Dissertations / Theses on the topic 'Carbon isotype discrimination'

Five different forms of ribulose 1,5-bisphosphate carboxylase/oxygenase (RubisCO; IA, IB, IC, ID, II), the carboxylase of the Calvin-Benson-Bassham cycle (CBB), are utilized by plants, algae and autotrophic bacteria for carbon fixation. Discrimination against 13C by RubisCO is a major factor dictating the stable carbon isotopic composition (δ13C = {[13C/12C sample/13C/12C standard] - 1} X 1000) of biomass. To date, isotope discrimination, expressed as ε values (={[12k/13k] - 1} X 1000; 12k and 13k = rates of 12C and 13C fixation) has been measured for form IA, IB, and II RubisCOs from only a few species, with ε values ranging from 18 to 29 /. The aim of this study was to better characterize form ID and IC RubisCO enzymes, which differ substantially in primary structure from the IB enzymes present in many cyanobacteria and organisms with green plastids, by measuring isotopic discrimination and kinetic parameters (KCO2 and Vmax). Several major oceanic primary producers, including diatoms, coccolithophores, and some dinoflagellates have form ID RubisCO, while form IC RubisCO is present in many proteobacteria of ecological interest, including marine manganese-oxidizing bacteria, some nitrifying and nitrogen-fixing bacteria, and extremely metabolically versatile organisms such as Rhodobacter sphaeroides. The ε - values of the form ID RubisCO from the coccolithophore, Emiliania huxleyi and the diatom, Skeletonema costatum (respectively 11.1 / and 18.5 /) were measured along with form IC RubisCO from Rhodobacter sphaeroides and Ralstonia eutropha (respectively 22.9 / and 19.0 /). Isotopic discrimination by these form ID/IC RubisCOs is low when compared to form IA/IB RubisCOs (22-29 /). Since the measured form ID RubisCOs are less selective against 13C, oceanic carbon cycle models based on 13C values may need to be reevaluated to accommodate lower ε values of RubisCOs found in major marine algae. Additionally, with further isotopic studies, the extent to which form IC RubisCO from soil microorganisms contributes to the terrestrial carbon sink may also be determined.

Water use efficiency (WUE), measured as the ratio of plant biomass to water consumption, is an essential agronomical trait for enhancing crop production under drought. Measuring water consumption is logistically difficult, especially in field conditions. The general objective of the present Thesis is to respond to three main questions: (i) can WUE be determined by using carbon isotope discrimination (CID), easy to measure?, (ii) how WUE and CID variation analysis can contribute to the genotypic selection of sunflower subjected to drought?, and (iii) can WUE variation be revealed by the variation of plant-water relation traits. Four experiments were carried out in greenhouse across two different years: (i) on two drought scenarios, progressive soil drying and stable water-stress, and (ii) on five levels of soil water content. The main traits that have been measured include WUE, CID, as well as plant-water relation traits, i.e. control of transpiration (FTSWt), water extraction capacity (TTSW), and dehydration tolerance (OA). A highly significant negative correlation was observed between WUE and CID, and a wide phenotypic variability was observed for both WUE and CID. A wide variability was also observed for FTSWt, TTSW and OA. The results provide new insight into the genetic control of WUE and CID related-traits, which, unlike to other crops, genetic control of WUE, CID, and TTSW in sunflower have never been reported in the literature. Further, quantitative trait loci (QTL) mapping for FTSWt was never reported in any plant species. The QTL for WUE and CID were identified across different drought scenarios. The QTL for CID is considered as a ‘‘constitutive’’ QTL, because it is consistently detected across different drought scenarios. The QTL for CID co-localized with the QTL for WUE, biomass and cumulative water transpired. Co-localization was also observed between the QTL for FTSWt and TTSW, between the QTL for TTSW and WUE-CID-biomass, as well as between the QTL for FTSWt-TTSW and biomass. This study highlights that WUE is physiologically and genetically associated with CID. CID is an excellent surrogate for WUE measurement, and can be used to improve WUE by using marker-assisted selection (MAS) to achieve the ultimate goal of plant breeding at genomic level.

The goal of this project was to determine the genetic architecture of water-use efficiency (WUE) for foxtail pine, which included genomic loci, and effect sizes of this trait. Foxtail pine is a subalpine endemic conifer that inhabits two distinct regional populations separated by 500 km in the mountains of California. In order to achieve this goal, a robust linkage map containing thousands of genetic markers was created using four megagametophyte arrays ranging in size from approximately 70 to 95 megagametophytes. Quantitative trait loci (QTL) discovered for WUE were mapped along the linkage map using linear mixed models and five half-sibling families grown in a common garden. Effect sizes of these QTL were tested for differences between the two regional populations of foxtail pine.

[Truncated abstract] Insufficient water use by annual crop and pasture species leading to costly rises in saline watertables has prompted research into potentially profitable deep-rooted perennial species in the Western Australian wheatbelt. Native mallee eucalypts are currently being developed as a short-rotation coppice crop for production of leaf oils, activated carbon and bio-electricity for low rainfall areas (300—450 mm) too dry for many of the traditional timber and forage species. The research in this study was aimed at developing a knowledge base necessary to grow and manage coppiced mallee eucalypts for both high productivity and salinity control. This firstly necessitated identification of suitable species, climatic and site requirements favourable to rapid growth, and understanding of factors likely to affect yield of the desirable leaf oil constituent, 1,8-cineole. This was undertaken using nine mallee taxa at twelve sites with two harvest regimes. E. kochii subsp. plenissima emerged as showing promise in the central and northern wheatbelt, particularly at a deep acid sand site (Gn 2.61; Northcote, 1979), so further studies focussed on physiology of its resprouting, water use and water-use efficiency at a similar site near Kalannie. Young E. kochii trees were well equipped with large numbers of meristematic foci and adequate root starch reserves to endure repeated shoot removal. The cutting season and interval between cuts were then demonstrated to have a strong influence on productivity, since first-year coppice growth was slow and root systems appeared to cease in secondary growth during the first 1.5—2.5 years after cutting. After decapitation, trees altered their physiology to promote rapid replacement of shoots. Compared to uncut trees, leaves of coppices were formed with a low carbon content per unit area, and showed high stomatal conductance accompanied by high leaf photosynthetic rates. Whole-plant water use efficiency of coppiced trees was unusually high due to their fast relative growth rates associated with preferential investments of photosynthates into regenerating canopies rather than roots. Despite relatively small leaf areas on coppice shoots over the two years following decapitation, high leaf transpiration rates resulted in coppices using water at rates far in excess of that falling as rain on the tree belt area. Water budgets showed that 20 % of the study paddock would have been needed as 0—2 year coppices in 5 m wide twin-row belts in order to maintain hydrological balance over the study period. Maximum water use occurred where uncut trees were accessing a fresh perched aquifer, but where this was not present water budgets still showed transpiration of uncut trees occurring at rates equivalent to 3—4 times rainfall incident on the tree belt canopy. In this scenario, only 10 % of the paddock surface would have been required under 5 m wide tree belts to restore hydrological balance, but competition losses in adjacent pasture would have been greater

