Changes in the Transcriptome of Dry Leafy Spurge (Euphorbia esula) Seeds Imbibed at a Constant and Alternating Temperature
Leafy spurge seeds are responsive to alternating temperature rather than constant temperature for germination. Transcriptome changes of dry leafy spurge seeds and seeds imbibed for 1 and 3 d at 20 C constant (C) and 20 ∶ 30 C alternating (A) temperature were determined by microarray analysis to exam...
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| Published in | Weed science Vol. 60; no. 1; pp. 48 - 56 |
|---|---|
| Main Authors | , , , , |
| Format | Journal Article |
| Language | English |
| Published |
810 East 10th Street, Lawrence, KS 66044-8897
Weed Science Society of America
01.01.2012
Cambridge University Press |
| Subjects | |
| Online Access | Get full text |
| ISSN | 0043-1745 1550-2759 |
| DOI | 10.1614/WS-D-11-00107.1 |
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| Abstract | Leafy spurge seeds are responsive to alternating temperature rather than constant temperature for germination. Transcriptome changes of dry leafy spurge seeds and seeds imbibed for 1 and 3 d at 20 C constant (C) and 20 ∶ 30 C alternating (A) temperature were determined by microarray analysis to examine temperature responsiveness. Principal component analysis revealed differences in the transcriptome of imbibed seeds based on the temperature regime. Computational methods in bioinformatics parsed the data into overrepresented AraCyc pathways and gene regulation subnetworks providing biological context to temperature responses. After 1 d of imbibition, the degradation of starch and sucrose leading to anaerobic respiration were common pathways at both temperature regimes. Several overrepresented pathways unique to 1 d A were associated with generation of energy, reducing power, and carbon substrates; several of these pathways remained overrepresented and up-regulated at 3 d A. At 1 d C, pathways for the phytohormones jasmonic acid and brassinosteroids were uniquely overrepresented. There was little similarity in overrepresented pathways at 1 d C between leafy spurge and arabidopsis seeds, indicating species-specific effects upon imbibition of dry seeds. Overrepresented gene subnetworks at 1 d and 3 d at both temperature regimes related to signaling processes and stress responses. A major overrepresented subnetwork unique to 1 d C related to photomorphogenesis via the E3 ubiquitin ligase COP1. At 1 d A, major overrepresented subnetworks involved circadian rhythm via LHY and TOC1 proteins and expression of stress-related genes such as DREB1A, which is subject to circadian regulation. Collectively, substantial differences were observed in the transcriptome of leafy spurge seeds imbibed under conditions that affect the capacity to germinate. Nomenclature: Mouse-ear cress, Arabidopsis thaliana (L.) Heynh.; leafy spurge, Euphorbia esula L. (EPHES). |
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| AbstractList | Leafy spurge seeds are responsive to alternating temperature rather than
constant temperature for germination. Transcriptome changes of dry leafy
spurge seeds and seeds imbibed for 1 and 3 d at 20 C constant (C) and 20 :
30 C alternating (A) temperature were determined by microarray analysis to
examine temperature responsiveness. Principal component analysis revealed
differences in the transcriptome of imbibed seeds based on the temperature
regime. Computational methods in bioinformatics parsed the data into
overrepresented AraCyc pathways and gene regulation subnetworks providing
biological context to temperature responses. After 1 d of imbibition, the
degradation of starch and sucrose leading to anaerobic respiration were
common pathways at both temperature regimes. Several overrepresented
pathways unique to 1 d A were associated with generation of energy, reducing
power, and carbon substrates; several of these pathways remained
overrepresented and up-regulated at 3 d A. At 1 d C, pathways for the
phytohormones jasmonic acid and brassinosteroids were uniquely
overrepresented. There was little similarity in overrepresented pathways at
1 d C between leafy spurge and arabidopsis seeds,
indicating species-specific effects upon imbibition of dry seeds.
