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Low temperature acclimation in plants : alterations in photosynthetic carbon metabolismLundmark, Maria January 2007 (has links)
<p>Although low temperature plays an important role in determining agricultural yield, little is known about the effect on the underlying biochemical and physiological processes that influence plant growth. Photosynthesis and respiration are central to plant growth and both processes are heavily affected by temperature. However, many plants have the ability to cope with low temperature and resume growth by cold acclimating.</p><p>We have shown that enhancement of carbon fixation, an increased flux of carbon into sucrose and the recovery of diurnal export is crucial for the recovery of functional carbon metabolism at low temperature in Arabidopsis thaliana. The recovery of efflux is governed by increased expression of sucrose transporters along with changes in vascularisation. We also demonstrate the importance of controlling the flux of metabolites between the chloroplast and the cytosol by regulating the expression of AtTPT.</p><p>We further investigated the difference in response between leaves developed at low temperature but originating from warm grown Arabidopsis and leaves from plants grown from seed at low temperature. We were able to distinguish factors that respond specifically to low temperature from those that are connected to the actual stress. Substantial difference could be seen in the different metabolomes. One conclusion drawn is that the increase in sucrose reported at low temperature is an essential feature for life in the cold. </p><p>In an extended study we were able to transfer some of the key factor of cold acclimation in Arabidopsis to other species. The study included forbs, grasses and evergreen trees/shrubs showed that there are striking similarities in the extent and biochemical changes that underpin acclimation among the different functional groups.</p><p>Low temperature does not only influence growth of the leaves, perennial organs such as the corm of the ornamental plant Crocus vernus is also affected. However in these plants low temperature has a positive effect on the final size of the corm. We were able to show that this enhanced growth was an affect of increased cell size and thus increased sink capacity, which ultimately delays leaf senescence</p>
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Ecophysiology of the Gray Snapper (Lutjanus griseus): Salinity Effects on Abundance, Physiology and BehaviorSerrano, Xaymara M. 01 January 2008 (has links)
Mangroves and seagrass beds serve as essential fish habitat for many economically- and ecologically-valuable species. Depending on their location, these shallow-water habitats are often characterized by substantial fluctuation in salinity levels, which can represent a source of osmoregulatory stress for associated organisms. In South Florida, one of the most important fish species that utilizes these habitats is the gray snapper (Lutjanus griseus). Although this species constitutes a significant portion of the region?s total recreational fishery harvest, the effects of salinity on its distribution, physiology and behavior remain poorly understood. The main goal of this thesis was then to investigate the ecophysiological basis of habitat selection by the gray snapper. Specific objectives include to: (1) examine patterns of distribution and abundance across gradients in environmental salinity; (2) measure physiological status and responses to controlled salinity challenges and; (3) conduct behavioral trials to examine for salinity preferenda (if any). To begin investigating if salinity could be a primary factor structuring the gray snapper assemblages, I examined empirical data collected from Biscayne Bay to test the null hypothesis that gray snapper abundances were evenly distributed along the full salinity range at which samples have been collected. Using the delta approach, three abundance metrics (frequency of occurrence, concentration and delta density) were used as an index for the distribution and abundance of this species. Results indicated that abundance patterns for the smaller gray snapper were consistent with a strategy of reducing osmoregulatory costs by selecting intermediate salinities. However, corresponding abundance patterns for subadult gray snapper were inconsistent with this strategy of minimizing energetic costs, suggesting that this life stage may be indifferent to the range of salinities at which they were observed. These patterns helped developed further hypotheses regarding the ecophysiology of juvenile and subadult gray snapper, the latter of which was then tested via laboratory experiments. Subsequently, I challenged fish in the laboratory with six different salinity treatments (0, 5, 30, 50, 60 and 70ppt, including control) for 192 consecutive hours and collected blood samples at different time points. Results indicated that physiological stress to salinity changes is unlikely to occur at a salinity range of 5 to 50 ppt. At salinities of 0 and 60 ppt transient significant changes in plasma osmolality and/or blood haematocrit were observed, but were corrected after an initial adjustment period of approximately 96 hours. At the highest salinity treatment (70 ppt), a constant osmolality could not be maintained, resulting in death for all fish within 48 hours of exposure. Overall, these findings demonstrate the strong euryhalinity and extraordinary tolerance of this species to both extreme hypo- and hypersaline environments. Finally, I investigated the salinity preference and effects on swimming behavior of the gray snapper in an automated salinity choice shuttlebox via 48-hr trials. In general, gray snapper tested displayed either one of two distinctively different salinity preferences. Half of gray snappers displayed a salinity preference in the range of 9-15 ppt, whereas the other half displayed a salinity preference in the range of 19-23 ppt. Recorded swimming speeds in all fish tested reflected a significant, but weak negative linear relationship with salinity during both time periods of the day (light and dark); however, gray snapper were usually most active during the dark period across all salinities. Overall, these findings reveal that gray snapper prefer slightly hyperosmotic salinities that may minimize the physiological costs of osmoregulation compared to extreme salinities.