Les travaux de cette thèse se sont situés autour de la relation entre discrimination isotopique du carbone 13 et échanges gazeux foliaires. Le modèle établi par Farquhar et al. (1982) permet de prédire la discrimination contre le 13C pendant la photosynthèse (delta13C) en tenant compte des processus de diffusion, de carboxylation et décarboxylation engagés pendant la photosynthèse. Cette relation permet d'utiliser delta13C comme indicateur de l'efficience d'utilisation de l'eau (WUE, quantité de carbone fixé en fonction de l'eau consommée), un paramètre particulièrement important dans un contexte de changement climatique, d'agriculture et de sylviculture. Le modèle de delta13C a également été utilisé pour estimer la conductance mésophyllienne au CO2 (gm), un paramètre qui limite fortement la photosynthèse via la disponibilité en carbone dans le chloroplaste. Au cours de nos travaux, nous avons analysé le modèle delta13C pour identifier les paramètres les plus influents dans le modèle, et mis en évidence que l'utilisation du "modèle simple" de delta13C (ignorant gm et les processus de décarboxylation) peut induire un biais important dans l'estimation de WUE. Dans un second temps nous nous sommes concentrés sur les possibles variations à court-terme de gm, un domaine encore sujet a débat. Nous avons confirmé que gm était sensible aux variations de CO2 et d'irradiance sur toutes les espèces d'arbres mesurées dans cette étude. Nous avons aussi montré que ces variations rapides ne peuvent pas être dues a des variations des autres paramètres du modèle, à l'exception possible du paramètre b (discrimination pendant la carboxylation). Nous suggérons que les prochaines études dans ce domaine portent sur (i) la possible variabilité environnementale et génétique du paramètre b et (ii) les mécanismes à l'origine des variations rapides de gm (aquaporines et anhydrases carboniques)
This work was focused on the relationship between isotopic discrimination of 13C during photosynthesis (delta13C) and leaf gas exchange. The model of Farquhar and colleagues (Farquhar et al. 1982) predicts delta13C by accounting for diffusion, carboxylation and decarboxylation processes during the photosynthesis. This relationship is widely used and delta13C is frequently considered as a proxy water use efficiency (WUE, the amount of water required to fix a amount of carbon), an interesting parameter in the context of climate change, crop production and sylviculture. The delta13C model is also used to assess mesophyll conductance to CO2 (gm), that strongly limits photosynthesis via the availability of carbon in the chloroplast. Along this work we analyzed the delta13C model and identified the most important parameters, and highlighted that using the "simple form" of the model (which ignores gm and the decarboxylations) could lead to misestimating WUE. We also focused on the possible rapid variations of gm, a subject still under debate. We confirmed that gm was sensitive to rapid variations of CO2 and irradiance in all species tested in this study. We also showed that apparent rapid variations of gm could not be induced by variations of other parameters in the model, with the exception of parameter b (discrimination during carboxylation). We propose that future studies should focus on (i) the possible environmental and genetic variability of parameter b, and (ii) the physiological processes able to change gm at short time scales (aquaporins and carbonic anhydrase)

The seasonal pattern of the carbon isotope content (delta C-13) of atmospheric CO2 depends on local and nonlocal land-atmosphere exchange and atmospheric transport. Previous studies suggested that the delta C-13 of the net land-atmosphere CO2 flux (delta(source)) varies seasonally as stomatal conductance of plants responds to vapor pressure deficit of air (VPD). We studied the variation of (source) at seven sites across the United States representing forests, grasslands, and an urban center. Using a two-part mixing model, we calculated the seasonal delta(source) for each site after removing background influence and, when possible, removing delta C-13 variation of nonlocal sources. Compared to previous analyses, we found a reduced seasonal (March-September) variation in delta(source) at the forest sites (0.5 parts per thousand variation). We did not find a consistent seasonal relationship between VPD and delta(source) across forest (or other) sites, providing evidence that stomatal response to VPD was not the cause of the global, coherent seasonal pattern in (source). In contrast to the forest sites, grassland and urban sites had a larger seasonal variation in (source) (5) dominated by seasonal transitions in C-3/C-4 grass productivity and in fossil fuel emissions, respectively. Our findings were sensitive to the location used to account for atmospheric background variation within the mixing model method that determined (source). Special consideration should be given to background location depending on whether the intent is to understand site level dynamics or regional scale impacts of land-atmosphere exchange. The seasonal amplitude in delta C-13 of land-atmosphere CO2 exchange (delta(source)) varied across land cover types and was not driven by seasonal changes in vapor pressure deficit. The largest seasonal amplitudes of delta(source) were at grassland and urban sites, driven by changes in C-3/C-4 grass productivity and fossil fuel emissions, respectively. Mixing model approaches may incorrectly calculate delta(source) when background atmospheric observations are remote and/or prone to anthropogenic influence.

