Cellular and molecular mechanisms of salinity acclimation in an amphidromous teleost fish

Lee, Jacqueline Amanda

January 2012

Inanga (Galaxias maculatus) is an amphidromous fish species that is able to successfully inhabit a variety of salinities. Using an integrated approach this thesis has characterised for the first time the physiological characteristics that facilitate acclimation in inanga. Structural studies using scanning electron microscopy (SEM) and laser scanning confocal microscopy (LSCM) revealed freshwater-acclimated inanga have a high density of apical pits and freshwater-type mitochondria-rich cells (MRCs) that can facilitate ion absorption from the hypo-osmotic environment. In seawater, inanga remodel their gills by increased proliferation of seawater-type MRCs to facilitate ion secretion in the hyper-osmotic environment. Concentration-dependent sodium (Na+) kinetic analysis revealed that at a whole body level, inanga regulate Na+ using a saturable, high affinity, low capacity uptake system which makes them extremely adept at extracting Na+ from very dilute freshwater environments. In fact inanga displayed an uptake affinity (Km) of 52 ± 29 µM, which is one of the lowest ever recorded in freshwater fish. The sodium/potassium ATPase transporter (NKA) is central to Na+ regulation within the gill. In high salinties inanga displayed increased NKA activity (6.42 ± 0.51 µmol ADP mg protein-1 h-1) in an effort to excrete the excess Na+, diffusively gained from the hyper-osmotic environment. This increase in NKA was most likely a reflection of the proliferation of NKA-containing MRCs. The NKA activities seen in freshwater- and 50% seawater-acclimated inanga were similar (2.54 ± 0.19 and 2.07 ± 0.22 µmol ADP mg protein-1 h-1 respectively) to each other suggesting the inanga gill is capable of supporting ion regulation in brackish waters without a significant increase in NKA activities, and the energetically-expensive changes in gill structure and function that accompany such a change. Molecular investigation of NKA isoform expression using quantitative PCR (qPCR) showed that inanga displayed salinity-induced changes in the expression of the three α NKA isoform variants investigated. Isoform α1a exhibited a pattern consistent with an important role in freshwater, confirming results from other fish species. While it is generally accepted that α1b isoform is the predominant NKA isoform in seawater, inanga did not display this pattern with a freshwater dominance seen. None of the salinity-induced changes could quantitatively explain the increased NKA activity in seawater suggesting that different isoforms may convey different activities, that there is also regulation of NKA at a post-transcriptional level, and/or other isoforms or subunits may have a significant role. The importance of the osmoregulatory hormone cortisol and prolactin is widely accepted and inanga were treated with cortisol, prolactin and a combination of the two in an effort to further elucidate their role. NKA activity and NKA isoform expression were assessed but no specific patterns were deduced, except for a decrease in both NKA activity and isoform expression in 100% seawater-acclimated inanga treated with cortisol and prolactin. The reasons for this decrease were not evident, although the impact of stress induced by the injection protocol was likely to be a confounding factor. The development of a new confocal-based technique in this study was able to describe, for the first time, intracellular sodium levels ([Na+]i) as a function of salinity in an intact euryhaline fish gill cell. Using the fluorescent Na+ indicator dye CoroNa Green this study demonstrated the ability of inanga gill cells to maintain [Na+]i in the face of environmental change. Freshwater-acclimated inanga displayed basal [Na+]i of 5.2 ± 1.8 mM, with 12 ± 2.3 mM and 16.2 ± 3.0 mM recorded in 50% seawater- and 100% seawater-acclimated cells, respectively. Low [Na+]i is advantageous in hypo-osmotic environments as it provides a gradient between the cell and the blood which is essential for generating electrochemical gradients cell volume regulation and other cellular homeostatic mechanisms. A slightly elevated [Na+]i seen at the higher sanities would help minimise the diffusive gradient for passive influx from the environment which would be of benefit in hyper-osmotic environments. Upon salinity challenge 50% seawater cells were equally adept at maintaining a constant [Na+]i at any salinity, suggesting these cells are have the necessary constituents to regulate Na+ in both lower and higher salinities. This novel LSCM approach is advantageous relative to existing transport models as it will allow the observation of cellular ion transport in real time, within a native filament structure displaying functional interaction of different cell types. The extreme ion uptake characteristics of the inanga and their amenability to in situ confocal-based studies demonstrated in this study, confirm inanga as a valuable model species for future research.

