Does Variation in Soil Water Content Induce Variation in the Size of Hatchling Snapping Turtles (Chelydra Serpentina)?
Most studies that have investigated the influence of hydric conditions during incubation on the size and quality of hatchling reptiles have used either vermiculite or sand as the incubation medium, and the applicability of data derived from eggs using one media type or the other to natural populations has had considerable debate. However, few studies have used soil from actual nesting areas as the incubation medium. In this study, I tested the influence of variation in substrate water content during incubation on the size of hatchling Snapping Turtles from southeastern Michigan using soil collected from actual Snapping Turtle nests. Eggs from six clutches were fully buried in sterilized soil that had been dried and then reconstituted to six different levels of hydration (3, 5, 7, 9, 11, and 13% gravimetric water content). Eggs in the driest soil (3%) had a slight net loss of mass over the course of incubation, whereas eggs in the wetter soils gained mass to varying degrees correlating positively with soil water content. Hatchling mass was significantly lower in the two driest soils than in the wetter soils. Carapace length was significantly shorter for hatchlings from the driest soil (3%) than for those from soils with 7% and 9% water contents, and significantly shorter for hatchlings from the wettest soil (13%) than for those from the 7, 9, and 11% water contents. Soil water contents measured adjacent to a single nest site over three consecutive field seasons ranged from 1.1 to 8.2%, with median water contents ≤ 5% in all three seasons. These findings support the hypothesis that normal variation in soil hydration can influence the size of hatchlings emerging from natural nests. The degree to which hatchling size varies with normal variation in soil water content, however, may have only minor impact on hatchling survivorship in light of other factors that could potentially influence hatchling survival in this species.Abstract
Variation in water content and estimated water potential at a single nest site over a three-year period.
(A) Example of soil water content (% water by mass) recording from single nest site during the 2004 field season. Data depicted are averaged between two dielectric soil moisture probes associated with the nest site. (B) Box and whisker plots describing variation in soil water content averaged between two dielectric soil moisture probes at same nest site among three different field seasons (2003–2005). Each box encloses 50% of the data with the median value of the variable displayed as a line. Top and bottom of the box mark limits of ± 25% of the variable population; “whiskers” extending from top and bottom of each box mark minimum and maximum values that fall within 1.5 × the inter-quartile distance (difference between upper and lower quartiles). Any value outside of this range (an outlier) is displayed as an individual point. (C) Box and whisker plots depicting variation in estimated soil water potential for nest site among three different field seasons (2003–2005). Soil water potential estimated from exponential curve (soil water potential = −121.74e−0.286x, R2 = 0.969) generated from measurements of water potential in soils with different gravimetric water contents at 25 C.
Changes in mean mass during incubation for eggs incubated in soil of six different water contents at 25 C.
Only eggs that survived to day 65 of incubation are included. Number of eggs in each soil moisture content are as follow: 3%: n = 12; 5%: n = 17; 7%: n = 17; 9%: n = 17; 11%: n = 19; 13%: n = 14.
(A) Duration of incubation, (B) live mass at hatching, and (C) carapace lengths at one week post-hatching for hatchlings from eggs incubated in soils of different water contents (by mass).
Data are presented as least-squares means ± SEM. Like letters indicate no significant difference between least-squares means (P > 0.025). Sample sizes in each treatment are as follow: 3%: n = 9; 5%: n = 10; 7%: n = 14; 9%: n = 16; 11%: n = 9; 13%: n = 8.
Contributor Notes
DEPARTMENT OF NATURAL, INFORMATION, AND MATHEMATICAL SCIENCES, INDIANA UNIVERSITY AT KOKOMO, KOKOMO, INDIANA 46904-9003.