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Low temperature acclimation in plants : alterations in photosynthetic carbon metabolismLundmark, Maria January 2007 (has links)
Although low temperature plays an important role in determining agricultural yield, little is known about the effect on the underlying biochemical and physiological processes that influence plant growth. Photosynthesis and respiration are central to plant growth and both processes are heavily affected by temperature. However, many plants have the ability to cope with low temperature and resume growth by cold acclimating. We have shown that enhancement of carbon fixation, an increased flux of carbon into sucrose and the recovery of diurnal export is crucial for the recovery of functional carbon metabolism at low temperature in Arabidopsis thaliana. The recovery of efflux is governed by increased expression of sucrose transporters along with changes in vascularisation. We also demonstrate the importance of controlling the flux of metabolites between the chloroplast and the cytosol by regulating the expression of AtTPT. We further investigated the difference in response between leaves developed at low temperature but originating from warm grown Arabidopsis and leaves from plants grown from seed at low temperature. We were able to distinguish factors that respond specifically to low temperature from those that are connected to the actual stress. Substantial difference could be seen in the different metabolomes. One conclusion drawn is that the increase in sucrose reported at low temperature is an essential feature for life in the cold. In an extended study we were able to transfer some of the key factor of cold acclimation in Arabidopsis to other species. The study included forbs, grasses and evergreen trees/shrubs showed that there are striking similarities in the extent and biochemical changes that underpin acclimation among the different functional groups. Low temperature does not only influence growth of the leaves, perennial organs such as the corm of the ornamental plant Crocus vernus is also affected. However in these plants low temperature has a positive effect on the final size of the corm. We were able to show that this enhanced growth was an affect of increased cell size and thus increased sink capacity, which ultimately delays leaf senescence
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Leaf photosynthesis in wheat (<i>Triticum</i> spp.) under conditions of low temperature and CO2 enrichment.Chytyk, Cody John 22 June 2010
It is well known that photosynthetic health impacts the overall fitness of the mature plant. This study aims to determine photosynthetic vigour of spring wheat cultivars during field development as well as their biomass composition at maturity to determine which cultivars/varieties would be optimum for cellulosic ethanol production. Additionally, specimens were grown at non-acclimating (20˚C), cold acclimating (5˚C), non-acclimating high CO2 (20˚C/750 µmol mol-1 CO2) and cold-acclimating high CO2 (5˚C/750 µmol mol-1 CO2) to resolve photosynthetic responses to different environments. Plants were photoinhibited under high irradiance (5 fold growth irradiance) and low temperature (5˚C) while photochemical efficiency of PSII was monitored throughout using chlorophyll fluorescence imaging. Vegetative production was monitored using normalised difference vegetation index. De-epoxidation of xanthophyll photoprotective pigments were also recorded using HPLC and photochemical reflectance index. Additionally, carbon assimilation rate was recorded with infra-red gas analysis methods. It was discovered that no one wheat cultivar demonstrated any photosynthetic advantage in the field or under photoinhibitory conditions. However, photosynthetic differences were observed between wheat grown in different environments. Plants that were cold-acclimated or grown under high CO2 were more resilient to photoinhibitory stress. This was also reflected by most cold-acclimated cultivars having increased triose phosphate utilization, electron transport and zeaxanthin induction. Plants acclimated to high CO2 at room temperature also displayed increased electron transport and triose phosphate utilization but had decreased zeaxanthin induction. It is hypothesized increased excitation pressure in cold acclimated and high CO2 cultivars allowed for their increase in the development of photoinhibitory tolerance.
