Novel mutant alleles reveal a role of the extra-large G protein in rice grain filling, panicle architecture, plant growth, and disease resistance

Novel mutant alleles reveal a role of the extra-large G protein in rice grain filling, panicle architecture, plant growth, and disease resistance

Plant growth and grain filling are the key agronomical traits for grain weight and yield of rice. The continuous improvement in rice yield is required for a future sustainable global economy and food security. The heterotrimeric G protein complex containing a canonical α subunit (RGA1) couples extracellular signals perceived by receptors to modulate cell function including plant development and grain weight. We hypothesized that, besides RGA1, three atypical, extra-large GTP-binding protein (XLG) subunits also regulate panicle architecture, plant growth, development, grain weight, and disease resistance. Here, we identified a role of XLGs in agronomic traits and stress tolerance by genetically ablating all three rice XLGs individually and in combination using the CRISPR/Cas9 genome editing in rice. For this study, eight (three single, two double, and three triple) null mutants were selected. Three XLG proteins combinatorically regulate seed filling, because loss confers a decrease in grain weight from 14% with loss of one XLG and loss of three to 32% decrease in grain weight. Null mutations in XLG2 and XLG4 increase grain size. The mutants showed significantly reduced panicle length and number per plant including lesser number of grains per panicle compared to the controls. Loss-of-function of all individual XLGs contributed to 9% more aerial biomass compared to wild type (WT). The double mutant showed improved salinity tolerance. Moreover, loss of the XLG gene family confers hypersensitivity to pathogens. Our findings suggest that the non-canonical XLGs play important roles in regulating rice plant growth, grain filling, panicle phenotype, stress tolerance, and disease resistance. Genetic manipulation of XLGs has the potential to improve agronomic properties in rice.

