Responses and adaptations of coconut plants "Green Dwarf" to interactions between water stress and soil salinity.

Detalhes bibliográficos
Autor(a) principal: Alexandre Reuber Almeida da Silva
Data de Publicação: 2015
Tipo de documento: Tese
Idioma: por
Título da fonte: Biblioteca Digital de Teses e Dissertações da UFC
Texto Completo: http://www.teses.ufc.br/tde_busca/arquivo.php?codArquivo=14726
Resumo: In this work morphological, physiological, biochemical and nutritional responses, to elucidate the possible adaptive strategies of young coconut plants, cultivating "Green Dwarf", involved with tolerance to the effects of stress isolated and combined soil salinity and water stress. In the experiment, conducted in a greenhouse, the greenhouse type, in Fortaleza, CearÃ, were evaluated under statistical design of randomized blocks in a split plot arrangement, the effects of different levels of water stress by imposing different percentages resets the potential evapotranspiration - ETpc (20; 40; 60; 80 and 100%), related to increasing levels of soil salinity (1.72, 6.25, 25.80 and 40.70 dS m-1) provided by soils derived from the Irrigated Perimeter Morada Nova - PIMN. The effects of treatments on plants were evaluated using the variables: plant height, leaf number, stem diameter, leaf area, biomass production (root, shoot and total), compared root dry biomass of aerial-1, to salinity tolerance indices, leaf gas exchange (stomatal conductance, transpiration, photosynthesis, instant and intrinsic efficiency of water use), quantum yield of chlorophyll fluorescence (Fv Fm-1) level for total chlorophyll (Spad index) , total content of chlorophyll (a + b) and carotenoids, leaf water potential, leaf and root levels of inorganic solutes (potassium ions, sodium and chloride) and organic (total soluble carbohydrates, N - aminossolÃveis and free proline) and nutritional state (foliar nutrients of nitrogen, phosphorus, potassium, calcium, magnesium, sulfur, iron, copper, manganese and zinc). The growth and biomass production of the plants are sharply reduced by the conditions of water stress and high soil salinity, apparently being more critical to fluid restriction culture. The degree of water stress can enhance the susceptibility to salinity. The physiological mechanisms are effectively limited when water stress and salinity act separately and / or together. The effects of water stress are more effective in the reduction of physiological parameters, to the detriment soil salinity. The magnitudes of physiological responses of plants to water supply and salinity depend on the intensity of stress. Adaptive physiological responses of plants are related mainly to stomatal regulation. In conditions of drought and soil salinity, the plants have linear reductions in the total levels of chlorophyll. Carotenoid levels respond to the combined effects of water availability and soil salinity and reflect the antagonism between them. The coconut has a number of physiological adjustments mechanisms that give the species a partial tolerance to drought stress and / or saline. Saline ions K+, Na+ and Cl- accumulate significantly in young coconut plants, to the detriment of organic solutes, both in the leaves and in the roots, evidencing an apparent root retention ions. Salinity did not change the concentration of organic solutes, however, show up increments in leaf and root levels of free proline in response to water stress. Water stress and soil salinity interact, affecting the nutritional status of plants, except for the nutrient P. Leaf contents of nutrients N, Ca, S, Fe, Mn and Zn grow positively with the increase of water availability and are reduced substantially with increasing salinity. The interaction of smaller water deficit levels with the highest saline levels maximizes the leaf contents of Mg and Cu and minimizes K. During the establishment of coconut seedlings, the need for macronutrients follows the descending order: N, K Ca, Mg, S and P and micronutrients: Fe, Mn, Zn and Cu. The plant nutrition proved to be adequate, except for the imbalances observed in nutrients K, Mg, S and Mn. The coconut seedlings show full capacity of the establishment in saline soils PIMN, corresponding to the level of electrical conductivity to 6.50 dS m-1, but only when the water supply remains adequate. For the higher salinity levels the plants survive, yet the size of the same is reduced by around 50%, even when fully irrigated.
