Great Basin Naturalist Volume 58 Number 4 Article 7 10-12-1998 Comparative demography of the high-altitude lizard, Sceloporus grammicus (Phrynosomatidae), on the Iztaccihuatl Volcano, Puebla, México Julio A. Lemos-Espinal Proyecto Fauna Silvestre, CENID-COMEF/SARH, Viveros de Coyoacan, Mexico Royce E. Ballinger University of Nebraska Lincoln, Lincoln Geoffrey R. Smith William Jewell College, Liberty, Missouri Follow this and additional works at: https://scholarsarchive.byu.edu/gbn Recommended Citation Lemos-Espinal, Julio A.; Ballinger, Royce E.; and Smith, Geoffrey R. (1998) "Comparative demography of the high-altitude lizard, Sceloporus grammicus (Phrynosomatidae), on the Iztaccihuatl Volcano, Puebla, México," Great Basin Naturalist: Vol. 58 : No. 4, Article 7. Available at: https://scholarsarchive.byu.edu/gbn/vol58/iss4/7 This Article is brought to you for free and open access by the Western North American Naturalist Publications at BYU ScholarsArchive. It has been accepted for inclusion in Great Basin Naturalist by an authorized editor of BYU ScholarsArchive. For more information, please contact scholarsarchive@byu.edu, ellen_amatangelo@byu.edu.
Creat Ba...in Natur.uist 58(4), :I 1998. pp. 375-379 COMPARATIVE DEMOGRAPHY OF THE HIGH-ALTITUDE LIZARD, SCEWPORUS GRAMMICUS (PHRYNOSOMATIDAE),, ON THE IZTACCIHUATL VOLCANO, PUEBLA, MEXICO Julio A. Lemos-Espinal l, Royce E. Ballinger 2, and Geoffrey R. Smith 3 ABSTRACT.-Population density, reproduction, and survivorship were compared between 2 populations of Sctdoporu5' gra.rll7nicus occurring at different altitudes (3700 m and 4400 m) on the eastern slopes of l:ttaceihuatl Volcano. Puehla, Mbdco. Lizards in both populatlom matured at the same l:lge (14-15 mon) and size (39--42 mm SLY). Population density was slightly greater at high altitude (131-163 per ha) than at low altitude (52-83 per ha). SUlvivorship and no were higher at the low-altitude area, but in general there were no significant demographic variations between altitudes that bave been reported in lizard population at higher latitudes. Studies or lower-elevlltion populations might reveal some differences because previous studies indicate that IiUer size increases at lower altitudes. although they do not differ between our 3700 m and 4400 m populations. Key words: lizard life history, derrwgmphy, reproductum, altitude variatwn, Sce!oporus grammieus, populaj.ian den "'Y, replacement rate, roroivorship. Life histories and demographic traits of lizards can vary along elevational gradients (Ballinger 1979, Grant and Dunham 1990, Smith and Ballinger 1994a, 1994b). Altitudinal variations in life history characteristics often mimic variation observed across broader geographic ranges that can be attrihuted to differences in environmental mnditions (e.g., Adolph and Porter 1993, 1996). In addition, some stud ies have shown that altitudinal variation can have at least a partial genetic basis (Smith et aj. 1994, Ballinger et aj. 1996), just as studies on geographic variation have shown (Ferguson and Talent 1993, Niewiarowski and Roosenburg 1993). Most ofthese studies have focused on lizard populations in north temperate latitudes. Understanding how life histories and demography vary in response to latitude and altitude combinations may be useful in identifying variables responsible for such changes. In this paper we present data on demographic variation of 2 populations of Scelo POf'US gmmmicus Wiegmann, 1828 at different elevations (3700 m and 4400 m) to examine whether variations in demography occur at subtropical latitudes. Sceloporus gmmmicus is a small, viviparous lizard that occurs from southern Texas, USA, to the state of Oaxaca, Mexico (Conant and Collins 1991, Flores Villela and Gerez 1994). This species has been poorly studied and little has been published on its biology, except for studies on its reproduction (Guillette and Casas-Andreu 1980, 1981, Ortega and Barb.ult 1984), general population biology (Lemos-Espinal and Amaya Elias 1986), growth (Lemos-Espinal and Ballinger 1995a), and thermal biology (Lemos Espinal and Ballinger 1995b). MATERIALS AND METHODS The 2 populations we studied are located in the Campo Experimental Forestal San Juan Tetla (19 IO'N, 98 36'W) on the eastern slope of Iztaccihuatl Volcano, Puebla, Mexico, at 3700 and 4400 m. On Iztaccihuatl Volcano, S. grammicus can be found up to 4600 m elevation. At this latitude tree line is 4000 m. The low-elevation site (hereafter designaled!..lignna), of approximately 4 ha, is located in a Pinus hartwegii forest surrounding a natural lake. Lizards were seen primarily on logs and stumps but were occasionally found under tree bark or in cracks in tree trunks. This site If'tC) eel!) Flluru. Sil.,..,.tre" GENID COMEFISARH, Avcni<1o. PnJI!res&l #S. ~ de Coyooc;In. ),(;1<;0"_ D.R 041 10. ts:cnool ocbiological Sctel'KX;S, Uni emtym Nebraslc.