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Leaf photosynthesis in wheat (<i>Triticum</i> spp.) under conditions of low temperature and CO2 enrichment.Chytyk, Cody John 22 June 2010 (has links)
It is well known that photosynthetic health impacts the overall fitness of the mature plant. This study aims to determine photosynthetic vigour of spring wheat cultivars during field development as well as their biomass composition at maturity to determine which cultivars/varieties would be optimum for cellulosic ethanol production. Additionally, specimens were grown at non-acclimating (20˚C), cold acclimating (5˚C), non-acclimating high CO2 (20˚C/750 µmol mol-1 CO2) and cold-acclimating high CO2 (5˚C/750 µmol mol-1 CO2) to resolve photosynthetic responses to different environments. Plants were photoinhibited under high irradiance (5 fold growth irradiance) and low temperature (5˚C) while photochemical efficiency of PSII was monitored throughout using chlorophyll fluorescence imaging. Vegetative production was monitored using normalised difference vegetation index. De-epoxidation of xanthophyll photoprotective pigments were also recorded using HPLC and photochemical reflectance index. Additionally, carbon assimilation rate was recorded with infra-red gas analysis methods. It was discovered that no one wheat cultivar demonstrated any photosynthetic advantage in the field or under photoinhibitory conditions. However, photosynthetic differences were observed between wheat grown in different environments. Plants that were cold-acclimated or grown under high CO2 were more resilient to photoinhibitory stress. This was also reflected by most cold-acclimated cultivars having increased triose phosphate utilization, electron transport and zeaxanthin induction. Plants acclimated to high CO2 at room temperature also displayed increased electron transport and triose phosphate utilization but had decreased zeaxanthin induction. It is hypothesized increased excitation pressure in cold acclimated and high CO2 cultivars allowed for their increase in the development of photoinhibitory tolerance.
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Effect of temperature on the physiology of two exotic frogs: possible causes of distributionAllen, Leon Akila Glynne January 2015 (has links)
Two Australian frogs were introduced to New Zealand over 100 years ago. Since their introduction they have become widespread and well established with Litoria ewingii being more prevalent in alpine and cooler areas of New Zealand, while Litoria raniformis is found in more temperate coastal areas. Very little physiological data
exists for these frogs and aside from their distribution not much is known about them in New Zealand. Thus the effects of thermal acclimation and temperature change on respiration and locomotion were examined in these two exotic frogs. The more terrestrial and alpine dwelling L. ewingii was found to be able to thermally acclimate
its respiration performance, where respiration was highest when acclimation temperature matched test temperature. It was also able to thermally acclimate its locomotory performance, jumping significantly further at lower temperatures, however, acclimation to high temperatures impacted its jump performance at cold temperatures. The frog L. raniformis was found to only be able to thermally acclimate its respiration and locomotion to high temperatures, as performance at low temperatures was often poor. The data shows that L. ewingii is a cold temperate frog rather than a warm habitat frog, while L. raniformis is an animal adapted to warm
temperatures. From this we can begin to see the effect that temperature has on the physiology of these two exotic frogs and the major role that temperature may be playing in driving the differences seen in the distribution of these two species in New
Zealand.