Thesis (MScAgric (Viticulture and Oenology))--University of Stellenbosch, 2010.
ENGLISH ABSTRACT: Within-vineyard variability in vigour and water status commonly occurs in South African vineyards. Different soil types found over short distances are probably the main cause of vigour variability, while differences in grapevine water status are commonly induced by lateral water flow in the vineyard, blocked irrigation emitters and differences in soil water-holding capacity. These factors can cause heterogeneous ripening and differences in fruit quality between different parts of the vineyard, an aspect that needs to be avoided as far as possible in order to produce quality wines. Measurements of carbon isotope discrimination (CID) have proved to be a tool to assess grapevine physiology in order to study the effects of environmental parameters on leaf carbon dioxide (CO2) gas exchange and stomatal conductance (gs). Grapevine water deficit stress/strain in reaction to these environmental conditions can then be determined by observing the amount of 13C absorbed by plant material after discrimination of 13C has taken place, and this is influenced by the grapevine stress condition and can indicate water-use efficiency. In this study, the variability of grapevine water status and vigour was determined in order to quantify these parameters in different parts of the vineyard. Two separate trials were conducted, the first at Wellington, South Africa, where different irrigation regimes resulted in variability in grapevine water status between plots. The second trial was at Stellenbosch, South Africa, where plots were divided among different vigour classes and irrigation was applied in different quantities for different irrigation treatments. Within-vineyard variability in water status (Wellington and Stellenbosch) and vigour (Stellenbosch) were then quantified and the effects on some grapevine physiological parameters and berry composition were measured. The treatments in the Wellington trial led to differences in grapevine water status, which could be quantified by measurements of stem water potential (SWP) and leaf water potential (LWP). Soil variability also led to differences in grapevine vigour, which were quantified by measurements of pruning mass, leaf area and shoot length. The effect of the variability in grapevine water status on grapevine physiology was assessed by measuring CID, which was the main focus of the study. Other physiological measurements, such as gs and leaf and canopy temperature, were also conducted. The effect of these conditions on grape berry composition was also studied. In the Stellenbosch trial, soil water content, plant water status measurements (SWP, predawn LWP and LWP), physiological measurements (CID and gs) and berry size measurements were used to classify plots into water status treatments (“wet” and “dry” treatments). The effect of vigour differences was analysed separately from these treatments by using pruning mass as a covariate in the statistical analyses. The effect of vigour variability on the measurements was studied by looking at the effect of the covariate on the measurements, while shoot growth rate, shoot length and leaf area measurements were conducted as vegetative growth measurements. Differences in measurements were then studied between the treatments and between the vigour levels of the different plots. In the Wellington trial, plant water status was determined by irrigation, showing increased stress for treatments that received less irrigation. The differences in plant water status then caused differences in grapevine physiology between the treatments, leading to increased gs for increased irrigation. This of course influenced leaf internal CO2 and therefore CID, although CID was also clearly influenced by berry development. Berry size was influenced by irrigation, with larger berries found in wetter treatments, while berry chemical composition was influenced by the irrigation regime, with increased irrigation leading to increased pH and leading to trends showing increased total soluble solids and malic acid, and reduced total and tartaric acid and colour intensity. In the Stellenbosch trial, plots with higher vigour had increased shoot growth rate, longer shoots and increased leaf area, although topping influenced this. Wet treatment vines also showed slightly longer shoots and larger leaf areas. There were differences in soil water content between the wet and dry treatments, and this led to differences in plant water status. Vigour also influenced pre-dawn LWP, especially in the 2007 season, as higher-vigour vines struggled more to rehydrate through the night. Differences in plant water potential led to differences in grapevine physiology, with increased gs for vines from the wet treatment, while higher-vigour vines had slightly increased gs. The differences in gs led to gas exchange differences and therefore differences in CID, meaning that water status and vigour influenced CID. CID measurements illustrated the long term effect of water status on plant physiology, while measurements such as SWP illustrated the short term effects. CID measurements therefore proved to be accumulative over the season, in contrast to SWP measurements that were much more dependent on the current state of grapevine water status. Other physiological measurements showed that wet-treatment vines had higher photosynthetic rates and evapotranspiration and lower leaf temperatures, while higher-vigour vines had slightly increased evapotranspiration and decreased leaf temperatures. Wet-treatment vines had larger berries, while a higher vigour also led to slightly larger berries. Berry composition was influenced by treatment, where wet-treatment vines had increased pH and total soluble solids, while higher-vigour vines had increased juice pH and, in the 2008 season, decreased total soluble solids. Extremely stressed conditions did not show significant effects on plant water potential, but SWP measurements indicated slightly higher stress for the extremely stressed vines and LWP showed slightly less stressed conditions for these vines. Measurements of gs showed slightly lower values for the extremely stressed vines, while measurements of CID showed large significant differences, with the extremely stressed vines having measurements showing high stress. The measurement therefore indicated highly stressed conditions accurately, while other physiological measurements, such as photosynthetic rate, evapotranspiration and leaf temperatures, only showed trends and no significant differences. Measurements of stomatal conductance reacted to plant water status measurements throughout the diurnal measurement days, while CID only reacted slightly with gs changes during these days and was perhaps influenced more by berry chemical composition and development at this early stage of the season. Vigour and water status therefore influenced grapevine physiology, with a more direct effect by water status and an indirect effect by vigour due to microclimatic differences. This also influenced berry composition and therefore quality. In future studies, CID measurements should be done on juice from which organic acids have been removed in order to eliminate the effect of seasonal berry composition on the measurement. Measurements of CID proved to be an integrative, but sensitive, indicator of grapevine stress, especially at the end of the season. It might at best be useful as a post-harvest management tool for producers or grape buyers, especially for irrigation control, as has also been stated by Van Leeuwen et al. (2007).
AFRIKAANSE OPSOMMING: Binne-wingerd variasie in groeikrag en waterstatus is algemeen in Suid-Afrikaanse wingerde. Verskillende grondsoorte wat na aan mekaar voorkom, is seker een van die vernaamste oorsake van variasie in groeikrag, terwyl verskille in wingerdwaterstatus algemeen deur laterale watervloei in die wingerd, verstopte besproeiingspuite en verskille in grond waterhouvermoë geïnduseer word. Hierdie faktore kan aanleiding gee tot heterogene rypwording en verskille in vrugkwaliteit tussen verskillende dele van die wingerd, ‘n aspek wat so ver moontlik vermy moet word om kwaliteitwyne te kan produseer. Die meting van koolstof-isotoopdiskriminasie (KID) is bewys om as gereedskap te kan dien vir die assessering van wingerdfisiologie om die effekte van omgewingsparameters op blaar koolstofdioksied (CO2) - gasuitruiling en stomatale geleiding (gs) te bestudeer. Die stres/stremming as gevolg van ‘n watertekort in die wingerd in reaksie op hierdie omgewingstoestande kan dan bepaal word deur te kyk na hoeveel 13C deur die plantmateriaal geabsorbeer word ná 13C-diskriminasie plaasgevind het, en dít word deur die wingerdstrestoestande beïnvloed en kan ‘n aanduiding verskaf van die doeltreffendheid van waterverbruik. In hierdie studie is die variasie in wingerdwaterstatus en groeikrag bepaal om hierdie parameters in verskillende dele van die wingerd te kwantifiseer. Twee afsonderlike proewe is uitgevoer, die eerste by Wellington, Suid-Afrika, waar verskillende besproeiingsregimes gelei het tot verskille in die wingerdwaterstatus tussen persele. Die tweede proef was by Stellenbosch, Suid-Afrika, waar persele tussen verskillende groeikragklasse verdeel is en besproeiing in verskillende hoeveelhede vir verskillende besproeiingsbehandelings toegepas is. Binne-wingerd variasie in waterstatus (Wellington en Stellenbosch) en groeikrag (Stellenbosch) is toe gekwantifiseer en die effekte op sekere wingerd-fisiologiese parameters en korrelsamestelling is gemeet. Die behandelings in die Wellington-proef het gelei tot verskille in wingerdwaterstatus, wat deur metings van stamwaterpotensiaal (SWP) en blaarwaterpotensiaal (BWP) gekwantifiseer kon word. Grondverskille het ook gelei tot verskille in wingerdgroeikrag, wat deur metings van snoeimassa, blaaroppervlak en lootlengte gekwantifiseer is. Die effek van die variasie in wingerdwaterstatus op wingerdfisiologie is deur metings van KID bepaal wat die hooffokus van hierdie studie was. Ander fisiologiese metings, soos gs en blaar- en lowertemperatuur, is ook gedoen. Die effekte van hierdie toestande op die samestelling van die druiwekorrels is ook bestudeer. In die Stellenbosch-proef is grondwaterinhoud, metings van plantwaterstatus (SWP, voorsonopgang SWP en BWP), fisiologiese metings (KID en gs) en metings van korrelgrootte gebruik om die persele in waterstatusbehandelings (“nat” en “droë” behandelings) te verdeel. Die effek van verskille in groeikrag is apart van hierdie behandelings geanaliseer deur snoeimassa as ‘n kovariaat in die statistiese analises te gebruik. Die effek van groeikragvariasie op die metings is bestudeer deur ondersoek in te stel na die effek van die kovariaat op die metings, terwyl lootgroeitempo-, lootlengte- en blaaroppervlakmetings as metings van vegetatiewe groei uitgevoer is. Verskille in metings tussen die behandelings en tussen die groeikragvlakke van die verskillende persele is toe bestudeer. In die Wellington-proef is plantwaterstatus deur besproeiing bepaal, met verhoogde stres in behandelings waar daar minder besproeiing toegedien is. Die verskille in plantwaterstatus het dan verskille in wingerdfisiologie tussen die behandelings veroorsaak, wat gelei het tot ‘n verhoogde gs in die geval van verhoogde besproeiing. Dit het natuurlik ‘n effek op die interne CO2 van die blaar en dus op KID gehad, hoewel KID ook duidelik deur korrelontwikkeling beïnvloed is. Korrelgrootte is deur besproeiing beïnvloed, met groter korrels in die natter behandelings, terwyl die chemiese samestelling van die korrel deur besproeiingsregime beïnvloed is. Verhoogde besproeiing het pH verhoog en gelei na tendense wat verhoogde totale oplosbare vaste stowwe en appelsuur, en verminderde totale suur, wynsteensuur en kleurintensiteit getoon het. In die Stellenbosch-proef het persele met hoër groeikrag ook verhoogde lootgroeitempo, langer lote en verhoogde blaaroppervlak getoon, hoewel dit deur top beïnvloed is. Wingerdstokke van die nat behandeling het ook effe langer lote en groter blaaroppervlakke getoon. Daar was verskille in grondwaterinhoud tussen die nat en droë behandelings en dit het verskille in plantwaterstatus veroorsaak. Groeikrag is ook deur voor-sonopgang BWP beïnvloed, veral in die 2007-seisoen, aangesien stokke met hoër groeikrag meer gesukkel het om in die nag te rehidreer. Verskille in plantwaterpotensiaal het gelei tot verskille in wingerdfisiologie, met ‘n verhoogde gs vir stokke in die nat behandeling, terwyl stokke met hoër groeikrag ‘n effens verhoogde gs getoon het. Die verskille in gs het gelei tot verskille in gasuitruiling en dus verskille in KID, wat beteken dat waterstatus en groeikrag ‘n invloed op KID het. KID was meer verteenwoordigend van die langtermyneffekte van water status op plantfisiologie, terwyl metings soos SWP die korttermyneffekte weerspieël het. KID metings was dus akkumalatief oor die seisoen, terwyl SWP metings meer ‘n weerspieëling was van die huidige toestand van plantwaterpotensiaal. Ander fisiologiese metings het getoon dat stokke in die nat behandeling ‘n hoër fotosintesetempo en evapotranspirasie sowel as laer blaartemperature ondervind het, terwyl die stokke met hoër groeikrag effe verhoogde evapotranspirasie en verminderde blaartemperature getoon het. Stokke in die nat behandeling het groter korrels gehad, terwyl hoër groeikrag ook effens groter korrels veroorsaak het. Korrelsamestelling is deur die behandelings beïnvloed, met stokke in die nat behandeling wat verhoogde pH en totale oplosbare vaste stowwe getoon het, terwyl stokke met hoër groeikrag verhoogde pH van die sap en verminderde totale oplosbare vaste stowwe (laasgenoemde in die 2008-seisoen) gehad het. Uitermate toestande van stres het geen beduidende effekte op plantwaterpotensiaal getoon nie, hoewel SWP-metings effens hoër stres vir die uitermate gestresde wingerde getoon het en BWP effens minder gestresde toestande vir hierdie stokke getoon het. Metings van gs het effens laer waardes vir die uitermate gestresde stokke getoon, terwyl metings van KID groot noemenswaardige verskille getoon het, met die metings vir die uitermate gestresde wingerde wat hoër stres aangedui het. Dié meting het dus hoogs gestresde toestande akkuraat aangedui, terwyl ander fisiologiese metings, soos tempo van fotosintese, evapotranspirasie en blaartemperature net tendense en nie beduidende verskille aangedui het nie. Metings van stomatale geleiding het dwarsdeur die dae waarop daaglikse metings gedoen is op plantwaterstatusmetings gereageer, terwyl KID net effens met gs-veranderinge op hierdie dae gereageer het en moontlik meer deur die chemiese samestelling en ontwikkeling van die korrel in hierdie vroeë stadium van die seisoen beïnvloed is. Groeikrag en waterstatus het dus wingerdfisiologie beïnvloed, met ‘n meer direkte effek deur waterstatus en ‘n indirekte effek deur groeikrag as gevolg van mikroklimaatsverskille. Dit het ook korrelsamestelling en dus kwaliteit beïnvloed. In toekomstige studies moet KID-metings gedoen word op sap waarvan die organiese sure verwyder is om die effek van seisoenale korrelsamestelling op die meting uit te sluit. Metings van KID is getoon om ‘n integrerende, maar gevoelige, aanduider van wingerdstres te wees, veral aan die einde van die seisoen. Dit is ten beste miskien bruikbaar as naoesbestuursgereedskap vir produsente of druiwekopers, veral vir besproeiingsbeheer, soos ook reeds deur Van Leeuwen et al. (2007) aangedui is.

