Morpho-Physiological Traits Linked to High Temperature Stress Tolerance in Tomato &amp;lt;i&amp;gt;(S. lycopersicum L.)&amp;lt;/i&amp;gt;

Alsamir, Muhammed; Ahmad, Nabil; Mahmood, Tariq; Trethowan, Richard

doi:10.4236/ajps.2017.811180

Cited by 6 publications

(3 citation statements)

References 28 publications

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“…However, plant responses to higher temperatures are difficult to assess by measuring the physiological processes of intact roots, especially when a minor change in root temperature (12 °C to 15 °C) can significantly reduce fruit yield ( Driedonks, 2018 , Bar Tsur et al, 1985 , , 2013 , Sato et al, 2000 ). The high temperature affected the morphology of the tomato flowers and its physiological metabolism, and altered the production of compounds, such as carbohydrates, polyamines, and proline ( Alsamir et al, 2017b , Pressman et al, 2002 , Sato et al, 2006 , Song et al, 2002 ).…”

Section: Tomato Responses To Heat Stressmentioning

confidence: 99%

An overview of heat stress in tomato (Solanum lycopersicum L.)

Alsamir

Mahmood

Trethowan

et al. 2021

Saudi Journal of Biological Sciences

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Heat stress has been defined as the rise of temperature for a period of time higher than a threshold level, thereby permanently affecting the plant growth and development. Day or night temperature is considered as the major limiting factor for plant growth. Earlier studies reported that night temperature is an important factor in the heat reaction of the plants. Tomato cultivars capable of setting viable fruits under night temperatures above 21 °C are considered as heat-tolerant cultivars. The development of breeding objectives is generally summarized in four points: (a) cultivars with higher yield, (b) disease resistant varieties in the 1970s, (c) long shelf-life in 1980s, and (d) nutritive and taste quality during 1990s. Some unique varieties like the dwarf “Micro-Tom”, and the first transgenic tomato (FlavrSavr) were developed through breeding; they were distributed late in the 1980s. High temperature significantly affects seed, pollen viability and root expansion. Researchers have employed different parameters to evaluate the tolerance to heat stress, including membrane thermo stability, floral characteristics (Stigma exertion and antheridia cone splitting), flower number, and fruit yield per plant. Reports on pollen viability and fruit set/plant under heat stress by comparing the pollen growth and tube development in heat-treated and non-heat-stressed conditions are available in literature. The electrical conductivity (EC) have been used to evaluate the tolerance of some tomato cultivars in vitro under heat stress conditions as an indication of cell damage due to electrolyte leakage; they classified the cultivars into three groups: (a) heat tolerant, (b) moderately heat tolerant, and (c) heat sensitive. It is important to determine the range in genetic diversity for heat tolerance in tomatoes. Heat stress experiments under field conditions offer breeders information to identify the potentially heat tolerant germplasm.

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Section: Tomato Responses To Heat Stressmentioning

confidence: 99%

An overview of heat stress in tomato (Solanum lycopersicum L.)

Alsamir

Mahmood

Trethowan

et al. 2021

Saudi Journal of Biological Sciences

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“…Proper phenotyping of germplasm for heat stress tolerance has been a challenge for researchers engaged in crop improvement. A consistent genotype response to normal and heat‐stressed conditions is essential for yield stability (Alsamir et al, 2017). Screening under late planting or endemic heat stress locations (hot spots) does not give much control over a specific (desired) crop stage during which the stress has to be imparted.…”

Section: Discussionmentioning

confidence: 99%

Genotype–Phenotype Relationships for High‐Temperature Tolerance: An Integrated Method for Minimizing Phenotyping Constraints in Wheat

et al. 2019

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Various attempts have been made to understand the traits and genes associated with heat stress tolerance in wheat (Triticum aestivum L.) in the field and under controlled conditions. Attempts made under controlled conditions have not been conclusive, mainly through a lack of sufficient precision in simulating the ambient temperature dynamics and microenvironments prevalent in the field. In addition, inconsistency in field phenotyping is a major concern. Hence, we attempted to develop a method for phenotyping wheat for heat stress tolerance through a novel temperature‐controlled phenotyping facility (TCPF), along with an inexpensive tool to ensure uniform crop establishment. The objective was to improve the precision of assessing plants' responses to elevated temperatures, particularly when these experiments are challenged by a large number of genotypes to be screened that show significant variations in their phenology. The study involved 75 genotypes from a recombinant inbred line population with differing responses to heat stress under three conditions: in the TCPF and in the field [regular field season and late sown (LS)] across two consecutive years. The results revealed that the yield components were different under LS and TCPF conditions. These differences reflected the plants' responses to morphophenological adaptations arising from the late planting time and were not really reflective of the heat stress response. However, greater precision in differentiating high‐temperature responses in the TCPF was evident from the repeatability in terms of growth, physiology, and productivity. This could be attributed to uniform crop establishment and improved capacity to maintain the desired temperature for phenotyping.

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“…Although there are many studies on physiology, plant growth, and yield of tomatoes under high-temperature conditions [21][22][23][24][25][26][27][28], there is limited research [29] on the nutrient and antioxidant content of the fruit affected by high temperatures. Also, there is a growing interest in increasing the antioxidant content of agricultural crops to improve food quality and produce crops with high-stress tolerance.…”

Section: Introductionmentioning

confidence: 99%

Effects of High-Temperature Stress during Plant Cultivation on Tomato (Solanum lycopersicum L.) Fruit Nutrient Content

Daşgan

Dere

Akhoundnejad

et al. 2021

Journal of Food Quality

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Agriculture is among the sectors that will be impacted first and most by the adverse effects of climate change. Therefore, developing new high-temperature tolerant varieties is an essential economic measure in adaptation to near-future climate change. Likewise, there is a growing interest in increasing the antioxidant content of crops to improve food quality and produce crops with high-stress tolerance. Tomato is the most grown and consumed species in horticultural plants; however, it is vulnerable to 35°C and above high temperatures during cultivation. This study used twenty high-temperature tolerant, two susceptible genotypes, and two commercial tomato varieties in the open field. The experiment was applied under control and high-temperature stress conditions based on a randomized block design with 4 replications and 12 plants per repetition. The study investigated the fruit’s selected quality properties and antioxidant compounds, namely, total soluble solutes (Brix), titratable acidity, pH, electrical conductivity (EC), lycopene, β-carotene, and vitamin C, along with total phenols and total flavonoids under control and stress conditions. As a result, in general, total soluble solutes, titratable acidity, total phenol, and vitamin C contents under high-temperature conditions were determined to increase in tolerant tomato genotypes, while decreases were noted for pH, EC, total flavonoids, lycopene, and β-carotene. However, different specific responses on the basis of genotypes and useful information for breeding studies have been identified. These data on fruit nutrient content and antioxidants will be helpful when breeding tomato varieties to be grown in high-temperature conditions.

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Morpho-Physiological Traits Linked to High Temperature Stress Tolerance in Tomato <i>(S. lycopersicum L.)</i>

Cited by 6 publications

References 28 publications

An overview of heat stress in tomato (Solanum lycopersicum L.)

An overview of heat stress in tomato (Solanum lycopersicum L.)

Genotype–Phenotype Relationships for High‐Temperature Tolerance: An Integrated Method for Minimizing Phenotyping Constraints in Wheat

Effects of High-Temperature Stress during Plant Cultivation on Tomato (Solanum lycopersicum L.) Fruit Nutrient Content

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