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Effect of Salinity, Photoperiod, Temperature, and Restricted Food Intake on Growth and Incidence of Sexual Maturation of Labrador Arctic charr (Salvelinus alpinus)MacPherson, Margaret Jeanette 15 August 2012 (has links)
Economic viability of Fraser River, Labrador Arctic charr (Salvelinus alpinus) aquaculture in Atlantic Canada may be greatly improved if grow-out could be completed in seawater (30 ppt), while having a low incidence of sexual maturation before harvesting. Growth and survival in seawater was investigated among individually PIT-tagged Arctic charr reared in tanks in the laboratory. Direct transfer from freshwater to brackish water (20 ppt), and then acclimation to 30 ppt was successful. The manipulation of photoperiod, temperature, and food ration can be used as practical applications in aquaculture to arrest maturation; this was investigated in two additional experiments. The most effective photoperiod was LD18:6 for 6 weeks starting December 21, which reduced maturation to 43% compared to 78% in controls. Restricted ration from December 21 through March 15 had no effect on maturation, however, rearing females in 5°C compared to 10°C reduced maturation to 15% compared to >80% in controls.
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Braškių užsigrūdinimo ir atsparumo šalčiui charakterizavimas in vitro ir in vivo / Characterization of cold acclimation and cold hardiness of strawberry in vitro and in vivoLukoševičiūtė, Vanda 02 January 2014 (has links)
Atsparumas šalčiui ir ištvermingumas žiemą – pagrindiniai veiksniai, lemiantys augalų geografinį pasiskirstymą. Be to, šie veiksniai turi didžiulę įtaką kultūrinių augalų derlingumui. Braškės, kurios yra tarp svarbiausių uoginių augalų pasaulyje ir Lietuvoje, stipriai pašąla esant nepastoviai sniego dangai, vis dažniau pasitaikančiomis permainingomis žiemojimo sąlygomis. Nepakankamas braškių ištvermingumas žiemą, aiškių kriterijų, kurie leistų per trumpesnį nei kelių metų laikotarpį atrinkti ištvermingas veisles nebuvimas, apsunkina naujų, adaptyvių, derlingų, kokybiškomis uogomis, braškių veislių sukūrimą ir introdukciją. Atsparumo šalčiui mechanizmai intensyviai tirti naudojant modelinius augalus, tačiau žinių apie žiemojančių kultūrinių augalų, kurių įvairovė labai didelė, ištvermingumo žiemą mechanizmus ir jo genetinį reguliavimą labai trūksta. Atsparių šalčiui augalų atrankai vykdyti reikalingos žinios apie augalų užsigrūdinimą, apie atsparumą šalčiui lemiančius veiksnius ir juos kontroliuojančius genus. Tiriant augalus kontroliuojamomis sąlygomis in vitro, galima ištirti atskirų veiksnių įtaką užsigrūdinimui ir atsparumui šalčiui, atsiribojant nuo, neišvengiamo natūraliomis sąlygomis, daugelio įvairių veiksnių poveikio. Braškių užsigrūdinimas ir atsparumas šalčiui svarbūs ne vien tik atrankai. Genetinių išteklių išsaugojimas ateities kartoms - svarbus šiuolaikinės biologijos uždavinys. Didelių kolekcijų išsaugojimą palengvina ir sąnaudas sumažina, augalų laikymas... [toliau žr. visą tekstą] / Cold hardiness and resistance in winter are key factors determining the geographical distribution of plants. In addition, these factors have a huge impact on harvest of cultural plants. Strawberries, which are among the most important berry plants in the world and in Lithuania, are vulnerable to cold because of unstable snow cover, which is more and more often occurring during variable wintering conditions. Insufficient resistance of strawberries in winter, absence of clear criteria, which enable to select the most resistant varieties during a shorter time than the few year period, impedes the development and introduction of new, adaptive, fertile, and of high-quality berries strawberry cultivars. The mechanisms of cold hardiness were intensively investigated using model plants. However, there is a lack of knowledge about the genetic regulation mechanisms of winterhardiness of cultural plants. For the selection of resistant to cold plants, the knowledge about plants cold acclimation and factors determining cold resistance and controlling genes is necessary. Investigating the plants under controlled conditions in vitro, it is possible to investigate the influence of individual factors on acclimation and cold hardiness by disassociating from the influence of many different factors, which is unavoidable under natural conditions. The cold acclimation and cold hardiness of strawberries are important not only for breeding. Preservation of plant genetic resources for future... [to full text]
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Kartotinio pasyvaus vėsinimo poveikis aklimacijos šalčiui požymių kaitai / Repeated passive cooling effect of acclimation frost features changeBalsevičius, Aurimas 28 June 2011 (has links)
Išstudijavus mokslinius literatūros šaltinius susijusius su hipotermija pastebėta, kad kūno
temperatūros sumažėjimas sukelia daug fiziologinių reakcijų žmogaus organizme, tačiau vis dar mažai
darbų, nagrinėjančių aklimacijos (aklimacija – tai dirbtinėse sąlygose (laboratorijoje) sukelta ilgalaikė
aklimatizacija) hipotermijai, sukeltos dirbtiniu būdu, poveikį žmogaus fiziologinių rodiklių kaitai.
