Academic literature on the topic 'Snook ecology'

Research that identifies behavioral contingents, portions of a population that exhibit alternate life history strategies or habitat preferences, can provide a better understanding of a species’ resilience to disturbances, changes in environmental factors, and harvest. Sightings of the estuarine-dependent common snook Centropomus undecimalis at offshore reef areas throughout the year in southeast Florida prompted an investigation to determine whether a contingent of the snook population remains offshore year-round and if they can contribute to the inshore population. This study employed underwater visual observations, specimen collections, and acoustic telemetry over 7 yr to document and describe the snook that utilize offshore habitat. Fish were observed in groups of up to 225 individuals, 20.4 km from an inlet, and in waters up to 36.6 m deep. Snook were present in 79.4% of dive surveys conducted on artificial reefs but only in 18.4% of surveys on natural reefs. Acoustic telemetry showed that many fish remained offshore for multiple years. Most sampled fish (89.1%) were spawning capable, with some classified as actively spawning (15.8%). Reports of snook using offshore reefs occur elsewhere, including southwest Florida and the Florida Keys, indicating that this contingent behavior may not be unique to southeast Florida. Evaluating these occurrences and identifying potential triggers that prompt snook to leave the estuary for an offshore environment can aid in determining how the offshore contingent affects the overall population.

Disturbances that alter cross-habitat food web linkages can lead to whole-scale changes to aquatic systems. In coastal rivers of the Everglades (Florida, U.S.A.), increases in rainfall inundate adjacent floodplains, providing habitat for floodplain fish and macroinvertebrate species. In the dry season, rainfall decreases and floodplains dry, forcing floodplain prey into these river systems. These prey provide a prey subsidy for an estuarine predator, the common snook (Centropomus undecimalis). In 2011, severe drought impacted the region, likely affecting this prey subsidy. In this study, we ask (i) did the 2011 drought affect the magnitude and composition of floodplain prey subsidies to the common snook? and (ii) if species composition changed, were there energetic differences between the pre- and post-disturbance prey species? Results showed that 1 year after the drought, subsidies to the common snook decreased by 75%. On top of that decrease in overall flux, diet composition of the common snook switched from floodplain fishes to drought-tolerant floodplain macroinvertebrates. Lastly, energetic analyses showed that these postdrought macroinvertebrate prey subsidies had 43% less calories than floodplain fishes. Our findings illustrate the importance of considering not only the biomass that transfers from one food web to the next, but also how the species composition of the subsidy may affect incorporation into recipient food webs.

Between April and December 2000, seventy-nine specimens of Centropomus undecimalis from Angra dos Reis, coastal zone of the State of Rio de Janeiro (23º01'S, 44º19'W), Brazil, were necropsied to study their infracommunities of metazoan parasites. Nine species of metazoan parasites were collected: 1 digenean, 1 monogenean, 1 acantocephalan, 1 nematode, 4 copepods, and 1 isopod, and 96.2% of the fishes were parasitized by one or more metazoan, with mean of 85.3 ± 122.9 parasite/fish. The digenean Acanthocollaritrema umbilicatum Travassos, Freitas & Bührnheim represented the majority of the parasites specimens collected, totaling, 94.7%. This species was the most abundant, prevalent, and dominant, showing positive correlation with the host's total body length and parasite abundance. The copepod species Acantholochus unisagittatus Tavares & Luque presented differences in abundance in relation to sex of host. The mean diversity in the infracommunities of C. undecimalis was H = 0.095 ± 0.116, with no correlation with the host's total body length but correlated with the host's sex. No pair of parasite species showed positive or negative association or covariation. The dominance of digenean A. umbilicatum in the later juvenile common snook parasite community could be related with the predatory food habits of common snook and an apparent feeding transition period which might occasion great exposure to infective forms.

The common snook, Centropomus undecimalis, is an estuarine dependent sport fish that relies upon subtidal wetlands as nursery habitat. Despite the economic and recreational significance of this species, there are portions of its life history and biology that are poorly understood, particularly its early life history. Understanding juvenile snook use of wetland habitats is crucial given the rapid loss and degradation of these areas to anthropogenic impacts. Young-of-the-year snook were collected in pond and creek habitats of a single wetland system to assess early life ecology and habitat use. Proxies of habitat quality were used to determine which habitats within a small spatial scale were optimal for young-of-the-year snook recruitment. Results indicated that even on a very small spatial scale, differences in habitat use were apparent, whereby smaller snook initially recruited to pond habitats and dedicated all energy into growth. Upon reaching a size of at least 40 mm SL snook began an ontogenetic habitat shift and moved to the tidal creek habitat. There, snook began to store energy, thus becoming more robust. Stable carbon and nitrogen isotopic analyses confirmed the ontogenetic habitat shift and revealed that snook have high site fidelity within the pond and creek habitats. Stable isotopic analysis also indicated that YOY snook appear to feed at the third trophic level consuming neonatal poecilliids and shrimp, and ultimately rely on benthic microalgae and particulate organic matter as basal resources. Results of this study advance the knowledge of juvenile snook ecology and will likely have implications for resource managers who are responsible for preserving and restoring wetland habitats upon which juvenile snook rely.

