Temporal and spatial variability in recruitment of a temperate, seagrass-associated fish is largely determined by physical processes in the pre- and post-settlement phases

Jenkins, Gregory P.; Black, Kerry P.; Wheatley, Melissa J; Hatton, David

doi:10.3354/meps148023

Cited by 85 publications

(96 citation statements)

References 18 publications

(32 reference statements)

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“…For example, S. punctata is a percoid, has a full compliment of fin elements, and falls within a size-range similar to that of reef fishes studied. However, Jenkins & Welsford (2002) found the swimming capabilities of S. punctata post-larvae to be relatively weak, which supports the contention (gained through hydrodynamic dispersal models) that recruitment into Port Phillip Bay is largely a passive process (Jenkins et al 1997(Jenkins et al , 1999.…”

Section: Introductionsupporting

confidence: 56%

“…Early in the recruitment period, most post-larvae are close to the entrance of Port Phillip Bay, but over time numbers decrease in this area and increase in seagrass beds further inside the bay towards the Geelong Arm (Jenkins et al 1996b). At present, hydrodynamic dispersal models and known larval behaviours have failed to explain the settlement of S. punctata to seagrass beds located in the Geelong Arm on the western side of Port Phillip Bay (Jenkins et al 1997(Jenkins et al , 1999. The aim of this study, using cage inclusion experiments, was to assess whether wave disturbance generated by onshore winds can facilitate secondary dispersal in S. punctata post-larvae.…”

Section: Introductionmentioning

confidence: 99%

“…Recent studies in shallow seagrass beds suggest that wave disturbance generated by onshore winds may facilitate secondary dispersal for a number of seagrassassociated fishes (Jenkins et al 1997, Moran et al 2003. One species that may be particularly susceptible to secondary dispersal is the King George whiting Sillaginodes punctata.…”

Section: Introductionmentioning

confidence: 99%

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Small-scale dynamics of secondary dispersal in a seagrass associated fish: a caging study

Moran¹,

Jenkins²,

Keough³

et al. 2004

Mar. Ecol. Prog. Ser.

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Secondary planktonic dispersal potentially alters recruitment patterns of marine organisms, but little is known about whether this process occurs in temperate fishes. This study investigated whether disturbance in seagrass beds, caused by onshore winds that induce high wave action, facilitated the resuspension and secondary dispersal of post-larval King George whiting Sillaginodes punctata (Cuvier). Cage inclusion experiments were conducted in seagrass beds within Port Phillip Bay, Australia. Live post-larvae were released into cages during 3 different wind conditions (onshore, alongshore and offshore) and their positions in the cage relative to the shoreline were recorded after 1 h. Significantly higher numbers of post-larvae were collected on the seaward side of cages during high waves associated with onshore winds. Of these post-larvae, higher numbers were collected with increasing onshore wind speed. Our results suggest that physical disturbance, at the seagrass-bed scale, has the potential to alter recruitment patterns of S. punctata by facilitating secondary dispersal.KEY WORDS: Physical disturbance · Secondary dispersal · Seagrass · Sillaginodes punctata · Post-larvae Resale or republication not permitted without written consent of the publisher

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Section: Introductionsupporting

confidence: 56%

Section: Introductionmentioning

confidence: 99%

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Small-scale dynamics of secondary dispersal in a seagrass associated fish: a caging study

Moran¹,

Jenkins²,

Keough³

et al. 2004

Mar. Ecol. Prog. Ser.

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“…In Port Phillip Bay (Victoria, Australia), postlarval abundances of King George whiting (Sillaginodes punctata) at seagrass sites are strongly correlated with zonal westerly winds, the main westerly wind belt over Tasmania, and are likely to be influenced by climate change (Jenkins et al 1997;Jenkins 2005).…”

Section: Ocean Currents and Wind Patternsmentioning

confidence: 99%

“…Sea-level rise in Australia may also directly affect estuarine and marine fish during their pre-and post-settlement phases. For example, Jenkins et al (1997) showed that spatial and temporal variability in recruitment of a temperate, seagrass-associated fish, King George whiting (Sillaginodes punctata), was largely determined by physical processes, including the residual sea level (caused by changes in barometric pressure). Other Australian commercial species that might be similarly affected include pink snapper (Pagurus auratus), southern sea garfish (Hyporhamphus melanochir), Australian herring (Arripis georgianus), whiting and mullet (Fletcher and Head 2006).…”

Section: Sea-level Risementioning

confidence: 99%

Detecting range shifts among Australian fishes in response to climate change

Booth

Bond

Macreadie

2011

Mar. Freshwater Res.

143

136

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Abstract. One of the most obvious and expected impacts of climate change is a shift in the distributional range of organisms, which could have considerable ecological and economic consequences. Australian waters are hotspots for climate-induced environmental changes; here, we review these potential changes and their apparent and potential implications for freshwater, estuarine and marine fish. Our meta-analysis detected ,300 papers globally on 'fish' and 'range shifts', with ,7% being from Australia. Of the Australian papers, only one study exhibited definitive evidence of climate-induced range shifts, with most studies focussing instead on future predictions. There was little consensus in the literature regarding the definition of 'range', largely because of populations having distributions that fluctuate regularly. For example, many marine populations have broad dispersal of offspring (causing vagrancy). Similarly, in freshwater and estuarine systems, regular environmental changes (e.g. seasonal, ENSO cycles -not related to climate change) cause expansion and contraction of populations, which confounds efforts to detect range 'shifts'. We found that increases in water temperature, reduced freshwater flows and changes in ocean currents are likely to be the key drivers of climateinduced range shifts in Australian fishes. Although large-scale frequent and rigorous direct surveys of fishes across their entire distributional ranges, especially at range edges, will be essential to detect range shifts of fishes in response to climate change, we suggest careful co-opting of fisheries, museum and other regional databases as a potential, but imperfect alternative.

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