Nepavyko rasti duomenų, kurie nagrinėtų kontroliuojamo kartotino pasyvaus vėsinimo poveikį iki tam
tikros fiksuotos rektalinės temperatūros taip pat nėra aišku apie blauzdos raumens vidinės temperatūros
kaitą, priklausančią nuo aklimacijos hipotermijai.
Tyrimo problema: Ar dirbtinėmis sąlygomis sukeliant aklimaciją hipotermijai, žmogaus
organizmas adaptuojasi? ir kaip kinta fiziologiniai rodikliai? Kaip žmogaus organizmas toleruoja
temperatūros sumažėjimą?
Pagrindinis šio tyrimo tikslas buvo nustatyti ir įvertinti kartotinio pasyvaus vėsinimo poveikį
aklimacijos šalčiui požymių kaitai.
Uždaviniai: 1. Nustatyti kartotinio pasyvaus vėsinimo poveikį aklimacijos šalčiui temperatūrų
kaitai (Traumens, Tsk, Tre ir Tb). 2. Nustatyti kartotinio pasyvaus vėsinimo poveikį aklimacijos šalčiui
subjektyvių požymių kaitai: a) drebėjimo b) šiluminio/terminio pojūčio c) šiluminio/terminio komforto.
3. Nustatyti kartotinio pasyvaus vėsinimo poveikį aklimacijos šalčiui, fiziologinio streso (šalčio)
indekso kaitai..
Šio tyrimo metu tiriamieji buvo pasyviai pratinami prie šalčio taikant septyniolikos... [toliau žr. visą tekstą] / Studied scientific literature related with hypothermia observed that decrease in body
temperature causes a lot of physiological reactions in human body, but still there are low works dealing
with acclimation (acclimation – in artificial conditions (laboratory) caused long-term acclimatization)
hypothermia, induced artificially, impact on human physiological indicators of change. Unable to find
data, that deal with controlled confirmatory passive cooling effect up to a fixed rectal temperature is
also not clear about the internal temperature change of the shank muscle, depends on the acclimation to
hypothermia.
Research problem: Does by artificial conditions causing acclimation to hypothermia human
body adapts? And the evolution of physiology indicators? How the human body tolerates decrease of
temperature?
The main purpose of the study was to identify and evaluate repeated passive cooling effect to
acclimation to cold symptoms change.
Objectives: 1. Identify repeated passive cooling effect of acclimation frost temperature changes
(Tmuscle, Tsk, Tre ir Tb). 2. Identify repeated passive cooling effect of acclimation frost subjective
symptoms change: a) shaking, b) heat/thermal sense, c) heat/thermal comfort. 3. Identify effects of
repeated passive cooling to cold acclimation, physiological stress (cold) index change.
