Physiology and biochemistry of food limitation in marine invertebrate larvae

Unrestricted For high fecundity organisms, the number of offspring that survive to adulthood are very few. The mechanisms of individual-based survival remain of great interest in biology. In this dissertation, larval survival was examined by taking an integrative approach, from organismal physiology...

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Bibliographic Details
Main Author: Yu, Pauline Chia-Wen
Format: Dataset
Language:English
Published: University of Southern California Digital Library (USC.DL) 2015
Subjects:
Biology
larvae
starvation survival
starvation recovery
amino acid transporter
energy budget
pluteus
veliger
Crassostrea gigas
Online Access:https://dx.doi.org/10.25549/usctheses-m2402
https://digitallibrary.usc.edu/asset-management/2A3BF1UKATKW
id ftdatacite:10.25549/usctheses-m2402
record_format openpolar
spelling ftdatacite:10.25549/usctheses-m2402 2023-05-15T15:59:10+02:00 Physiology and biochemistry of food limitation in marine invertebrate larvae Yu, Pauline Chia-Wen 2015 https://dx.doi.org/10.25549/usctheses-m2402 https://digitallibrary.usc.edu/asset-management/2A3BF1UKATKW en eng University of Southern California Digital Library (USC.DL) Biology larvae starvation survival starvation recovery amino acid transporter energy budget pluteus veliger Dataset dataset 2015 ftdatacite https://doi.org/10.25549/usctheses-m2402 2022-02-09T12:43:26Z Unrestricted For high fecundity organisms, the number of offspring that survive to adulthood are very few. The mechanisms of individual-based survival remain of great interest in biology. In this dissertation, larval survival was examined by taking an integrative approach, from organismal physiology to molecular biology.; Large numbers of larvae from sea urchins (Lytechinus pictus) and bivalve mollusks (Crassostrea gigas) were experimentally tested for starvation tolerance. Theoretically, survival during the "critical period" of early feeding is low in the absence of appropriate particulate foods. Empirically, survival was measured in large-volume culture experiments (200-l). Analysis revealed that some larvae could resist starvation for over 40 days. Bivalve larval families of known genotype had large survival differences despite similar biochemical contents and metabolic rates. Sea urchin larvae had similar physiological capacities to survive extended periods of starvation while still conserving organic mass and maintaining metabolic rates. Importantly, such “starved” larvae for both species subsequently recovered when fed showed normal morphological and physiological characteristics. For instance, sea urchin larvae that were starved for 18 days prior to feeding were subsequently able to undergo metamorphosis. For bivalve larvae, specific genotypes with high starvation resistance were also the families that showed high growth rates when fed. The significance of this finding is that “one genotype fits all” in that the same genotype showed the best performance under poor and good conditions (starved or fed ad libitum).; Exogenous nutrition from dissolved organic matter has long been speculated to provide energy for marine invertebrates. In sea urchins, amino acid transporter proteins were localized ultrastructurally in subcellular compartments of unfertilized eggs and in larval ectoderm in later development. Genes of the same family were also identified in bivalve larvae. In same-aged bivalve larvae of different sizes (phenotypic contrasts), high growth rates were related to differential gene expression.; The major finding from this dissertation is that physiological mechanisms of survival are genotype-related. This has important consequences for the adaptive basis of survival of early life history stages. Predicting which phenotype has the adaptive ability to survive in rapidly changing environments is a critical requirement for understanding ocean ecology. Dataset Crassostrea gigas DataCite Metadata Store (German National Library of Science and Technology)
institution Open Polar
collection DataCite Metadata Store (German National Library of Science and Technology)
op_collection_id ftdatacite
language English
topic Biology
larvae
starvation survival
starvation recovery
amino acid transporter
energy budget
pluteus
veliger
spellingShingle Biology
larvae
starvation survival
starvation recovery
amino acid transporter
energy budget
pluteus
veliger
Yu, Pauline Chia-Wen
Physiology and biochemistry of food limitation in marine invertebrate larvae
topic_facet Biology
larvae
starvation survival
starvation recovery
amino acid transporter
energy budget
pluteus
veliger
description Unrestricted For high fecundity organisms, the number of offspring that survive to adulthood are very few. The mechanisms of individual-based survival remain of great interest in biology. In this dissertation, larval survival was examined by taking an integrative approach, from organismal physiology to molecular biology.; Large numbers of larvae from sea urchins (Lytechinus pictus) and bivalve mollusks (Crassostrea gigas) were experimentally tested for starvation tolerance. Theoretically, survival during the "critical period" of early feeding is low in the absence of appropriate particulate foods. Empirically, survival was measured in large-volume culture experiments (200-l). Analysis revealed that some larvae could resist starvation for over 40 days. Bivalve larval families of known genotype had large survival differences despite similar biochemical contents and metabolic rates. Sea urchin larvae had similar physiological capacities to survive extended periods of starvation while still conserving organic mass and maintaining metabolic rates. Importantly, such “starved” larvae for both species subsequently recovered when fed showed normal morphological and physiological characteristics. For instance, sea urchin larvae that were starved for 18 days prior to feeding were subsequently able to undergo metamorphosis. For bivalve larvae, specific genotypes with high starvation resistance were also the families that showed high growth rates when fed. The significance of this finding is that “one genotype fits all” in that the same genotype showed the best performance under poor and good conditions (starved or fed ad libitum).; Exogenous nutrition from dissolved organic matter has long been speculated to provide energy for marine invertebrates. In sea urchins, amino acid transporter proteins were localized ultrastructurally in subcellular compartments of unfertilized eggs and in larval ectoderm in later development. Genes of the same family were also identified in bivalve larvae. In same-aged bivalve larvae of different sizes (phenotypic contrasts), high growth rates were related to differential gene expression.; The major finding from this dissertation is that physiological mechanisms of survival are genotype-related. This has important consequences for the adaptive basis of survival of early life history stages. Predicting which phenotype has the adaptive ability to survive in rapidly changing environments is a critical requirement for understanding ocean ecology.
format Dataset
author Yu, Pauline Chia-Wen
author_facet Yu, Pauline Chia-Wen
author_sort Yu, Pauline Chia-Wen
title Physiology and biochemistry of food limitation in marine invertebrate larvae
title_short Physiology and biochemistry of food limitation in marine invertebrate larvae
title_full Physiology and biochemistry of food limitation in marine invertebrate larvae
title_fullStr Physiology and biochemistry of food limitation in marine invertebrate larvae
title_full_unstemmed Physiology and biochemistry of food limitation in marine invertebrate larvae
title_sort physiology and biochemistry of food limitation in marine invertebrate larvae
publisher University of Southern California Digital Library (USC.DL)
publishDate 2015
url https://dx.doi.org/10.25549/usctheses-m2402
https://digitallibrary.usc.edu/asset-management/2A3BF1UKATKW
genre Crassostrea gigas
genre_facet Crassostrea gigas
op_doi https://doi.org/10.25549/usctheses-m2402
_version_ 1766394956249825280

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