Acta Herpetologica 12(2): 187-191, 2017

ISSN 1827-9635 (print) © Firenze University Press 
ISSN 1827-9643 (online) www.fupress.com/ah

DOI: 10.13128/Acta_Herpetol-19981

Reproductive timing and fecundity in the Neotropical lizard Enyalius 
perditus (Squamata: Leiosauridae)

Serena Najara Migliore1,2,*, Henrique Bartolomeu Braz2,3, André Felipe Barreto-Lima4, Selma Maria 
Almeida-Santos1,2

1 Setor de Anatomia, Departamento de Cirurgia, Faculdade de Medicina Veterinária e Zootecnia, Universidade de São Paulo, Av. 
Orlando Marques de Paiva 87, Cidade Universitária, São Paulo, SP, Brazil. 05508-270
2 Laboratório de Ecologia e Evolução, Instituto Butantan - Av. Dr. Vital Brazil, 1500 Butantã, São Paulo - SP, Brazil. 05503-900
3 School of Life and Environmental Sciences, Heydon-Laurence Building, A08, University of Sydney, NSW, 2006, Australia
4 Laboratório de Herpetologia, Departamento de Zoologia, Instituto de Ciências Biológicas, Campus Darci Ribeiro, Universidade de Bra-
sília - DF, Brazil. 70910-900
*Corresponding author. E-mail: serena_891@hotmail.com

Submitted on: 2016, 16th December; revised on: 2017, 24th February; accepted on: 2017, 29th July 
Editor: Giovanni Scillitani

Abstract. Enyalius perditus is a semi-arboreal lizard species whose reproduction is poorly known. Here, we combine 
information obtained from preserved and live specimens to describe the reproductive timing (vitellogenesis, gravid-
ity, and egg-laying) and fecundity (clutch size, egg size, and relative clutch mass) in females of E. perditus. Female 
reproduction is remarkably seasonal and occurs in the warmer and wetter periods of the year. Secondary vitellogenesis 
occurs from mid to late spring, whereas gravidity and egg-laying occur in early summer. Mating appears to be syn-
chronized with secondary vitellogenesis, indicating an associated reproductive cycle. We suggest that E. perditus females 
produce only a single clutch per reproductive season. Clutch size ranged from three to 11 eggs and was positively cor-
related with female body size. Finally, the relative clutch mass was high, a recurrent feature to “sit-and-wait” foragers.

Keywords. Clutch size, reproductive biology, reproductive cycle, seasonal reproduction.

Detailed information on the reproductive biology of 
a number of species is critical for elaborating and test-
ing ecological-evolutionary hypotheses and providing 
informed decisions on conservation strategies (Shine and 
Bonnet, 2009; Vitt, 2013). Despite the recent increase in 
the number of studies on the reproduction of Neotropi-
cal lizards (e.g., Balestrin et al., 2010; Ferreira et al., 2009; 
Vieira et al., 2001), knowledge about the reproductive 
biology of several species is still scarce. 

Enyalius is composed of insectivorous, diurnal, and 
semi-arboreal lizards (Jackson, 1978; Rautenberg and 
Laps, 2010; Sturaro and Silva, 2010; Barreto-Lima and 
Sousa, 2011; Barreto-Lima et al., 2013). Enyalius is dis-
tributed mostly in Atlantic Forest areas but some species 

may also occur in the Amazon Forest, forest galleries in 
‘Cerrado’, and isolated forested areas in ‘Caatinga’ (Barre-
to-Lima, 2012).

Enyalius perditus is commonly found in Atlantic for-
est areas in southeastern Brazil, where it may occur in 
sympatry with E. brasiliensis, E. iheringii, and E. bilineatus 
(Barreto-Lima, 2012). Many studies have addressed sev-
eral aspects of the natural history of the species, including 
feeding ecology, activity patterns, microhabitat use, sex-
ual dimorphism, and behavior (Barreto-Lima and Sousa, 
2006, 2011, Sturaro and Silva, 2010; Barreto-Lima et al., 
2013; Migliore et al., 2014). Recently, Migliore et al. (2014) 
summarized the reproductive information available for E. 
perditus and E. iheringii and found that published data is 



188 Serena Najara Migliore et alii

limited to punctual observations on clutch size, courtship 
and mating behavior, and timing of mating and gravid-
ity. This limited information impairs both an overview on 
the reproduction of the species and broad comparisons 
across other species. To fill this gap, we combine informa-
tion obtained from both museum and live specimens to 
describe the reproductive timing (vitellogenesis, gravidity, 
and egg-laying) and fecundity (clutch size, egg size, and 
relative clutch mass) in females of E. perditus.