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spelling info:eu-repo/semantics/publishedVersioninfo:eu-repo/semantics/doctoralThesisResponses and adaptations of coconut plants "Green Dwarf" to interactions between water stress and soil salinity. Respostas e adaptaÃÃes de plantas de coqueiro "anÃo verde" Ãs interaÃÃes entre deficiÃncia hÃdrica e salinidade do solo2015-06-03Francisco Marcus Lima Bezerra10125922353http://lattes.cnpq.br/3323417707721098Claudivan Feitosa de Lacerda38810948300http://lattes.cnpq.br/4576414337840820Marlos Alves Bezerra25972723387http://lattes.cnpq.br/4787543991573578Carlos Henrique Carvalho de Sousa90640357334http://lattes.cnpq.br/7463670043908997Cley Anderson Silva De Freitas63889412300http://lattes.cnpq.br/2818524375516539 Aiala Vieira Amorim98792911315http://lattes.cnpq.br/5450555345810730 02204153311http://lattes.cnpq.br/1081735337951184 Alexandre Reuber Almeida da SilvaUniversidade Federal do CearÃPrograma de PÃs-GraduaÃÃo em Engenharia AgrÃcolaUFCBRCocos nucifera L. Plantas e Ãgua SalinizaÃÃo do solo Estresses mÃltiplosCocos nucifera L. Plants and water Soil salinization Multiple stressesENGENHARIA AGRICOLAIn this work morphological, physiological, biochemical and nutritional responses, to elucidate the possible adaptive strategies of young coconut plants, cultivating "Green Dwarf", involved with tolerance to the effects of stress isolated and combined soil salinity and water stress. In the experiment, conducted in a greenhouse, the greenhouse type, in Fortaleza, CearÃ, were evaluated under statistical design of randomized blocks in a split plot arrangement, the effects of different levels of water stress by imposing different percentages resets the potential evapotranspiration - ETpc (20; 40; 60; 80 and 100%), related to increasing levels of soil salinity (1.72, 6.25, 25.80 and 40.70 dS m-1) provided by soils derived from the Irrigated Perimeter Morada Nova - PIMN. The effects of treatments on plants were evaluated using the variables: plant height, leaf number, stem diameter, leaf area, biomass production (root, shoot and total), compared root dry biomass of aerial-1, to salinity tolerance indices, leaf gas exchange (stomatal conductance, transpiration, photosynthesis, instant and intrinsic efficiency of water use), quantum yield of chlorophyll fluorescence (Fv Fm-1) level for total chlorophyll (Spad index) , total content of chlorophyll (a + b) and carotenoids, leaf water potential, leaf and root levels of inorganic solutes (potassium ions, sodium and chloride) and organic (total soluble carbohydrates, N - aminossolÃveis and free proline) and nutritional state (foliar nutrients of nitrogen, phosphorus, potassium, calcium, magnesium, sulfur, iron, copper, manganese and zinc). The growth and biomass production of the plants are sharply reduced by the conditions of water stress and high soil salinity, apparently being more critical to fluid restriction culture. The degree of water stress can enhance the susceptibility to salinity. The physiological mechanisms are effectively limited when water stress and salinity act separately and / or together. The effects of water stress are more effective in the reduction of physiological parameters, to the detriment soil salinity. The magnitudes of physiological responses of plants to water supply and salinity depend on the intensity of stress. Adaptive physiological responses of plants are related mainly to stomatal regulation. In conditions of drought and soil salinity, the plants have linear reductions in the total levels of chlorophyll. Carotenoid levels respond to the combined effects of water availability and soil salinity and reflect the antagonism between them. The coconut has a number of physiological adjustments mechanisms that give the species a partial tolerance to drought stress and / or saline. Saline ions K+, Na+ and Cl- accumulate significantly in young coconut plants, to the detriment of organic solutes, both in the leaves and in the roots, evidencing an apparent root retention ions. Salinity did not change the concentration of organic solutes, however, show up increments in leaf and root levels of free proline in response to water stress. Water stress and soil salinity interact, affecting the nutritional status of plants, except for the nutrient P. Leaf contents of nutrients N, Ca, S, Fe, Mn and Zn grow positively with the increase of water availability and are reduced substantially with increasing salinity. The interaction of smaller water deficit levels with the highest saline levels maximizes the leaf contents of Mg and Cu and minimizes K. During the establishment of coconut seedlings, the need for macronutrients follows the descending order: N, K Ca, Mg, S and P and micronutrients: Fe, Mn, Zn and Cu. The plant nutrition proved to be adequate, except for the imbalances observed in nutrients K, Mg, S and Mn. The coconut seedlings show full capacity of the establishment in saline soils PIMN, corresponding to the level of electrical conductivity to 6.50 dS m-1, but only when the water supply remains adequate. For the higher salinity levels the plants survive, yet the size of the same is reduced by around 50%, even when fully irrigated.Neste trabalho foram estudadas repostas morfolÃgicas, fisiolÃgicas, bioquÃmicas e nutricionais, visando elucidar as possÃveis estratÃgias adaptativas de plantas jovens de coqueiro, cultivar âAnÃo Verdeâ, envolvidas com sua tolerÃncia aos efeitos dos estresses isolados e/ou combinados, salinidade do solo e deficiÃncia hÃdrica. No experimento, conduzido em casa de vegetaÃÃo, do tipo telado, em Fortaleza, CearÃ, avaliaram-se, sob delineamento estatÃstico de blocos casualizados, no arranjo de parcelas subdivididas, os efeitos de diferentes nÃveis de deficiÃncia hÃdrica, mediante a imposiÃÃo de distintos percentuais de reposiÃÃes da evapotranspiraÃÃo potencial da cultura - ETpc (20; 40; 60; 80 e 100%), associados à crescentes nÃveis de salinidade do solo (1,72; 6,25; 25,80 e 40,70 dS m-1), proporcionados pelos solos oriundos do PerÃmetro Irrigado Morada Nova - PIMN. Os efeitos dos tratamentos sobre as plantas foram avaliados por meio das variÃveis: altura de plantas, nÃmero de folhas, diÃmetro do caule, Ãrea foliar, produÃÃo de biomassa (radicular, parte aÃrea e total), relaÃÃo biomassa seca raiz parte aÃrea-1, Ãndices de tolerÃncia à salinidade, trocas gasosas foliares (condutÃncia estomÃtica, transpiraÃÃo, fotossÃntese, eficiÃncia instantÃnea e intrÃnseca de uso da Ãgua), rendimento quÃntico da fluorescÃncia da clorofila a (Fv Fm-1), teores relativos de clorofila total (Ãndice Spad), teores totais de clorofilas (a+b) e de carotenÃides, potencial hÃdrico foliar, teores foliares e radiculares dos solutos inorgÃnicos (Ãons potÃssio, sÃdio e cloreto) e orgÃnicos (carboidratos solÃveis totais, N - aminossolÃveis e prolina livre) e estado nutricional (teores foliares dos nutrientes nitrogÃnio, fÃsforo, potÃssio, cÃlcio, magnÃsio, enxofre, ferro, cobre, manganÃs e zinco). O crescimento e a produÃÃo de biomassa das plantas sÃo acentuadamente reduzidos pelas condiÃÃes de restriÃÃo hÃdrica e de elevada salinidade do solo, sendo aparentemente mais crÃtica à cultura a restriÃÃo hÃdrica. O grau de estresse hÃdrico à capaz de acentuar a suscetibilidade à salinidade. Os mecanismos fisiolÃgicos sÃo efetivamente limitados quando a deficiÃncia hÃdrica e a salinidade atuam isoladamente e/ou em conjunto. Os efeitos do estresse hÃdrico se mostram mais efetivos nas reduÃÃes dos parÃmetros fisiolÃgicos, em detrimento à salinidade do solo. As magnitudes das respostas fisiolÃgicas das plantas ao suprimento hÃdrico e à salinidade dependem das