Acta Herpetologica 11(2): 221-225, 2016

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

DOI: 10.13128/Acta_Herpetol-17842

Notes on the reproductive ecology of the rough-footed mud turtle 
(Kinosternon hirtipes) in Texas, USA

Steven G. Platt1, Dennis J. Miller2, Thomas R. Rainwater3,*, Jennifer L. Smith4

1 Department of Biology, Box C-64, Sul Ross State University, Alpine, TX 79832, USA
2 Box 792, Alpine, Texas 79831, USA. Present address: Wildlife Conservation Society, Myanmar Program, Office Block C-1, Aye Yeik 
Mon 1st Street, Hlaing Township, Yangon, Myanmar
3 Tom Yawkey Wildlife Center & Belle W. Baruch Institute of Coastal Ecology and Forest Science, Clemson University, Georgetown, 
South Carolina 29440, USA. * Corresponding author. E-mail: trrainwater@gmail.com
4 Department of Biology, New Mexico State University-Alamogordo, Alamogordo, New Mexico 88310, USA

Submitted on 2016, 20th January; revised on 2016, 25th June; accepted on 2016, 27th June 
Editor: Paolo Casale

Abstract. Kinosternon hirtipes is among the least-studied North American turtles and little is known concerning 
reproduction. In the United States, K. hirtipes occurs at < 10 sites within a single creek drainage in Presidio County, 
Texas where it is considered a threatened species. We investigated the reproductive ecology of one of these popula-
tions at Plata Wetland Complex in 2007. We captured nine female K. hirtipes in wire mesh traps and hoop nets baited 
with fish. Eggs were obtained by injecting females with oxytocin. We recovered 19 eggs from six females captured in 
May and June. The smallest female that produced eggs was about 7.1 years old. Mean (± 1SD) clutch size, egg length, 
egg width, egg mass, and clutch mass were 3.1 ± 1.4 eggs, 28.7 ± 1.4 mm, 17.5 ± 0.9, 5.3 ± 0.6 g, and 17.5 ± 0.8 g, 
respectively. Relative egg mass and relative clutch mass were 0.035 and 0.011, respectively. There was a significant, 
positive linear relationship between female carapace length (CL) and egg width. The relationship between CL and rel-
ative egg mass was negative, and approached statistical significance. Relationships between CL and clutch size, egg 
length, and egg mass were not significant. Reproductive attributes of K. hirtipes in Texas are similar to those reported 
from a population in Mexico. 

Keywords. Clutch size, egg size, Kinosternon hirtipes, reproduction, threatened species, Texas. 

The rough-footed mud turtle (Kinosternon hirtipes) is 
a highly variable species comprising six recognized sub-
species distributed from west Texas, USA, southwards 
into Chihuahua, Mexico, and south and east on the Mexi-
can Plateau to the Chapala, Zapotlán, San Juanico, Pátzc-
uaro, and Valle de México basins (Iverson, 1981; Legler 
and Vogt, 2013). Kinosternon hirtipes murrayi is the larg-
est subspecies (straight-line carapace length [CL] to 196 
mm; Smith et al., 2015) and has the most extensive distri-
bution, occurring from west Texas and Chihuahua, south 
into northern Jalisco, northern Michoacan, and eastern 
Estado de Mexico (Iverson, 1981; Legler and Vogt, 2013). 

The northernmost populations of K. hirtipes (sensu lato) 
occur in Presidio County, Texas where < 10 small, iso-
lates are known from the Alamito Creek drainage (Ernst 
and Lovich, 2009; Platt and Medlock, 2015). Kinosternon 
hirtipes is considered a threatened species by Texas Parks 
and Wildlife Department (2013) owing to a limited geo-
graphic distribution within the state and on-going habitat 
degradation. 