-Iinooln, Un(.'\lln, Nfo: 6H58S. ('.orrespoooenee allthor. 3[)(,~n! ufbiology. William Jewell College, l.iherty, MO 64068. 375
376 GREAT BASIN NATURALIST [Volume 58 Q) N en 6 5 4 3 Laguna y.. 5.300 + O.194x Q).- N en 6 5 4 3 2 Paredon y.. 8,108.. O.247x A.. 0.8e/ 2 1 1+-L-.-~--~--~ 30 40 50 60 Snout-Vent Length (mm) O+--'-.--~--~--~ 30 40 50 Snout-Vent Length (mm) 60 Fig.!. Relationship of litter size to body size in pregnant Sceloporus grammichs from low- (Laguna) and high- (Paredon) altitude populations on the Iztaccihuatl Volcano, Puebla, Mexico. was studied from November 1984 to June 1988, and from September 1990 to January 1992, The high-elevation site (hereafter designated Paredon), ofapproximately 1 ha, is a volcanic rock formation surrounded by grassland composed primarily of Festuca tolucensis. Lizards at this site live under rocks and in rock crevices. "Ve studied this site from November 1985 to June 1988, and from September 1990 to January 1992, From May 1991 to April 1992, average minimum temperatures for these 2 sites were very similar (Laguna = 2.0 + a.goe [mean + Is,,], Paredon = 2,2 + 0,6 C); however, average maximum temperatures for Laguna were higher (13,1 + 0,9 C) than for Paredon (5,7 + 0,5 C; Lemos-Espinal and Ballinger 1995a), Both populations were censused monthly, For each captured lizard we measured snoutvent length (SVL) to the nearest mm using a clear plastic ruler, and body mass (BM) to the nearest 0,01 g using a Pesola '1'1< spring scale. We also recorded sex, tail condition (broken, regenerated, or unbroken), time of capture, and microhabitat of capture site, Each lizard was permanently marked by toe clipping, To examine reproduction, we collected females in adjacent areas more than 500 m from the 2 study sites (n = 67 for Laguna, n = 54 for Paredon) during May 1991 and dissected them to examine reproductive tracts (specimens currently in JALs personal collection). Size and number of yolked follicles or embryos were recorded for each female, All means are given + ls x ' unless specified otherwise. Using Jolly's (1965) stochastic method, which is relatively insensitive to differences in chance of capture or survival among animals (Carothers 1973), we calculated population density for each month, Although young and old lizards may have differed in capture frequency and survivorship, bias in population estimates was probably small (Smith 1981), Lizards were aged according to size at first capture, Since Lemos-Espinal and Ballinger (1995a) found that lizards from both study sites show the same growth rates, we used the same size categories for both populations: size class 1 (females <39 mm SVL, males <42 mm SVL; individuals in their 1st yr), size class 2 (females 39-45 mm SVL, males 42-49 mm SVL; individuals in their 2nd yr), and size class 3 (females >45 mm SVL, males >49 mm SVL; 3 yr or older), For life table analyses we estimated age by recapture of animals marked as hatchlings or by using von BertalanflY (1957) growth analyses (Lemos-Espinal and Ballinger 1995a), Survivorship was estimated for each age class as the proportion of marked animals recaptured the following year, RESULTS Litter size increased with female body size in both populations (Fig, 1;,- = 0.85, n = 67, P < 0,0001 for Laguna, and r = 0,89, n = 54,