intensidades do estresses. As respostas fisiolÃgicas adaptativas das plantas estÃo relacionadas, principalmente, à regulaÃÃo estomÃtica. Em condiÃÃes de dÃficit hÃdrico e de salinidade do solo, as plantas apresentam reduÃÃes lineares nos teores totais de clorofilas. Os teores de carotenÃides respondem aos efeitos combinados da disponibilidade hÃdrica e da salinidade do solo e refletem o antagonismo entre estes. O coqueiro apresenta uma sÃrie de mecanismos de ajustes fisiolÃgicos que conferem à espÃcie uma parcial tolerÃncia ao estresse hÃdrico e/ou salino. Os Ãons salinos K+, Na+ e Cl- acumulam-se significativamente em plantas jovens de coqueiro, em detrimento aos solutos orgÃnicos, tanto nas folhas quanto nas raÃzes, sendo evidenciada uma aparente retenÃÃo radicular de Ãons. A salinidade nÃo altera os teores dos solutos orgÃnicos, todavia, denotam-se incrementos nos teores foliares e radiculares de prolina livre em resposta à deficiÃncia hÃdrica. A deficiÃncia hÃdrica e a salinidade do solo interagem, afetando o estado nutricional das plantas, excetuando o nutriente P. Os teores foliares dos nutrientes N, Ca, S, Fe, Mn e Zn crescem positivamente com a ampliaÃÃo da disponibilidade hÃdrica e reduzem-se substancialmente com o aumento da salinidade. A interaÃÃo dos menores nÃveis de deficiÃncia hÃdrica com os maiores nÃveis salinos maximiza os teores foliares de Mg e Cu e minimiza os de K. Durante o estabelecimento das plantas jovens de coqueiro, a necessidade de macronutrientes obedece à ordem decrescente: N, K Ca, Mg, S e P e à de micronutrientes: Fe, Mn, Zn e Cu. A nutriÃÃo das plantas mostra-se adequada, excetuando-se, os desequilÃbrios observados nos nutrientes K, Mg, S e Mn. As plantas jovens de coqueiro mostram plena capacidade de estabelecimento nos solos salinizados do PIMN, atà o nÃvel de condutividade elÃtrica correspondente a 6,50 dS m-1, porÃm apenas quando o suprimento hÃdrico se mantÃm adequado. Para os nÃveis de salinidade mais elevados as plantas sobrevivem, contudo o porte das mesmas reduz-se em torno de 50%, mesmo quando plenamente irrigadas.Conselho Nacional de Desenvolvimento CientÃfico e TecnolÃgicoCoordenaÃÃo de AperfeiÃoamento de Pessoal de NÃvel Superiorhttp://www.teses.ufc.br/tde_busca/arquivo.php?codArquivo=14726application/pdfinfo:eu-repo/semantics/openAccessporreponame:Biblioteca Digital de Teses e Dissertações da UFCinstname:Universidade Federal do Cearáinstacron:UFC2019-01-21T11:28:52Zmail@mail.com -
dc.title.en.fl_str_mv Responses and adaptations of coconut plants "Green Dwarf" to interactions between water stress and soil salinity.
dc.title.alternative.pt.fl_str_mv Respostas e adaptaÃÃes de plantas de coqueiro "anÃo verde" Ãs interaÃÃes entre deficiÃncia hÃdrica e salinidade do solo
title Responses and adaptations of coconut plants "Green Dwarf" to interactions between water stress and soil salinity.
spellingShingle Responses and adaptations of coconut plants "Green Dwarf" to interactions between water stress and soil salinity.
Alexandre Reuber Almeida da Silva
Cocos nucifera L.
Plantas e Ãgua
SalinizaÃÃo do solo
Estresses mÃltiplos
Cocos nucifera L.
Plants and water
Soil salinization
Multiple stresses
ENGENHARIA AGRICOLA
title_short Responses and adaptations of coconut plants "Green Dwarf" to interactions between water stress and soil salinity.
title_full Responses and adaptations of coconut plants "Green Dwarf" to interactions between water stress and soil salinity.
title_fullStr Responses and adaptations of coconut plants "Green Dwarf" to interactions between water stress and soil salinity.
title_full_unstemmed Responses and adaptations of coconut plants "Green Dwarf" to interactions between water stress and soil salinity.
title_sort Responses and adaptations of coconut plants "Green Dwarf" to interactions between water stress and soil salinity.