Knowledge of fish habitat use and connectivity is critical for understanding the structure and dynamics of fish populations and, therefore, necessary for the implementation of successful fisheries management strategies. Tagging is an effective means of providing such information, and the elemental composition contained within fish otoliths is increasingly being used as a natural tag. The chemical composition of otoliths reflects the incorporation of elements from different water bodies and can thus be used to understand the habitat use, movements, and life history patterns of fishes. To assess the applicability of otolith elemental composition as a tagging technique within the Tampa Bay estuary, Florida, laser ablation-inductively coupled-plasma mass spectrometry (LA-ICP-MS) was used to analyze the elemental composition of otoliths from two estuarine-dependent fish species, Snook (Centropomus undecimalis) and Red Drum (Sciaenops ocellatus). Otolith elemental fingerprints can be used to quantify the proportion of juveniles from different nurseries that survive to join the sub-adult and adult fisheries, thus, providing resource managers with quantitative criteria to prioritize the most productive areas for conservation and restoration. To evaluate the use of otolith elemental fingerprinting in the Tampa Bay estuary, the spatial and temporal scales of chemical variation in otoliths collected from throughout Tampa Bay were examined by performing permutation-based multivariate analyses of variance (MANOVA) on the elemental data at several spatial (individual tributary, two-region, and three-region) and temporal (annual and seasonal) scales. Canonical Analysis of Principal Coordinates (CAP) was used to generate classifiers based on the otolith elemental fingerprints of juvenile fish, and `leave-one-out' cross-validation procedures indicated that the greatest classification accuracy was obtained by using the two-region model (upper vs. lower Tampa Bay) for both species (for Snook F=45.8, p=0.001, CAP cross-validation success=76%; for Red Drum F=9.7, p=0.001, CAP cross-validation success=87%). For both species, all temporal analyses at the inter-annual scale indicated that otolith elemental fingerprints were significantly different across years (two-way MANOVA; p Several environmental factors which may have contributed to the regional differences in otolith chemistry were examined, including physico-chemical parameters (surface measurements of salinity, dissolved oxygen, pH, and temperature taken at the time of sample collection), surficial geologic stratigraphy, and land development. Weak, but significant correlations were identified between some elements and physico-chemical parameters; however, instantaneous measurements taken at the time of fish collection may not have provided an accurate representation of the overall conditions experienced by the fish during the period in which the otolith material used in analyses had been deposited (2 - 4 weeks). A significant correlation between latitude and otolith Sr/Ca was found, likely corresponding to an increasing ambient gradient that occurs from the upper to lower bay (for Red Drum F=77.1, p=0.001; for Snook F=69.2, p=0.001). The Land Development Intensity metric was negatively correlated with otolith Li/Ca and Sr/Ca. While surficial geologic inputs may have also contributed to the elemental composition of otoliths, the relationships revealed by redundancy analyses (RDA) were somewhat unclear or contradictory. Once the appropriate chemical characterization of the study area was identified (the two-region models for both species), elemental fingerprints from the core portions of sub-adult and adult otoliths were assigned to their most probable juvenile habitat region using a maximum likelihood estimator based on the posterior probabilities generated by CAP analyses (CAP-MLE). Application of the two-region model revealed that the majority of Red Drum (83%) was determined to have originated from juvenile habitats in the upper Tampa Bay region, while most Snook (60%) originated from juvenile habitats in the lower Tampa Bay region. The majority of sub-adult/adult Snook and Red Drum were collected from the same region in which they were determined to have originated (for Snook, 36 out of 55 = 65%; for Red Drum, 58 out of 78 = 74%), indicating some level of site fidelity to juvenile habitat areas. The use of otolith elemental profiling to reconstruct specific environmental and physiological experiences has the potential to provide unique insights regarding the life histories of Snook, a species with unpredictable spawning and movement characteristics. Otoliths from Snook maintained in captivity at the Mote Aquaculture Park (MAP) were analyzed to elucidate the degree to which various factors, including otolith growth (macrostructure features), spawning events, handling stress, and salinity influence otolith chemistry. Cross-correlation analyses of otolith elemental profiles and quantified macrostructure features (including annuli and checks) demonstrated that interpretations of elemental patterns should not be confounded by changes associated with otolith crystallography. An elemental marker for known spawning events was not identified (ANOVA spawners vs. non-spawners, p>0.05); however, because the physiological costs and alterations in blood chemistry associated with gonadal maturation (rather than the singular act of spawning) could affect otolith chemistry, additional studies which more thoroughly track maturation stages may be able to identify a suite of elements that can be used to discern the reproductive histories of Snook. Significantly elevated Zn:Ca (ANOVA: F=5.64, p=0.012) and decreased Fe:Ca (ANOVA: F=25.02, p Continuous life history Ba:Ca and Sr:Ca profiles of 56 wild Snook collected from throughout Tampa Bay revealed significant plasticity in the types of juvenile habitats settled, as well as in the timing of ontogenetic movements from these habitats. Of the profiles examined, 55% exhibited otolith core signatures characterized by an opposing Sr:Ca and Ba:Ca pattern, followed by an inverted pattern, providing an indicator of the movement of larvae from high salinity, pre-settlement environments into mesohaline, tidally-influenced juvenile habitats. In contrast, nearly half (45%) the Sr:Ca and Ba:Ca profiles indicated settlement in higher salinity environments, suggesting a high degree of habitat plasticity for juveniles of this species. For fish that settled into mesohaline habitats, decreases in Ba:Ca and/or increases in Sr:Ca over the first several years of life signaled the ontogenetic transition out of the juvenile habitat, with the timing of emergence ranging from within the first year to age-3. Because conditions during early life may propagate into divergent behaviors in subsequent life stages, information on the experiences of early life and juvenile stages could help to inform whether the occupation of different juvenile habitat types, or the precocious or delayed emergence from those habitats, explain the peculiar spawning and movement habits that occur in this species.

