An Improved Assembly of the "Cascade" Hop () Genome Uncovers Signatures of Molecular Evolution and Refines Time of Divergence Estimates for the Cannabaceae Family

Overview

Journal Hortic Res

Publisher Oxford University Press

Date 2023 Feb 23

PMID 36818366

Authors

Lillian K Padgitt-Cobb

Nicholi J Pitra

Paul D Matthews

John A Henning

David A Hendrix

Affiliations

Soon will be listed here.

Abstract

We present a chromosome-level assembly of the Cascade hop ( L. var. ) genome. The hop genome is large (2.8 Gb) and complex, and early attempts at assembly were fragmented. Recent advances have made assembly of the hop genome more tractable, transforming the extent of investigation that can occur. The chromosome-level assembly of Cascade was developed by scaffolding the previously reported Cascade assembly generated with PacBio long-read sequencing and polishing with Illumina short-read DNA sequencing. We developed gene models and repeat annotations and used a controlled bi-parental mapping population to identify significant sex-associated markers. We assessed molecular evolution in gene sequences, gene family expansion and contraction, and time of divergence from and other closely related plant species using Bayesian inference. We identified the putative sex chromosome in the female genome based on significant sex-associated markers from the bi-parental mapping population. While the estimate of repeat content (~64%) is similar to the estimate for the hemp genome, syntenic blocks in hop contain a greater percentage of LTRs. Hop is enriched for disease resistance-associated genes in syntenic gene blocks and expanded gene families. The Cascade chromosome-level assembly will inform cultivation strategies and serve to deepen our understanding of the hop genomic landscape, benefiting hop researchers and the Cannabaceae genomics community.

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