C4 plants have a biochemical carbon concentrating mechanism (CCM) that increases CO2 concentration around Rubisco in the bundle sheath (BS). Maize CCM has two CO2 delivery pathways to the Bundle Sheath (BS) (respectively via malate, MAL or aspartate, ASP); rates of PGA reduction, carbohydrate synthesis and PEP regeneration vary between BS and Mesophyll (M) cells. For these anatomical and biochemical complexities, C4 plants are highly sensitive to light conditions. Under limiting light, the activity of the CCM generally decreases, causing an increase in leakiness, (Φ), the ratio of CO2 retrodiffusing from the BS relative to C4 carboxylation processes. This increase in Φ had been theoretically associated with a decrease in biochemical operating efficiency (expressed as ATP cost of gross assimilation, ATP / GA) under low light and, because a proportion of canopy photosynthesis is carried out by shaded leaves, to potential productivity losses at field scale. In C4 leaves, because of the concentric anatomy, light reaches M cells before the deeper BS (Evans et al., 2007), and could alter the energetic partitioning balance between BS and M and potentially cause efficiency losses. In this experimental programme I investigated strategies deployed by C4 plants to adjust operating efficiency under different illumination conditions. Firstly, maize plants were grown under high and low light regimes (respectively HL, 600 vs LL, 100 μE m-2 s-1). Short term acclimation of Φ was compared from isotopic discrimination (Δ), gas exchange and photochemistry using an improved modelling approach which does not suffer from elements of circularity. Long term acclimation to low light intensities brought about physiological changes which could potentially increase the operating efficiency under limiting ATP supplies. Secondly, profiles of light penetration across a leaf were used to derive the potential ATP supply for M and BS cells induced by changing light quality. Empirical measurements of net CO2 uptake, ATP production rate and carbon isotope discrimination were made on plants under a low light intensity. The overall conversion efficiency was not affected by light quality. A comprehensive metabolic model highlighted the importance of both CO2 delivery pathways in maize. Further, metabolic plasticity allowed the balancing of ATP and NADPH requirements between BS and M. Finally, I tested the hypothesis that plants can modify their physiology so as to reach a status of higher operating efficiency when exposed to high light and then to low light, so as to mimic the transition which leaves undergo when shaded by newly emerging leaves in a crop canopy. Plants were grown under high light and low light for three weeks, then, HL plants were transferred to low light for a further three weeks. Re-acclimation was very effective in reducing ATP cost of net assimilation under low light intensities. In addition, the hyperbolic leakiness increase observed under low light intensities was not associated to operating efficiency loss. Overall, in the three experimental Chapters I showed compelling theoretical and empirical evidence proving the hypothesis that C4 plants deal with low light conditions and with different light qualities without losing operating efficiency.