In this study subjects were passively to the cold with seventeen courses program, passive
cooling course was repeated every day, the experimental from control... [to full text]
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The Effect of Chronic and Acute Temperature Exposure on the Antarctic Notothenioid Trematomus bernacchii during Hypoxia Exercise and FeedingAustin, Charlotte Anne January 2014 (has links)
Antarctic fish from the Perciform suborder Notothenioidei inhabit arguably the most thermally stable ocean environment on earth. In order to populate the subzero environment Antarctic fish have evolved numerous adaptations. However, specialisation to -1.9°C has incurred a trade off, thermal flexibility is lost likely due to modifications to the cold and as a result Notothenioidei are extremely stenothermic. Climate change mediated warming is predicted to increase the ocean temperature surrounding the Antarctic continent by 2°C within the next century. This increase is projected to affect individuals, populations and the community structures of those inhabiting the area and therefore the physiological study of the acclimation ability and thermal limitations of Antarctic fish is an area scientific interest.
The present study is a series of discrete experiments relating to one species, Trematomus bernacchii, a circumpolar benthic Notothenioidei found in nearly all inshore waters surrounding the Antarctic coastline. These studies included investigation of the response of this species to both chronic and acute temperature exposure prior to and following a feeding event, a reduction in environmental oxygen and an exhaustive exercise event, as well as examination of T. bernacchii ability to recovery from these challenges.
T. bernacchii demonstrated variable success when acclimated to +3°C. Failure appeared to be determined by the recovery period following capture and aquarium housing, 7 days housing following capture resulted in 100% mortality, conversly 3 months resulted in 100% survival. Following successful acclimation T. bernacchii showed physiological adjustment as acclimated resting metabolic rate mirrored that of T. bernacchii tested at environmental temperature, 20.63 ± 1.3 compared to 22.38 ± 1.02 mg. O₂. kg⁻¹. h⁻¹.
The previously undefined specific dynamic action response (SDA), in T. bernacchii was characteristic of polar species. At environmental temperatures SDA scope was small 14.52 ± 3.52 mg O₂. kg⁻¹. h⁻¹, and lengthy ,72 hours; SDA duration was reduced to 9 hours in acclimated fish. Resting metabolic rate was elevated following acute exposure to +3°C, 34.27 ± 2.35 mg O₂. kg⁻¹. h⁻¹, masking the SDA response and associated parameters.
T. bernacchii were relatively sensitive to hypoxia, Pcrit over four acute temperature exposures, ranged between 69 and 102mmHg, higher than the average range for teleosts (40 – 60 mmHg). Above -1°C Pcrit increased, rising with acute temperature exposure. Ventilation rate was temperature dependent and completely absent at +4 and +6°C. A bradycardia (beginning at 60 and 70mmHg) was observed at all temperature exposures, this response was consistent as all heart rates reduced by 25%. Recovery from both hypoxia and acute temperature exposure was rapid.
Following an exhaustive exercise event aerobic Scope of T. bernacchii was constrained over an acute temperature increase, reducing from 38.58 ± 5.64 to 24.41 ± 4.92 mg.O₂. kg⁻¹.h⁻¹ over a 7°C temperature increase, respiratory scope too was reduced such that at +4 and +6°C scope was absent. Heart rate of T. bernacchii was highly constrained at -1°C, increasing by 2.54 ± 0.9 bpm following exercise. Acute temperature increase resulted in an increase in cardiac scope, maximum 6.29 ± 1.2 bpm at +2°C, due likely to a thermally mediated loss of cholinergic tonus following exhaustive exercise. Recovery of all parameters was temperature dependent and rapid upon return to -1°C.
The present study is the first to quantify and assess the effect of acute and chronic temperature exposure on the SDA response of T. bernacchii. Furthermore, it supplements the current literature on acclimation ability, acute temperature exposure, aerobic scope and hypoxia tolerance for this species. This work will be of use in future investigations of the effects of rapid climate change on Antarctic notothenioid fish and the interconnected ecosystem.
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