Title Life cycle and ecology of the loggerhead turtle (Caretta caretta, Linnaeus, 1758) : Development and application of the dynamic energy budget model
Title (croatian) Životni ciklus i ekologija glavate želve (Caretta caretta, Linnaeus, 1758) : razvoj i primjena modela dinamičkog energijskog proračuna
Author Nina Marn MBZ: 323363
Mentor Tin Klanjšček (mentor)
Mentor Sebastian A. L. M. Kooijman (komentor) strani drzavljanin: Nije dostupno
Committee member Petar Kružić (predsjednik povjerenstva)
Committee member Bob Kooi https://orcid.org/0000-0003-3477-9924 (član povjerenstva)
Committee member Romana Gračan (član povjerenstva)
Committee member Kiki Dethmers (član povjerenstva) strani drzavljanin: Nije dostupno
Committee member Cor Zonneveld (član povjerenstva) strani drzavljanin: Nije dostupno
Granter University of Zagreb Faculty of Science (Department of Geology) Zagreb
Defense date and country 2016-05-30, Croatia
Scientific / art field, discipline and subdiscipline NATURAL SCIENCES Interdisciplinary Natural Sciences Marine Science
Universal decimal classification (UDC ) 502/504 - Environmental science. Conservation of natural resources. Threats to the environment and protection against them 55 - Geology. Meteorology. Hydrology
Abstract After the general introduction presented in Chapter 1, Chapter 2 tackles the problem of disjointed and conflicting data, and explores to what extent do loggerhead turtle populations and life stages differ in morphology. In order to take into account the possible geographic and life stage variability, I study two neighboring populations and all postembryonic life stages by comparing the ratio of carapace length, width and height of sea turtles. I conduct a detailed analysis of empirical models (growth curves, conversion formulae). One of the aims is to answer a somewhat technical question whether or not can the growth of loggerhead turtles be considered isomorphic. Considerable deviations from isomorphy would require additional steps when defining through out the life the acquisition (or use) of energy in relation to the surface area-volume ratio. The focus of Chapter 3 is on developing a full life cycle model of loggerhead turtles. Due to substantial variability present in data related to loggerhead turtles living in different sea basins, I decided to focus on a geographically defined population rather than the whole species. In this chapter the North Atlantic population of loggerhead turtles is analyzed as it has one of the largest nesting aggregations of loggerhead turtles. After estimating the parameter values using the covariation method [126] of the package DEBtool implemented in Matlab, I compare model predictions to observations, and discuss the implications of the results. In Chapter 4 another population of loggerhead turtles, the Mediterranean population, is the main focus, together with the comparison between individuals belonging to the Mediterranean, and individuals belonging to the North Atlantic population. Individuals belonging to the two populations are first compared based solely on their morphology (length, weight, and the ratio of the two) at two life events: hatching and nesting. The average egg size reported for each population is taken into account, as it has been generally reported to account for most of the variation in hatchling sizes. As the next step, I develop a DEB model for the individuals of the Mediterranean population, analyze the model predictions, and discuss the implications of the results. Then I compare the model parameters between the populations, and suggest a physiological (maturity based) explanation for the adults having such markedly different sizes at nesting. In addition, posthatchling growth is analyzed in more detail, expanding the results of the previous chapter which suggested faster growth of posthatchlings than predicted by the model. Lastly, I reproduce a pattern of biphasic growth by modifying the food availability during the first part of the life cycle. Chapter 5 showcases the applications of the DEB model to study the effects of temperature and food availability, and the effects of plastic ingestion on the energy budget and life cycle of the loggerhead turtle. I simulate a realistic range of temperatures and food densities to explore their effect on the energy budget, i.e. observable quantities such as size and reproduction output. I present a mechanism for the effects of plastic ingestion on 6 General introduction the energy budget, applicable to any species for which the DEB parameters are known. I simulate a range of observed amounts of ingested debris, and study their effects on the processes of growth, maturation, and reproduction while assuming the plastic has (a) the same, and (b) several times longer gut residence time compared to that of food. Finally, in Chapter 6 I discuss my results in a broader context, and present an outlook on future studies, applications, and possible expansions of the developed model.
Abstract (croatian) Glavate želve (Caretta caretta, Linnaeus 1758) prisutne su u umjerenoj klimatskoj zoni svih svjetskih oceana, evoluirajući u nekoliko populacija i lokalnih subpopulacija. Žive duže od 65 godina, a njihov spol određen je temperaturom inkubacije tijekom zadnje trećine embrionalnog razvoja (koji traje oko dva mjeseca). Tijekom svog života, mogu narasti do veličine čak 25 puta veće od one pri izlijeganju: u prosjeku 4 cm dugačka i 20 g “teška” kornjačica koja izađe iz gnijezda, može postati odrasla jedinka teška preko 100 kg s oklopom dugačkim 100 do 130 cm. Ženke dolaze položiti jaja na istu plažu na kojoj su se izlegle, zbog čega ponekad preplivaju stotine kilometara. Životni ciklus morskih kornjača je dugo vremena bio u grubo podijeljen u tri životna stadija: embrio, seksualno nezrele (juvenilne) jedinke, i odrasle (adultne) jedinke. Iako je provedeno mnogo studija i objavljeno mnogo literature na tematici glavatih želvi i morskih kornjača općenito, fokus određene studije je najčešće bila određena karakteristika ili određen životni stadij. Odabrala sam teoriju dinamičckog energijskog proračuna (eng. Dynamic Energy Budget, DEB) kao stazu koja će me dovesti do mog “Svetog Grala”: DEB modela glavate želve. Pristup ove teorije je sveobuhvatan: praćenje zakona termodinamike, nekoliko tipova homeostaze (ravnoteže) koju svaki sustav (od stanice preko jedinke do ekosustava) pokušava postići i održati, utjecaj hrane i temperature na energijski proračun, međuovisnost energijskog proračuna i procesa kao što su rast, održavanje, sazrijevanje,i reprodukcija. Dodatno, DEB teorija bila je i ostala jedna od najbolje razrađenih i dosljednih dostupnih teorija.
Keywords
DEB
loggerhead turtle
mechanistic model
environmental changes
plastic ingestion
Mediterranean
North Atlantic
Keywords (english)
DEB
glavata želva
mehanistički model
promjene okoliša
ingestija plastike
Mediteran
Sjeverni Atlantik
Language english
URN:NBN urn:nbn:hr:217:954675
Study programme Title: Interdisciplinary doctoral study in Oceanology Study programme type: university Study level: postgraduate Academic / professional title: doktor/doktorica znanosti, područje prirodnih znanosti, polje interdisciplinarne prirodne znanosti (znanost o moru) (doktor/doktorica znanosti, područje prirodnih znanosti, polje interdisciplinarne prirodne znanosti (znanost o moru))
Type of resource Text
Extent IV+217 str. ; 30 cm
File origin Born digital
Access conditions Open access
Terms of use
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Created on 2017-11-20 09:56:21