Varietal forestry may increase the productivity of loblolly pine (Pinus taeda L.) in the Southern United Sates. However, the effects of these genetic x environment interactions are still poorly understood. In this study we examined the responses in growth, stand uniformity and leaf level physiology of loblolly pine clonal varieties and families to silvicultural intensity and site effects. We also looked for patterns in observed traits that were consistent between crown ideotypes. Two varieties of each crown ideotype (narrow vs broad crowns) and two families (controlled mass pollinated (CMP) and open pollinated (OP) family) were tested on the Virginia Piedmont (VA) and the North Carolina Coastal Plain (NC) under different silvicultural intensities (operational vs intensive), and planting density (617, 1235 and 1852 trees per hectare). Data were collected during the first four growing season after establishment. At NC, intensive silviculture increased crown-width, height and dbh by 33%, 14%, and 23%, respectively. At VA, intensive silviculture increased crown-width, height and dbh by 41%, 10%, and 23%, respectively. Intensive silviculture also increased slightly but significantly the stand uniformity of stem growth. However, the differences in productivity between silvicultural treatments were not explained by differences in leaf-level physiology. Across all treatments and sites the varieties generally grew faster than the OP family, but the differences were higher at VA. Varieties did not differ in stem growth, but the broadest crown variety had greater stand uniformity, photosynthetic rate (Asat), carbon isotope discrimination (∆¹³) and lower fascicle size than the OP family. None of the traits assessed inthis study was consistent within the ideotypes. Varieties classified in the same crown-ideotypes may respond differently to the environmental effects of site and silviculture, which reinforces the need of matching varietal forestry with precision silviculture to achieve gains in productivity.
Ph. D.

Cette thèse visait (i) à quantifier la variabilité de l'efficience d'utilisation de l'eau (WUE) chez le peuplier noir (Populus nigra L.), (ii) à juger de sa plasticité phénotypique en réponse à des contraintes hydrique et thermique et (iii) à juger des liens entre WUE, croissance et survie. A cette fin, des études à partir de semis, en chambre de croissance et en milieu naturel, ainsi qu'à partir de populations installées en dispositifs de pépinière ont été réalisées. Nos travaux ont permis de montrer une importante variabilité et une importante plasticité du caractère 'efficience d'utilisation de l'eau' quels que soient l'échelle d'étude, le fond génétique et les conditions de croissance. Une diminution de WUE a été observée en réponse à la contrainte thermique alors qu'une augmentation de WUE a été observée en réponse à un déficit hydrique modéré. Nos travaux démontrent également un lien entre WUE et la survie sous de fortes températures suggérant que sous ces conditions, une faible efficience d'utilisation de l'eau conférerait un avantage pour les individus. De plus in situ, un lien négatif entre WUE et la densité de régénération a été observé démontrant que les plus faibles valeurs de WUE sont observées pour les plus fortes densités. Le caractère 'efficience d'utilisation de l'eau' pourrait donc s'avérer un caractère limitant de la régénération de l'espèce dans des conditions d'augmentation de température ; une telle augmentation pourrait alors avoir une conséquence directe sur la structuration génétique des populations futures. Ces travaux suggèrent enfin une structuration géographique de la variabilité de WUE qui reste à confirmer à partir d'un plus grand nombre de populations. Ce travail ouvre des perspectives intéressantes pour l'identification des bases physiologiques à l'origine des variations de WUE, de sa plasticité et de sa structuration géographique.