Galaxias maculatus

gills

inanga

ion transport

salinity acclimation

sodium

sodium/potassium ATPase (NKA)

osmoregulation

Effects of Variable and Constant Acclimation Regimes on the Upper Thermal Tolerance of Intertidal Barnacle, Balanus Glandula

Guo, Lian W

01 January 2014

As a unique habitat that encompasses steep environmental gradients, it is important to evaluate threats posed to the intertidal zone by rapid climate change. It is thought that intertidal ectotherms are living close to their physiological limit; therefore slight changes in temperature could result in high levels of mortality. Past studies on intertidal species measured thermal tolerance under constant temperatures, neglecting to consider the impacts of natural variation in field temperatures. I conducted a study on the barnacle, Balanus glandula, to assess if a variable thermal environment would alter thermal tolerance. Barnacles were acclimated in an intertidal mesocosm to either daily cold (maximum 20.4◦C), daily warm (maximum 26.5◦C), or variable (two days cold, two days warm) low-tide temperatures. I measured each barnacle’s critical thermal maximum (CTmax) by increasing air temperature 6◦C/hour and identifying the point at which the barnacle ceased to function. Barnacles exposed to any warm temperatures demonstrated an increased thermal tolerance, suggesting that this population of barnacles is capable of shifting their thermal maximum. Furthermore, acclimation to thermal heterogeneity raised thermal maximum, reinforcing the need for future thermal tolerance studies to incorporate biologically-relevant thermal regimes in laboratory experiments. These results demonstrate that B. glandula in the field are well-adapted for increasing air temperatures.

thermal tolerance

acclimation

Balanus glandula

climate change

intertidal

thermal heterogeneity

Terrestrial and Aquatic Ecology

The temperature dependence of plant alternative oxidase and its impact on respiration rates in nature