author Alexandre Reuber Almeida da Silva
author_facet Alexandre Reuber Almeida da Silva
author_role author
dc.contributor.advisor1.fl_str_mv Francisco Marcus Lima Bezerra
dc.contributor.advisor1ID.fl_str_mv 10125922353
dc.contributor.advisor1Lattes.fl_str_mv http://lattes.cnpq.br/3323417707721098
dc.contributor.advisor-co1.fl_str_mv Claudivan Feitosa de Lacerda
dc.contributor.advisor-co1ID.fl_str_mv 38810948300
dc.contributor.advisor-co1Lattes.fl_str_mv http://lattes.cnpq.br/4576414337840820
dc.contributor.referee1.fl_str_mv Marlos Alves Bezerra
dc.contributor.referee1ID.fl_str_mv 25972723387
dc.contributor.referee1Lattes.fl_str_mv http://lattes.cnpq.br/4787543991573578
dc.contributor.referee2.fl_str_mv Carlos Henrique Carvalho de Sousa
dc.contributor.referee2ID.fl_str_mv 90640357334
dc.contributor.referee2Lattes.fl_str_mv http://lattes.cnpq.br/7463670043908997
dc.contributor.referee3.fl_str_mv Cley Anderson Silva De Freitas
dc.contributor.referee3ID.fl_str_mv 63889412300
dc.contributor.referee3Lattes.fl_str_mv http://lattes.cnpq.br/2818524375516539
dc.contributor.referee4.fl_str_mv Aiala Vieira Amorim
dc.contributor.referee4ID.fl_str_mv 98792911315
dc.contributor.referee4Lattes.fl_str_mv http://lattes.cnpq.br/5450555345810730
dc.contributor.authorID.fl_str_mv 02204153311
dc.contributor.authorLattes.fl_str_mv http://lattes.cnpq.br/1081735337951184
dc.contributor.author.fl_str_mv Alexandre Reuber Almeida da Silva
contributor_str_mv Francisco Marcus Lima Bezerra
Claudivan Feitosa de Lacerda
Marlos Alves Bezerra
Carlos Henrique Carvalho de Sousa
Cley Anderson Silva De Freitas
Aiala Vieira Amorim
dc.subject.por.fl_str_mv Cocos nucifera L.
Plantas e Ãgua
SalinizaÃÃo do solo
Estresses mÃltiplos
topic Cocos nucifera L.
Plantas e Ãgua
SalinizaÃÃo do solo
Estresses mÃltiplos
Cocos nucifera L.
Plants and water
Soil salinization
Multiple stresses
ENGENHARIA AGRICOLA
dc.subject.eng.fl_str_mv Cocos nucifera L.
Plants and water
Soil salinization
Multiple stresses
dc.subject.cnpq.fl_str_mv ENGENHARIA AGRICOLA
dc.description.sponsorship.fl_txt_mv Conselho Nacional de Desenvolvimento CientÃfico e TecnolÃgico
CoordenaÃÃo de AperfeiÃoamento de Pessoal de NÃvel Superior
dc.description.abstract.por.fl_txt_mv In this work morphological, physiological, biochemical and nutritional responses, to elucidate the possible adaptive strategies of young coconut plants, cultivating "Green Dwarf", involved with tolerance to the effects of stress isolated and combined soil salinity and water stress. In the experiment, conducted in a greenhouse, the greenhouse type, in Fortaleza, CearÃ, were evaluated under statistical design of randomized blocks in a split plot arrangement, the effects of different levels of water stress by imposing different percentages resets the potential evapotranspiration - ETpc (20; 40; 60; 80 and 100%), related to increasing levels of soil salinity (1.72, 6.25, 25.80 and 40.70 dS m-1) provided by soils derived from the Irrigated Perimeter Morada Nova - PIMN. The effects of treatments on plants were evaluated using the variables: plant height, leaf number, stem diameter, leaf area, biomass production (root, shoot and total), compared root dry biomass of aerial-1, to salinity tolerance indices, leaf gas exchange (stomatal conductance, transpiration, photosynthesis, instant and intrinsic efficiency of water use), quantum yield of chlorophyll fluorescence (Fv Fm-1) level for total chlorophyll (Spad index) , total content of chlorophyll (a + b) and carotenoids, leaf water potential, leaf and root levels of inorganic solutes (potassium ions, sodium and chloride) and