Resumo: Artemisia annua L. (Asteraceae) é uma planta herbácea altamente aromática, nativa da Ásia e aclimatada no Brasil. As folhas são fonte abundante de artemisinina, uma lactona sesquiterpênica que, conjuntamente aos seus derivados semi-sintéticos, apresentam ação efetiva contra as cepas resistentes das espécies de Plasmodium causadoras da malária. Os objetivos deste trabalho foram identificar o mecanismo fotossintético e avaliar o efeito de diferentes condições de temperatura e fotoperíodo no crescimento e desenvolvimento do acesso CPQBA 2/39x1V de A. annua. Para identificar o mecanismo fotossintético foram realizados experimentos para determinar composição dos isótopos do carbono (d‰13C) e a anatomia foliar associada a testes histoquímicos. Para avaliar o efeito da temperatura e fotoperíodo no crescimento e desenvolvimento de A. annua foram realizados dois experimentos em câmaras fotoperiódicas (o primeiro com temperaturas médias máx. de 37ºC e mín. de 19ºC e o segundo com máx. de 29ºC e mín. de 13ºC) e um experimento com 6 épocas de plantio em campo no município de Pato Branco-PR (26º11' S, 52º36' W e 760 m de altitude), sul do Brasil. Um último experimento realizado, foi a aplicação exógena de artemisinina em plantas de A. annua para verificar o papel da molécula na indução do florescimento. Como resultados, A. annua apresentou uma d‰13C - 31.76 l 0.07, valor típico de espécies com mecanismo fotossintético C3, que apresentam em média valores de d‰13C - 28. Os estudos da anatomia foliar e testes histoquímicos confirmaram os resultados encontrados para a d‰13C, onde, a despeito da existência de células parenquimáticas formando um anel ao redor do feixe vascular, estas não apresentaram cloroplastos e amido, confirmando ser A. annua uma espécie de mecanismo...
Abstract: Leaves of Artemisia annua L. are a plentiful source of artemisinin, a drug with proven effectiveness against malaria. One of the objectives of this work was to identify the photosynthetic type of A. annua through studies of the carbon isotope composition (d‰13C) and the leaf anatomy. We also verified the growth and development of the CPQBA 2/39x1V accession under moist subtropical climate. Two experiments were carried out in greenhouse using photoperiodic chambers. The plants were submitted to photoperiods of 7, 9, 11, 13, 15 and 17 h, in two natural conditions of temperature: spring/summer (maximum of 37ºC and minimum of 19ºC) and autumn/winter (maximum of 29ºC and minimum of 13ºC). Another experiment with different planting dates at field was carried out in Pato Branco, PR (26º11' S, 52º36' W and 760 m), Southern part of Brazil. The last experiment was the application of artemisinin (0, 500, 5000, and 10000 mg L-1) in A. annua plants to verify the role of the molecule on the flowering induction. A. annua presented a d‰13C - 31.76 l 0.07, what characterizes it as typical species with a C3 photosynthetic mechanism, with an average of d‰13C- 28, while C4 species possess an average of d‰13C - 14. The study of A. annua leaf anatomy confirms the results of d‰13C, where, in spite of the existence of parenchymatic cells forming a different sheath surrounding of the vascular tissue, these cells do not have chloroplast or starch. These features do not describe the Kranz anatomy typical of C4 species. The application of artemisinin did not induce the flowering of A. annua at any of the concentrations used. The results suggest that the accumulation of the artemisinin in the pre-flowering and flowering phases in A. annua is not the physiological signal of floral induction in this species...
Orientador: Fernando Broetto
Coorientador: Rita Maria Moraes
Banca: João Domingos Rodrigues
Banca: Lin Chau Ming
Banca: Cícero Deschamps
Banca: Vera Lúcia Garcia Rehder
Doutor

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Artemisia annua L. (Asteraceae) é uma planta herbácea altamente aromática, nativa da Ásia e aclimatada no Brasil. As folhas são fonte abundante de artemisinina, uma lactona sesquiterpênica que, conjuntamente aos seus derivados semi-sintéticos, apresentam ação efetiva contra as cepas resistentes das espécies de Plasmodium causadoras da malária. Os objetivos deste trabalho foram identificar o mecanismo fotossintético e avaliar o efeito de diferentes condições de temperatura e fotoperíodo no crescimento e desenvolvimento do acesso CPQBA 2/39x1V de A. annua. Para identificar o mecanismo fotossintético foram realizados experimentos para determinar composição dos isótopos do carbono (d 13C) e a anatomia foliar associada a testes histoquímicos. Para avaliar o efeito da temperatura e fotoperíodo no crescimento e desenvolvimento de A. annua foram realizados dois experimentos em câmaras fotoperiódicas (o primeiro com temperaturas médias máx. de 37ºC e mín. de 19ºC e o segundo com máx. de 29ºC e mín. de 13ºC) e um experimento com 6 épocas de plantio em campo no município de Pato Branco-PR (26º11' S, 52º36' W e 760 m de altitude), sul do Brasil. Um último experimento realizado, foi a aplicação exógena de artemisinina em plantas de A. annua para verificar o papel da molécula na indução do florescimento. Como resultados, A. annua apresentou uma d 13C - 31.76 l 0.07, valor típico de espécies com mecanismo fotossintético C3, que apresentam em média valores de d 13C - 28. Os estudos da anatomia foliar e testes histoquímicos confirmaram os resultados encontrados para a d 13C, onde, a despeito da existência de células parenquimáticas formando um anel ao redor do feixe vascular, estas não apresentaram cloroplastos e amido, confirmando ser A. annua uma espécie de mecanismo...
Leaves of Artemisia annua L. are a plentiful source of artemisinin, a drug with proven effectiveness against malaria. One of the objectives of this work was to identify the photosynthetic type of A. annua through studies of the carbon isotope composition (d 13C) and the leaf anatomy. We also verified the growth and development of the CPQBA 2/39x1V accession under moist subtropical climate. Two experiments were carried out in greenhouse using photoperiodic chambers. The plants were submitted to photoperiods of 7, 9, 11, 13, 15 and 17 h, in two natural conditions of temperature: spring/summer (maximum of 37ºC and minimum of 19ºC) and autumn/winter (maximum of 29ºC and minimum of 13ºC). Another experiment with different planting dates at field was carried out in Pato Branco, PR (26º11' S, 52º36' W and 760 m), Southern part of Brazil. The last experiment was the application of artemisinin (0, 500, 5000, and 10000 mg L-1) in A. annua plants to verify the role of the molecule on the flowering induction. A. annua presented a d 13C - 31.76 l 0.07, what characterizes it as typical species with a C3 photosynthetic mechanism, with an average of d 13C- 28, while C4 species possess an average of d 13C - 14. The study of A. annua leaf anatomy confirms the results of d 13C, where, in spite of the existence of parenchymatic cells forming a different sheath surrounding of the vascular tissue, these cells do not have chloroplast or starch. These features do not describe the Kranz anatomy typical of C4 species. The application of artemisinin did not induce the flowering of A. annua at any of the concentrations used. The results suggest that the accumulation of the artemisinin in the pre-flowering and flowering phases in A. annua is not the physiological signal of floral induction in this species...

The forest product industry is keenly interested in extending the normal planting season, as well as in the comparative field performance of standard nursery bare-root seedlings and containerized rooted cuttings. The effect of seasonal planting dates on survival, above and belowground biomass allocation, water relations, gas exchange attributes and foliar carbon isotope composition (δ13C) of two stock types of slash pine (Pinus elliottii Engelm.) were examined. Slash pine bare-root seedlings (BRS) and containerized rooted cuttings (CRC) were hand planted in September, November, January, March and April in three consecutive planting seasons (2000-2001, 2001-2002 and 2002-2003) on three sites with silt loam topsoils in southwestern Louisiana. First-year mean survival of CRC across all planting dates and sites was consistently high at 96 to 98%, whereas BRS survival was significantly (P < 0.0001) lower at 59 to 81% and highly variable among study sites and dates through three planting seasons. Generally, there was a negative relationship between soil moisture at the time of planting and first-year survival of BRS planted September through March in 2001-2002 and 2002-2003 planting seasons, whereas the opposite was observed only for BRS planted in April 2002 and 2003. Survival of CRC was affected very little by the variation in soil moisture. Containerized rooted cuttings had higher early above and belowground biomass, and height and diameter than did BRS. However, three years after planting the size differences between stock types disappeared or became negligible. Early size differences among trees planted September through March also decreased after three years, although September trees were tallest. Growth of the April-planted trees was poor compared to trees planted in other months. Late-planted April trees had higher δ13C values, and higher water-use efficiency in the first growing season compared to earlier planted trees. Differences in δ13C values among the planting dates disappeared in the second growing season. Net photosynthesis rates did not differ considerably between stock types or among planting dates in the second and third growing seasons. This study indicates that it is possible to extend the planting season to as early as September and as late as March by using CRC.

