IMD immune pathway, selenoprotein utilization, purine salvage, and the entire urea cycle. The pea aphid genome reveals that only a limited number of genes have been acquired from bacteria; thus the reduced gene count of Buchnera does not reflect gene transfer to the host genome. The inventory of metabolic genes in the pea aphid genome suggests that there is extensive metabolite exchange between the aphid and Buchnera, including sharing of amino acid biosynthesis between the aphid and Buchnera. The pea aphid genome provides a foundation for post-genomic studies of fundamental biological questions and applied agricultural problems.
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