organic (total soluble carbohydrates, N - aminossolÃveis and free proline) and nutritional state (foliar nutrients of nitrogen, phosphorus, potassium, calcium, magnesium, sulfur, iron, copper, manganese and zinc). The growth and biomass production of the plants are sharply reduced by the conditions of water stress and high soil salinity, apparently being more critical to fluid restriction culture. The degree of water stress can enhance the susceptibility to salinity. The physiological mechanisms are effectively limited when water stress and salinity act separately and / or together. The effects of water stress are more effective in the reduction of physiological parameters, to the detriment soil salinity. The magnitudes of physiological responses of plants to water supply and salinity depend on the intensity of stress. Adaptive physiological responses of plants are related mainly to stomatal regulation. In conditions of drought and soil salinity, the plants have linear reductions in the total levels of chlorophyll. Carotenoid levels respond to the combined effects of water availability and soil salinity and reflect the antagonism between them. The coconut has a number of physiological adjustments mechanisms that give the species a partial tolerance to drought stress and / or saline. Saline ions K+, Na+ and Cl- accumulate significantly in young coconut plants, to the detriment of organic solutes, both in the leaves and in the roots, evidencing an apparent root retention ions. Salinity did not change the concentration of organic solutes, however, show up increments in leaf and root levels of free proline in response to water stress. Water stress and soil salinity interact, affecting the nutritional status of plants, except for the nutrient P. Leaf contents of nutrients N, Ca, S, Fe, Mn and Zn grow positively with the increase of water availability and are reduced substantially with increasing salinity. The interaction of smaller water deficit levels with the highest saline levels maximizes the leaf contents of Mg and Cu and minimizes K. During the establishment of coconut seedlings, the need for macronutrients follows the descending order: N, K Ca, Mg, S and P and micronutrients: Fe, Mn, Zn and Cu. The plant nutrition proved to be adequate, except for the imbalances observed in nutrients K, Mg, S and Mn. The coconut seedlings show full capacity of the establishment in saline soils PIMN, corresponding to the level of electrical conductivity to 6.50 dS m-1, but only when the water supply remains adequate. For the higher salinity levels the plants survive, yet the size of the same is reduced by around 50%, even when fully irrigated.
Neste trabalho foram estudadas repostas morfolÃgicas, fisiolÃgicas, bioquÃmicas e nutricionais, visando elucidar as possÃveis estratÃgias adaptativas de plantas jovens de coqueiro, cultivar âAnÃo Verdeâ, envolvidas com sua tolerÃncia aos efeitos dos estresses isolados e/ou combinados, salinidade do solo e deficiÃncia hÃdrica. No experimento, conduzido em casa de vegetaÃÃo, do tipo telado, em Fortaleza, CearÃ, avaliaram-se, sob delineamento estatÃstico de blocos casualizados, no arranjo de parcelas subdivididas, os efeitos de diferentes nÃveis de deficiÃncia hÃdrica, mediante a imposiÃÃo de distintos percentuais de reposiÃÃes da evapotranspiraÃÃo potencial da cultura - ETpc (20; 40; 60; 80 e 100%), associados à crescentes nÃveis de salinidade do solo (1,72; 6,25; 25,80 e 40,70 dS m-1), proporcionados pelos solos oriundos do PerÃmetro Irrigado Morada Nova - PIMN. Os efeitos dos tratamentos sobre as plantas foram avaliados por