Flooding tolerance of tomato genotypes during vegetative and reproductive stages

Ezin, Vincent; Pena, Rodica; Ahanchédé, Adam

doi:10.1590/s1677-04202010000200007

Cited by 76 publications

(51 citation statements)

References 45 publications

(33 reference statements)

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“…Thus, the flooded plants between 4 and 8 days showed a delay in growth and development as compared with a shorter stress time (Tables 1 and 2), so the onset of flowering was delayed, considering that the cape gooseberry produces one flower at each node of the reproductive shoots (Fischer, 2000). Also, Ezin et al (2010) found a reduction in the number of flowers and fruits and in the fruit size and weight in the tomato, attributing these results to the inhibition of photosynthesis and the adverse effects of flooding conditions.…”

Section: Number Of Reproductive Organsmentioning

confidence: 85%

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Effect of waterlogging stress on the growth, development and symptomatology of cape gooseberry (Physalis peruviana L.) plants

Aldana

García

Fischer

2014

Rev. Acad. Colomb. Cienc. Ex. Fis. Nat.

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Waterlogging stress in cape gooseberry plants 393 Rev. Acad. Colomb. Cienc. Ex. Fis. Nat. 38(149) AbstractClimate change has altered normal rainfall cycles; causing the flooding of arable land and, thus, affecting agricultural production in Colombia. Two-month-old cape gooseberry plants, propagated by seeds, were subjected to different durations of continuous waterlogging in a greenhouse: 0, 2, 4, 6 and 8 days, with evaluations up to 50 days. The plants were placed in ditches covered with polyethylene and filled with water up to 5 cm above the substrate surface of the pots. The parameters evaluated were: plant height, leaf area, stem diameter, dry weight of the aerial part, root and reproductive organs, and general symptoms following a wilting scale. The 6 and 8-day-waterlogged plants were the most affected by the flooding conditions, presenting the lowest values for all the measured variables. Due to the oxygen stress in the root zone, the plants showed yellowing, epinasty, necrosis and abscission of the leaves, more so in the 8-day-waterlogged plants.Key words: Hypoxia, leaf area, dry weight, symptoms. Efecto del estrés por anegamiento sobre el crecimiento, desarrollo y sintomatología de plantas de uchuva (Physalis peruviana L.) ResumenEl cambio climático ha alterado el ciclo normal de las lluvias, inundando así las tierras arables y afectando la producción agrícola en Colombia. Plantas de uchuva, de 2 meses de edad, y propagadas por semilla, fueron sometidas bajo invernadero a diferentes duraciones de anegamiento continuo: 0, 2, 4, 6 y 8 días y evaluaciones hasta 50 días. Las plantas se colocaron en zanjas cubiertas con polietileno que se llenaron con agua hasta 5 cm por encima de la superficie del sustrato contenido en las macetas. Los parámetros evaluados fueron: altura de planta, área foliar, diámetro del tallo, pesos secos de parte aérea, raíz y órganos reproductivos y escala de síntomas generales de marchitamiento. Las plantas anegadas durante 6 y 8 días presentaron los valores más bajos para todas las variables evaluadas. Debido al estrés por falta de oxígeno en la rizósfera las plantas mostraron amarillamiento, epinastia, necrosis y abscisión de hojas, sobre todo en las de 8 días anegadas.Palabras clave: hipoxia, área foliar, peso seco, síntomas.

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Section: Number Of Reproductive Organsmentioning

confidence: 85%

“…In studies with flooded tomatoes that applied chlorophyll fluorescence, Ezin et al (2010) and Kläring and Zude (2009) observed that the reduction in photosynthetic rates is related to limitations in the PSII reaction center.…”

Section: Leaf Areamentioning

confidence: 99%

Effect of waterlogging stress on the growth, development and symptomatology of cape gooseberry (Physalis peruviana L.) plants

Aldana

García

Fischer

2014

Rev. Acad. Colomb. Cienc. Ex. Fis. Nat.