Cette thèse visait à développer nos connaissances quant au contrôle génétique et environnemental et la structuration géographique de la variabilité phénotypique pour des caractères fonctionnels chez le peuplier noir (Populus nigra L.). Trois caractères fonctionnels ont été étudiés : la phénologie de croissance, WUE et la résistance à la cavitation. La variabilité phénotypique exprimée pour la phénologie de croissance et WUE a été évaluée au sein d’une collection européenne de peuplier noir regroupant 1085 génotypes échantillonnés dans 13 métapopulations et installés en test clonal en pépinière dans deux sites expérimentaux. Nos résultats ont révélé une importante variabilité génétique ainsi qu’une importante plasticité phénotypique des caractères phénologiques et de WUE au sein des métapopulations. Une différenciation génétique modérée à forte des métapopulations a été observée pour la phénologie de croissance et WUE. Les différences entre métapopulations se structuraient selon des patrons plus ou moins complexes, qui semblaient refléter, pour la phénologie de croissance, une adaptation locale des métapopulations aux conditions de photopériode et de température. Tenant compte des capacités de phénotypage limitées pour la résistance à la cavitation, la variabilité génétique exprimée pour ce caractère a été évaluée au sein d’une population naturelle de peuplier noir regroupant 33 génotypes et installée en test clonal en pépinière dans un site expérimental. Nous avons détecté une variation significative du niveau de résistance à la cavitation entre génotypes. De manière générale, aucune relation phénotypique significative n’a été détectée entre la phénologie de croissance, WUE et la résistance à la cavitation au niveau intra-population, suggérant le maintien d’une diversité de combinaisons fonctionnelles. Le développement d’une puce à 10 331 marqueurs SNPs distribués à l’échelle du génome de P. nigra, notamment dans des régions candidates pour la phénologie de croissance, devrait permettre, à court terme, de confirmer l’adaptation locale des populations de peuplier noir et d’explorer ses bases génétiques
This work aimed at improving our understanding of the genetic and environmental control as well as the geographic structure of phenotypic variation for functional traits in black poplar (Populus nigra L.). Three functional traits were studied: bud phenology, water-use efficiency (WUE) and xylem resistance to drought-induced cavitation. The phenotypic variation expressed for bud phenology and WUE was evaluated in a European P. nigra collection composed of 1085 cloned individuals sampled in 13 natural metapopulations and established in clonal test in nursery at two experimental sites. Substantial genetic variation and substantial phenotypic plasticity for bud phenology and WUE were observed within all metapopulations. Moderate to strong genetic differentiation of metapopulations was evidenced for phenological traits and WUE. Patterns of genetic differentiation were more or less complex depending on traits and seemed to reflect, for phenological traits, local adaptation of metapopulations to photoperiod and temperature. Taking into account the limited phenotyping capacity for xylem resistance to cavitation, genetic variation expressed for this trait was evaluated within one single natural population of black poplar composed of 33 genotypes which were established in clonal test in nursery at one experimental site. Significant variations were observed between genotypes for the degree of cavitation resistance. Overall, no significant relationship was detected between bud phenology, WUE and cavitation resistance at the within-population level, indicating the maintenance of a diversity of functional combinations. The development of an array covering 10 331 SNPs distributed across the P. nigra genome, notably in candidate regions for bud phenology, will enable in the short-term to confirm local adaptation of P. nigra populations and to identify its genetic basis

La masse de la baie est le résultat de l’effet intégré de plusieurs facteurs. La recherche a été dessinée afin d’étudier l’effet simultané des facteurs majeurs influençant la masse et la composition de la baie, de les hiérarchiser selon leur degré d’impact à des échelles différentes, de séparer leur effet direct et indirect sur la composition du raisin et de comparer le profil de vins élaborés à partir de petites et grosses baies. L’étude a été conduite sur deux sites expérimentaux, localisés dans les régions de Saint-Emilion (France) et Alcamo (Italie), pendant les années 2014 et 2015. Sur le premier site, les vignes sont plantées sur deux types de sols, tandis que sur le deuxième, deux traitements hydriques étaient appliqués. A l’échelle intra-parcellaire, l’état hydrique de la vigne représente le facteur le plus important, tandis que l’effet du nombre de pépins par baie n’est pas significatif. Des résultats opposés sont obtenus lorsque les relations sont étudiées à l’échelle de la grappe et de la plante. A large échelle, les facteurs impactent directement et indirectement la composition du raisin et les petites baies produisent des moûts et des vins plus concentrés. A l’inverse, à l’échelle de la grappe et de la plante, la masse de la baie n’influence pas la composition du raisin. Seule la concentration en anthocyanes est significativement liée à la masse à toutes les échelles. Cette relation est particulièrement évidente sous conditions hydriques limitantes. Un déficit hydrique augmente le ratio pellicule/pulpe, indépendamment de la masse de la baie. Petites et grosses baies d’une parcelle ayant une condition hydrique homogène, tendent à avoir un profil similaire
Final berry mass is the result of the integrated effect of several factors. They also influence berry composition. The present work was designed to study the simultaneous effect of major factors influencing berry mass and composition, to hierarchize their impact at different scales, to distinguish their direct and indirect effect on berry composition and to compare the profile of wines made from large and small berries. The study was carried out simultaneously on two vineyards located in the Saint Emil ion (France) and Alcamo (Sicily) areas, during 2014 and 2015. On the first site, vines were planted on two soil types, while on the second site two different irrigation treatments were applied. Depending on the scale, some factors homogeneously impacted the berry mass and composition. At the intra-parcel scale, vine water status represented the most impacting factor, while berry seed number did not have significant effect. Opposite results were obtained when the investigation was carried out at the intra-bunch and intra-plant scales. At large scale, factors impacted directly and indirectly berry compounds and grape juices and wines produced from smaller berries were more concentrated. Neither at intra-bunch, nor at intra-plant scales, berry size effect on juice composition was significant. Only anthocyanin concentration was related to berry size at all scales. This fact was particularly obvious in berries produced under limited water conditions. Water deficit increased the skin to flesh ratio, independently of berry size. This means that small and large berries, produced from a single parcel with homogenous water uptake conditions, tend to have similar enological profiles

