Affiliations 

  • 1 Department of Plant Sciences University of Oxford Oxford UK
  • 2 Institute of Forest and Wildlife Research and Development Phnom Penh Cambodia
  • 3 National Agriculture and Forestry Research Institute Forestry Research Center Vientiane Lao PDR
  • 4 Forest Genetics and Conservation Center for Biodiversity and Biosafety Institute of Agricultural Genetics Vietnam Academy of Agricultural Sciences Hanoi Vietnam
  • 5 Bioversity International, Malaysia Office c/o TNCPI, University Putra Malaysia, off Lebuh Silikon Serdang Malaysia
Ecol Evol, 2020 Oct;10(19):10872-10885.
PMID: 33072302 DOI: 10.1002/ece3.6744

Abstract

Dalbergia cochinchinensis and D. oliveri are classified as vulnerable and endangered, respectively, in the IUCN Red List and under continued threat from deforestation and illegal harvesting for rosewood. Despite emerging efforts to conserve and restore these species, little is known of their responses to drought and heat stress, which are expected to increase in the Greater Mekong Subregion where the species co-occur and are endemic. In this study of isolated and combined drought and heat effects, we found that D. oliveri had an earlier stomatal closure and more constant midday water potential in response to increasing drought level, suggesting that D. oliveri is relatively isohydric while D. cochinchinensis is relatively anisohydric. Heat shock and drought had synergistic effects on stomatal closure. Our results indicate contrasting relationships in water relations, photosynthetic pigment levels, and total soluble sugars. An increase in chlorophyll a was observed in D. cochinchinensis during drought, and a concomitant increase in carotenoid content likely afforded protection against photo-oxidation. These physiological changes correlated with higher total soluble sugars in D. cochinchinensis. By contrast, D. oliveri avoided drought by reducing chlorophyll content and compromising productivity. Anisohydry and drought tolerance in D. cochinchinensis are adaptations which fit well with its ecological niche as a pioneering species with faster growth in young trees. We believe this understanding of the stress responses of both species will be crucial to their effective regeneration and conservation in degraded habitats and in the face of climate change.

* Title and MeSH Headings from MEDLINE®/PubMed®, a database of the U.S. National Library of Medicine.