Searle, Stephanie Yoke-Ying

January 2010

The physiological function of the plant enzyme alternative oxidase has long been a topic of debate. The cyanide-resistant alternative oxidase (AOX), along with the cytochrome c oxidase (COX), catalyzes the reduction of oxygen to water in the electron transport chain of mitochondrial respiration. Although respiration via the alternative pathway (AP) results in approximately one third of the ATP production as respiration via the cytochrome pathway (CP), the AP is utilized by all plants and some fungi and animals. This “energy wasteful” pathway has been proposed to reduce oxidative stress in plant cells under a variety of stressful conditions. Virtually all previous work on the AP has been performed on laboratory-grown plants in controlled environment conditions; thus, there is little knowledge of how the AP responds to unstable conditions and multiple environmental stresses in the field. This thesis presents new methodology for studying AP respiration and the AOX protein in field-grown plants, and investigates how the AP responds to natural changes in environmental conditions in the field in several plant species grown in diverse ecosystem types. The experimental work presented here also investigates how AP activity is related to changes in total rates of respiration, and questions whether abundance of the AOX protein determines electron partitioning to the AP. AP partitioning (or relative changes in AP partitioning) varied over seasonal timescales in each of the experimental studies. Chapter 3 reports on two species of Chionochloa, a native New Zealand tussock grass growing along an altitudinal gradient. In Chapter 4, seasonal variation was studied in two tree types: Populus x canadensis, a deciduous angiosperm, and Pinus radiata, an evergreen gymnosperm. Quercus rubra trees were studied along an urban-rural gradient originating in New York City in Chapter 5. In a highly exposed and variable environment, relative changes in AP partitioning in two species of Chionochloa were correlated with the previous day’s integrated light. In Quercus rubra, the AP was instead related to temperature changes: relative AP partitioning increased in response to seasonally low temperature in trees grown at colder, more rural field sites, while at the warmer, urban sites, it increased in response to high summer temperatures. Each of these environmental conditions that were related to increases in the AP (high light, low temperatures, and heat) are potentially stressful to plants. Thus, it is possible that the increases in AP respiration observed in these studies served to oxidize excess reducing equivalents generated through stressful conditions. In Chapter 4, although AP partitioning in Populus x canadensis and Pinus radiata varied seasonally, these changes were not directly related to environmental parameters. However, AP partitioning in Populus x canadensis was clearly shown to be dependent on measurement temperature. In each of the studies presented here, changes in the AP were not related to abundance of the AOX protein. AOX protein abundance showed consistent seasonal patterns in the two deciduous angiosperms, Populus sp. and Quercus sp, and was correlated with seasonal changes in temperature in Chionochloa spp. However, the lack of correlation between protein abundance and AP partitioning indicates that the AP is subject to post-translational control and likely varies more rapidly than protein levels. In each of Chapters 3 – 5, there was no clear impact of changes in AP partitioning on rates of total respiration. As the AP produces less ATP than the CP, I hypothesized that increases in AP activity would lead to higher respiration rates in order to meet a plant’s energy demands. However, in Populus x canadensis and Quercus rubra, respiration rates remained stable during sharp increases in AP partitioning, indicating that, at least under certain conditions, increases in AP activity are accompanied by a decrease in the CP. In some of the first research studying AP partitioning in field-grown plants, this thesis illuminates possible mechanisms, functions, and implications of the AP. Over a range of plant taxa and environmental settings, this work shows that the AP does respond to stressful conditions in the wild, but that this does not result in increased respiration. Lastly, the methods presented here to study AP activity and AOX proteins in the field enable future studies to further probe the specific responses of AOX to natural stresses.

leaf respiration

alternative oxidase

cytochrome oxidase

temperature

acclimation

oxygen isotope discrimination

seasonal variation

The response of photosynthesis and respiration of a grass and a native shrub to varying temperature and soil water content

Joseph, Tony

January 2011

In New Zealand, native shrubs are considered an important potential carbon-sink in disturbed or abandoned land (e.g., pastoral land that is unsustainable for long-term pastoral agriculture). However, the impact of varying environmental drivers on carbon uptake from photosynthesis and carbon loss from respiration of a developing shrubland remains uncertain. In this study, the effects of both temperature and soil water content (θ) on photosynthesis and respiration were examined under controlled growth cabinet and field conditions in a pasture grass and the native shrub, kānuka (Kunzea ericoides var. ericoides). The purpose of the investigation was to assess the combined impacts of varying temperature and θ on canopy processes and to disentangle the effects of θ on photosynthesis and respiration for the two different plant types. A controlled growth cabinet study (Chapter 2) showed that θ had a greater effect on the short-term temperature response of photosynthesis than the temperature response of respiration. The optimum value of θ for net photosynthesis was around 30 % for both kānuka and the grass. Statistical analysis showed that the temperature sensitivity of photosynthetic parameters was similar for both plant types, but the sensitivity of respiratory parameters was different. Reduction in θ induced an inhibition of photosynthetic capacity in both plant types. The response of respiratory parameters to θ was not related to substrate limitations, however available evidence suggests that it is likely to be a species dependent plant mechanism in regulating the cost of maintenance due to reduced photosynthate assimilation and decreasing energy supply to support the activity of respiratory enzymes. Results obtained from a field study (Chapter 3) showed that photosynthesis and respiration in the grass and kānuka were sensitive to seasonal changes in temperature and θ. Photosynthetic parameters showed little acclimation following changes in seasonal growth conditions. In contrast, respiratory parameters tended to acclimate more strongly. Respiratory acclimation to multiple environmental conditions was characterised by changes in temperature sensitivity and a shift in the response of respiration to temperature, demonstrating the involvement of both ‘Type I’ and ‘Type II’ acclimation in both plant types. The results from controlled growth cabinet and field studies were used to drive a leaf level model that integrates the responses of photosynthesis and respiration to changes in temperature and θ and incorporates acclimation using variable photosynthetic and respiratory parameters (Chapter 4). This model was used to estimate the annual canopy carbon exchange of the grass and kānuka in response to seasonal changes and to predict changes in canopy carbon exchange under varying future climate change scenarios. The model highlighted the importance of considering seasonally-acclimated parameters in estimating canopy carbon exchange of both plant types to concurrent changes in multiple environmental variables. The overall results support the conclusion that understanding the combined effects of environmental variables on canopy processes is essential for predicting canopy net carbon exchange of a pasture-shrub system in a changing global environment. It has been shown here that the rate of increase in photosynthesis with increasing θ is greater than that of respiration which results in a progressively greater apparent carbon gain at moderate values of θ. Moreover, the impact of lower values of θ, which reduced the apparent sensitivity of respiration to temperature, may effectively decrease the rate of respiration during warmer summer months and enhance thermal acclimation via downregulation of respiration. Therefore, considering the influence of soil water conditions on the temperature sensitivity of photosynthetic and respiratory model parameters has important implications for precisely predicting the net carbon exchange of a pasture-shrub system.