Western hemlock (Tsuga heterophylla) is one of the most important tree species in coastal British Columbia. Forest fertilization is a method used by foresters to enhance the growth of forest trees, but results are inconsistent for western hemlock. The objective of my research was to explore the use of carbon isotope analysis as a physiological tool to diagnose the nutritional status and potential response of western hemlock to fertilization. Normally cellulose is isolated from wood samples to be analyzed for carbon isotope analysis (expressed as 813C values), but this is a tedious and likely unnecessary process. Reaction wood (high lignin content) and adjacent normal wood in two western hemlock saplings was analysed to evaluate the possible effects of wood composition on 813C. The 8 C values of the lignin and cellulose fractions differed by 3.43 %c ± 0.26 (mean ± SD; n = 40). 813C values of lignin and cellulose from different disk positions were more variable in one sapling than the other. The isotopic mass balance of whole wood was conserved and therefore did not vary with lignin content indicating that use of whole wood, rather than cellulose, is suitable for isotopic analysis. Eight pure western hemlock stands selected and experimentally fertilized in an earlier study were used as source for foliage and stemwood samples. Fertilization treatments applied to these stands in mid to late May of 1995 were as follow: (1) control, (2) N (225 kg/ha), (3) N (225 kg/ha) + P (100 kg/ha), (4) N (225 kg/ha) + P (500 kg/ha), (5) N (225 kg/ha) + P (100 kg/ha) + blend (230 kg/ha), and (6) N (225 kg/ha) + P (500 kg/ha) + blend (230 kg/ha). The blend included additions of S, K, Mg, Zn and Cu. 813C values within foliage and stemwood were analysed after fertilization. At the end of first growing season after fertilization, the effect of treatments on foliar 8 C was almost significant (P = 0.0539) and there was an interaction between sites and treatments. At the end of second growing season, no interaction between site and treatment was evident and the effect of treatments on foliar 813C was not significant. Foliar SO4-S (Sulfate) levels at the end of the first and second growing seasons following fertilization were reduced by either N or N + P fertilization treatments. The change in 813C values of tree rings from before to after nutrient additions was significantly affected by treatment and site and there was an interaction between sites and treatments. N applied alone had no significant effect on change in wood 813C. The greatest change (0.33 %o) was in the NP100 (treatment 3 above) level of treatment. Relative change in six-year basal area increment (BAI) was significantly affected by treatments and sites and there was an interaction between sites and treatments. N applied alone had no significant effect on relative change in basal area increment whereas NP100B (treatment 5 above) had the greatest effect. The relative change in basal area increment was also significantly affected by sites.
Forestry, Faculty of
Graduate

碩士
國立臺灣海洋大學
環境生物與漁業科學學系
105
The aquaculture of Lutjanus argentimaculatus has paid immense attention by countries and is one of the important species of stock enhancement programs in Taiwan. In order to assess the impact of hatchery-produced releasing group on wild stock, identifying fish origin is a critical issue. In this study, samples of wild and hatchery red snapper were collected and 3 culture experiments were conducted. Stable carbon and nitrogen isotopic compositions of the non-lethal tissue, scale, were measured by EA-IRMS for testing whether the chemical signatures in scales can reflect the environmental difference. Original scales were used to analysis for tracing fish sources precisely. Thus, most appropriate original scale sampling area on fish body was investigated. The relationship between total length and scale radius were analyzed for sub-sampling representing the area on scale to its specific life history. The fish samples of culture experiments were from the same hatchery and divided into 3 groups. Group A and B were fed with artificial feeds in indoor tanks and group C prey on natural foods in wild environment. The results suggested that the area under the pelvic fin had the highest proportion of original scales. However, due to scale morphology difference and minimum mass requirements for analysis, the area near the pectoral fin was chosen for further scale sampling. Stable isotopic signatures of the hatchery individuals gradually enriched as ontogenetic stage. The scales were further divided into focus and edge part for comparison, and it was found that δ15N of group C was the same as group B, but different with the edge of group B, corresponding to food sources that the fish were from the same hatchery but differentiated food sources in later stage. The ratio of δ13C in hatchery samples were averaged at -17.2 ± 0.9 ‰ and were significantly different from the wild population at -13.4 ± 2.2 ‰ with a higher variation than the hatcheries. The wild and hatchery samples were analyzed by cluster analysis and random forest model. The result suggested that carbon isotopic value of scale can be used to distinguish hatchery population to their original group with a 100 % correctly classification, but wild population (86.7%) had lower discrimination that was conjectured the misjudgment individuals were released in the past releasing program. Overall, 94.7 % of original groups were correctly classified by using scale stable isotopic signatures. Furthermore, isotopic values of muscle tissues in subgroups of samples analyzed, and a strong linear relationship was existed between 2 types of tissues (δ13CMuscle = 0.822 × δ13CScale - 5.716 ; δ15NMuscle = 0.810 × δ15NScale + 3.285), showing that scales can be used as an alternative tissue for muscles. In summary, we conclude that stable isotopic signatures in scales can provide a powerful non-lethal method to determine the fish origin.

Perennial ryegrass (Lolium perenne L.) is a cool-season turfgrass susceptible to low temperature injury. Wilt-based (WB) irrigation is a common practice in scheduling turf irrigation as an alternative to well-watered (WW). Moisture stress has been shown to promote cold hardiness but this has not been investigated in response to WB irrigation. Measurements of 13C isotope discrimination (DELTA) are useful predictors of water use efficiency (WUE), drought resistance, evapotranspiration (ET) and salinity tolerance but the relevance to turfgrass cold hardiness has not been determined. DELTA analyses may enable more efficient screening protocols in breeding for improved cold hardiness. Objectives of this study were to examine perennial ryegrass genotypes in relation to cold hardiness, DELTA and WUE in response to WW and WB irrigation schedules, to compare genetic diversity between top-performing (TP) and bottom-performing (BP) perennial ryegrass genotypes, and to assess the predictive value of DELTA of for cold hardiness. Six genotypes were selected based on turf quality from the most northern NTEP location (Orono, ME) and included three TP (‘All Star 2’, ‘Mach I’ and ‘Sunkissed’) and three BP (‘APR-1234’, ‘Buccaneer’ and ‘WVPB-R-82’) genotypes. ET, yield, WUE, shoot water content, rooting potential, wilting tendency, DELTA and median lethal temperatures (LT50) using whole-plant survival were measured from greenhouse samples grown in weighing lysimeters in 2007 and 2008. Plant measurements in both years were based on sampling conducted at the last cycle after 68-d of irrigation with 100% of ET applied at leaf-roll (WB) versus ET replacement every 4-d (WW). Lower LT50 values were generally associated with low yield, low WUE and low shoot water content, whether the result of irrigation treatment or genotypic variation. TP genotypes demonstrated significantly lower LT50 temperatures (greater cold hardiness) in comparison to BP genotypes in both years. Modest cold hardiness enhancement with WB irrigation was highest for TP genotypes. Wilting tendency and DELTA were not reliable predictors of cold hardiness, although individual TP genotypes exhibited responses distinctly different than some BP genotypes. Further research is needed to investigate the physiological mechanisms of enhanced turfgrass cold hardiness in response to moisture stress.