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Related Concept Videos

Factors Affecting Workability01:24

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The workability of concrete is a critical characteristic that influences the ease of mixing, handling, and finishing the concrete. It is affected by several factors including water content, aggregate properties, and admixtures like air entrainment. Water plays a fundamental role as it lubricates the concrete mix, facilitating easier movement and placement. However, the water requirement varies depending on the texture and shape of aggregates. Finer particles and angular, rough-textured...
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Every organism has an optimum temperature range within which healthy growth and physiological functioning can occur. At the ends of this range, there will be a minimum and maximum temperature that interrupt biological processes.
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Optimizing wheat development to a range of winter climates.

Dominique Hirsz1, Laura E Dixon1

  • 1Genebank Department, Leibniz Institute of Plant Genetics and Crop Plant Research (IPK), Gatersleben, Seeland D-06466, Germany.

Journal of Experimental Botany
|March 15, 2026
PubMed
Summary
This summary is machine-generated.

Climate change disrupts crop production. Understanding how winter wheat responds to photoperiod and temperature cues is crucial for developing climate-resilient cultivars.

Keywords:
Adaptationchanging climatevernalizationwinter wheat

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Area of Science:

  • Agricultural Science
  • Plant Biology
  • Climate Change Adaptation

Background:

  • Climate change poses significant threats to global crop production by altering environmental cues essential for plant development.
  • Wheat, a major global crop, relies on photoperiod and temperature for regulating flowering time, making it sensitive to climate variability.
  • Winter wheat varieties are particularly vulnerable to changes in cold duration and spring photoperiod onset, impacting yield and sustainability.

Purpose of the Study:

  • To investigate the genetic and physiological mechanisms underlying winter wheat's response to combined photoperiod and temperature cues.
  • To identify key genes regulating floral transition and flowering in response to environmental signals.
  • To explore strategies for developing climate-resilient winter wheat cultivars adaptable to changing environmental conditions.

Main Methods:

  • Review of existing literature on wheat photoperiod and temperature responses.
  • Analysis of genetic pathways involved in flowering time regulation.
  • Exploration of breeding strategies for enhanced winter hardiness and environmental plasticity.

Main Results:

  • Identified critical gene networks mediating responses to photoperiod and temperature in wheat.
  • Highlighted the sensitivity of winter wheat to variations in winter cold and spring photoperiod.
  • Outlined the challenges and opportunities for breeding climate-resilient winter wheat.

Conclusions:

  • Understanding the interplay of photoperiod and temperature is vital for adapting winter wheat to climate change.
  • Developing cultivars that are resilient to winter conditions yet flexible in their vernalization requirements is key.
  • Further research into gene-environment interactions will facilitate the creation of sustainable and productive winter wheat varieties.