Photosynthesis

Respiration

Acclimation

Pasture grass

Shrub

Kanuka

Temperature

Soil water content

Phenotypic Plasticity and Population-level Variation in Thermal Physiology of the Bumblebee 'Bombus impatiens'

Rivière, Bénédicte Aurélie

17 April 2012

Temperature variation affects most biological parameters from the molecular level to community structure and dynamics. Current studies on thermal biology assess how populations vary in response to environmental temperature, which can help determine how populations differentially respond to climate change. To date, temperature fluctuation effects on endothermic poikilotherms such as the common eastern bumblebee (Bombus impatiens) are unknown even though bumblebees are the most important natural pollinators in North America. A cold-acclimation experiment with B. impatiens colonies revealed individuals acclimated to 5°C or 10°C at night did not differ in resting metabolic rate, flight metabolic rate, wingbeat frequency, or morphological measurements, compared to the control group. Moreover, an infrared camera showed that all colonies maintained maximum nest temperature consistently above 36.8°C. A latitudinal sampling of flight metabolic rate and morphological measurements of B. impatiens from four locations spanning Ontario (N 45°; W 75°) to North Carolina (N 34°; W 77°) indicated no latitudinal trend in the measured variables. This study shows that bumblebees are well equipped to face a wide range of environmental temperatures, both in the short term and long term, and can use a combination of behavioural and physiological mechanisms to regulate body and nest temperatures. These results are reassuring on the direct effects of climate change on bumblebee ecology, but further studies on the indirect effect of temperature variation on North American bumblebees are required to predict future ecosystem dynamics.

bumblebee

Bombus

metabolic rate

wingbeat frequency

thermoregulation

phenotypic plasticity

thermal acclimation

latitudinal compensation

Bombus impatiens

Mechanisms regulating the thermal acclimation of dark respiration in snow tussock and ryegrass

