A central role for venom in predation by
 Varanus komodoensis
 (Komodo Dragon) and the extinct giant
 Varanus
 (
 Megalania
 )
 priscus

Fry, Bryan G.; Wroe, Stephen; Teeuwisse, Wouter M.; Osch, Matthias J.P. van; Moreno, Karen; Ingle, Jeanette; McHenry, Colin R.; Ferrara, Toni L.; Clausen, Philip; Scheib, Holger; Winter, Kelly Lee; Greisman, Laura; Roelants, Kim; Weerd, Louise van der; Clemente, Christofer J.; Giannakis, Eleni; Hodgson, Wayne Clarence; Luz, Sonja; Martelli, Paolo; Krishnasamy, Karthiyani; Kochva, Elazar; Kwok, Hang Fai; Scanlon, Denis B.; Karas, John A.; Citron, Diane M.; Goldstein, Ellie J. C.; McNaughtan, J; Norman, Janette A

doi:10.1073/pnas.0810883106

Cited by 130 publications

(155 citation statements)

References 29 publications

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“…snakegenomics.org/) and formatted into a BLAST-able database. Both databases were interrogated using representative venom sequences utilised by Fry et al [10][11][12]29 . Sequence searches were undertaken for 12 toxin families identified as basal to the Toxicofera (AVIT, cystatin, cysteine-rich secretory protein, CVF, crotamine, hyaluronidase, kallikrein, lectin, natriuretic peptides, NGF, veficolin and vespryn) [10][11][12] .…”

Section: Methodsmentioning

confidence: 99%

“…Contig hits were incorporated into DNA data sets of toxin (derived from members of the Toxicofera) and non-toxin (sampled from outside groups -that is, non-reptilian species) sequences used in the analyses of Fry et al [10][11][12]29 . All sequences were obtained from GenBank -GI accession numbers are displayed in the resulting gene trees (Figs 2-5; Supplementary Figs S2-S6).…”

Section: Methodsmentioning

confidence: 99%

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Dynamic evolution of venom proteins in squamate reptiles

2012

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Phylogenetic analyses of toxin gene families have revolutionised our understanding of the origin and evolution of reptile venoms, leading to the current hypothesis that venom evolved once in squamate reptiles. However, because of a lack of homologous squamate non-toxin sequences, these conclusions rely on the implicit assumption that recruitments of protein families into venom are both rare and irreversible. Here we use sequences of homologous non-toxin proteins from two snake species to test these assumptions. Phylogenetic and ancestral-state analyses revealed frequent nesting of 'physiological' proteins within venom toxin clades, suggesting early ancestral recruitment into venom followed by reverse recruitment of toxins back to physiological roles. These results provide evidence that protein recruitment into venoms from physiological functions is not a one-way process, but dynamic, with reversal of function and/or co-expression of toxins in different tissues. This requires a major reassessment of our previous understanding of how animal venoms evolve.

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Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Dynamic evolution of venom proteins in squamate reptiles

2012

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“…The presence of a venom delivery system in a wide variety of squamates (12,22) suggests that this adaptation can be expected in other diapsids, including the dromaeosaurs. Venom glands in lizards tend to be mandibular whereas those in snakes are maxillary; the basal condition is to have both (6).…”

Section: Discussionmentioning

confidence: 99%

The birdlike raptor Sinornithosaurus was venomous

Gong

Martin

Burnham

et al. 2009

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

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We suggest that some of the most avian dromaeosaurs, such as Sinornithosaurus, were venomous, and propose an ecological model for that taxon based on its unusual dentition and other cranial features including grooved teeth, a possible pocket for venom glands, and a groove leading from that pocket to the exposed bases of the teeth. These features are all analogous to the venomous morphology of lizards. Sinornithosaurus and related dromaeosaurs probably fed on the abundant birds of the Jehol forests during the Early Cretaceous in northeastern China.dromaeosaur | Jehol | grooved fangs | venomous delivery system O ne of the more bizarre innovations in organismic evolution is the ability to manufacture toxic substances. Venomous taxa occur in a variety of ecologic settings and include insects, lizards, snakes, and mammals (1-5). Clearly, venom has evolved numerous times in many different lineages employing various delivery apparatus. A combination of morphological and molecular research has recently shown that venomous taxa are far more widespread and primitive within tetrapod lineages than had previously been suspected (6).Sinornithosaurus is a dromaeosaurid closely related to the 4-winged glider Microraptor gui and therefore within the early avian radiation (7). It has unusually long maxillary teeth that are morphologically similar to those of "rear-fanged" snakes specialized to carry poison (Fig. 1). This type of fang discharges venom along a groove on the outer surface of the tooth that enters the wound of the bitten animal by capillary action (8, 9). Supporting this interpretation in Sinornithosaurus is an additional space on the lateral surface of the maxillary bone that we interpret on the basis of analogy with venomous squamates as having housed a venom gland. This previously undescribed fossa, herein termed the subfenestral fossa, could have housed an elongate, ascinar venom gland similar to that found in rear-fanged (i.e., opisthoglyphous) snakes (10, 11). We suggest that the venom traveled in ducts to the bases of the teeth and mixed with the saliva in a manner also similar to extant venomous squamates (6). The position of the venom collecting duct was probably along the oblique ventral surface of the maxilla, where there is a supradental groove (i.e., longitudinal depression running along the base of the tooth row). This groove bears small pits that seem to be related to tooth sites and may represent the location of small venom reservoirs. These depressions were illustrated and mentioned in the original description of Sinornithosaurus, but their purpose was not addressed. As in modern venomous taxa that employ grooved fangs, the ducts feed the venom to the base of the teeth. The mechanism for dispensing the venom may be similar to the system used by open-fanged snakes and lizards that discharge it under low pressure provided largely by force of the bite-a strategy for prey control rather than quick death (12). We believe Sinornithosaurus was a venomous predator that fed on birds by using its long fangs to...

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“…Venoms are produced in probably all animal phyla (2,3) and represent a mixture of effector proteins often aimed at tissue integrity by targeting extracellular matrix (ECM) 3 and receptor molecules. Intriguingly, many toxins share close structural and functional properties with ECM proteins, indicating a common evolutionary origin or co-evolution (4).…”

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confidence: 99%

Proteome of Hydra Nematocyst

Balasubramanian

Beckmann

Warnken

et al. 2012

Journal of Biological Chemistry

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Background: Nematocysts are the most sophisticated organelles in the animal kingdom and a hallmark of the phylum Cnidaria.Results: We present the first complete protein map of the Hydra nematocyst. Conclusion:The nematocyst proteome is highly complex and includes novel structural proteins. Significance: The proteome data reveal a eukaryotic origin of the nematocyst and point to common molecular features with the extracellular matrix.

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A central role for venom in predation by Varanus komodoensis (Komodo Dragon) and the extinct giant Varanus ( Megalania ) priscus

Cited by 130 publications

References 29 publications

Dynamic evolution of venom proteins in squamate reptiles

Dynamic evolution of venom proteins in squamate reptiles

The birdlike raptor Sinornithosaurus was venomous

Proteome of Hydra Nematocyst

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