Caracterização de respostas morfológicas e fisiológicas de plantas de soja submetidas a estresse hídrico / Morphological and physiological characterization of soybean plants under water stress

Guilherme Felisberto

20 January 2016

A cultura de soja (Glycine max (L.) Merrill) é muito importante mundialmente em função de seu uso na alimentação animal, como principal fonte de proteína e óleo, além de constituir a matéria prima básica para diversos setores da indústria. Sabe-se que a produtividade potencial de uma cultura é determinada por fatores genéticos e pelos seguintes atributos do ambiente de produção: temperatura, radiação solar, dióxido de carbono e fotoperíodo, sem restrição de água, nutrientes, plantas daninhas, pragas e doenças. A disponibilidade hídrica afeta o crescimento e desenvolvimento da cultura de soja, especialmente durante o período reprodutivo, fase de elevada atividade fisiológica. A deficiência hídrica é o principal fator limitante da produção mundial da cultura, que em sua maioria é cultivada em sistema de sequeiro em áreas com consideráveis riscos de ocorrência de deficit hídrico ao longo do ciclo da cultura. As plantas, ao longo do tempo, desenvolveram mecanismos para tolerar e/ou evitar os efeitos negativos desse estresse. O presente estudo teve como objetivo caracterizar esses mecanismos de tolerância associando-os ao potencial matricial do solo em processo de secagem. Foi avaliado a umidade gravimétrica e potencial matricial do solo, conteúdo relativo de água na folha, potencial hídrico foliar, prolina e caracteres relacionados à produção de plantas de soja, durante o período de enchimento de grãos, submetidas a três, seis, nove e doze dias sem irrigação, comparados com o controle irrigado diariamente. De acordo com o observado, os mecanismos de tolerância da soja à deficiência hídrica foram satisfatórios para a manutenção do conteúdo relativo de água e potencial hídrico foliar em níveis adequados até o valor de potencial matricial de água no solo de -0,8 atm, tendo a prolina papel importante nesse mecanismo. As avaliações hídricas, conteúdo relativo de água e potencial foliar se mostraram relacionados com a manutenção da produtividade de soja sob situação de deficiência hídrica, mostrando-se adequados para o estudo de tolerância de cultivares de soja à restrição hídrica. / Soybean crop (Glycine max (L.) Merrill) is very important worldwide because it is used in animal feeding, a source of protein and oil, and also raw material for many manufactured goods. It is known that a crop potential yield is determined by genetic factors and by the following production environment characteristics: temperature, solar radiation, carbon dioxide, photoperiod, water availability, nutrients, weeds, pests and diseases. Water availability affects soybean growth and development especially during the reproductive phase which has high physiological activity. Water deficit is a key factor on world`s soybean production which is generally grown in dry land systems with considerable high risks of water deficit along soybean crop season. Plants have developed mechanisms over time to tolerate and/or avoid negative effects of this kind of stress. The present study had as the main goal to characterize these mechanisms of tolerance associating them with soil matric potential of a soil in a drying process. It was assessed the gravimetrical humidity and soil matric potential, leaf relative water content, leaf water potential, proline and yield component of plants under three, six, nine and twelve days without irrigation during grain filling phase. In accordance with the observed, soybean water deficit tolerance mechanisms were enough to maintain leaf relative water content and leaf water potential at acceptable levels until soil matric potential were around -0.8 atm, which proline was a key factor in this mechanism. Leaf relative water content and leaf water potential showed to be related in maintaining soybean yield under water deficit and they may be used in studies of soybean tolerant cultivars to water restriction.

Glycine max (L.) Merrill

Conteúdo relativo de água na folha

Potencial matricial do solo

Prolina

Tolerância a deficiência hídrica

Glycine max (L.) Merrill

Leaf relative water content

Proline

Soil matric potential

Water deficit tolerance

Influence of soil water management on plant growth, essential oil yield and oil composition of rose-scented geranium (Pelargonium spp.)

Eiasu, B.K. (Bahlebi Kibreab)

