Phased-Genome Assemblies of Saltgrass Reveal Structural Dynamics and Genomic Basis for Extreme Salt Tolerance and Dioecy.

Authors

Kashif Nawaz, King Abdullah University of Science and Technology (KAUST)
Izamar Olivas Orduna, King Abdullah University of Science and Technology (KAUST)
Dal-Hoe Koo, Kansas State University
Francisco Molina-Freaner, Universidad Nacional Autonoma de Mexico
Hester L. Bell, California Botanic Garden, Claremont, California, USA.
Mara Miculan, King Abdullah University of Science and Technology (KAUST)
Victor Llaca, Corteva Agriscience
Judith Harrington, Colorado State University
Sarah M. Eppley, Portland State UniversityFollow
Jesse Poland, King Abdullah University of Science and Technology (KAUST)

Author ORCID Identifier(s)

Kashif Nawaz (0000-0002-5482-3366)

Jesse Poland (0000-0002-7856-1399)

Published In

Plant Communications

Document Type

Pre-Print

Publication Date

3-19-2026

Subjects

Saltgrass -- Halophyte, neodomestication, saltgrass (Distichlis spp.), Chromosome fusion, B 60 chromosome, Sex-determining region

Abstract

The climate crisis poses a critical challenge to agriculture, with freshwater scarcity becoming a major constraint on crop production. Harnessing halophytic adaptations for growth in saline environments offers a promising path for neodomestication of salt-tolerant crops. Distichlis spp. (saltgrass)-a genus of dioecious, halophytic C4 grasses in the PACMAD clade-thrives in extreme saline conditions, making it a compelling species to understand salinity tolerance and adaptation. Here, we present high-quality phased genome assemblies of four Distichlis genets, revealing an allotetraploid genome (576-610 Mb) with two highly syntenic but degenerate subgenomes, each exhibiting over 30% gene loss across orthologous pairs. Comparative genomic analyses uncovered a novel chromosome fusion event differentiating D. spicata (2n=40) and D. stricta (2n=38), highlighting a chromosomal rearrangement differentiating the species. Population genomic analysis of 364 genets across 35 populations demonstrated strong geographic differentiation and confirmed D. stricta as a distinct species. Additionally, we identified a 7 Mb B chromosome in two genets, displaying common features shared with B chromosomes in other species. Using k-mer analyses of sex-typed populations, we identified an 8 Mb sex-determining region in female genets with 24 candidate genes, confirming that Distichlis has a ZW-type sex determination. Expression profiling of plants under extreme (seawater-level) salinity revealed key salt-tolerance genes that are also implicated in drought resilience, suggesting an overlapping genetic basis for these stress responses. These genomic resources establish a foundation for neodomestication of saltgrass as a climate-resilient crop for saline agroecosystems and enhance our understanding of genome evolution in halophytic grasses.

Rights

Copyright © 2026 The Author(s). Published by Elsevier Inc. All rights reserved.

Description

Pre print

DOI

10.1016/j.xplc.2026.101827

Persistent Identifier

https://archives.pdx.edu/ds/psu/44559

Publisher

Elsevier BV

Citation Details

Nawaz, K., Orduna, I. O., Koo, D.-H., Molina-Freaner, F., Bell, H. L., Miculan, M., Llaca, V., Harrington, J., Eppley, S., & Poland, J. (2026). Phased-genome assemblies of saltgrass reveal structural dynamics and genomic basis for extreme salt tolerance and dioecy. Plant Communications, 101827.