32
views
0
recommends
+1 Recommend
0 collections
    0
    shares
      • Record: found
      • Abstract: found
      • Article: found
      Is Open Access

      Rethinking competence in marine life cycles: ontogenetic changes in the settlement response of sand dollar larvae exposed to turbulence

      research-article

      Read this article at

      Bookmark
          There is no author summary for this article yet. Authors can add summaries to their articles on ScienceOpen to make them more accessible to a non-specialist audience.

          Abstract

          Complex life cycles have evolved independently numerous times in marine animals as well as in disparate algae. Such life histories typically involve a dispersive immature stage followed by settlement and metamorphosis to an adult stage on the sea floor. One commonality among animals exhibiting transitions of this type is that their larvae pass through a ‘precompetent’ period in which they do not respond to localized settlement cues, before entering a ‘competent’ period, during which cues can induce settlement. Despite the widespread existence of these two phases, relatively little is known about how larvae transition between them. Moreover, recent studies have blurred the distinction between the phases by demonstrating that fluid turbulence can spark precocious activation of competence. Here, we further investigate this phenomenon by exploring how larval interactions with turbulence change across ontogeny, focusing on offspring of the sand dollar Dendraster excentricus (Eschscholtz). Our data indicate that larvae exhibit increased responsiveness to turbulence as they get older. We also demonstrate a likely cost to precocious competence: the resulting juveniles are smaller. Based upon these findings, we outline a new, testable conception of competence that has the potential to reshape our understanding of larval dispersal and connectivity among marine populations.

          Related collections

          Most cited references27

          • Record: found
          • Abstract: found
          • Article: not found

          Temperature or Transport? Range Limits in Marine Species Mediated Solely by Flow.

          Clusters of range boundaries in coastal marine species often occur at shoreline locations where major nearshore ocean currents collide. Observing that these currents are typically composed of waters with quite different physical characteristics, biologists have traditionally assumed that high local densities of marine range limits result primarily from the strong water property gradients (particularly in temperature) that arise at oceanographic discontinuities. However, this view may overlook the potential for ocean flows themselves to generate distributional pattern. Here we explore this possibility in more detail using an extension of a coupled population dispersal model developed previously for benthic marine species with dispersing larvae. Results suggest that simple, common flow fields often observed in association with biogeographic boundaries worldwide may have the potential to constrain a species' geographic range, even when suitable habitat outside that range is abundant. Model predictions suggest that these boundaries can function as one- or two-way barriers to range expansion and may be differentially permeable, with boundary leakiness depending on life-history characteristics and the degree of temporal variability in the nearshore flow field.
            Bookmark
            • Record: found
            • Abstract: found
            • Article: not found

            Sound as an orientation cue for the pelagic larvae of reef fishes and decapod crustaceans.

            The pelagic life history phase of reef fishes and decapod crustaceans is complex, and the evolutionary drivers and ecological consequences of this life history strategy remain largely speculative. There is no doubt, however, that this life history phase is very significant in the demographics of reef populations. Here, we initially discuss the ecology and evolution of the pelagic life histories as a context to our review of the role of acoustics in the latter part of the pelagic phase as the larvae transit back onto a reef. Evidence is reviewed showing that larvae are actively involved in this transition. They are capable swimmers and can locate reefs from hundreds of metres if not kilometres away. Evidence also shows that sound is available as an orientation cue, and that fishes and crustaceans hear sound and orient to sound in a manner that is consistent with their use of sound to guide settlement onto reefs. Comparing particle motion sound strengths in the field (8 x 10(-11) m at 5 km from a reef) with the measured behavioural and electrophysiological threshold of fishes of (3 x 10(-11) m and 10 x 10(-11), respectively) provides evidence that sound may be a useful orientation cue at a range of kilometres rather than hundreds of metres. These threshold levels are for adult fishes and we conclude that better data are needed for larval fishes and crustaceans at the time of settlement. Measurements of field strengths in the region of reefs and threshold levels are suitable for showing that sound could be used; however, field experiments are the only effective tool to demonstrate the actual use of underwater sound for orientation purposes. A diverse series of field experiments including light-trap catches enhanced by replayed reef sound, in situ observations of behaviour and sound-enhanced settlement rate on patch reefs collectively provide a compelling case that sound is used as an orientation and settlement cue for these late larval stages.
              Bookmark
              • Record: found
              • Abstract: found
              • Article: not found

              Testing the molecular clock: molecular and paleontological estimates of divergence times in the Echinoidea (Echinodermata).

              The phylogenetic relationships of 46 echinoids, with representatives from 13 of the 14 ordinal-level clades and about 70% of extant families commonly recognized, have been established from 3 genes (3,226 alignable bases) and 119 morphological characters. Morphological and molecular estimates are similar enough to be considered suboptimal estimates of one another, and the combined data provide a tree that, when calibrated against the fossil record, provides paleontological estimates of divergence times and completeness of their fossil record. The order of branching on the cladogram largely agrees with the stratigraphic order of first occurrences and implies that their fossil record is more than 85% complete at family level and at a resolution of 5-Myr time intervals. Molecular estimates of divergence times derived from applying both molecular clock and relaxed molecular clock models are concordant with estimates based on the fossil record in up to 70% of cases, with most concordant results obtained using Sanderson's semiparametric penalized likelihood method and a logarithmic-penalty function. There are 3 regions of the tree where molecular and fossil estimates of divergence time consistently disagree. Comparison with results obtained when molecular divergence dates are estimated from the combined (morphology + gene) tree suggests that errors in phylogenetic reconstruction explain only one of these. In another region the error most likely lies with the paleontological estimates because taxa in this region are demonstrated to have a very poor fossil record. In the third case, morphological and paleontological evidence is much stronger, and the topology for this part of the molecular tree differs from that derived from the combined data. Here the cause of the mismatch is unclear but could be methodological, arising from marked inequality of molecular rates. Overall, the level of agreement reached between these different data and methodological approaches leads us to believe that careful application of likelihood and Bayesian methods to molecular data provides realistic divergence time estimates in the majority of cases (almost 80% in this specific example), thus providing a remarkably well-calibrated phylogeny of a character-rich clade of ubiquitous marine benthic invertebrates.
                Bookmark

                Author and article information

                Journal
                R Soc Open Sci
                R Soc Open Sci
                RSOS
                royopensci
                Royal Society Open Science
                The Royal Society Publishing
                2054-5703
                June 2015
                24 June 2015
                24 June 2015
                : 2
                : 6
                : 150114
                Affiliations
                [1 ]Hopkins Marine Station of Stanford University , Pacific Grove, CA 93950, USA
                [2 ]San Francisco Bay National Estuarine Research Reserve and Department of Biology, San Francisco State University , Tiburon, CA 94920, USA
                [3 ]Bodega Marine Laboratory and Department of Evolution and Ecology, University of California at Davis , Bodega Bay, CA 94923, USA
                Author notes
                Author for correspondence: Jason Hodin e-mail: seastar@ 123456stanford.edu
                Article
                rsos150114
                10.1098/rsos.150114
                4632551
                26543587
                f621f2a8-316b-4024-af61-91afc9defbb5

                © 2015 The Authors. Published by the Royal Society under the terms of the Creative Commons Attribution License http://creativecommons.org/licenses/by/4.0/, which permits unrestricted use, provided the original author and source are credited.

                History
                : 16 March 2015
                : 25 May 2015
                Categories
                1001
                1005
                58
                60
                140
                Biology (Whole Organism)
                Research Article
                Custom metadata
                June, 2015

                metamorphosis,echinoidea,hydrodynamics,shear forces,environmental cues,recruitment

                Comments

                Comment on this article