Regulation of Seed Germination in the Close Arabidopsis Relative<i>Lepidium sativum</i>: A Global Tissue-Specific Transcript Analysis

Morris, Karl; Linkies, Ada; Müller, Kerstin; Oracz, Krystyna; Lynn, James R.; Leubner‐Metzger, Gerhard; Finch‐Savage, William E.

doi:10.1104/pp.110.169706

Cited by 76 publications

(67 citation statements)

References 118 publications

(169 reference statements)

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“…Transcripts involved in cell wall modifications were found to be more abundant in the translatome of nondormant seeds than dormant seeds. Overrepresentation of cell wall-related transcripts in the transcriptome was shown in Lepidium sativum (Morris et al, 2011) and Arabidopsis (Endo et al, 2012) germinating seeds and in the translatome of sunflower seeds (Layat et al, 2014). Transcripts for expansins such as EXPA1, EXPA10, EXPA4, and EXPA2 (At1g69530, At1g26770, At2g39700, and At5g05290; Fig.…”

Section: Discussionmentioning

confidence: 99%

Germination Potential of Dormant and Nondormant Arabidopsis Seeds Is Driven by Distinct Recruitment of Messenger RNAs to Polysomes

et al. 2015

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Dormancy is a complex evolutionary trait that temporally prevents seed germination, thus allowing seedling growth at a favorable season. High-throughput analyses of transcriptomes have led to significant progress in understanding the molecular regulation of this process, but the role of posttranscriptional mechanisms has received little attention. In this work, we have studied the dynamics of messenger RNA association with polysomes and compared the transcriptome with the translatome in dormant and nondormant seeds of Arabidopsis (Arabidopsis thaliana) during their imbibition at 25°C in darkness, a temperature preventing germination of dormant seeds only. DNA microarray analysis revealed that 4,670 and 7,028 transcripts were differentially abundant in dormant and nondormant seeds in the transcriptome and the translatome, respectively. We show that there is no correlation between transcriptome and translatome and that germination regulation is also largely translational, implying a selective and dynamic recruitment of messenger RNAs to polysomes in both dormant and nondormant seeds. The study of 59 untranslated region features revealed that GC content and the number of upstream open reading frames could play a role in selective translation occurring during germination. Gene Ontology clustering showed that the functions of polysome-associated transcripts differed between dormant and nondormant seeds and revealed actors in seed dormancy and germination. In conclusion, our results demonstrate the essential role of selective polysome loading in this biological process.

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Section: Discussionmentioning

confidence: 99%

Germination Potential of Dormant and Nondormant Arabidopsis Seeds Is Driven by Distinct Recruitment of Messenger RNAs to Polysomes

et al. 2015

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“…The testa is dead tissue, but cell wall-modifying enzymes could be secreted from the underlying endosperm to cause modifications in the inner testa cell walls, which could lead to sitespecific weakening. A number of cell wall-modifying genes, and the enzyme activities of their products, have been shown to be differentially regulated before ER in the seeds of various endospermic species, such as b-1,3-glucanase in tobacco (Nicotiana tabacum; Leubner-Metzger et al, 1995;Manz et al, 2005), b-1,4-mannanase in tomato (Solanum lycopersicum; Nonogaki et al, 2000), garden cress (Morris et al, 2011), and Arabidopsis (Iglesias-Fernández et al, 2011), and xyloglucan endotransglycosylases/hydrolases in garden cress (Voegele et al, 2011;Graeber et al, 2014) and Arabidopsis (Endo et al, 2012), and species-specific changes in cell wall composition have been observed during the later germination process (Lee et al, 2012), supporting the importance of the cell wall remodeling during seed germination.…”

Section: Discussion Tr Constitutes a Transition Between Phases Of Genmentioning

confidence: 99%

“…After TR, endosperm resistance decreases through tissue softening, a process called endosperm weakening (Müller et al, 2006;Linkies et al, 2009). Both radicle elongation and endosperm weakening require cell wall modifications (Schopfer, 2006;Müller et al, 2009;Morris et al, 2011).…”

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Promotion of Testa Rupture during Garden Cress Germination Involves Seed Compartment-Specific Expression and Activity of Pectin Methylesterases

et al. 2014

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Pectin methylesterase (PME) controls the methylesterification status of pectins and thereby determines the biophysical properties of plant cell walls, which are important for tissue growth and weakening processes. We demonstrate here that tissue-specific and spatiotemporal alterations in cell wall pectin methylesterification occur during the germination of garden cress (Lepidium sativum). These cell wall changes are associated with characteristic expression patterns of PME genes and resultant enzyme activities in the key seed compartments CAP (micropylar endosperm) and RAD (radicle plus lower hypocotyl). Transcriptome and quantitative real-time reverse transcription-polymerase chain reaction analysis as well as PME enzyme activity measurements of separated seed compartments, including CAP and RAD, revealed distinct phases during germination. These were associated with hormonal and compartment-specific regulation of PME group 1, PME group 2, and PME inhibitor transcript expression and total PME activity. The regulatory patterns indicated a role for PME activity in testa rupture (TR). Consistent with a role for cell wall pectin methylesterification in TR, treatment of seeds with PME resulted in enhanced testa permeability and promoted TR. Mathematical modeling of transcript expression changes in germinating garden cress and Arabidopsis (Arabidopsis thaliana) seeds suggested that group 2 PMEs make a major contribution to the overall PME activity rather than acting as PME inhibitors. It is concluded that regulated changes in the degree of pectin methylesterification through CAP-and RAD-specific PME and PME inhibitor expression play a crucial role during Brassicaceae seed germination.

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“…Radicle protrusion through the micropylar endosperm is also stimulated by ethylene, which has an antagonist action with ABA on endosperm cap weakening (Linkies and LeubnerMetzger, 2012). Microarray analyses highlighted the importance of cell wall remodeling processes during germination in various species (Penfield et al, 2006;Morris et al, 2011;Endo et al, 2012;Martínez-Andújar et al, 2012;Dekkers et al, 2013). These studies provided compelling evidence that the tissue-specific expression of genes encoding cell wall biosynthesis or modification enzymes, and their differential response to hormonal signals in the endosperm and embryo, influences the rate of germination.…”

mentioning

confidence: 99%

Xyloglucan Metabolism Differentially Impacts the Cell Wall Characteristics of the Endosperm and Embryo during Arabidopsis Seed Germination

et al. 2016

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Regulation of Seed Germination in the Close Arabidopsis RelativeLepidium sativum: A Global Tissue-Specific Transcript Analysis

Cited by 76 publications

References 118 publications

Germination Potential of Dormant and Nondormant Arabidopsis Seeds Is Driven by Distinct Recruitment of Messenger RNAs to Polysomes

Germination Potential of Dormant and Nondormant Arabidopsis Seeds Is Driven by Distinct Recruitment of Messenger RNAs to Polysomes

Promotion of Testa Rupture during Garden Cress Germination Involves Seed Compartment-Specific Expression and Activity of Pectin Methylesterases

Xyloglucan Metabolism Differentially Impacts the Cell Wall Characteristics of the Endosperm and Embryo during Arabidopsis Seed Germination

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