Clifford, Veronica Rose

January 2007

The aim of this research was to identify the mechanisms that underpin changes in respiratory capacity during acclimation to temperature. Dark respiration, enzyme activities and leaf ultrastructure were measured from ryegrass (Lolium perenne) in controlled environmental chambers and two species of native grass (Chionochloa rubra & C. pallens) growing at different altitudinal ranges on Mount Hutt, Canterbury, New Zealand. The overall hypothesis was that the changes in both mitochondrial numbers and enzyme activity underpin the greater respiratory capacity observed in response to decreasing temperatures. Gas exchange measurements were carried out to measure rates of dark respiration (Rd) in leaves of both ryegrass and tussocks. Respiratory homeostasis (full acclimation) was achieved in ryegrass leaves but only partial acclimation in both species of tussock plants. Dark respiration rates for warm-grown ryegrass were greatly reduced compared to cool-grown grasses. Rd was lower for C. rubra growing at the base of the mountain (450m) compared to plants at a higher altitude (1060m). The dark respiration rates were also lower for C. pallens growing at 1070m than at 1600m. When comparing Rd between high and low altitude plants, it was significantly lower in low altitude plants at 450m than at 1600m. Oxygen consumption was measured in intact leaves and roots, crude mitochondria and isolated mitochondria from ryegrass to investigate whether a change in respiratory capacity was involved with changes in Rd. Mitochondrial respiratory capacity was slightly reduced in warm leaves and roots (not significantly). The respiratory capacity results from isolated mitochondria for C. rubra (at 450m and 1060m) and C. pallens (at 1070m and 1600m) were consistent with the hypothesis that plants from warm sites have lower respiratory capacity in comparison to plants from cool sites. Based on these results and those of previous studies, it was concluded that respiratory flux for any given temperature is not simply determined by maximal capacities of the respiratory apparatus but rather a combination of the availability of substrate supply, the demand for respiratory products (i.e. ATP) and/or the maximal capacity of respiratory enzymes. Utilizing transmission electron micrographs, it was found that mitochondria were significantly less abundant in warm-grown than cool-grown ryegrass mesophyll cells. Mitochondria dimensions increased slightly between the cool and warm treatment. At lower altitudes (C. rubra), there was a significant decrease in mitochondria numbers with decreasing elevation. At higher altitudes (C. pallens), there was no noticeable change in mitochondria numbers between 1070m and 1600m. It was concluded that mitochondrial abundance for the controlled and field experiments, and mitochondrial sizes in the field, were associated with changes in Rd. The maximal activities of fumarase and succinate dehydrogenase (SDH) in isolated mitochondria from leaves of ryegrass and tussock were measured spectrophotometrically. The results in the controlled experiment indicate that enzymes other than fumarase and SDH could be responsible for the increased respiratory capacity observed in cold acclimated leaves of ryegrass. However, fumarase maximal activity was significantly reduced in C. rubra at low altitude compared with C. pallens growing at high altitude - this suggests that it may be involved in the differences in respiratory capacity and Rd between the two sites. Succinate dehydrogenase did not differ significantly in response to altitude. The large difference between the two field sites for fumarase activity is comparable to the large difference in Rd and reduction in mitochondrial abundance and dimensions seen between the two sites. This supports the overall hypothesis that cool-grown plants keep up with energy demands at low temperatures by increasing enzyme concentrations/capacity. The results of this study are supportive of the hypothesis that growth in low altitudes and warm conditions will result in the reduction of Rd as a consequence of: (1) temperature sensitivity of the respiratory apparatus, resulting in the reduction of the respiratory capacities of mitochondria; (2) a reduction in mitochondria size and numbers; and as a consequence of this (3) a reduction in the activities of mitochondrial enzymes. However, these responses are species specific and vary according to the range of temperatures experienced by plants in the field and controlled environments.

acclimation

respiration

Lolium perenne

Chionochloa rubra

Chionochloa pallens

ultrastructure

mitochondria

fumarase

succinate dehydrogenase

Φωτοσυνθετικές διαφορές φύλλων φωτός και σκιάς μετρούμενες με μεθόδους επαγωγής του φθορισμού της χλωροφύλλης