meio das variÃveis: altura de plantas, nÃmero de folhas, diÃmetro do caule, Ãrea foliar, produÃÃo de biomassa (radicular, parte aÃrea e total), relaÃÃo biomassa seca raiz parte aÃrea-1, Ãndices de tolerÃncia à salinidade, trocas gasosas foliares (condutÃncia estomÃtica, transpiraÃÃo, fotossÃntese, eficiÃncia instantÃnea e intrÃnseca de uso da Ãgua), rendimento quÃntico da fluorescÃncia da clorofila a (Fv Fm-1), teores relativos de clorofila total (Ãndice Spad), teores totais de clorofilas (a+b) e de carotenÃides, potencial hÃdrico foliar, teores foliares e radiculares dos solutos inorgÃnicos (Ãons potÃssio, sÃdio e cloreto) e orgÃnicos (carboidratos solÃveis totais, N - aminossolÃveis e prolina livre) e estado nutricional (teores foliares dos nutrientes nitrogÃnio, fÃsforo, potÃssio, cÃlcio, magnÃsio, enxofre, ferro, cobre, manganÃs e zinco). O crescimento e a produÃÃo de biomassa das plantas sÃo acentuadamente reduzidos pelas condiÃÃes de restriÃÃo hÃdrica e de elevada salinidade do solo, sendo aparentemente mais crÃtica à cultura a restriÃÃo hÃdrica. O grau de estresse hÃdrico à capaz de acentuar a suscetibilidade à salinidade. Os mecanismos fisiolÃgicos sÃo efetivamente limitados quando a deficiÃncia hÃdrica e a salinidade atuam isoladamente e/ou em conjunto. Os efeitos do estresse hÃdrico se mostram mais efetivos nas reduÃÃes dos parÃmetros fisiolÃgicos, em detrimento à salinidade do solo. As magnitudes das respostas fisiolÃgicas das plantas ao suprimento hÃdrico e à salinidade dependem das intensidades do estresses. As respostas fisiolÃgicas adaptativas das plantas estÃo relacionadas, principalmente, à regulaÃÃo estomÃtica. Em condiÃÃes de dÃficit hÃdrico e de salinidade do solo, as plantas apresentam reduÃÃes lineares nos teores totais de clorofilas. Os teores de carotenÃides respondem aos efeitos combinados da disponibilidade hÃdrica e da salinidade do solo e refletem o antagonismo entre estes. O coqueiro apresenta uma sÃrie de mecanismos de ajustes fisiolÃgicos que conferem à espÃcie uma parcial tolerÃncia ao estresse hÃdrico e/ou salino. Os Ãons salinos K+, Na+ e Cl- acumulam-se significativamente em plantas jovens de coqueiro, em detrimento aos solutos orgÃnicos, tanto nas folhas quanto nas raÃzes, sendo evidenciada uma aparente retenÃÃo radicular de Ãons. A salinidade nÃo altera os teores dos solutos orgÃnicos, todavia, denotam-se incrementos nos teores foliares e radiculares de prolina livre em resposta à deficiÃncia hÃdrica. A deficiÃncia hÃdrica e a salinidade do solo interagem, afetando o estado nutricional das plantas, excetuando o nutriente P. Os teores foliares dos nutrientes N, Ca, S, Fe, Mn e Zn crescem positivamente com a ampliaÃÃo da disponibilidade hÃdrica e reduzem-se substancialmente com o aumento da salinidade. A interaÃÃo dos menores nÃveis de deficiÃncia hÃdrica com os maiores nÃveis salinos maximiza os teores foliares de Mg e Cu e minimiza os de K. Durante o estabelecimento das plantas jovens de coqueiro, a necessidade de macronutrientes obedece à ordem decrescente: N, K Ca, Mg, S e P e à de micronutrientes: Fe, Mn, Zn e Cu. A nutriÃÃo das plantas mostra-se adequada, excetuando-se, os desequilÃbrios observados nos nutrientes K, Mg, S e Mn. As plantas jovens de coqueiro mostram plena capacidade de estabelecimento nos solos salinizados do PIMN, atà o nÃvel de condutividade elÃtrica correspondente a 6,50 dS m-1, porÃm apenas quando o suprimento hÃdrico se mantÃm adequado. Para os nÃveis de salinidade mais elevados as plantas sobrevivem, contudo o porte das mesmas reduz-se em torno de 50%, mesmo quando plenamente irrigadas.