1998] DEMOGRAPHY OF SCEWPORUS GRAMMICUS 377 P < 0.0001 for Paredon). Females from Laguna had significantly larger litter sizes than did females from Paredon, after controlling for differences in body size with ANCaVA (3.64 + 0.10 [n = 54] vs. 3.31 + 0.13 [n = 67]; F t, 117 = 4.92, P < 0.03). The interaction term was not significant. There was no indication in our study, or in that ofguillette and Casas-Andreu (1980), that females have more than 1 litter per year. Lizards at both study sites were born at 19-20 mm SVL. Females attained sizes of approximately 39 mm SVL by 14 mon of age (Lemos-Espinal and Ballinger 1995a). The smallest reproductive female was 39 mm SVL at both Laguna and Paredon, but an SVL of approximately 40-42 mm was the typical minimum size of reproductive females (Fig 1). These data indicate that females at both study sites mature at an age of 14-15 mon (i.e., in their 2nd fall). Annual survivorship (lxl was calculated for 1985-86 and 1986-87 at Laguna, and for 1986-87 at Paredon. In general, survivorship tended to be greater at Laguna than at Paredon (Fig. 2). The number ofindividuals per ha was greater at Paredon than at Laguna for all years ofstudy (Table 1). Contribution of the different age classes to age-specific fertility was similar at both study sites. Age classes 2 and 3 contributed the most (32% and 29% at Laguna, and 30% and 31% at Paredon; see Table 2). Average generation time was 3.32 yr for Laguna and 3.37 yr for Paredon. Replacement rates varied between years as did average population density (Table 2). Lower R o values in 1987 may have resulted because both study sites were sampled only 6 mon in 1988 (until June 1988); thus some lizards that survived from 1987 to 1988 may not have been registered. DISCUSSION In general, the 2 populations of S. grammi CU8 studied here do not differ greatly in their biology. Survivorship estimates appear to be slightly higher in the Laguna population, but the difference is quite small. Growth rates and body temperatures also do not differ between these populations (Lemos-Espinal and Ballinger 1995a, 1995b). One of the few population differences is litter size. Females from Laguna, the 1e+O 5e-1 1 2 3 Age (years) _ 85 Laguna _ 86 Laguna -a- 87 Laguna - 86 Parudon _ 87 Pareclon Fig. 2. Survivorship (Ix) curves for Sceloporus grammielm from low- (Laguna) and high- (Paredon) altitude populations on the Iztaccihuatl Volcano, Puebla, Mexico. low-elevation site, had slightly larger litters than did individuals from Paredon, the highelevation site. This difference may help explain the difference in R o between these populations: Laguna's R o suggests a growing population, whereas Paredon's suggests a decreasing population. It is interesting to note that litter sizes of S. grammicus from lowerelevation populations (2000-3200 m) are even larger (mean = 5.2) than from our Laguna site (Guillette and Casas-Andreu 1980). The lack ofmajor differences between these 2 populations of S. grammicus is in contrast to several other studies of elevational variation in life history and demographic traits, such as growth (Grant and Dunham 1990, Smith and Ballinger 1994a) and survivorship (Smith and Ballinger 1994b). While it is tempting to attribute differences between the present study and other studies to geography (i.e., differences in latitude) or elevation (present study took place at higher elevations than other studies), such a conclusion is premature. Our results, taken along with those of Guillette and Casas-Andreu (1980), do suggest there may be additional elevational differences among populations of S. grammicus if a broader range of elevations were studied. Our results also suggest that further studies comparing populations at different elevations from a variety of latitudes would be useful in elucidating potential causes of life history and demographic variation in lizards (and other ectotherms). 4 5
378 GREAT BASIN NATURALIST [Volume 58 TABLE L Average population density for 2 populations of Sceloporus grammicus from the Iztaccihuatl Volcano, PuebIa, Mexico for 5 yr. Densities arc given as individuals per hectare. Population 198.5 1986 1987 1988 1991 Laguna Parodan 81 79 155 83 163 52 131 77 13,5 TABLE 2. Age-specific fertility rates (l,mj and Ros for 10w- (Lab'Uoa) and high- (Paredon) altitude populations of Scelopums grammicus from the Iztaccihuatl Volcano, Plichla, Mexico. Absolute longevity is unknown, but 5-yr-old animals have been recorded. Life table was arbitrarily stopped at the end ofthe 6th yr. Laguna ParedoD Age 1985 1986 1987 Mean 1986 1987 Mean 0 0 0 0 0 0 0 0 I 0 0 0 0 0 0 0 2 0.423 0.439 0.273 0.378 0.207 0.181 0.244 3 0.375 0.398 0.243 0.338 0.334 0.170 0.252 4 0.239 0.259 0.154 0.217 0.223 0.98 0.160 5 0.152 0.169 0.099 0.140 0.148 0.056 0.102 6 0.095 0.107 0,062 0.089 0.096 0.030 0.063 R" 1.284 1.372 0.831 1.159 1.108 0.535 0.821 ACKNOWLEDGMENTS For field assistance and use of facilities, we thank G. Praxedis-Martinez and workers from the Campo Experimental Forestal San Juan Tetla. Financial support to J.L,-E. was provided by the Instituto Nacioual de luvestigaeiones Forestales y Agropecuarias and the Consejo Nacional de Ciencia y Tecnologia. J,L.