HEALTH ASSESSMENT OF WILD NORTHERN DIAMOND-BACKED TERRAPINS (MALACLEMYS TERRAPIN TERRAPIN) IN NEW JERSEY, USA.

A popular species in the pet trade, and therefore in the illegal wildlife trade, the diamond-backed terrapin, Malaclemys terrapin terrapin, population has seen significant declines. Associated with the illegal wildlife trade, occasions arise in which terrapins are confiscated, and no standard operating procedures exist for repatriation into the wild. To develop such procedures, an understanding of the pathogens circulating in the wild diamond-backed terrapin population in New Jersey is needed. We sampled 30 wild female diamond-backed terrapins for herpesvirus, Mycoplasmopsis, ranavirus, and intestinal and blood parasites and performed white blood cell counts and differentials and evaluated biochemistry values. Terrapins had an average age of 10 yr (8-15 yr), and 70% were gravid at the time of sampling. Thirty-three percent of the sampled northern diamond-backed terrapins were positive for Mycoplasmopsis sp., and all were negative for ranavirus and herpesviruses. Occasional blood parasites were found, and few intestinal parasites were noted. There was no significant difference between gravid status and any of the blood parameters (P<0.05). Blood chemistry values appeared to vary according to feeding activity; no differences were noted in the values in relation to gravid status. Four terrapins had heterophil to lymphocyte (H:L) ratios above 4.5, significantly higher than the other terrapins sampled, which may indicate inflammation. Two of the four had Mycoplasmopsis, one sample was contaminated by other bacteria and was discarded, and one was negative. No significant difference was found between Mycoplasmopsis infection status and H:L ratio (P=0.926). Our findings, though conducted on a small number of female terrapins at a specific time point, provide data on the pathogens that may be circulating in this population, adding to the current body of knowledge and helping to guide decision making for the reintroduction of confiscated diamond-backed terrapins into New Jersey's wild population.

Above vs. belowground plant biomass along a barrier island: Implications for dune stabilization.

Coastal regions are inherently and increasingly vulnerable and geomorphologically unstable, yet are invaluable economic and residential hubs. Dunes are dynamic buffers to erosion and the most natural, economical, and effective defense for coastal communities. Vegetation is integral to dune structure as it facilitates accretion and stabilization. Differences in the vegetation and root density likely translate to variability in coastal erosion prevention, but this notion has been largely unconsidered. We directly compared stabilizing factors, depth and density, of the root systems of two dominant mid-Atlantic dune plant species, native American beach grass (Ammophila breviligulata) and invasive Asiatic sand sedge (Carex kobomugi). Despite high plant density, C. kobomugi is targeted for removal in restoration efforts as its roots are assumed to provide less effective stabilization than A. breviligulata. We collected 30 cores and hand dug 14 A. breviligulata ramets at Island Beach State Park, New Jersey to examine biomass, root:shoot ratios, and root density. C. kobomugi had a more extensive root system with a root:shoot ratio of 11.36:1 compared to 1.62:1 for A. breviligulata. Similarly, cores 60 cm deep and 7.6 cm wide were sufficient to attain fully intact A. breviligulata roots, which did not extend deeper than 40 cm, but insufficient for C. kobomugi roots which extended beyond the sampling system vertically and horizontally. Scaling these findings to m(-2), aboveground biomass is relatively equal, but C. kobomugi had over 700% more root mass m(-2) than A. breviligulata. These results have strong implications for dune management. The root system of C. kobomugi may be better adapted to stabilize dunes and thus protect coastal areas during small and large-scale perturbations than previously supposed. This is a unique situation whereby the creation of monocultures will hyperstabilize dunes and make them more resistant to erosion at the cost of reduced biodiversity within the framework of resiliency.

Artificial nesting habitats as a conservation strategy for turtle populations experiencing global change.

Diamondback terrapins (Malaclemys terrapin) inhabit estuaries in eastern USA and may tolerate salinity of sea-water for short durations. Many North American estuaries are adversely affected by anthropogenic impacts, such as pollution, dredging and invasion by non-native plants. Many nesting areas have been altered or destroyed, causing terrapins to nest on roadsides and artificial islands made of dredged substrate from bottom sediments. Shading by non-native plants may suppress development and reduce survival of embryos. In Barnegat Bay, New Jersey, USA, there is a mosaic of natural and degraded terrapin nesting habitats. We investigated the effects of dredge soil and shade on the hatching success of diamondback terrapins to determine whether nesting habitat could be increased by using dredged bottom sediments. In year 1, unshaded nests in natural loamy-sand had the highest hatching success (55.2%), while nests in dredge soil produced no hatchlings. In year 2, nests in unshaded loamy-sand had a hatching success of 85.3%, whereas those in dredge soil, aged 1 year, had a hatching success of 59.4%. Dredge soil improved as an incubation substrate after aging 1 year by the washout of salt. Nest temperatures were generally cool and produced mostly male hatchlings. Uncontaminated dredge soil may provide suitable nesting substrates for diamondback terrapins if used after one year, and may be particularly beneficial if used for constructing islands that provide new nesting sites with reduced access of mammalian predators.