The phenotypic and genetic effects of drought-induced stress on wood specific conductivity and anatomical properties in white spruce seedlings, and relationships with growth and wood density

André Soro; Patrick Lenz; Jean-Romain Roussel; Simon Nadeau; David Pothier; Jean Bousquet; Alexis Achim

doi:10.3389/fpls.2023.1297314

The phenotypic and genetic effects of drought-induced stress on wood specific conductivity and anatomical properties in white spruce seedlings, and relationships with growth and wood density

Front Plant Sci. 2023 Dec 22:14:1297314. doi: 10.3389/fpls.2023.1297314. eCollection 2023.

Authors

André Soro^{1

2

3}, Patrick Lenz^{2

3}, Jean-Romain Roussel¹, Simon Nadeau³, David Pothier¹, Jean Bousquet^{1

2}, Alexis Achim¹

Affiliations

¹ Renewable Materials Research Centre, Department of Wood and Forest Sciences, Université Laval, Québec, QC, Canada.
² Canada Research Chair in Forest Genomics, Forest Research Centre and Institute for Systems and Integrative Biology, Université Laval, Québec QC, Canada.
³ Natural Resources Canada, Canadian Wood Fibre Centre, Québec, QC, Canada.

Abstract

Drought frequency and intensity are projected to increase with climate change, thus amplifying stress on forest trees. Resilience to drought implicates physiological traits such as xylem conductivity and wood anatomical traits, which are related to growth and wood density. Integrating drought-stress response traits at the juvenile stage into breeding criteria could help promote the survival of planted seedlings under current and future climate and thus, improve plantation success. We assessed in greenhouse the influence of drought-induced stress on 600 two-year-old white spruce (Picea glauca) seedlings from 25 clonal lines after two consecutive growing seasons. Three levels of drought-induced stress were applied: control, moderate and severe. Seedlings were also planted at a 45° angle to clearly separate compression from normal wood. We looked at the phenotypic and genetic effects of drought stress on xylem specific hydraulic conductivity, lumen diameter, tracheid diameter and length, and the number of pits per tracheid in the normal wood. We detected no significant effects of drought stress except for tracheid length, which decreased with increasing drought stress. We found low to high estimates of trait heritability, which generally decreased with increasing drought stress. Genetic correlations were higher than phenotypic correlations for all treatments. Specific conductivity was genetically highly correlated positively with lumen diameter and tracheid length under all treatments. Tracheid length and diameter were always negatively correlated genetically, indicating a trade-off in resource allocation. Moderate to high genetic correlations sometimes in opposite direction were observed between physico-anatomical and productivity traits, also indicating trade-offs. A large variation was observed among clones for all physico-anatomical traits, but clonal ranks were generally stable between control and drought-induced treatments. Our results indicate the possibility of early screening of genetic material for desirable wood anatomical attributes under normal growing conditions, thus allowing to improve the drought resilience of young trees.

Keywords: conifer; drought-induced stress; heritability; phenotypic and genetic correlations; tracheids; xylem specific hydraulic conductivity.

Grants and funding

The author(s) declare financial support was received for the research, authorship, and/or publication of this article. This research was part of the Spruce-Up LSARP spruce genomics project (234FOR) (http://spruceup.ca), co-lead by JB and J. Bohlmann and funded by Génome Canada, Génome Québec and Genome British Columbia. Funding for this work was also provided by a Natural Sciences and Engineering Research Council of Canada discovery grant (AA), and contributions from the Univ. Laval Centre de recherche des matériaux renouvelables (AA), the Canada Research Chair in Forest Genomics (JB), and the Canadian Wood Fibre Centre and Laurentian Forestry Centre of Natural Resources Canada (PL).