-E. is especially grateful to lug. C. Gouzales Vicente and S, Sanoja Sarabia for advice and support. LITERATURE CITED AI::>OLPH, S.c., AND W.P. PORTElL 1993. Temperature, activity, and lizard (ife histories. American Naturalist 142: 273-295. --,. 1996. Crowth, seasonality, and lizard life histories: age and si7;e at maturity. Gikos 77:267-278. BALLINGER, R.E. 1979. Intraspecific variation in demography and life history of the lizard, Sceloporus jarrovi, along an altitudinal gradient in southeastern Arizona. Ecology 60:901-909. BALLINGER, R.E., C.R. SMITH, AND J.w. NIETFELDT. 1996. Elevational variation in age at maturity in Sceloporus jarrovi: an experimental evaluation. Southwestern Naturalist 41:179--182. BEHTALANFFY, L. YO.'1 1957. Quantitative laws in metabolism and ).,rrowth. Quarterly Review of Biology 32:217-231. CAROTHERS, A.D. 1973. The effects of unequal eatchability on Jolly-Seber estimates. Biometrics 29:70-100. CONANT, R., AND J.T. COLLINS. 1991. Reptiles and amphibians: eastern and central North America. 3rd edition. Houghton Mifflin Co., Boston. FERGUSON, C.w., AND L.C. TALEN'l: 199.3. Life-history traits of the lizc'l.rd Sceloporus undulatus from two populations raised in a common laboratory environment. Decologia 9.3:88-94. FLORES VILLELA, D., Ai'lD P. CEREZ. 1994. Biod.iversidad y conservacion en Mexico: vertebrados, vegetacion y uso del suelo. D.R. Universidad Nacional Autonoma de Mexico, Mexico. G.RANT, B.W., Ai'lD A.E. DUNHAM. 1990. Elevational covariatiol1 in environmental constraints in life histories of the desert lizard Sceloporus merriami. Ecology 71: 1765-1776. CUILLETIE, L.J., AND C. CASAS-ANDREe. 1980. Fall reproductive activity in the high altitude Mexican lizard, Sceloporus grammicus microlepidotus. Journal of Herpetology 14:143-147. _-co' 1981. Seasonal variation in fat body weights of the Mexican high elevation lizard Sceloporus grarnmicus microlepidotus. Journal of Herpetology 15: 366-371. JOLLY, C.M, 1965. Explicit estimates from capture-recapture data with both death and immigration stochastic model. Biometrika 52:225-247. LEMOS-EsPINAL, J.A., AND J. AMAYA-ELIAS. 1986. Aspectos generates sobre la ecologia poblacional de la lagartija Sceloporus grammicus microlepidotus (Sauria: Iguanidae), en Ia vertiente oriental del volcan Iztaccihuatl, Puebla. Ciencia Forestal 59:127-151. LEMOS-EsPINAL, J.A., AND R.E. BALLINGER. 1995a. Ecology of growth of the high altitude lizard Sceloporus grammict1s on the eastern slope of Iztaccihuatl Volcano, Puebla, Mexico. Transactions of the Nebraska Academy of Sciences 22:77-85.
1998] DEMOGRAPHY OF SCEWPOlWS GllAMMICUS 379 _-c;' 1995b. Cornpllrutive thermal ecology of the highaltitude lizard SccWporu.'I grommiclls on the eastern slope of tbe Iztat.'\:ihuatl Volcano, Pucbla, Mexit.'o. Canadian loumal ofzoology 73:2184-2191. NIEWIAI\OWSKI, PH., AND W..\i. ROOSENBUIlG. 1993. Reciprocal transplant reveals sources of variation in growth rates of the li~rd Sceloporus wmulatus. EcoJo~'Y 74:1992-2002. ORTEGA, A., A:'JO it BAIIBAULT. 1984.. Reproductive cycles in the mesquite lizard Saloporm gramtnims. Journal of Herpetology 18:168-175. SMITH, D.c. 1981. Compt:titive interactions of the striped plateau lizard (SceloponJ.s livgatus) and the tree lizard (Urosoums OOUlftu,'). E<.'O!ogy 62:679-687. SMITH, C.R., AND R.E. BALI.INGER. 1994a. Temporal and spatial V'.lriation in individual growth in the spiny Lizard, Sceloporusjorrovi. Copeia 1994:1007-1013. _-;,:' 1994b. Survivorship in a high-elevation popula~ lion orsceloporus jarrovi during a period ofdrought. Copeia 19lJ4:104Q-I042. S~U'JlI, C.R, R.E. BAJ.I.I)/CY.R, AND J.W NIETFEillT. 1994. Elevatiollal variation of growth rates in neonate Sceloporus jarrqvi: an experimental evaluation. Functional Ecology 8:215--218. Receiood 11 June 1997 Accepted 20 JanuilrlJ 1998