description In this work morphological, physiological, biochemical and nutritional responses, to elucidate the possible adaptive strategies of young coconut plants, cultivating "Green Dwarf", involved with tolerance to the effects of stress isolated and combined soil salinity and water stress. In the experiment, conducted in a greenhouse, the greenhouse type, in Fortaleza, CearÃ, were evaluated under statistical design of randomized blocks in a split plot arrangement, the effects of different levels of water stress by imposing different percentages resets the potential evapotranspiration - ETpc (20; 40; 60; 80 and 100%), related to increasing levels of soil salinity (1.72, 6.25, 25.80 and 40.70 dS m-1) provided by soils derived from the Irrigated Perimeter Morada Nova - PIMN. The effects of treatments on plants were evaluated using the variables: plant height, leaf number, stem diameter, leaf area, biomass production (root, shoot and total), compared root dry biomass of aerial-1, to salinity tolerance indices, leaf gas exchange (stomatal conductance, transpiration, photosynthesis, instant and intrinsic efficiency of water use), quantum yield of chlorophyll fluorescence (Fv Fm-1) level for total chlorophyll (Spad index) , total content of chlorophyll (a + b) and carotenoids, leaf water potential, leaf and root levels of inorganic solutes (potassium ions, sodium and chloride) and organic (total soluble carbohydrates, N - aminossolÃveis and free proline) and nutritional state (foliar nutrients of nitrogen, phosphorus, potassium, calcium, magnesium, sulfur, iron, copper, manganese and zinc). The growth and biomass production of the plants are sharply reduced by the conditions of water stress and high soil salinity, apparently being more critical to fluid restriction culture. The degree of water stress can enhance the susceptibility to salinity. The physiological mechanisms are effectively limited when water stress and salinity act separately and / or together. The effects of water stress are more effective in the reduction of physiological parameters, to the detriment soil salinity. The magnitudes of physiological responses of plants to water supply and salinity depend on the intensity of stress. Adaptive physiological responses of plants are related mainly to stomatal regulation. In conditions of drought and soil salinity, the plants have linear reductions in the total levels of chlorophyll. Carotenoid levels respond to the combined effects of water availability and soil salinity and reflect the antagonism between them. The coconut has a number of physiological adjustments mechanisms that give the species a partial tolerance to drought stress and / or saline. Saline ions K+, Na+ and Cl- accumulate significantly in young coconut plants, to the detriment of organic solutes, both in the leaves and in the roots, evidencing an apparent root retention ions. Salinity did not change the concentration of organic solutes, however, show up increments in leaf and root levels of free proline in response to water stress. Water stress and soil salinity interact, affecting the nutritional status of plants, except for the nutrient P. Leaf contents of nutrients N, Ca, S, Fe, Mn and Zn grow positively with the increase of water availability and are reduced substantially with increasing salinity. The interaction of smaller water deficit levels with the highest saline levels maximizes the leaf contents of Mg and Cu and minimizes K. During the establishment of coconut seedlings, the need for macronutrients follows the descending order: N, K Ca, Mg, S and P and micronutrients: Fe, Mn, Zn and Cu. The plant nutrition proved to be adequate, except for the imbalances observed in nutrients K, Mg, S and Mn. The coconut seedlings show full capacity of the establishment in saline soils PIMN, corresponding to the level of electrical conductivity to 6.50 dS m-1, but only when the water supply remains adequate. For the higher salinity levels the plants survive, yet the size of the same is reduced by around 50%, even when fully irrigated.
publishDate 2015
dc.date.issued.fl_str_mv 2015-06-03
dc.type.status.fl_str_mv info:eu-repo/semantics/publishedVersion
dc.type.driver.fl_str_mv info:eu-repo/semantics/doctoralThesis
status_str publishedVersion
format doctoralThesis
dc.identifier.uri.fl_str_mv http://www.teses.ufc.br/tde_busca/arquivo.php?codArquivo=14726
url http://www.teses.ufc.br/tde_busca/arquivo.php?codArquivo=14726
dc.language.iso.fl_str_mv por
language por
dc.rights.driver.fl_str_mv info:eu-repo/semantics/openAccess
eu_rights_str_mv openAccess
dc.format.none.fl_str_mv application/pdf
dc.publisher.none.fl_str_mv Universidade Federal do CearÃ
dc.publisher.program.fl_str_mv Programa de PÃs-GraduaÃÃo em Engenharia AgrÃcola
dc.publisher.initials.fl_str_mv UFC
dc.publisher.country.fl_str_mv BR
publisher.none.fl_str_mv Universidade Federal do CearÃ
dc.source.none.fl_str_mv reponame:Biblioteca Digital de Teses e Dissertações da UFC
instname:Universidade Federal do Ceará
instacron:UFC
reponame_str Biblioteca Digital de Teses e Dissertações da UFC
collection Biblioteca Digital de Teses e Dissertações da UFC
instname_str Universidade Federal do Ceará
instacron_str UFC
institution UFC
repository.name.fl_str_mv -
repository.mail.fl_str_mv mail@mail.com
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