17 October 2009

Introducing effective irrigation management in arid and semi-arid regions, like most areas of South Africa, is an indispensable way of maximising crop yield and enhancing productivity of scarce freshwater resources. Holistic improvements in agricultural water management could be realised through integrating the knowledge of crop-specific water requirements. In order to develop effective irrigation schedules for rose-scented geranium (Pelargonium capitatum x P. radens), greenhouse and field experiments were conducted at the Hatfield Experimental Farm of the University of Pretoria, Pretoria, South Africa, from 28 October 2004 to 2006. Results from 20, 40, 60 and 80% maximum allowable depletion (MAD) levels of the plant available soil water (ASW) indicated that plant roots extracted most of the soil water from the top 40 cm soil layer, independent of the treatment. Both essential oil yield and fresh herbage mass responded positively to high soil water content. Increasing the MAD level to 60% and higher resulted in a significant reduction in herbage mass and essential oil yields. An increase in the degree of water stress apparently increased the essential oil concentration (percentage oil on fresh herbage mass basis), but its contribution to total essential oil yield (kg/ha oil) was limited. There was no significant relationship between MAD level and essential oil composition. For water saving without a significant reduction in essential oil yield of rose-scented geranium, a MAD of 40% of ASW is proposed. Response of rose-scented geranium to a one-month irrigation withholding period in the second or third month of regrowth cycles showed that herbage mass and oil yield were positively related. Herbage yield was significantly reduced when the water stress period was imposed during the third or fourth month of regrowth. A remarkable essential oil yield loss was observed only when the plants were stressed during the fourth month of regrowth. Essential oil content (% oil on fresh herbage mass basis) was higher in stressed plants, especially when stressed late, but oil yield dropped due to lower herbage mass. The relationship between essential oil composition and irrigation treatments was not consistent. Water-use efficiency was not significantly affected by withholding irrigation in the second or in the third month of regrowth. With a marginal oil yield loss, about 330 to 460 m3 of water per hectare per regrowth cycle could be saved by withholding irrigation during the third month of regrowth. The overall results highlighted that in water-scarce regions withholding irrigation during either the second or the third month of regrowth in rose-scented geranium could save water that could be used by other sectors of society. In greenhouse pot experiments, rose-scented geranium was grown under different irrigation frequencies, in two growth media. Irrigation was withheld on 50% of the plants (in each plot) for the week prior to harvesting. Herbage and essential oil yields were better in the sandy clay soil than in silica sand. Essential oil content (% oil on fresh herbage mass basis) apparently increased with a decrease in irrigation frequency. Both herbage and total essential oil yields positively responded to frequent irrigation. A one-week stress period prior to harvesting significantly increased essential oil content and total essential oil yield. Hence, the highest essential oil yield was obtained from a combination of high irrigation frequency and a one-week irrigation-withholding period. In the irrigation frequency treatments, citronellol and citronellyl formate contents tended to increase with an increase in the stress level, but the reverse was true for geraniol and geranyl formate. Leaf physiological data were recorded during the terminal one-week water stress in the glasshouse pot trial. Upon rewatering, stomatal conductance (Gs) and transpiration rate (Rt) were significantly lower in the less often irrigated than in the more often irrigated treatments, while leaf water potential (yw) and relative water content (RWC) were the same for all plants, indicating that water stress had an after-effect on Gs and Rt. At the end of the stress period, Gs, Rt, yw and RWC were lower in the plants from the more often irrigated than from the less often irrigated treatments. Irrespective of irrigation treatment, one type of non-glandular and two types (different in shape and size) of glandular trichomes were observed. In water stressed-conditions, stomata and trichome densities increased, while the total number of stomata and trichomes per leaf appeared to remain more or less the same. Water stress conditions resulted in stomatal closure. / Thesis (PhD)--University of Pretoria, 2009. / Plant Production and Soil Science / unrestricted

Irrigation-withholding period

Herbage yield

Transpiration rate

Maximum allowable depletion level

Relative water content

Stomatal conductance

Trichomes

Water stress

Water potential

Water use

Water-use efficiency

Geranyl formate

Geraniol

Citronellol

Essential oil content

Citronellyl formate

UCTD

Physiological effects of drought on perennial ryegrass (Lolium perenne L.) and tall fescue (Festuca arundinacea Schreb.)

