JOURNAL OF EXPERIMENTAL ZOOLOGY 307A:568–577 (2007)
Prey Envenomation Does Not Improve Digestive Performance in Western Diamondback Rattlesnakes (Crotalus atrox) MARSHALL D. MCCUE Department of Biological Sciences, University of Arkansas, Fayetteville, Arkansas
ABSTRACT
Although the toxic properties of snake venoms have been recognized throughout history, very little is known about the adaptive significance of these powerful mixtures. This study examined the popular hypothesis that prey envenomation enhances digestion by influencing the energetic costs of digestion and assimilation, gut passage time, and apparent assimilation efficiency (ASSIM) in western diamondback rattlesnakes (Crotalus atrox), a species whose venom is recognized for its comparatively high proteolytic activities. A complete randomized block design allowed repeated measures of specific dynamic action and gut passage time to be measured in eight snakes ingesting four feeding treatments (i.e., artificially envenomated live mice, artificially envenomated prekilled mice, saline injected live mice, and saline injected prekilled mice). A second experiment measured ASSIM in eight snakes ingesting a series of six artificially envenomated or six saline injected mice meals over an 8-week period. Contrary to expectations, the results of both these experiments revealed that envenomation had no significant influence on any of the measured digestive performance variables. Gut passage time averaged 6 days and ASSIM averaged 79.1%. Twenty-one hours following ingestion, postprandial metabolic rates exhibited factorial increases that averaged 3.9-fold greater than resting metabolic rate. Specific dynamic action lasted on average 88 hr and accounted for 26% of the total ingested energy. The results of this study reinforce the need to systematically examine the potential adaptive advantages that venoms confer on the snakes that produce them. J. Exp. Zool. 307A:568–577, 2007. r 2007 Wiley-Liss, Inc. How to cite this article: McCue MD. 2007. Prey envenomation does not improve digestive performance in western diamondback rattlesnakes (Crotalus atrox). J. Exp. Zool. 307A:568–577.
For decades scientists have speculated about the various adaptive functions of snake venoms (Zeller, ’48; Gans and Elliott, ’68; Pough and Groves, ’83; Hayes et al., ’95; Daltry et al., ’96; Kardong, ’96). The most popular theories suggest that snake venoms serve chiefly predatory, defensive, and/or digestive functions. Although each of these hypotheses are supported by a long history of anecdotal evidence, because of the obvious logistical difficulties in dealing with venomous snakes, very few studies have attempted to investigate systematically the specific advantages that venoms concede to the relative fitness or life histories (sensu Dunham et al., ’89; Boggs, ’92; Zera and Harshman, 2001) of venomous snakes. The ‘‘defensive hypothesis’’ suggests that venom functions to release snakes from predation pressures (Bogert, ’43; Ruben, ’76; Saint-Girons, r 2007 WILEY-LISS, INC.
’97), but no studies have formally examined whether venomous and nonvenomous species are subjected to differential predation pressures. Moreover, this hypothesis does not address how snake predators may be able to ‘‘learn’’ to identify venomous from nonvenomous snake species, a lesson that is likely to be lethal to potential predators. The ‘‘predatory hypothesis’’ suggests that the primary function of snake venoms is to kill or otherwise incapacitate prey items that could somehow injure the snake (Kardong, ’75;
Grant sponsor: NSF-GRF and Walton Distinguished Doctoral Fellowship. Correspondence to: Marshall D. McCue, Department of Biological Sciences, 601 Science Engineering, University of Arkansas, Fayetteville, AR 72701. E-mail: mmccue@uark.edu Received 10 April 2007; Revised 16 May 2007; Accepted 2 July 2007 Published online 1 August 2007 in Wiley InterScience (www. interscience.wiley.com). DOI: 10.1002/jez.411