Kinosternon hirtipes ranks among the least-studied 
North American turtles and many aspects of its natural 
history remain poorly known (Lovich and Ennen, 2013). 
In particular, there is a notable paucity of information on 



222 Steven G. Platt et alii

reproductive ecology. Iverson et al. (1991) investigated 
reproduction among a population in Chihuahua, Mexico, 
and laboratory studies indicate that hatchling sex is deter-
mined by incubation temperature (Ewert et al., 2004); 
otherwise the reproductive ecology of K. hirtipes has gone 
unreported. Importantly, published reports of reproduc-
tion among the remnant K. hirtipes populations in Texas 
are lacking, although such natural history data are criti-
cal for designing effective conservation measures (Dayton, 
2003). We here report on the reproductive ecology of one 
of the few known K. hirtipes populations in Texas. 

Our study was conducted at Plata Wetland Complex 
(PWC; elevation = 1125 m), located on a private ranch 
in the Alamito Creek drainage approximately 56 km SE 
of Marfa in Presidio County, Texas. PWC consists of four 
livestock tanks (ponds): Railroad (612 m2), Crotalus (900 
m2), Turner One (2520 m2), and Turner Two (3780 m2). 
Railroad Tank is fed by an artesian spring and linked to 
Crotalus Tank by a shallow drainage ditch about 244 m 
long. Turner One is located approximately 190 m from 
Railroad Tank and water is supplied by rainfall and a 
wind-driven pump. Turner Two is approximately 245 m 
from Turner Tank One and reliant on rainfall for water. 
Because Railroad and Crotalus Tanks are spring fed, 
water levels remain relatively stable throughout the year 
with a maximum depth of about 1.5 m. Water depth in 
Turner Tanks One and Two varies depending on seasonal 
rainfall (less so at Turner One); maximum depth in each 
is about 1.2 m. The environmental characteristics of the 
study site are described in greater detail elsewhere (Wil-
de and Platt, 2011; Platt et al., 2016). Regional climate 
is characterized by mild winters (rarely < 0 °C) and hot 
summers (> 40 °C) with highly variable annual rainfall 
(mean ca. 370 mm) (Powell, 1998).

We trapped turtles at PWC from April through mid-
July, and September 2007 as part of a larger population 
study of K. hirtipes conducted in the Alamito Creek 
drainage (2007-2010). We captured turtles using a com-
bination of wire mesh funnel traps (1.0 m long × 50 cm 
diameter; mesh = 12.5 mm) and hoop nets (2.5 m long 
× 1.0 m diameter; mesh = 25 mm). Traps and hoop 
nets were baited with sardines (packed in oil or water) 
or fresh carcasses of locally captured sunfish (Lepomis). 
Wire mesh traps were set from mid-morning to early 
evening (ca. 1000-2030 hr) and checked at intervals of 
1-2 hours. Hoop nets were deployed in mid-morning (ca. 
1030) on one day and checked the following morning. 
Each captured turtle was permanently marked by shell 
notching (Cagle, 1939) and then measured (CL and plas-
tron length [PL]) with dial (± 0.1 mm) or tree calipers (± 
1.0 mm) depending on body size. Body mass (BM) was 
determined with spring scales (± 1.0 g). Turtles with a CL 

≥ 100 mm were sexed using external secondary sexual 
characteristics (Iverson 1985b). We were unable to relia-
bly determine the sex of turtles below this size threshold. 