Μπεσσόνοβα, Αναστασία

24 October 2012

Οι μορφολογικές, φυσιολογικές και βιοχημικές προσαρμογές των φυτών (ή φύλλων) με διαφορετική έκθεση στην ηλιακή ακτινοβολία (σε συνθήκες πλήρους φωτός ή φυσικής σκίασης στο εσωτερικό της φυτικής κόμης) έχουν μελετηθεί και καταγραφεί λεπτομερώς. Στην παρούσα εργασία επανεξετάσαμε κάποιες από τις φυσιολογικές αυτές προσαρμογές, εκμεταλλευόμενοι τα πλεονεκτήματα της χρήσης σύγχρονων μεθόδων μέτρησης του in vivo φθορισμού της χλωροφύλλης. Επίσης, διερευνήθηκε η ύπαρξη προσαρμογών της φωτοσυνθετικής συσκευής σε διαφορετική ένταση φωτός, οι οποίες δεν ήταν είχαν μελετηθεί διεξοδικά. Πιο συγκεκριμένα, χρησιμοποιήθηκαν διαφορετικές τεχνικές φθορισμομετρίας, με τις οποίες μελετήθηκαν συγκριτικά αφ’ ενός οι κβαντικές αποδόσεις και οι περιορισμοί στα επιμέρους στάδια της φωτοσυνθετικής ροής ηλεκτρονίων και αφ’ ετέρου το ποσοστό συμμετοχής της κυκλικής ροής ηλεκτρονίων γύρω από το PSI και της φωτοαναπνοής στα φύλλα φωτός και σκιάς. Με βάση τα αποτελέσματά μας, θεωρούμε ότι το JIP-test μπορεί να προσφέρει αξιόπιστα και αξιοποιήσιμα αποτελέσματα. Πιο συγκεκριμένα, στα φύλλα που είναι προσαρμοσμένα στη σκιά φαίνεται να υπάρχει ένα εμπόδιο στη γραμμική ροή ηλεκτρονίων που εντοπίζεται γύρω από το φωτοσύστημα Ι. Οι παράμετροι που υποδεικνύουν αυτή την κατάσταση δείχνουν ότι περιοριστικός παράγοντας της ροής ηλεκτρονίων φαίνεται να είναι το μικρότερο ποσό των ενεργών κέντρων του PSI (1-VI) σε συνδυασμό με τα μικρότερα αποθέματα των τελικών αποδεκτών ηλεκτρονίων του (1/VI). Αυτό επιβεβαιώνεται από τη μικρότερη πιθανότητα μεταφοράς των ηλεκτρονίων από τους ενδιάμεσους φορείς στους τελικούς αποδέκτες ηλεκτρονίων του PSI (δRo) στα φύλλα σκιάς. Επιπρόσθετα, στην πλειοψηφία των φυτικών ειδών που εξετάστηκαν, η διαφορετική ποιότητα φωτός που δέχονται τα φύλλα σκιάς (φως εμπλουτισμένο σε βαθύ ερυθρό, που διεγείρει επιλεκτικά το PSI) σε σχέση με τα φύλλα φωτός φαίνεται να αυξάνει την κυκλική ροή ηλεκτρονίων γύρω από το PSI. Σε αυτά τα είδη οι προαναφερθείσες παράμετροι του JIP-test έχουν καλή συσχέτιση με το μέγεθος της κυκλικής ροής ηλεκτρονίων. Τέλος, μελετώντας τη φωτοαναπνοή, προκύπτει ότι στα φύλλα φωτός το ποσοστό του κύκλου C2 αυξάνεται με την αύξηση της φωτεινής ακτινοβολίας. Τα φύλλα σκιάς από την άλλη, φαίνεται να έχουν ένα όριο ως προς την προσαρμογή τους σε υψηλές εντάσεις φωτός. / The morphological and biochemical adjustments of plant leaf to high and low light intensity have been widely studied and recorded over the past years. In the present work, some of those physiological adjustments have been re-evaluated with the use of modern methods. In parallel, novel aspects of the light/shade acclimation syndrome were sought. Our results indicate that the JIP-test is quite useful for assessing parameters related to the function of both photosystems. In shade leaves, a lower content of PSI reaction centers (1-VI) combined with a smaller pool size of final electron acceptors of PSI seem to create an obstacle in linear electron flow around photosystem I. This is confirmed by the lower efficiency of electron transfer between intermediate carriers to the reduction of end electron acceptors of PSI (δRo). In addition, in the majority of plant species examined, shade leaves have higher rates of cyclic electron flow around PSI, which is probably caused by the quality of incident light (enriched in far red, FR). In these species there is good correlation between cyclic electron flow and the JIP-test parameters mentioned above. Photorespiration is known to be higher when the plant is under stress. Light acclimated leaves seem confirm that theory as they have higher oxygenase activity of Rubisco with increasing light intensity. On the other hand, shade leaves seem unable to fully adjust to very high light intensity.

