Divergent Metabolic Changes in Rhizomes of Lowland and Upland Switchgrass () from Early Season Through Dormancy Onset

Overview

Journal Plants (Basel)

Date 2023 Apr 28

PMID 37111955

Authors

Nathan A Palmer

Gautam Sarath

Michael J Bowman

Aaron J Saathoff

Serge J Edme

Robert B Mitchell

Christian M Tobias

Soundararajan Madhavan

Erin D Scully

Scott E Sattler

Affiliations

Soon will be listed here.

Abstract

High-biomass-yielding southerly adapted switchgrasses ( L.) frequently suffer from unpredictable winter hardiness at more northerly sites arising from damage to rhizomes that prevent effective spring regrowth. Previously, changes occurring over the growing season in rhizomes sampled from a cold-adapted tetraploid upland cultivar, Summer, demonstrated a role for abscisic acid (ABA), starch accumulation, and transcriptional reprogramming as drivers of dormancy onset and potential keys to rhizome health during winter dormancy. Here, rhizome metabolism of a high-yielding southerly adapted tetraploid switchgrass cultivar, Kanlow-which is a significant source of genetics for yield improvement-was studied over a growing season at a northern site. Metabolite levels and transcript abundances were combined to develop physiological profiles accompanying greening through the onset of dormancy in Kanlow rhizomes. Next, comparisons of the data to rhizome metabolism occurring in the adapted upland cultivar Summer were performed. These data revealed both similarities as well as numerous differences in rhizome metabolism that were indicative of physiological adaptations unique to each cultivar. Similarities included elevated ABA levels and accumulation of starch in rhizomes during dormancy onset. Notable differences were observed in the accumulation of specific metabolites, the expression of genes encoding transcription factors, and several enzymes linked to primary metabolism.

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