Browsing by Subject "bottlenose dolphin"
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Item Open Access Determining the northern range of the NNCES stock of bottlenose dolphins (Tursiops truncatus) through photo-identification(2018-04-27) Young, AlainaThe Roanoke Sound is an important summer habitat for coastal Atlantic bottlenose dolphins, including members of the Northern North Carolina Estuarine System (NNCES) stock. However, our understanding of the northern range of this stock is limited. It has been assumed that the stock occurs northward only as far as the NC/VA border, but there is considerable uncertainty in the location of this boundary. The objective of the present study was to better delineate this boundary by determining the northern range of individual dolphins sighted in Roanoke Sound. I matched individuals with high capture probabilities (n=59) in Roanoke Sound (NC-OBXCDR catalog) with individuals sighted in Norfolk, Virginia (VA-HDR catalog), the Potomac (MD-PCDP) catalog, and Cape May, NJ (NJ-CMWWRC catalog) through the MABDC. Five individuals, all likely females, were matched to VA-HDR, but none were matched to MD-PCP nor to NJ-CMWWRC. Four of the matched individuals were also sighted in the Pamlico Sound. The movements of these dolphins show some degree of seasonality, with sightings in the Roanoke Sound peaking in June but occurring from May to October, and in Virginia only in July and August. The results of my study indicate that the NC/VA border is not the northern boundary of the NNCES stock, but instead that the movement of these dolphins extends into the Chesapeake Bay. Thus, the management of this stock of dolphins should consider the threats, including by-catch, that may occur in this extended range.Item Open Access Occurrence of depredation by common bottlenose dolphins (Tursiops truncatus) on reef fish captured and released by rod and reel fisheries in the northeastern Gulf of Mexico(2021-04-30) Grewal, Corie E.In the northeastern Gulf of Mexico, depredation by common bottlenose dolphins (Tursiops truncatus) on rod and reel fishing gear leads to increased costs for anglers and serious injury and mortality for dolphins. I analyzed data collected from the Florida Fish and Wildlife Conservation Commission fisheries-dependent monitoring at-sea observer program to determine contributing factors to, spatial distribution of, and frequency of interactions for bottlenose dolphin depredation from 2009-2020. The dataset included 110,575 observations, of which 269 were recorded depredation events. I chose potential predictive factors from the dataset based on their known or hypothesized influence on dolphin behavior and used a generalized linear model to examine relationships between instances of depredation and these predictive factors. The number of anglers fishing, two geographic areas (Panama City and Destin, FL), years 2015 and 2017-2019, and captured fish families Lutjanidae (snapper family), Carangidae (jack family), and Serranidae (grouper and sea bass family) were significant predictive factors in the model. These results, as well as the results of a spatial analysis and an examination of the frequencies of these predictors suggest that food provisioning in the Florida panhandle is a driver of depredation and that the incidence of depredation is increasing over time. Bottlenose dolphins from the Gulf of Mexico northern and eastern coastal stocks have become conditioned to exhibit a range of low cost foraging techniques such as scavenging and begging, and depredation is an augmentation of those behaviors. Lutjanidae species were observed in 78% of depredation events and the family was the most significant factor in the model, revealing a regional prey preference for snapper. This study can help inform management and mitigation of bottlenose dolphin depredation in the Gulf of Mexico and provides a baseline for future scientific study.Item Open Access Occurrence, Distribution and Reproductive Status of Female Bottlenose Dolphins (Tursiops truncatus) in Roanoke Sound, NC(2020-04-23) Reibel, WaverlyI examined the spatial distribution of bottlenose dolphin (Tursiops truncatus) nursery groups in Roanoke Sound, NC, to gain insight into how environmental parameters affect site fidelity, and to determine whether habitat use patterns change based on the reproductive state of females. For mature females, I compiled information on interbirth intervals and length of calf dependency to obtain a more comprehensive picture of the ecology and life history of this age-sex class of estuarine dolphins. I analyzed photo-identification data from Roanoke Sound to compare the location and extent of kernel density estimates of home ranges for nursery groups, non-nursery groups and individual females. Many nursery groups are observed in this area during spring and summer, leading to the hypothesis that Roanoke Sound is an important nursery habitat. The importance of this area to lactating females may be attributable to its relatively shallow depth and abundant seagrass beds, which provide protection and a relatively plentiful supply of prey. In Roanoke Sound, nursery groups (n = 170) were significantly (p < 0.00001) larger than non-nursery groups (n = 68) with a mean of 12 individuals per sighting, while non-nursery groups averaged 4 individuals. Nursery groups and non-nursery groups had a high overlap percentage between ranging patterns, with home ranges overlapping 88%. This demonstrates that there is no specific “nursery area” within the Roanoke Sound, but coupled with the high numbers of large nursery groups sighted during the summer, the entire site itself may be of importance to these females. Four focal females had a mean interbirth interval of 7.5 years, and a mean length of calf dependency of 4.75 years. The females exhibited individual variation in ranging patterns, with habitat use overlap between nursery and non-nursery areas ranging from 11-79%. These females may be choosing areas based on their needs (and those of their calves), either for energetic purposes or protection. Documentation of nursery habitat can aid protection of these important areas through implementation of measures such as safe boating zones and increased water quality monitoring, as well as assist in the development of educational materials.Item Open Access The Influence of Genetic Variation on Susceptibility of Common Bottlenose Dolphins (Tursiops truncatus) to Harmful Algal Blooms(2014) Cammen, Kristina MarstrandThe capacity of marine organisms to adapt to natural and anthropogenic stressors is an integral component of ocean health. Harmful algal blooms (HABs), which are one of many growing threats in coastal marine ecosystems, represent a historically present natural stressor that has recently intensified and expanded in geographic distribution partially due to anthropogenic activities. In the Gulf of Mexico, HABs of Karenia brevis occur almost annually and produce neurotoxic brevetoxins that have been associated with large-scale mortality events of many marine species, including the common bottlenose dolphin (Tursiops truncatus). The factors resulting in large-scale dolphin mortality associated with HABs are not well understood, particularly in regards to the seemingly different impacts of HABs in geographically disjunct dolphin populations. My dissertation investigates a genetic basis for resistance to HABs in bottlenose dolphins in central-west Florida and the Florida Panhandle. I used both genome-wide and candidate gene approaches to analyze genetic variation in dolphins that died putatively due to brevetoxicosis and live dolphins from the same geographic areas that survived HAB events. Using restriction site-associated DNA sequencing, I identified genetic variation that suggested both a common genetic basis for resistance to HABs in bottlenose dolphins across the Gulf coast of Florida and regionally specific resistance. Many candidate genes involved in the immune, nervous, and detoxification systems were found in close genomic proximity to survival-associated polymorphisms throughout the bottlenose dolphin genome. I further investigated two groups of candidate genes, nine voltage-gated sodium channel genes selected because of their putative role in brevetoxin binding and four major histocompatibility complex (MHC) loci selected because of their genomic proximity to a polymorphism exhibiting a strong association with survival. I found little variation in the sodium channel genes and conclude that bottlenose dolphins have not evolved resistance to HABs via mutations in the toxin binding site. The immunologically relevant MHC loci were highly variable and exhibited patterns of genetic differentiation among geographic regions that differed from neutral loci; however, genetic variation at the MHC also could not fully explain variation in survival of bottlenose dolphins exposed to HABs. In my final chapter, I consider the advantages and drawbacks of the genome-wide approach in comparison to a candidate gene approach and, as laid out in my dissertation, I recommend using both complementary approaches in future investigations of adaptation in genome-enabled non-model organisms.