An Insight into the Transcriptome of the Digestive Tract of the Bloodsucking Bug, Rhodnius prolixus

Ribeiro, José M. C.; Genta, Fernando Ariel; Sorgine, Marcos Henrique Ferreira; Logullo, Raquel; Mesquita, Rafael D.; Paiva-Silva, Gabriela O.; Majerowicz, David; Medeiros, Marcelo N.; Koerich, Leonardo B.; Terra, Walter R.; Ferreira, Clélia; Pimentel, André C.; Bisch, Paulo Mascarello; Leite, Daniel C.; Diniz, Michelle M. P.; V., João Lídio da S. G.; Silva, Manuela L. da; Araújo, Ricardo Nascimento; Gandara, Ana Caroline P.; Brosson, Sébastien; Salmon, Didier; Bousbata, Sabrina; González-Caballero, Natalia; Silber, Ariel Mariano; Auger, Michèle; Gondim, Kátia C.; Silva-Neto, Mário A.C.; Atella, Geórgia C.; Araujo, Helena; Dias, Felipe A.; Polycarpo, Carla; Vionette-Amaral, Raquel J.; Fampa, Patrı́cia; Melo, Ana C.A.; Tanaka, Aparecida S.; Balczun, Carsten; Oliveira, José Henrique M.; Gonçalves, Renata L.S.; Lazoski, Cristiano; Rivera‐Pomar, Rolando; Diambra, Luis; Schaub, Günter A.; Garcia, Elói S.; Azambuja, Patrı́cia; Braz, Glória R.C.; Oliveira, Pedro L.

doi:10.1371/journal.pntd.0002594

Cited by 195 publications

(309 citation statements)

References 233 publications

(246 reference statements)

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“…Peptide sequences of chemoreceptors and binding proteins of the following species were obtained from NCBI, and used as BLAST queries for our peptide database with an E-value cutoff of 1E−7: Z. nevadensis [14], P. americana [34], T. castaneum [31,35,23], H. oblita [36], D. ponderosae [37], A. mellifera [38,39], D. melanogaster [17,[40][41][42][43], A. gambiae [44], A. aegypti [45], A. lineolatus [46], R. prolixus [47], L. migratria [48], and B. mori [30,49,50]. The peptide sequences of ORs of M. caryae were translated from the nucleotide sequences [51] using the Nucleotide Sequence Translation tool (EMBL-EBI, http://www.ebi.ac.uk/Tools/st/).…”

Section: Annotation Of Chemoreceptor and Binding Proteinsmentioning

confidence: 99%

Caste-specific and sex-specific expression of chemoreceptor genes in a termite

Mitaka¹

2016

2016 International Congress of Entomology

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The sophisticated colony organization of eusocial insects is primarily maintained through the utilization of pheromones. The regulation of these complex social interactions requires intricate chemoreception systems. The recent publication of the genome of Zootermopsis nevadensis opened a new avenue to study molecular basis of termite caste systems. Although there has been a growing interest in the termite chemoreception system that regulates their sophisticated caste system, the relationship between division of labor and expression of chemoreceptor genes remains to be explored. Using high-throughput mRNA sequencing (RNA-seq), we found several chemoreceptors that are differentially expressed among castes and between sexes in a subterranean termite Reticulitermes speratus. In total, 53 chemoreception-related genes were annotated, including 22 odorant receptors, 7 gustatory receptors, 12 ionotropic receptors, 9 odorant-binding proteins, and 3 chemosensory proteins. Most of the chemoreception-related genes had caste-related and sex-related expression patterns; in particular, some chemoreception genes showed king-biased or queen-biased expression patterns. Moreover, more than half of the genes showed significant age-dependent differences in their expression in female and/or male reproductives. These results reveal a strong relationship between the evolution of the division of labor and the regulation of chemoreceptor gene expression, thereby demonstrating the chemical communication and underlining chemoreception mechanism in social insects.

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Section: Annotation Of Chemoreceptor and Binding Proteinsmentioning

confidence: 99%

Caste-specific and sex-specific expression of chemoreceptor genes in a termite

Mitaka¹

2016

2016 International Congress of Entomology

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“…The majority of the predator reduvid bites are very painful for vertebrates due to their markedly proteolytic saliva, which is fundamental for them to paralyze and digest their invertebrate prey. The presence of trypsin transcripts in the sialome of T. infestans and Panstrongylus geniculatus (Latreille) suggests a role for these molecules very different from the digestive one (Ribeiro et al 2014). In the same way, it is interesting from the point of view of the evolution of the predator habit to hematophagy that a paralyzing protein has been detected in the saliva of T. infestans, a function previously only found in predator insects (Alves et al 2011).…”

Section: Salivamentioning

confidence: 99%

“…The phytophagous ancestors of the early reduvids lost their ability to use trypsin, the common digestive protease, because plant sap is virtually without protein and the seeds have strong antitrypsins (Savelkoul et al 1992;Lehane 2005). In the same way the predator reduvids and the hematophagous triatomines developed the capacity to secrete catepsins in the intestine to digest the proteins found most abundantly in their food (Lehane 2005;Ribeiro et al 2014). The catepsins are a family of proteases normally found in the intracellular lysosomes, which generally become active at low pH (best 5.5 to 6), so that it can be said that the triatomines developed a system to acidify lightly alkaline blood (pH ≈ 7.4) (Terra et al 1996).…”

Section: Digestive Enzymesmentioning

confidence: 99%

“…The catepsins are a family of proteases normally found in the intracellular lysosomes, which generally become active at low pH (best 5.5 to 6), so that it can be said that the triatomines developed a system to acidify lightly alkaline blood (pH ≈ 7.4) (Terra et al 1996). The finding of proteases (trypsins) in the rectal ampulla of R. prolixus is congruent with the loss of their digestive function in triatomines (Ribeiro et al 2014). …”

Section: Digestive Enzymesmentioning

confidence: 99%

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Evolution of hematophagous habit in Triatominae (Heteroptera: Reduviidae)

Otálora-Luna

Pérez-Sánchez

Sandoval

et al. 2015

Rev. Chil. de Hist. Nat.