Butler, Tony

January 2008

The Canterbury plains are frequently exposed to summer drought and climate predictions forecast that the severity and frequency of summer drought will increase. The most commonly used pasture grass, perennial ryegrass (Lolium perenne L.), is drought sensitive. One possible method to maintain sward dry matter (DM) production under water stress is to use an alternative grass species such as tall fescue (Festuca arundinacea Schreb.). The objective of this research was to compare summer DM production of monoculture swards of perennial ryegrass and tall fescue under various seasonal drought regimes to study physiological and biochemical drought responses of each species. Data were collected over a period of two-summer seasons, Season One (2006-2007) and Season Two (2007-2008) in an automated rain shelter at Lincoln, Canterbury. Drought treatments included exposure of plants to a spring or autumn drought or a four-weekly "irrigated" drought regime. DM yields of the two species were similar under each watering regime. The control treatment, under non-limiting conditions, has the highest accumulated yield in both Season One and Two for ryegrass (17.1 and 15.7 t DM ha⁻¹) and tall fescue (18.8 and 16.0 t DM ⁻¹) respectively. Spring and autumn drought treatments were similar for the two species in accumulated yield in either season, however the exposure to drought stress returned yields lower than the control. Consistently, the lowest-yielding treatment was the four-weekly irrigated drought, which resulted in an average yield across species in Season One of 10.1 t DM ha⁻¹ and 8.35 t DM ha⁻¹ in Season Two. Growth rates of the swards were calculated using accumulated DM production against accumulated thermal time using a base temperature of 3°C for both species. The control treatments showed a strong linear relationship for both species in both seasons, though Season Two showed a period of approximately 390 °Cd of no growth. Spring growth was similar for all treatments until October when both the spring drought and four-weekly irrigated treatment deviated from the control as water stress commenced. Growth also ceased under autumn drought later in the season. The physiological drought responses between species and among treatments differed. Tall fescue under control conditions had the highest photosynthesis rates of 20.5 µmol CO₂ m⁻² s⁻¹,or 22% higher than ryegrass, whereas the four-weekly irrigated treatment showed no inter-species differences. Differences were also found for other gas exchange parameters. Physiological water use efficiency (phys WUE) in ryegrass was 15% greater than tall fescue in Season Two. Photosynthesis and gas exchange rates against leaf water potential showed declining gas flow in both species across all treatments in response to drying soil conditions and across all irrigation treatments. The osmo-protectant proline was 22% higher in concentration in ryegrass than in tall fescue in Season Two and increased in drought stressed treatments in both seasons. Water stress was found to reduce total chlorophyll concentrations in all treatments and in tall fescue, while little change occurred in the chlorophyll a:b ratio. In conclusion, the findings from this thesis suggest similar DM responses for the two species under drought. The findings suggests that tall fescue performs more as a "water user" under drought conditions, compared with perennial ryegrass, which is more a "water saver." Resonses to the changing environment to a point, before "shuttting up shop" through lower stomatal conductance.

tall fescue

ryegrass

nutritional value

water stress

water relations

DM production

stomata

thermal time

relative water content

photosynthesis

ME

N%

proline

osmotic adjustment

Festuca arundinacea Schreb.

Lolium perenne

chlorophyll

glucose

leaf water potential

transpiration

Arquitetura da macieira em regimes térmicos hibernais contrastantes - tipologia da ramificação primaveril e sua relação com o estado hídrico de gemas durante o inverno / Apple shoot architecture in response to cold and mild winter temperatures: spring branching typology and relation with winter bud water status.