Changes in global climate will likely increase climate variability. In turn, changes in climate variability have begun to alter the frequency, intensity, and timing of climate disturbances. Continued changes in the climate disturbance regime experienced by natural systems will undoubtedly affect ecological processes at every hierarchical scale. Thus, in order to predict the dynamics of ecological systems in the future, we must develop a more mechanistic understanding of how and in what ways climate disturbance affects natural systems. In South Florida, two climate disturbances recently affected the region, a severe cold spell in 2010, and a drought in 2011. Importantly, these disturbances affected an ecosystem of long-term, comprehensive, and persistent ecological study in the Shark River estuary in the Everglades National Park. The aims of my dissertation were to (1) assess the relative severity of these two climate disturbances, (2) identify effects of these disturbances on community structuring, (3) compare community change from the 2010 cold spell with community change from another extreme cold spell that affected sub-tropical China in 2008, (4) assess the effects of the drought on predator prey interactions in the Shark River and (5) apply a spatial approach to predicting population resistance to these events. My results show that the 2010 cold spell was the most severe cold event to affect the Shark River in the last 80 years, while the drought was the worst drought to occur in the last 10 years. The cold spell drove community change that was predictable based on the traits of component species, whereas community change was less predictable using trait-based approaches. When comparing community change from the extreme 2010 event in Florida with the event in China, I identified three consistencies related to community change from extreme cold events that occurred across both events that will help build generalized understanding of community resistance to increasingly extreme climate events in the future. From the trophic study, I found that the drought reduced prey for estuarine piscivores. Not only was prey biomass reduced, the drought drove a compositional shift in prey communities from fish to invertebrates, which are lower in calories. Last, I found that animal movement may create temporally dynamic resistance scenarios that should be accounted for when developing predictive models.

With the majority of Earth’s population living in coastal areas, estuarine ecosystems have been particularly affected by anthropogenic disturbances. My dissertation research focused on three interrelated types of human disturbance that affect estuaries: Anthropogenic alteration of freshwater inflow, the introduction of invasive species, and habitat alteration. Using the LoxahatcheeRiver(Jupiter, FL) as a model system, my goal was to understand how these disturbances affect estuarine organisms, particularly fishes. One of the most ecologically harmful disturbances affecting estuaries is anthropogenic alteration of freshwater inflow (and resulting changes in salinity patterns). To identify effects of freshwater inflow on the behavior of an ecologically and economically important fish (common snook Centropomus undecimalis), I conducted a 19-month acoustic telemetry study. Common snook were more abundant and made more frequent upstream migrations during the wet season, but freshwater inflow did not appear to be the proximate cause for these behaviors. Increased estuarine salinity resulting from anthropogenic flow alteration may have facilitated the second type of disturbance that I address in this dissertation; the invasion of non-native Indo-Pacific lionfish into estuarine habitats. During the course of my dissertation research, I documented the first ever estuarine invasion by non-native lionfish. Using mark-recapture, I identified high site fidelity in lionfish, a trait that may aid future control efforts. The extremely low minimum salinity tolerance that I identified in lionfish appears to have allowed the species to colonize far upriver in estuaries with anthropogenically modified salinity patterns. Anthropogenic salinity alteration has also led to a severe degradation of oyster reef habitats in theLoxahatcheeRiver. As a foundation species, oysters provide food, shelter, and nursery habitat for a wide variety of estuarine organisms, including many ecologically and economically important fishes. Increasingly, degraded oyster reef habitats have been the focus of restoration efforts. I identified a relatively rapid (< 2 years) convergence between restored and natural oyster reef communities, and documented the importance of vertical relief in restoration success. My dissertation research is critical for the management and conservation of coastal rivers inFlorida, while more broadly informing restoration and management decisions in many other estuarine and coastal ecosystems.