Overrepresented gene subnetworks at 1 d and 3 d at both temperature regimes
related to signaling processes and stress responses. A major overrepresented
subnetwork unique to 1 d C related to photomorphogenesis via the E3
ubiquitin ligase COP1. At 1 d A, major overrepresented subnetworks involved
circadian rhythm via LHY and TOC1 proteins and expression of stress-related
genes such as DREB1A, which is subject to circadian
regulation. Collectively, substantial differences were observed in the
transcriptome of leafy spurge seeds imbibed under conditions that affect the
capacity to germinate. Leafy spurge seeds are responsive to alternating temperature rather than constant temperature for germination. Transcriptome changes of dry leafy spurge seeds and seeds imbibed for 1 and 3 d at 20 C constant (C) and 20 ∶ 30 C alternating (A) temperature were determined by microarray analysis to examine temperature responsiveness. Principal component analysis revealed differences in the transcriptome of imbibed seeds based on the temperature regime. Computational methods in bioinformatics parsed the data into overrepresented AraCyc pathways and gene regulation subnetworks providing biological context to temperature responses. After 1 d of imbibition, the degradation of starch and sucrose leading to anaerobic respiration were common pathways at both temperature regimes. Several overrepresented pathways unique to 1 d A were associated with generation of energy, reducing power, and carbon substrates; several of these pathways remained overrepresented and up-regulated at 3 d A. At 1 d C, pathways for the phytohormones jasmonic acid and brassinosteroids were uniquely overrepresented. There was little similarity in overrepresented pathways at 1 d C between leafy spurge and arabidopsis seeds, indicating species-specific effects upon imbibition of dry seeds. Overrepresented gene subnetworks at 1 d and 3 d at both temperature regimes related to signaling processes and stress responses. A major overrepresented subnetwork unique to 1 d C related to photomorphogenesis via the E3 ubiquitin ligase COP1. At 1 d A, major overrepresented subnetworks involved circadian rhythm via LHY and TOC1 proteins and expression of stress-related genes such as DREB1A, which is subject to circadian regulation. Collectively, substantial differences were observed in the transcriptome of leafy spurge seeds imbibed under conditions that affect the capacity to germinate. Nomenclature: Mouse-ear cress, Arabidopsis thaliana (L.) Heynh.; leafy spurge, Euphorbia esula L. (EPHES). Leafy spurge seeds are responsive to alternating temperature rather than constant temperature for germination. Transcriptome changes of dry leafy spurge seeds and seeds imbibed for 1 and 3 d at 20 C constant (C) and 20 ∶ 30 C alternating (A) temperature were determined by microarray analysis to examine temperature responsiveness. Principal component analysis revealed differences in the transcriptome of imbibed seeds based on the temperature regime. Computational methods in bioinformatics parsed the data into overrepresented AraCyc pathways and gene regulation subnetworks providing biological context to temperature responses. After 1 d of imbibition, the degradation of starch and sucrose leading to anaerobic respiration were common pathways at both temperature regimes. Several overrepresented pathways unique to 1 d A were associated with generation of energy, reducing power, and carbon substrates; several of these pathways remained overrepresented and up-regulated at 3 d A. At 1 d C, pathways for the phytohormones jasmonic acid and brassinosteroids were uniquely overrepresented. There was little similarity in overrepresented pathways at 1 d C between leafy spurge and arabidopsis seeds, indicating species-specific effects upon imbibition of dry seeds. Overrepresented gene subnetworks at 1 d and 3 d at both temperature regimes related to signaling processes and stress responses. A major overrepresented subnetwork unique to 1 d C related to photomorphogenesis via the E3 ubiquitin ligase COP1. At 1 d A, major overrepresented subnetworks involved circadian rhythm via LHY and TOC1 proteins and expression of stress-related genes such as DREB1A, which is subject to circadian regulation. Collectively, substantial differences