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Main Authors: Biswal, A.K., Wu, T.-Y., Urano, D., Pelissier, R., Morel, J.-B., Jones, A.M.
Format: Article biblioteca
Language:English
Published: Frontiers 2022
Subjects:AGRICULTURAL SCIENCES AND BIOTECHNOLOGY, Heterotrimeric G Proteins, Extra-Large G Proteins, CRISPR/Cas9, OsXLG, CRISPR, RICE, PROTEINS, PLANT GROWTH, DISEASE RESISTANCE,
Online Access:https://hdl.handle.net/10883/21911
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spelling dig-cimmyt-10883-219112024-03-14T14:18:40Z Novel mutant alleles reveal a role of the extra-large G protein in rice grain filling, panicle architecture, plant growth, and disease resistance Biswal, A.K. Wu, T.-Y. Urano, D. Pelissier, R. Morel, J.-B. Jones, A.M. Biswal, A.K. AGRICULTURAL SCIENCES AND BIOTECHNOLOGY Heterotrimeric G Proteins Extra-Large G Proteins CRISPR/Cas9 OsXLG CRISPR RICE PROTEINS PLANT GROWTH DISEASE RESISTANCE Plant growth and grain filling are the key agronomical traits for grain weight and yield of rice. The continuous improvement in rice yield is required for a future sustainable global economy and food security. The heterotrimeric G protein complex containing a canonical α subunit (RGA1) couples extracellular signals perceived by receptors to modulate cell function including plant development and grain weight. We hypothesized that, besides RGA1, three atypical, extra-large GTP-binding protein (XLG) subunits also regulate panicle architecture, plant growth, development, grain weight, and disease resistance. Here, we identified a role of XLGs in agronomic traits and stress tolerance by genetically ablating all three rice XLGs individually and in combination using the CRISPR/Cas9 genome editing in rice. For this study, eight (three single, two double, and three triple) null mutants were selected. Three XLG proteins combinatorically regulate seed filling, because loss confers a decrease in grain weight from 14% with loss of one XLG and loss of three to 32% decrease in grain weight. Null mutations in XLG2 and XLG4 increase grain size. The mutants showed significantly reduced panicle length and number per plant including lesser number of grains per panicle compared to the controls. Loss-of-function of all individual XLGs contributed to 9% more aerial biomass compared to wild type (WT). The double mutant showed improved salinity tolerance. Moreover, loss of the XLG gene family confers hypersensitivity to pathogens. Our findings suggest that the non-canonical XLGs play important roles in regulating rice plant growth, grain filling, panicle phenotype, stress tolerance, and disease resistance. Genetic manipulation of XLGs has the potential to improve agronomic properties in rice. 2022-02-01T01:10:15Z 2022-02-01T01:10:15Z 2022 Article Published Version https://hdl.handle.net/10883/21911 10.3389/fpls.2021.782960 English https://figshare.com/collections/Novel_Mutant_Alleles_Reveal_a_Role_of_the_Extra-Large_G_Protein_in_Rice_Grain_Filling_Panicle_Architecture_Plant_Growth_and_Disease_Resistance/5773688 CIMMYT manages Intellectual Assets as International Public Goods. The user is free to download, print, store and share this work. In case you want to translate or create any other derivative work and share or distribute such translation/derivative work, please contact CIMMYT-Knowledge-Center@cgiar.org indicating the work you want to use and the kind of use you intend; CIMMYT will contact you with the suitable license for that purpose Open Access Switzerland Frontiers 12 1664-462X Frontiers in Plant Science 782960
institution CIMMYT
collection DSpace
country México
countrycode MX
component Bibliográfico
access En linea
databasecode dig-cimmyt
tag biblioteca
region America del Norte
libraryname CIMMYT Library
language English
topic AGRICULTURAL SCIENCES AND BIOTECHNOLOGY
Heterotrimeric G Proteins
Extra-Large G Proteins
CRISPR/Cas9
OsXLG
CRISPR
RICE
PROTEINS
PLANT GROWTH
DISEASE RESISTANCE
AGRICULTURAL SCIENCES AND BIOTECHNOLOGY
Heterotrimeric G Proteins
Extra-Large G Proteins
CRISPR/Cas9
OsXLG
CRISPR
RICE
PROTEINS
PLANT GROWTH
DISEASE RESISTANCE
spellingShingle AGRICULTURAL SCIENCES AND BIOTECHNOLOGY
Heterotrimeric G Proteins
Extra-Large G Proteins
CRISPR/Cas9
OsXLG
CRISPR
RICE
PROTEINS
PLANT GROWTH
DISEASE RESISTANCE
AGRICULTURAL SCIENCES AND BIOTECHNOLOGY
Heterotrimeric G Proteins
Extra-Large G Proteins
CRISPR/Cas9
OsXLG
CRISPR
RICE
PROTEINS
PLANT GROWTH
DISEASE RESISTANCE
Biswal, A.K.
Wu, T.-Y.
Urano, D.
Pelissier, R.
Morel, J.-B.
Jones, A.M.
Biswal, A.K.
Novel mutant alleles reveal a role of the extra-large G protein in rice grain filling, panicle architecture, plant growth, and disease resistance
description Plant growth and grain filling are the key agronomical traits for grain weight and yield of rice. The continuous improvement in rice yield is required for a future sustainable global economy and food security. The heterotrimeric G protein complex containing a canonical α subunit (RGA1) couples extracellular signals perceived by receptors to modulate cell function including plant development and grain weight. We hypothesized that, besides RGA1, three atypical, extra-large GTP-binding protein (XLG) subunits also regulate panicle architecture, plant growth, development, grain weight, and disease resistance. Here, we identified a role of XLGs in agronomic traits and stress tolerance by genetically ablating all three rice XLGs individually and in combination using the CRISPR/Cas9 genome editing in rice. For this study, eight (three single, two double, and three triple) null mutants were selected. Three XLG proteins combinatorically regulate seed filling, because loss confers a decrease in grain weight from 14% with loss of one XLG and loss of three to 32% decrease in grain weight. Null mutations in XLG2 and XLG4 increase grain size. The mutants showed significantly reduced panicle length and number per plant including lesser number of grains per panicle compared to the controls. Loss-of-function of all individual XLGs contributed to 9% more aerial biomass compared to wild type (WT). The double mutant showed improved salinity tolerance. Moreover, loss of the XLG gene family confers hypersensitivity to pathogens. Our findings suggest that the non-canonical XLGs play important roles in regulating rice plant growth, grain filling, panicle phenotype, stress tolerance, and disease resistance. Genetic manipulation of XLGs has the potential to improve agronomic properties in rice.
format Article
topic_facet AGRICULTURAL SCIENCES AND BIOTECHNOLOGY
Heterotrimeric G Proteins
Extra-Large G Proteins
CRISPR/Cas9
OsXLG
CRISPR
RICE
PROTEINS
PLANT GROWTH
DISEASE RESISTANCE
author Biswal, A.K.
Wu, T.-Y.
Urano, D.
Pelissier, R.
Morel, J.-B.
Jones, A.M.
Biswal, A.K.
author_facet Biswal, A.K.
Wu, T.-Y.
Urano, D.
Pelissier, R.
Morel, J.-B.
Jones, A.M.
Biswal, A.K.
author_sort Biswal, A.K.
title Novel mutant alleles reveal a role of the extra-large G protein in rice grain filling, panicle architecture, plant growth, and disease resistance
title_short Novel mutant alleles reveal a role of the extra-large G protein in rice grain filling, panicle architecture, plant growth, and disease resistance
title_full Novel mutant alleles reveal a role of the extra-large G protein in rice grain filling, panicle architecture, plant growth, and disease resistance
title_fullStr Novel mutant alleles reveal a role of the extra-large G protein in rice grain filling, panicle architecture, plant growth, and disease resistance
title_full_unstemmed Novel mutant alleles reveal a role of the extra-large G protein in rice grain filling, panicle architecture, plant growth, and disease resistance
title_sort novel mutant alleles reveal a role of the extra-large g protein in rice grain filling, panicle architecture, plant growth, and disease resistance
publisher Frontiers
publishDate 2022
url https://hdl.handle.net/10883/21911
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