We analyzed 35 sexually mature females of E. per-
ditus housed in six scientific collections from Brazil 
(Appendix 1). The specimens were mostly collected 
throughout the Atlantic forest domain. The climate in 
the area is seasonal and characterized by a distinct hot, 
rainy season from spring to summer (October-March) 
and a dry season from autumn to winter (April-Septem-
ber) associated with lower temperatures (Mendonça and 
Danni-Oliveira, 2007). Females were considered sexually 
mature if they contained vitellogenic follicles, oviductal 
eggs, or folded oviducts. For each individual, we record-
ed the: (1) snout-vent length (SVL) to the nearest 1 mm, 
(2) number of ovarian follicles or eggs, (3) diameter of 
the largest ovarian follicle, and (4) length and width of 
oviductal eggs. Additional observations on body sizes, 
egg-laying, egg size, and clutch size were obtained from 
two gravid females collected in the Biological Reserve of 
Boracéia, São Paulo state, on 8th December 2015. These 
females were kept in terrarium containing branches and 
leaf litter and allowed to oviposit naturally. Procedures 
for egg measurements and incubation were used accord-
ing to Migliore et al. (2014).

We determined the timing of secondary vitellogen-
esis using a scatterplot of the diameter of the largest ovar-
ian follicle (Almeida-Santos et al., 2014). Relative clutch 
mass (RCM) was calculated by dividing the total clutch 
mass by maternal body mass after oviposition + total 
clutch mass (Vitt and Price, 1982). We used simple linear 
regression to determine the relationship between mater-
nal SVL and clutch size (both log-transformed; King, 
2000) and significance was assumed at P ≤ 0.05. Mean 
values are always followed by ± standard deviation.

Body sizes of E. perditus females ranged from 58 to 
91 mm (mean = 74.7 ± 7.8 mm; n = 36). Females with 
follicles in primary vitellogenesis were found throughout 
the year (Fig. 1). Substantial increases in follicular size 
(and thus secondary vitellogenesis) were observed from 
mid to late spring (November-December; Fig. 1). Gravid 
females (n = 11) were observed in early-summer (Janu-
ary; Fig. 1). No female contained follicles in secondary 
vitellogenesis simultaneously with oviductal eggs. Egg-
laying was recorded in early summer (Table 1). The two 
wild-caught females laid eight and six eggs each on 26th 
December 2015 and 1st January 2016, respectively (Fig. 
1). All eggs spoiled over incubation due to fungal con-
tamination. Clutch size (including preserved and captive 
specimens) averaged 7.1 ± 2.4 eggs (range: 3-11 eggs; n 
= 13 clutches). Clutch size was positively correlated with 
maternal SVL (r = 0.70; n = 13; P = 0.008; Fig. 2). Egg 
length in all gravid females averaged 15.45 ± 1.36 mm 
(range: 12.45-17.80 mm; n = 92 eggs from 13 females) 
and egg width averaged 8.15 ± 0.56 mm (range: 7.38-

Fig. 1. Reproductive timing in females of Enyalius perditus. The 
graph shows the seasonal variation in the diameter of the larg-
est ovarian follicle or oviductal egg and the timing of egg-laying. 
Closed circle: ovarian follicles; open circle: oviductal eggs; arrows: 
egg-laying.

Table 1. Morphometrics of two clutches of Enyalius perditus from Biological Reserve of Boracéia, São Paulo state, Brazil. RCM: Relative 
clutch mass.

 Individual Date laid Clutch size
Female mass1 

(g) 
Total clutch 

mass (g)
RCM2

Egg length 
(mm)

Egg width 
(mm)

Egg mass 
(g)

Female 1 26 Dec 2015 8 12.3 6.91 0.36 16.71 ± 0.28 9.58 ± 0.12 0.86 ± 0.02
Female 2 1 Jan 2016 6 11.4 4.28 0.27 16.09 ± 0.43 8.66 ± 0.26 0.71 ± 0.01

1Post parition mass.
2RCM was calculated by dividing the total clutch mass by maternal body mass after oviposition plus total clutch mass (Vitt and Price, 1982).



189Reproduction in Enyalius perditus

9.58 mm; n = 92 eggs from 13 females). RCM for the two 
wild-caught females that laid eggs in captivity was 0.27 
and 0.36. 

Reproductive timing in E. perditus females is remark-
ably seasonal, with secondary vitellogenesis, gravid-
ity, and egg-laying occurring within three months, from 
November to January (see Sturaro and Silva, 2010; Bar-
reto-Lima and Sousa, 2011 for additional records of vitel-
logenesis and gravidity). Therefore, reproductive timing 
in E. perditus females is associated with the warmer and 
wetter periods of the year. Reproductive information for 
other Enyalius species is rather limited. However, the 
reproductive timing in E. perditus appears to be concen-
trated within a shorter period of time than other Enya-
lius from the Atlantic forest (Marques and Sazima, 2004; 
Teixeira et al. 2005; Rautenberg and Laps, 2011; Migliore 
et al., 2014). This short reproductive season in females 
of E. perditus suggests that females produce only a single 
clutch per reproductive season. Indeed, this is corrobo-
rated by the absence of females containing follicles in sec-
ondary vitellogenesis simultaneously with oviductal eggs 
(Almeida-Santos et al., 2014).