Male and juvenile turtles were processed in the field 
and released, while females were returned to the lab and 
held in plastic wading pools for 21-24 days to insure that 
oviducal eggs were fully shelled. We then induced ovipo-
sition by injecting oxytocin into the pectoral muscles at a 
dosage of 2.0 units/100 g of body mass (Ewert and Legler, 
1978). Following the injection, each female was placed 
in a 38 liter tub half-filled with water and fitted with a 
wire-mesh grate positioned 5 cm above the bottom; this 
allowed eggs to fall through and prevented accidental 
trampling by the female (Platt et al., 2008; Legler and 
Vogt, 2013). A second injection was administered with-
in 24 hours to insure deposition of the complete clutch. 
Most eggs were removed from the tub 10-20 minutes 
after deposition, although a few remained underwater for 
somewhat longer; all eggs were recovered < 1 hour after 
being deposited. Eggs were then weighed on an Ohaus 
triple beam balance (± 0.1 g), and measured (length and 
width) with dial calipers (± 0.1 mm). Following Iverson 
et al. (1991) we calculated relative clutch mass (RCM) 
[clutch mass / (gravid female body mass — clutch mass) 
× 100] and relative egg mass (REM) [RCM/clutch size]. 
Female turtles were released at their respective capture 
sites 24-48 hours after oviposition. We used linear regres-
sion to explore relationships between female body size 
and clutch and egg attributes. Statistical analyses were 
performed by program JMP (version 3.2, SAS Institute, 
Cary, North Carolina, USA). General statistical references 
are from Zar (1996). Mean values are presented as ± 1SD, 
and results were considered significant at P ≤ 0.05. 

We captured 87 turtles (25 males, nine females, and 
53 juveniles) at PWC. We treated the females (mean 
CL = 142 ± 15 mm; range = 121-163 mm) captured in 
May-June with oxytocin, and recovered 19 eggs from 
six females (CL = 132-159 mm) in late June (Table 1). 
Based on von Bertalanffy growth models (Fabens, 1965) 
developed for this population (Smith, 2016), the smallest 
female in our sample that produced eggs was estimated 
to be 7.1 years old. There was a significant positive lin-
ear relationship between egg width (EW) and CL (R = 
0.91; F1, 5 = 20.72; P = 0.0104; Fig. 1). The relationship 
between CL and relative egg mass (REM) was negative 
(REM = -0.0002CL + 0.04) and approached statistical sig-
nificance (R = 0.76; F1, 5 = 5.52; P = 0.0785). The relation-
ships between CL and clutch size (R = 0.03; P = 0.94), egg 
length (R = 0.02; P = 0.96), and egg mass (R = 0.68; P = 
0.13) were not significant. 

Our data provide the only information on the repro-
ductive ecology of K. hirtipes outside of Mexico (Iverson 



223Kinosternon hirtipes reproduction

et al., 1991). The clutch size (mean and range) we report 
for K. hirtipes in Texas is almost identical to the clutch 
size estimated from corpora lutea counts in Chihuahua, 
Mexico (3.0 ± 0.8 eggs; range = 1-5 eggs; n = 34; Iver-
son et al. 1991). However, it should be noted that egg 
retention can occur after oxytocin injections (Congdon 
and Gibbons, 1985) and without taking radiographs of 
females (Gibbons and Greene, 1979), we cannot be cer-
tain that females deposited a complete clutch. Therefore, 
the clutch size we report is best considered a conservative 
estimate. That said, Tucker (2007) found that clutch size 
in a group of female red-eared sliders (Trachemys scripta 
elegans) treated with oxytocin was statistically equiva-
lent to clutch size in natural nests. Although Iverson et 
al. (1991) found a positive correlation between clutch 
size and CL in K. hirtipes, no such relationship was evi-
dent in our study, possibly owing to the small number of 
females we sampled. Because K. hirtipes deposits multiple 
clutches during a single reproductive season (Iverson et 

al., 1991), CL may be a more suitable predictor of total 
annual fecundity rather than individual clutch size. 