Φωτοσύνθεση

Προσαρμογή φυτών

Φως

Σκιά

575.57

Photosynthesis

Plant acclimation

Light

Shade

Necropolis : yellow fever, immunity, and capitalism in the Deep South, 1800-1860

Olivarius, Kathryn

January 2016

This thesis is a social history of disease and mortality in the American Deep South before the Civil War. Yellow fever attacked the region at epidemic levels every two or three years between 1800 and 1860, killing about eight percent of the urban population, and as many as 20 or 30 percent of recent migrants from Europe. With little epidemiological understanding of mosquito-borne viruses-and almost no public health infrastructure to ameliorate disease-the only real protection from this scourge was to "get acclimated": fall sick with, and survive, yellow fever. About half of all people would die in the acclimating process. By placing the Deep South within an Atlantic disease diaspora uncontained by continental boundaries, the project shifts the fault-lines of the Southern past from North-South political conflicts onto similarly formative but overlooked ecological processes in the Greater Caribbean. Yellow fever and mass mortality are largely absent from the recent historiography on the cotton kingdom and "slave racial capitalism." But as well as being a “slave society,” this thesis suggests the Deep South was also a "disease society": Deep Southerners discussed yellow fever obsessively, worked according to its seasonal schedule, and judged others based on their perceived vulnerability to the disease. Yellow fever, and immunity to it, profoundly shaped the asymmetrical hierarchies of Deep Southern society, with acclimated "immunocapitalist" creoles on top, and unacclimated "foreigners" below. Slavers and their allies argued only intellectually-inferior but naturally-resistant black people could perform the arduous labour of sugar and cotton cultivation in the Deep South, as whites too frequently died. This became the region's chief argument for permanent racial slavery. However, almost every slave revolt in Louisiana coincided with a particularly bad epidemic, suggesting slaves found disease politically intriguing and understood that yellow fever left white society chaotic and vulnerable to attack.

Respostas fisiológicas e estruturais em plantas submetidas a estresse hídrico recorrente em diferentes condições de luz

Rodrigues, Angélica Lino.