Associated reproductive cycles are common in lizards 
and consist of reproductive events in males and females 
(i.e., sperm production, mating, and ovulation) occurring 
at the same period (Crews and Gans, 1992; Méndez-de 
la Cruz et al., 2014). Courtship and mating in E. perdi-
tus have been reported in spring (November-December: 
Barreto-Lima and Sousa, 2006; Migliore et al., 2014) and 
thus are synchronized with the timing of secondary vitel-
logenesis and ovulation. This suggests that E. perditus 

exhibits associated reproductive cycles. However, histo-
logical investigations of the reproductive cycle of E. per-
ditus males are required to confirm if the species exhibits 
associated reproductive cycles.

Mean clutch size in E. perditus is low relative to at 
least three other congenerics (14.0 eggs in E. iheringii: 
Rautenberg and Laps, 2010; Migliore et al., 2014; 12.3 
eggs in E. leechi: Vitt et al., 1996; and 11.5 eggs in E. bra-
siliensis: Teixeira et al., 2005) but high relative to another 
congeneric (4.4 eggs in E. bilineatus: Teixeira et al., 2005). 
These differences may be explained by interspecific dif-
ferences in mean body size since all Enyalius species that 
showed higher clutch size than E. perditus also exhibited 
larger body sizes (see Rand, 1982; Vitt et al., 1996; Teix-
eira et al., 2005; Rautenberg and Laps, 2010). This idea is 
corroborated by our finding that the clutch size in E. per-
ditus increased with maternal SVL, as observed in other 
Enyalius (Teixeira et al., 2005; Vitt et al., 1996) and in 
many lizard species with variable clutch size (Fitch, 1970; 
Tinkle et al., 1970).

The RCM for E. perditus (0.27-0.36) is similar to that 
reported for a congeneric (0.38 in E. iheringii; Migliore 
et al., 2014). In lizards, RCM tends to be relatively low 
in “wide forager” species and relatively high in “sit-and-
wait” foragers (Vitt and Price, 1982). Females of Enyalius 
species appear to be “sit-and-wait” foragers (Sousa and 
Cruz, 2008; Borges et al., 2013) and move shorter dis-
tances than males (Barreto-Lima et al., 2013). The RCM 
for Enyalius is higher than the upper limit reported for 
other oviparous lizards that forage widely (~ 0.21) and 
consistent with values reported for “sit-and-wait” foragers 
(Vitt and Price, 1982), thus in agreement with the asso-
ciation between RCM and foraging tactics. 

ACKNOWLEDGEMENTS

We thank G. Puorto, P. R. Manzani, J. C. Moura-
Leite, M. R. S. Pires, R. N. Feio, and V. Silva for allowing 
access to specimens under their care, M. T. Rodrigues for 
providing some specimens, M. Teixeira-Junior for assis-
tance in field work. We also thank P. Monteiro, N. Torel-
lo-Vieira and K. Banci for criticism on an earlier draft. 
We thank CAPES (Coordenação de Aperfeiçoamento de 
Pessoal de Nível Superior) for providing financial support 
(Master’s scholarship to S. N. Migliore), SISBIO (Sistema 
de Autorização e Informação em Biodiversidade; permit 
number SISBIO 47011-4), and Butantan Institute Animal 
Ethics Committee (approval number 3491021015) for the 
permission to collect and maintain the lizard specimens 
at the Ecology and Evolution Lab–Butantan Institute.

Fig. 2. Relationship between maternal snout-vent length and clutch 
size (both log-transformed) in Enyalius perditus. Closed circles: 
data from preserved specimens; open circles: data from freshly laid 
clutches.



190 Serena Najara Migliore et alii

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APPENDIX

Appendix 1. List of museums and voucher specimens of Enyalius perditus examined. 

Collection (Abbreviation) Voucher number

Instituto Butantan, São Paulo, Coleção de Referência (IBSPCR) SÃO PAULO: São José do Barreiro (IBSPCR 407).

Museu de Zoologia, Universidade Estadual de Campinas (ZUEC)
SÃO PAULO: Ilhabela (ZUEC 2934, 2935, 2936, 2938, 2942), 
Ubatuba (ZUEC 1887).

Museu de Zoologia João Moojen (MZUFV) MINAS GERAIS: Lambari (MZUFV 633).

Coleção Herpetológica Alfred Russel Wallace (CHARW)
MINAS GERAIS: Lambari (CHARW 94, 155, 158, 160, 161, 194, 289, 
293, 296, 321), Alfenas (CHARW 322), Boa Esperança (CHARW 
317).

Coleção Herpetológica da Universidade Federal de Ouro Preto 
(UFOP)

MINAS GERAIS: Itatiaia, Serra de Ouro Branco (UFOP 939s, 968s, 
976s, 978s, 993s, 995s, 996s, 997s, 1042s, 1062s, 1077s, 1087s).

Museu de História Natural Capão da Imbuia (MHNCI) PARANÁ: Telêmaco Borba (MHNCI 3128, 12956, 12966).


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