The values we report for egg mass (EM), egg length 
(EL), and egg width (EW) are similar to those from a 
much larger sample of K. hirtipes in Mexico (EM = 4.8 
± 1.0 g; range = 3.7-6.5 g; n = 11; EL = 28.8 ± 1.8 mm; 
range = 24.1-33.2 mm; n = 74; EW = 16.3 ± 0.8 mm; 
range = 14.6-18.5; n = 74; Iverson et al., 1991). Because 
females in our study deposited eggs directly into the 
water and these remained submerged for varying (but 
usually brief ) periods, it is possible some eggs absorbed 
water and increased in mass (e.g., Wilgenbusch and 
Gantz, 2000). However, any increase in mass was prob-
ably minimal as most eggs were retrieved < 20 minutes 
after deposition. Clutch mass (CM) and relative clutch 
mass (RCM) were also similar to values reported by Iver-
son et al. (1991) among K. hirtipes in Mexico (CM = 14.4 
± 4.3 g; range = 6.7-29.4 g; n = 28; RCM = 0.071 ± 0.014; 
range = 0.048-0.105; n = 28). The negative relationship 
between REM and body size reported by Iverson et al. 
(1991) was likewise evident in our data, although of mar-
ginal statistical significance. This relationship suggests a 
decreased investment in each egg with increasing mater-
nal body size (Iverson et al., 1991). 

Similar to our results, Iverson et al. (1991) found a 
significant positive relationship between female CL and 
mean egg width. This relationship is not unexpected if 
egg width is determined by the pelvic aperture diameter 
which in turn scales to body size (Congdon and Gibbons, 
1987). However, evidence for pelvic aperture constraints 
on egg size in kinosternids is conflicting (Macip-Rios 
et al., 2013). Some studies suggest egg width is deter-
mined by pelvic morphology (Wilkinson and Gibbons, 
2005; Macip-Rios et al., 2012, 2013), while others found 
no evidence for such constraints (Iverson, 1991; Macip-
Ríos et al., 2009; Lovich et al., 2012; Macip-Rios et al., 
2013). Larger female K. hirtipes are producing larger 
eggs and according to Iverson et al. (1991), this increase 
is achieved by increases in egg width rather than length, 
which is probably constrained by oviduct length. 

The two smallest mature females with corpora lutea 
found by Iverson et al. (1991) in Mexico had CLs of 
99.4 and 97.4 mm, a body size very similar to the small-
est females exhibiting secondary sexual characteristics in 
our study population. However, the smallest female from 
which we recovered eggs was considerably larger (CL = 
132 mm). Despite this difference between the two popu-
lations, growth models suggest sexual maturity is attained 
at approximately the same age in Texas (7-8 years) and 
Mexico (6-8 years; Iverson et al., 1991). Obviously given 
our small sample size of reproductive females, further 
study is necessary to fully address this question.

Table 1. Attributes of clutches obtained from six female Kinosternon 
hirtipes collected in Presidio County, Texas, USA. *See text for dis-
cussion of potential methodological biases. 

Attribute n Mean ± 1 SD Range

Clutch size* 6 3.1 ± 1.4 1–5
Egg length (mm) 19 28.7 ± 1.4 24.7–30.8
Egg width (mm) 19 17.5 ± 0.9 15.0–18.7
Egg mass (g)* 19 5.3 ± 0.6 3.6–6.4
Mean clutch mass (g)* 6 17.5 ± 8.8 5.3–29.1
Relative clutch mass* 6 0.035 ± 0.019 0.009–0.061
Relative egg mass* 6 0.011 ± 0.002 0.008–0.015
 

Carapace length (mm)
130 140 150 160

E
gg

 w
id

th
 (m

m
)

16.0

16.5

17.0

17.5

18.0

18.5

r2 = 0.83
p = 0.0104

 

 
Fig. 1. Relationship between carapace length and egg width in a 
sample (n = 6) of female Kinosternon hirtipes murrayi from Presidio 
County, Texas, USA.



224 Steven G. Platt et alii

ACKNOWLEDGEMENTS

This research was conducted under a scientific 
research permit (SPR-0307-844) issued to SGP by the Tex-
as Department of Parks and Wildlife, with the approval of 
the Sul Ross State University (SRSU) Institutional Animal 
Care and Use Committee. Support for this project was 
provided by Research Enhancement Grants from SRSU 
to SGP. We thank Lewis Medlock for field assistance and 
Hardrock Mining Company for allowing us to conduct 
research on their property. 

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