TY - JOUR
T1 - Species-specific duplication event associated with elevated levels of nonstructural carbohydrates in Sorghum bicolor
AU - Brenton, Zachary W.
AU - Juengst, Brendon T.
AU - Cooper, Elizabeth A.
AU - Myers, Matthew T.
AU - Jordan, Kathleen E.
AU - Dale, Savanah M.
AU - Glaubitz, Jeffrey C.
AU - Wang, Xiaoyun
AU - Boyles, Richard E.
AU - Connolly, Erin L.
AU - Kresovich, Stephen
N1 - Funding Information:
We thank the Department of Energy Joint Genome Institute for use to the pre-publication Sorghum bicolor Rio genome sequence and annotation. Funding for this project was provided by the United Sorghum Checkoff Program and the Department of Energy’s Advanced Research Project Agency (award number DE-AR0000595). Work conducted by the Connolly lab was supported by NSF PGRP (award number 144435). We also thank Dr. Jeremey Schmutz for his thoughtful comments.
Funding Information:
and annotation. Funding for this project was provided by the United Sorghum Checkoff Program and the Department of Energy’s Advanced Research Project Agency (award number DE-AR0000595). Work conducted by the Connolly lab was supported by NSF PGRP (award number 144435). We also thank Dr. Jeremey Schmutz for his thoughtful comments.
Publisher Copyright:
Copyright © 2020 Brenton et al.
PY - 2020/5/1
Y1 - 2020/5/1
N2 - Simple sugars are the essential foundation to plant life, and thus, their production, utilization, and storage are highly regulated processes with many complex genetic controls. Despite their importance, many of the genetic and biochemical mechanisms remain unknown or uncharacterized. Sorghum, a highly productive, diverse C4 grass important for both industrial and subsistence agricultural systems, has considerable phenotypic diversity in the accumulation of nonstructural sugars in the stem. We use this crop species to examine the genetic controls of high levels of sugar accumulation, identify genetic mechanisms for the accumulation of nonstructural sugars, and link carbon allocation with iron transport. We identify a species-specific tandem duplication event controlling sugar accumulation using genome-wide association analysis, characterize multiple allelic variants causing increased sugar content, and provide further evidence of a putative neofunctionalization event conferring adaptability in Sorghum bicolor. Comparative genomics indicate that this event is unique to sorghum which may further elucidate evolutionary mechanisms for adaptation and divergence within the Poaceae. Furthermore, the identification and characterization of this event was only possible with the continued advancement and improvement of the reference genome. The characterization of this region and the process in which it was discovered serve as a reminder that any reference genome is imperfect and is in need of continual improvement.
AB - Simple sugars are the essential foundation to plant life, and thus, their production, utilization, and storage are highly regulated processes with many complex genetic controls. Despite their importance, many of the genetic and biochemical mechanisms remain unknown or uncharacterized. Sorghum, a highly productive, diverse C4 grass important for both industrial and subsistence agricultural systems, has considerable phenotypic diversity in the accumulation of nonstructural sugars in the stem. We use this crop species to examine the genetic controls of high levels of sugar accumulation, identify genetic mechanisms for the accumulation of nonstructural sugars, and link carbon allocation with iron transport. We identify a species-specific tandem duplication event controlling sugar accumulation using genome-wide association analysis, characterize multiple allelic variants causing increased sugar content, and provide further evidence of a putative neofunctionalization event conferring adaptability in Sorghum bicolor. Comparative genomics indicate that this event is unique to sorghum which may further elucidate evolutionary mechanisms for adaptation and divergence within the Poaceae. Furthermore, the identification and characterization of this event was only possible with the continued advancement and improvement of the reference genome. The characterization of this region and the process in which it was discovered serve as a reminder that any reference genome is imperfect and is in need of continual improvement.
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U2 - 10.1534/g3.119.400921
DO - 10.1534/g3.119.400921
M3 - Article
C2 - 32132167
AN - SCOPUS:85084271042
SN - 2160-1836
VL - 10
SP - 1511
EP - 1520
JO - G3: Genes, Genomes, Genetics
JF - G3: Genes, Genomes, Genetics
IS - 5
ER -