Expression of AtPRP3, a Proline-Rich Structural Cell Wall Protein from Arabidopsis, Is Regulated by Cell-Type-Specific Developmental Pathways Involved in Root Hair Formation

Bernhardt, Christine; Tierney, Mary L.

doi:10.1104/pp.122.3.705

Cited by 110 publications

(85 citation statements)

References 64 publications

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“…Consistent with our results from Figure 10, the hormone ethylene would then act downstream of such regulators to promote LeExt1 expression and root hair outgrowth in tomato. A similar regulatory pathway recently has been suggested for the expression of the Arabidopsis Pro-rich protein AtPRP3 (Bernhardt and Tierney, 2000).…”

Section: Discussionmentioning

confidence: 56%

The Expression of an Extensin-Like Protein Correlates with Cellular Tip Growth in Tomato

et al. 2002

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Section: Discussionmentioning

confidence: 56%

The Expression of an Extensin-Like Protein Correlates with Cellular Tip Growth in Tomato

et al. 2002

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“…We functionally classified these gene sets to gain insight into the crosstalk using a Gene Ontology enrichment analysis. A series of root-hair-specific genes, RHS15, RHS17, RHS19 (Won et al 2009), and AtPRP3 (a gene encoding a proline-rich structural cell wall protein that regulates trichoblast differentiation, root hair formation, and elongation) (Bernhardt and Tierney 2000) were significantly enriched in the gene set specifically downregulated in the hxk1 mutant treated with glucose. These genes showed the different pattern of regulation in the max2 mutant ( Figure 3B; Supplemental Table 4).…”

Section: Comparative Transcriptomic Analysis Reveals That Max2 and Hxmentioning

confidence: 99%

Strigolactones are involved in sugar signaling to modulate early seedling development in <i>Arabidopsis</i>

Jiang

et al. 2016

Plant Biotechnology

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Strigolactones are a novel class of plant hormones that interact with multiple signaling molecules, including auxin, abscisic acid, ethylene, and brassinosteroid, to regulate plant growth and development. Recently, researchers have shown that sugars are involved in bud outgrowth control, suggesting a potential interaction between sugars and strigolactone signaling. To better understand the relationship between strigolactones and sugar in plant development, the sugar sensitivity of strigolactone biosynthesis and signaling mutants (max1 and max2) was evaluated in early seedling development with a low-glucose assay. Both max1 and max2 displayed obvious hyposensitivity to glucose repression, as do gin mutants, but they were hypersensitive like the wild type to the high-glucose conditions used for gin mutant screening. The strigolactones acted synergistically with glucose in repressing seedling establishment. A further comparative transcriptomic analysis indicated that the expression of stress-related genes in the max2 mutant is impaired by glucose, and a carbohydrate analysis revealed a reduced hexose content in the max mutants. Our results suggest that the roles of strigolactones in the regulation of early seedling development are probably independent of the HXK1 signaling pathway. Taken together, these findings provide evidence that strigolactones are involved in sugar signaling, thus modulating early seedling development.

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“…In root hairs, the walls are composed mostly of (xylo)glucans, pectins, and O-glycoproteins (Galway et al, 2011;Velasquez et al, 2011;Peña et al, 2012), while in pollen tubes, the walls are enriched in pectins and also contain glycoproteins and xyloglucans/cellulose (Dardelle et al, 2010). Cell wall deficiencies in any of these polymers inhibit polar cell elongation in root hairs and pollen tubes, indicating that these polymers operate together to modulate controlled expansion (Bernhardt and Tierney, 2000;Favery et al, 2001;Pang et al, 2010;Ringli, 2010;Park et al, 2011;Velasquez et al, 2011;Zabotina et al, 2012;Wang et al, 2014). Specifically, Hyp-rich glycoproteins of the EXT type (Velasquez et al, 2011) and PRP (Bernhardt and Tierney, 2000) are Tyr cross-linked by an unidentified apo PER III to facilitate the formation of a cell wall glycoprotein network (Cannon et al, 2008).…”

Section: Apo Ros Homeostasis Is Regulated By Plasma Membrane Noxs Andmentioning

confidence: 99%

ROS Regulation of Polar Growth in Plant Cells

2016

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ORCID ID: 0000-0001-6332-7738 (J.M.E.).Root hair cells and pollen tubes, like fungal hyphae, possess a typical tip or polar cell expansion with growth limited to the apical dome. Cell expansion needs to be carefully regulated to produce a correct shape and size. Polar cell growth is sustained by oscillatory feedback loops comprising three main components that together play an important role regulating this process. One of the main components are reactive oxygen species (ROS) that, together with calcium ions (Ca 2+ ) and pH, sustain polar growth over time. Apoplastic ROS homeostasis controlled by NADPH oxidases as well as by secreted type III peroxidases has a great impact on cell wall properties during cell expansion. Polar growth needs to balance a focused secretion of new materials in an extending but still rigid cell wall in order to contain turgor pressure. In this review, we discuss the gaps in our understanding of how ROS impact on the oscillatory Ca 2+ and pH signatures that, coordinately, allow root hair cells and pollen tubes to expand in a controlled manner to several hundred times their original size toward specific signals.

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Expression of AtPRP3, a Proline-Rich Structural Cell Wall Protein from Arabidopsis, Is Regulated by Cell-Type-Specific Developmental Pathways Involved in Root Hair Formation

Cited by 110 publications

References 64 publications

The Expression of an Extensin-Like Protein Correlates with Cellular Tip Growth in Tomato

The Expression of an Extensin-Like Protein Correlates with Cellular Tip Growth in Tomato

Strigolactones are involved in sugar signaling to modulate early seedling development in <i>Arabidopsis</i>

ROS Regulation of Polar Growth in Plant Cells

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