were observed in the transcriptome of leafy spurge seeds imbibed under conditions that affect the capacity to germinate.Nomenclature: Mouse-ear cress, Arabidopsis thaliana (L.) Heynh.; leafy spurge, Euphorbia esula L. (EPHES). Leafy spurge seeds are responsive to alternating temperature rather than constant temperature for germination. Transcriptome changes of dry leafy spurge seeds and seeds imbibed for 1 and 3 d at 20 constant (C) and 20 : 30 component analysis revealed differences in the transcriptome of imbibed seeds based on the temperature regime. Computational methods in bioinformatics parsed the data into overrepresented AraCyc pathways and gene regulation subnetworks providing biological context to temperature responses. After 1 d of imbibition, the degradation of starch and sucrose leading to anaerobic respiration were common pathways at both temperature regimes. Several overrepresented pathways unique to 1 d A were associated with generation of energy, reducing power, and carbon substrates; several of these pathways remained overrepresented and up-regulated at 3 d A. At 1 d C, pathways for the phytohormones jasmonic acid and brassinosteroids were uniquely overrepresented. There was little similarity in overrepresented pathways at 1 d C between leafy spurge and arabidopsis seeds, indicating species-specific effects upon imbibition of dry seeds. Overrepresented gene subnetworks at 1 d and 3 d at both temperature regimes related to signaling processes and stress responses. A major overrepresented subnetwork unique to 1 d related to photomorphogenesis via the E3 ubiquitin ligase COP1. At 1 d A, major overrepresented subnetworks involved circadian rhythm via LHY and TOC1 proteins and expression of stressrelated genes such as DREB1A, which is subject to circadian regulation. Collectively, substantial differences were observed in the transcriptome of leafy spurge seeds imbibed under conditions that affect the capacity to germinate. Leafy spurge seeds are responsive to alternating temperature rather than constant temperature for germination. Transcriptome changes of dry leafy spurge seeds and seeds imbibed for 1 and 3 d at 20 C constant (C) and 20 : 30 C alternating (A) temperature were determined by microarray analysis to examine temperature responsiveness. Principal component analysis revealed differences in the transcriptome of imbibed seeds based on the temperature regime. Computational methods in bioinformatics parsed the data into overrepresented AraCyc pathways and gene regulation subnetworks providing biological context to temperature responses. After 1 d of imbibition, the degradation of starch and sucrose leading to anaerobic respiration were common pathways at both temperature regimes. Several overrepresented pathways unique to 1 d A were associated with generation of energy, reducing power, and carbon substrates; several of these pathways remained overrepresented and up-regulated at 3 d A. At 1 d C, pathways for the phytohormones jasmonic acid and brassinosteroids were uniquely overrepresented. There was little similarity in overrepresented pathways at 1 d C between leafy spurge and arabidopsis seeds, indicating species-specific effects upon imbibition of dry seeds. Overrepresented gene subnetworks at 1 d and 3 d at both temperature regimes related to signaling processes and stress responses. A major overrepresented subnetwork unique to 1 d C related to photomorphogenesis via the E3 ubiquitin ligase COP1. At 1 d A, major overrepresented subnetworks involved circadian rhythm via LHY and TOC1 proteins and expression of stressrelated genes such as DREB1A, which is subject to circadian regulation. Collectively, substantial differences were observed in the transcriptome of leafy spurge seeds imbibed under conditions that affect the capacity to germinate. [PUBLICATION ABSTRACT] Leafy spurge seeds are responsive to alternating temperature rather than constant temperature for germination. Transcriptome changes of dry leafy spurge seeds and seeds imbibed for 1 and 3 d at 20 C constant (C) and 20 : 30 C alternating (A) temperature were determined by microarray analysis to examine temperature responsiveness. Principal component analysis revealed differences in the transcriptome of imbibed seeds based on the temperature