Schmitz, Juliano Dutra

03 December 2014

Submitted by Gabriela Lopes (gmachadolopesufpel@gmail.com) on 2016-09-14T18:22:14Z No. of bitstreams: 2 license_rdf: 0 bytes, checksum: d41d8cd98f00b204e9800998ecf8427e (MD5) Tese Juliano Dutra Schmitz.pdf: 9582623 bytes, checksum: f579b0458e2ab6f4ae5579715de842ea (MD5) / Approved for entry into archive by Aline Batista (alinehb.ufpel@gmail.com) on 2016-09-15T19:46:43Z (GMT) No. of bitstreams: 2 Tese Juliano Dutra Schmitz.pdf: 9582623 bytes, checksum: f579b0458e2ab6f4ae5579715de842ea (MD5) license_rdf: 0 bytes, checksum: d41d8cd98f00b204e9800998ecf8427e (MD5) / Made available in DSpace on 2016-09-15T19:46:43Z (GMT). No. of bitstreams: 2 Tese Juliano Dutra Schmitz.pdf: 9582623 bytes, checksum: f579b0458e2ab6f4ae5579715de842ea (MD5) license_rdf: 0 bytes, checksum: d41d8cd98f00b204e9800998ecf8427e (MD5) Previous issue date: 2014-12-03 / Conselho Nacional de Pesquisa e Desenvolvimento Científico e Tecnológico - CNPq / A macieira (Malus X domestica Borkh.) apresenta anomalias fisiológicas quando cultivada em regiões de inverno ameno, onde o frio hibernal é insuficiente para superação da dormência. Assim, na presente tese foram estudados três temas de pesquisa. No tema 1 estudou-se a distribuição e fenologia da brotação e crescimento inicial da ramificação primaveril; No tema 2 estudou-se a brotação primaveril através da determinação do status hídrico de gemas laterais e da condutância hidráulica do xilema. O tema 3 realizou-se a análise do comportamento da brotação primaveril de uma cultivar de baixo exigência em frio cultivada em inverno ameno. Para isso, foram montados dois dispositivos experimentais: Experimento 1: realizado em Montpellier/França, onde foram estudadas quatro cultivares de macieira, com diferentes requerimentos em frio (‘Condessa’, ‘Granny Smith’, ‘Royal Gala’ e ‘Starkrimson’), submetidas a dois regimes térmicos (inverno frio, condições naturais de Montpellier; e inverno ameno, temperatura controlada em casa-de-vegetação). Experimento 2: realizado com a cultivar de baixo requerimento em frio ‘Eva’ sob regime térmico hibernal ameno (condição natural de Capão do leão/Brasil). A partir do experimento 1, dois artigos foram redigidos . Conclui-se a partir dos resultados obtidos (artigos 1 e 2) que as temperaturas hibernais têm o principal efeito na distribuição da ramificação ao longo do eixo principal e no tempo para brotação; a presença de folha das plantas submetidas ao regime térmico de inverno ameno não afeta a distribu ição de ramos prolépticos vegetativos; a cultivar exerce efeito no crescimento da ramificação. Com relação ao status hídrico, conclui-se que durante o inverno (período de dormência) as gemas laterais permanecem hidraulicamente isoladas do eixo principal; assim como o potencial de brotação está relacionado a um efeito ramo inteiro (todo eixo principal) do que ao potencial individual de cada gema lateral. Através do experimento 2, um artigo foi elaborado, tendo por objetivo testar a hipótese que a posição em que a gema lateral está localizada sobre o eixo principal têm efeito na brotação primaveril, no conteúdo de água e tamanho das mesmas. Pode-se concluir deste estudo que uma semana antes a brotação, as gemas localizadas na zona distal possuem maior potencial de crescimento (maior frequência de brotação e menor tempo médio para brotação), além de apresentarem maior umidade ponderal e tamanho. / The apple tree (Malus X domestica Borkh.) presents morphological and physiological anomalies when grown in mild winter climates with insufficient winter chilling to overcome winter dormancy. Symptoms are typically delayed and erratic budburst, entailing desynchronized flowering and fruitset and poor agronomic performances. This thesis aimed at gaining more insights on the following issues. Firstly, what are the effects of winter temperatures on axillary burdburst and bud outgrowth, and what are the respective effects of winter temperatures and cultivar?, and secondly, is there a link between the temperature-dependent budburst and bud water status? Works were done in France and Brazil. In France, experiments were carried out in controlled conditions on four apple cultivars characterized by either high chilling (‘Granny Smith’, ‘Royal Gala’, ‘Starkrimson’) or low chilling (‘Condessa’) requirements and were submitted to outdoor-cold and greenhouse-mild winter temperatures. We showed that the actual shoot architecture and budburst resulted from an ordered sequence of events with a pivotal role of winter temperatures on the dormancy completion of individual lateral buds. Endogenous factors related to the cultivar branching pattern overtook the temperature effect on the lateral bud outgrowth. Furthermore, the delayed senescence and subsequent leaf persistence during winter, characterizing the apple tree in the mild winter temperature conditions, had only a weak effect on the topological distribution of budburst and lateral outgrowth. The analyses of bud water status were done on distal buds only, characterized by high budburst frequency in cold winter conditions. We showed that, from endodormancy to the pre-budburst stage, xylem conductance at the stem-to-bud junction did not show consistent changes across cultivars and winter temperature treatments. Bud water potential had negative values, between -4.35 and -2.24 MPa, depending on cultivars and winter temperature treatments. Moreover, whatever the cultivar, there were no significant trends across dates for the effects of winter temperatures on bud water potential and relative water content without a consistent relationship with actual spring budburst frequency. These results suggested that lateral buds were hydraulically isolated from the parent stem during winter until a few days before budburst. The other set of experiments was carried out in Brazil, under mild winter conditions, on the low chilling apple cultivar ‘Eva’. The objectives were to gain more insights on the effect of the position of the over-wintering lateral bud along the whole-parent shoot on bud size and water content. Results highlighted that distal buds were larger and had a higher water content than proximal buds with a strong increase of water content a week before spring budburst. It was concluded that the acrotonic pattern of budburst was mainly established during ecodormancy. As a whole, we showed that spring budburst seemed more related to a whole-shoot effect than to the water status of the individual bud during winter dormancy. Our study substantiated the importance of the whole shoot as an integrated morphological and physiological unit in driving budburst and further growth.

CNPQ::CIENCIAS AGRARIAS::AGRONOMIA

Brotação

Ramificação

Requerimento em frio

Malus X domestica Borkh

Inverno ameno

Fenologia

Conteúdo relativo em água

Potencial hídrico

Condutância hidráulica do xilema

Dormência

Budburst

Branching

Chilling requirements

Cold winter

Mild winter

Phenology

Relative water content

Water potential

Xylem hydraulic conductance

Winter dormancy