Diverse Physiological and Physical Responses among Wild, Landrace and Elite Barley Varieties Point to Novel Breeding Opportunities
Climate change from elevated [CO<sub>2</sub>] may reduce water availability to crops through changes in precipitation and higher temperatures. However, agriculture already accounts for 70% of human consumption of water. Stomata, pores in the leaf surface, mediate exchange of water and CO...
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doaj-be7a8deee31c43d3bfc195fd13749fc62021-05-31T23:25:19ZengMDPI AGAgronomy2073-43952021-05-011192192110.3390/agronomy11050921Diverse Physiological and Physical Responses among Wild, Landrace and Elite Barley Varieties Point to Novel Breeding OpportunitiesJim Stevens0Matthew Alan Jones1Tracy Lawson2School of Life Sciences, University of Essex, Colchester CO4 3SQ, UKInstitute of Molecular Cell & Systems Biology, University of Glasgow, Glasgow G12 8QQ, UKSchool of Life Sciences, University of Essex, Colchester CO4 3SQ, UKClimate change from elevated [CO<sub>2</sub>] may reduce water availability to crops through changes in precipitation and higher temperatures. However, agriculture already accounts for 70% of human consumption of water. Stomata, pores in the leaf surface, mediate exchange of water and CO<sub>2</sub> for the plant. In crops including barley, the speed of stomatal response to changing environmental conditions is as important as maximal responses and can thus affect water use efficiency. Wild barleys and landraces which predate modern elite lines offer the breeder the potential to find unexploited genetic diversity. This study aimed to characterize natural variation in stomatal anatomy and leaf physiology and to link these variations to yield. Wild, landrace and elite barleys were grown in a polytunnel and a controlled environment chamber. Physiological responses to changing environments were measured, along with stomatal anatomy and yield. The elite barley lines did not have the fastest or largest physiological responses to light nor always the highest yields. There was variation in stomatal anatomy, but no link between stomatal size and density. The evidence suggests that high photosynthetic capacity does not translate into yield, and that landraces and wild barleys have unexploited physiological responses that should interest breeders.https://www.mdpi.com/2073-4395/11/5/921stomataclimate changebarleyphotosynthesiswater usekinetics |
collection |
DOAJ |
language |
English |
format |
Article |
sources |
DOAJ |
author |
Jim Stevens Matthew Alan Jones Tracy Lawson |
spellingShingle |
Jim Stevens Matthew Alan Jones Tracy Lawson Diverse Physiological and Physical Responses among Wild, Landrace and Elite Barley Varieties Point to Novel Breeding Opportunities Agronomy stomata climate change barley photosynthesis water use kinetics |
author_facet |
Jim Stevens Matthew Alan Jones Tracy Lawson |
author_sort |
Jim Stevens |
title |
Diverse Physiological and Physical Responses among Wild, Landrace and Elite Barley Varieties Point to Novel Breeding Opportunities |
title_short |
Diverse Physiological and Physical Responses among Wild, Landrace and Elite Barley Varieties Point to Novel Breeding Opportunities |
title_full |
Diverse Physiological and Physical Responses among Wild, Landrace and Elite Barley Varieties Point to Novel Breeding Opportunities |
title_fullStr |
Diverse Physiological and Physical Responses among Wild, Landrace and Elite Barley Varieties Point to Novel Breeding Opportunities |
title_full_unstemmed |
Diverse Physiological and Physical Responses among Wild, Landrace and Elite Barley Varieties Point to Novel Breeding Opportunities |
title_sort |
diverse physiological and physical responses among wild, landrace and elite barley varieties point to novel breeding opportunities |
publisher |
MDPI AG |
series |
Agronomy |
issn |
2073-4395 |
publishDate |
2021-05-01 |
description |
Climate change from elevated [CO<sub>2</sub>] may reduce water availability to crops through changes in precipitation and higher temperatures. However, agriculture already accounts for 70% of human consumption of water. Stomata, pores in the leaf surface, mediate exchange of water and CO<sub>2</sub> for the plant. In crops including barley, the speed of stomatal response to changing environmental conditions is as important as maximal responses and can thus affect water use efficiency. Wild barleys and landraces which predate modern elite lines offer the breeder the potential to find unexploited genetic diversity. This study aimed to characterize natural variation in stomatal anatomy and leaf physiology and to link these variations to yield. Wild, landrace and elite barleys were grown in a polytunnel and a controlled environment chamber. Physiological responses to changing environments were measured, along with stomatal anatomy and yield. The elite barley lines did not have the fastest or largest physiological responses to light nor always the highest yields. There was variation in stomatal anatomy, but no link between stomatal size and density. The evidence suggests that high photosynthetic capacity does not translate into yield, and that landraces and wild barleys have unexploited physiological responses that should interest breeders. |
topic |
stomata climate change barley photosynthesis water use kinetics |
url |
https://www.mdpi.com/2073-4395/11/5/921 |
work_keys_str_mv |
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