regime. Computational methods in bioinformatics parsed the data into overrepresented AraCyc pathways and gene regulation subnetworks providing biological context to temperature responses. After 1 d of imbibition, the degradation of starch and sucrose leading to anaerobic respiration were common pathways at both temperature regimes. Several overrepresented pathways unique to 1 d A were associated with generation of energy, reducing power, and carbon substrates; several of these pathways remained overrepresented and up-regulated at 3 d A. At 1 d C, pathways for the phytohormones jasmonic acid and brassinosteroids were uniquely overrepresented. There was little similarity in overrepresented pathways at 1 d C between leafy spurge and arabidopsis seeds, indicating species-specific effects upon imbibition of dry seeds. Overrepresented gene subnetworks at 1 d and 3 d at both temperature regimes related to signaling processes and stress responses. A major overrepresented subnetwork unique to 1 d C related to photomorphogenesis via the E3 ubiquitin ligase COP1. At 1 d A, major overrepresented subnetworks involved circadian rhythm via LHY and TOC1 proteins and expression of stress-related genes such as DREB1A , which is subject to circadian regulation. Collectively, substantial differences were observed in the transcriptome of leafy spurge seeds imbibed under conditions that affect the capacity to germinate. |
| Author | Doğramaci, Münevver Horvath, David P Chao, Wun S Foley, Michael E Anderson, James V |
| Author_xml | – sequence: 1 givenname: Michael E surname: Foley fullname: Foley, Michael E – sequence: 2 givenname: Wun S surname: Chao fullname: Chao, Wun S – sequence: 3 givenname: Münevver surname: Doğramaci fullname: Doğramaci, Münevver – sequence: 4 givenname: David P surname: Horvath fullname: Horvath, David P – sequence: 5 givenname: James V surname: Anderson fullname: Anderson, James V email: michael.foley@ars.usda.gov |
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| CitedBy_id | crossref_primary_10_1016_j_actao_2021_103711 crossref_primary_10_1016_j_jplph_2012_11_008 crossref_primary_10_1017_S0960258514000051 crossref_primary_10_1139_cjps_2015_0269 |
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| Copyright | Weed Science Society of America Copyright © Weed Science Society of America Copyright 2012 Weed Science Society of America 2015 INIST-CNRS Copyright Allen Press Publishing Services Jan-Mar 2012 |
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| Keywords | germination microarray leafy spurge, Euphorbia esula L. (EPHES) Mouse-ear cress, Arabidopsis thaliana (L.) Heynh weed imbibition Gene expression Biotechnology Weed RNA Biochemical compound Germination Transcriptome Imbibition Euphorbia esula Microarray Dicotyledones Weed science Angiospermae Euphorbiaceae Spermatophyta Nucleic acid Thermal variation |
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| Snippet | Leafy spurge seeds are responsive to alternating temperature rather than constant temperature for germination. Transcriptome changes of dry leafy spurge seeds... Leafy spurge seeds are responsive to alternating temperature rather than constant temperature for germination. Transcriptome changes of dry leafy spurge seeds... |
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| SubjectTerms | Abscisic acid Anaerobic respiration anaerobiosis Arabidopsis thaliana Bioinformatics Biological and medical sciences Biosynthesis Biotechnology brassinosteroids carbon circadian rhythm Circadian rhythms Dormancy energy Euphorbia esula Fundamental and applied biological sciences. Psychology Gene expression Gene expression regulation Genes Genomics Germination Imbibition jasmonic acid microarray microarray technology Parasitic plants. Weeds photomorphogenesis Phytopathology. Animal pests. Plant and forest protection plant hormones Plants principal component analysis Principal components analysis proteins Seed germination Seeds starch stress response sucrose Temperature Transcription factors transcriptome ubiquitin-protein ligase weed WEED BIOLOGY AND ECOLOGY weed science Weeds |
| Title | Changes in the Transcriptome of Dry Leafy Spurge (Euphorbia esula) Seeds Imbibed at a Constant and Alternating Temperature |
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