January 2018

Orientador: Luiz Fernando Rolim de Almeida / Resumo: As plantas estão expostas à seca extrema e cada vez mais frequente devido aos cenários das mudanças climáticas. A superação dos períodos de estresse hídrico e a rápida recuperação com o retorno da estação chuvosa são características de ajuste importantes para o estabelecimento e distribuição dos vegetais. Para amenizar os danos causados pela seca e intensa radiação, o metabolismo vegetal dispõe de mecanismos bioquímicos, anatômicos e epigenéticos que auxiliam na eliminação de radicais livres, no transporte e reserva de água e garantem respostas mais rápidas à reidratação assim que a água estiver novamente disponível no ambiente. Neste contexto, estudos baseados na deficiência hídrica se limitam em expor plantas a apenas um ciclo de défice, o que não acontece normalmente no ambiente. Os vegetais armazenam informações de estresses precedentes que não se resumem a padrões de sinalização isolados, mas funcionam como marcas deixadas anteriormente que auxiliam nas respostas a adversidades futuras. Deste modo, as consequências da seca de forma recorrente relacionando o estresse e a reidratação pós-estresse ainda não são bem compreendidos. A espécie utilizada para este estudo foi a Copaifera langsdorffii Desf. que possui folhas com mecanismos anatômicos e fisiológicos para superação das alterações ambientais. É conhecida pelas propriedades medicinais por meio do óleo amplamente consumido pela população em geral. Copaifera langsdorffii que ocorre em ambientes de diferentes regimes híd... (Resumo completo, clicar acesso eletrônico abaixo) / Abstract: Plants are exposed to extreme drought increasingly frequent due to climate change scenarios. Overcoming periods of water stress and fast recovery with the rainy season return are characteristics of important adjustment for the establishment and wide vegetables distribution. To mitigate the damages caused by drought and intense radiation, plant metabolism features biochemical, anatomical and epigenetic mechanisms that assist in scavenging free radicals, increase the transport and water supply and ensure faster response to rehydration as soon as water is available in the environment again. In this context, studies based on water deficiency are limited to exposing plants only in one deficit cycle, which does not normally happen in the environment. Vegetables store information from previous stresses that are not limited to isolated signaling patterns, but function as previously left imprint that assist in responses to future adversities. Thus, the consequences of recurrent drought form related to stress and post-stress rehydration are not well understood yet. The species used for this study was Copaifera langsdorffii Desf. which has leaves with anatomical and physiological mechanisms to overcome environmental changes. The species has medicinal properties through the oil widely consumed by Brazilian population. It is present in several vegetation types in Brazil and South America that have different water and light pattern. These factors, among others, make this one of the most im... (Complete abstract click electronic access below) / Doutor

Aclimatação.

Copaifera langsdorffii

luminosidade

marca de estresse

seca

acclimation

Copaifera langsdorffii

drought

luminosity

stress imprint

Mechanisms of heat acclimation and exercise performance

Lorenzo, Santiago, 1978-

03 1900

xvii, 245 p. : ill. A print copy of this thesis is available through the UO Libraries. Search the library catalog for the location and call number. / There has been a lot of research investigating the effects of heat stress and exercise on the physiological adaptations to heat acclimation. It is well documented that heat acclimation improves heat tolerance and performance in a hot environment; however, some of the mechanisms of adaptation are not clear. Furthermore, the role of heat acclimation on exercise performance in cool environments is currently unknown. Therefore, in Chapter IV we aimed to determine the effects of heat acclimation on lactate threshold and maximal oxygen uptake (VO 2max ) in cool and hot conditions. We also sought to investigate the effects of heat acclimation on leg blood flow and oxygen delivery during a single-leg knee extensor exercise. We found that heat acclimation improved lactate threshold and VO 2max in cool and hot environments but did not alter the leg blood flow and oxygen delivery during the leg kicking exercise. In Chapter V we investigated the heat acclimation effects on performance during a 1-hour time trial in hot and cool environmental conditions and the potential mechanisms by which this occurs. A secondary objective was to study whether the pacing strategy was modified during the time trial post-heat acclimation. The results demonstrated that heat acclimation improved time trial performance in both thermal environments by approximately 7% but pacing strategy was not altered. The purpose of the studies in Chapter VI were twofold. First, we sought to investigate how heat acclimation affects the skin blood flow and sweating responses to pharmacological treatment with specific dosages of the muscarinic receptor agonist acetylcholine. Second, we examined the maximal skin blood flow responses to a period of heat acclimation by locally heating the forearm with a water spray device for 45 minutes and measured brachial artery blood flow via ultrasound. We found that heat acclimation increased sweat rate and skin blood flow responses to given concentrations of acetylcholine, suggesting a role for peripheral mechanisms. On the other hand, maximal skin blood flow remained unchanged after heat acclimation. / Committee in charge: Christopher Minson, Chairperson, Human Physiology; John Halliwill, Member, Human Physiology; Andrew Lovering, Member, Human Physiology; Michael Sawka, Member, Not from U of 0; Scott Frey, Outside Member, Psychology

Heat acclimation

Exercise performance

Heat stress

Lactate threshold

Blood flow

Kinesiology

Physiology