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“…Tomato plants had ability to develop adventitious roots which attributed to its tolerance to excess water conditions (Walter et al, 2004). Adventitious root formation compensated for loss of the original roots due to hypoxic condition below water table (Ezin et al, 2010).…”

Section: Slfw and Slwc Were Not Affected By Shallow Water Tablementioning

confidence: 99%

Steady shallow water table did not decrease leaf expansion rate, specific leaf weight, and specific leaf water content in tomato plants

Meihana¹,

Lakitan²,

Susilawati³

et al. 2017

Aust J Crop Sci

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It was presumed that shallow water table restricted leaf growth and some water-related parameters; therefore, they can be used as indicators of plant stress due to the water table condition. Objective of this research was to evaluate morphological stress indicators in tomato plants exposed to shallow water table. The research was conducted in two stages: (1) developing reliable LA estimation model from June to September 2016; as pre-requisite for (2) calculating and evaluating the morphological indicators for stress due to shallow water table treatments, conducted from February to May 2017. Treated plants were placed inside experimental pools. Each treatment was done by partially submerging growing substrate to the targeted water tables at 5 cm and 10 cm below surface of the substrate. Untreated control plants were kept outside the pools. Zero-intercept linear model was the selected model for leaf area estimation after evaluating 15 combinations of five regression models and three predictors. Results of this study indicated that steady water table at 5-cm and 10-cm depth did not restrain relative leaf expansion rate (RLER) and there was no significant difference in specific leaf fresh weight (SLFW) and specific leaf water content (SLWC) between treated and untreated plants, measured prior to, during, and after recovery from shallow water table treatments. In conclusion, if position of water table was steady, the shallow water table at 5-cm depth or deeper did not affect tomato growth.

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“…Intolerant species undergo leaf chlorosis, as reported by Reyna et al (2003) for soy (Glycine max (L.) Merr.) and Ezin et al (2010) for the tomato (Lycopersicon esculentum Mill. ).…”

Section: Oliveira Akm E Gualtieri Scjmentioning

confidence: 99%

“…Several researchers have studied the effects of flooding during certain periods by considering the morphological, anatomical, physiological and biochemical changes in plants, such as changes in gas exchange (MOMMER et al, 2004;EZIN et al, 2010;SCREMIN-DIAS et al, 2011;KATO;OKAMI, 2011;PARLANTI et al, 2011;among others). Stressed plants adapt to disturbances caused by hypoxia or anoxia in the root have different adaptations; the most common of these adaptation strategies being increased stomatal conductance, reducing photosynthesis, changes in transpiration rates, the inhibition of growth, the wilting and/or abscission of leaves, and reduced leaf water potential (KOZLOWS KI, 1997;WITTMANN, 2010;PAREEK et al, 2010).…”

Section: Introductionmentioning

confidence: 99%

GAS EXCHANGE IN YOUNG PLANTS OF Tabebuia aurea(Bignoniaceae Juss.) SUBJECTED TO FLOODING STRESS1

Oliveira

Gualtieri

2016

Rev. Árvore

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-The Paratudo (Tabebuia aurea) is a species occurring in the Pantanal of Miranda, Mato Grosso do Sul, Brazil, an area characterized by seasonal flooding. To evaluate the tolerance of this plant to flooding, plants aged four months were grown in flooded soil and in non-flooded soil (control group). Stomatal conductance, transpiration and CO 2 assimilation were measured during the stress (48 days) and recovery (11 days) period, totalling 59 days. The values of stomatal conductance of the control group and stressed plants at the beginning of the flooded were 0.33 mol m . Flooded soil reduced photosynthesis and stomatal conductance, leading to the hypertrophy of the lenticels. These parameters recovered and after this period, and plants exhibited tolerance to flooding stress by reducing their physiological activities.Keywords: CO 2 assimilation; Hydric stress; Hypoxia tolerance. TROCAS GASOSAS EM PLANTAS JOVENS DE Tabebuia aurea (Bignoniaceae Juss.) SUBMETIDAS A ESTRESSE POR ALAGAMENTORESUMO -O paratudo, Tabebuia aurea, é uma espécie de larga ocorrência no Pantanal de Miranda, Mato Grosso do Sul, uma área de inundação sazonal. Para determinar o grau de tolerância da espécie ao alagamento, um grupo de plantas com quatro meses de idade foi mantido em vasos alagados, além do grupo controle, com as taxas de condutância estomática, transpiração e assimilação de CO 2 determinadas durante o período de estresse (48 dias) e de recuperação (11 dias), totalizando 59 dias. Em relação aos valores obtidos, a condutância estomática, no início do alagamento, atingiu 0,33 mol m

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Flooding tolerance of tomato genotypes during vegetative and reproductive stages

Cited by 76 publications

References 45 publications

Effect of waterlogging stress on the growth, development and symptomatology of cape gooseberry (Physalis peruviana L.) plants

Effect of waterlogging stress on the growth, development and symptomatology of cape gooseberry (Physalis peruviana L.) plants

Steady shallow water table did not decrease leaf expansion rate, specific leaf weight, and specific leaf water content in tomato plants

GAS EXCHANGE IN YOUNG PLANTS OF Tabebuia aurea(Bignoniaceae Juss.) SUBJECTED TO FLOODING STRESS1

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