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All members of Triatominae subfamily (Heteroptera: Reduviidae), potential vectors of Trypanosoma cruzi, etiologic agent of the Chagas disease, feed on blood. Through evolution, these bugs have fixed special morphological, physiological, and behavioral aptations (adaptations and exaptations) adequate to feed on blood. Phylogeny suggests that triatomines evolved from predator reduvids which in turn descended from phytophagous hemipterans. Some pleisiomorphic traits developed by the reduvid ancestors of the triatomines facilitated and modeled hematophagy in these insects. Among them, mouthparts, saliva composition, enzymes, and digestive symbionts are the most noticeable. However, the decisive step that allowed the shift from predation to hematophagy was a change of behavior. The association of a predator reduvid with nesting vertebrate (≈110 to 32 Ma) permitted the shift from an arthropod prey to a vertebrate host. In this work, we review the phylogeny and dispersion of triatomines and the current controversy over the monophyly or polyphyly of this group. We also discuss how these insects were able to overcome, and even have taken advantage of, diverse ancestral and physical barriers to adapt to sucking blood of nidicolous vertebrates. We provide a Spanish version of this work.

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“…For example, it is quite possible that there are further types of luminal digestive enzymes waiting to be discovered in triatomines. A recent transcriptome analysis of the R. prolixus intestine has revealed many genes related to digestive physiology including digestive enzymes lacking some amino acid residues important for enzymatic activity [24]. Furthermore, it would be very important to know whether or not microbiota plays a role in the digestion of triatomines and how strong the influence of T. cruzi on the digestive system might be.…”

Section: Editorialmentioning

confidence: 99%

Pathways of Insect Protein Digestion: Triatominae (Kissing Bugs)

Waniek¹

2014

Entomol Ornithol Herpetol

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EditorialThe majority of insects use serine proteinases like trypsin and chymotrypsin as main enzymes to digest their food [1]. These types of peptidases develop their maximum activity under alkaline to neutral pH conditions [2]. In some insect groups the intestinal lumen is acidic and the digestion switched to cysteine-like proteinases such as cathepsin D or L [3,4]. Some Coleoptera groups (e.g. Bruchidae, Tenebrionidae) developed a digestive system based on such proteinases [2,5]. But the major group using acid proteinases are the Hemiptera. This taxon uses cysteine proteinases because ancestral groups were using plant seeds containing serine proteinases inhibitors as a food source and therefore had to evolve their digestive system [6,7]. The conquest of this food source was a challenge for the digestive system [8] but it certainly contributed to the success of this insect group opening up new niches.One of the best analyzed hemipteran groups considering their digestion is the Triatominae (Heteroptera, Reduviidae) subfamily. Many species of this group -especially from the genera Triatoma, Rhodnius and Panstrongylus [9] -are medically important because they are able to transmit Trypanosoma cruzi (Kinetoplastida, Trypanosomatidae), the causative agent of Chagas disease [10]. In contrast to mosquitoes which develop from egg to adult in few weeks and frequently show low rates of parasitic infection, some long-lived triatomine species needs several months to complete their life cycle [1]. Besides this, kissing bugs takes huge amounts of blood from their vertebrate host at each nymph stage and, consequently usually show higher infection rates (up to about 80%) [1,[11][12][13][14][15]. In this insect group several digestive enzymes and their respective genes were identified and characterized. In the beginning of the 1980s activities of cathepsin B and D, aminopeptidase and carboxypeptidase have been shown [16,17]. Later, when the appropriate molecular biology methods were available, different isoforms of genes from different triatomine species have been identified encoding cathepsin B, L and D and serine carboxypeptidase [18][19][20][21][22]. At the same time Borges et al. [23] have demonstrated a significant increase of cathepsin D activity in Rhodnius prolixus infected with T. cruzi. However, despite the numerous studies concerning the Triatominae, many questions about their digestive system and its interactions with the parasite are still unanswered. For example, it is quite possible that there are further types of luminal digestive enzymes waiting to be discovered in triatomines. A recent transcriptome analysis of the R. prolixus intestine has revealed many genes related to digestive physiology including digestive enzymes lacking some amino acid residues important for enzymatic activity [24]. Furthermore, it would be very important to know whether or not microbiota plays a role in the digestion of triatomines and how strong the influence of T. cruzi on the digestive system might be. It would also be interesting ...

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An Insight into the Transcriptome of the Digestive Tract of the Bloodsucking Bug, Rhodnius prolixus

Cited by 195 publications

References 233 publications

Caste-specific and sex-specific expression of chemoreceptor genes in a termite

Caste-specific and sex-specific expression of chemoreceptor genes in a termite

Evolution of hematophagous habit in Triatominae (Heteroptera: Reduviidae)

Pathways of Insect Protein Digestion: Triatominae (Kissing Bugs)

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