BishtRef
Articles Journals Publishers Authors Subjects Most Cited New Papers Year Stats Open Access
journal article Jan 01, 2025

Water retention capacity in association with the accumulation and composition of cuticular wax contributing to drought tolerance in centipedegrass

Jinyue Gao Tian Hao Qiuguo Li Ningli Fan Zhimin Yang ORCID Jingjin Yu
Grass Research Vol. 5 No. 1 pp. 0-0 · Maximum Academic Press
View at Publisher Save 10.48130/grares-0025-0012
Topics

No keywords indexed for this article. Browse by subject →

References
71
[1]
<p>Askari E, Ehsanzadeh P. 2015. Osmoregulation-mediated differential responses of field-grown fennel genotypes to drought. <i>Industrial Crops and Products</i> 76:494−508</p> 10.1016/j.indcrop.2015.07.010
[2]
<p>Fang Y, Xiong L. 2015. General mechanisms of drought response and their application in drought resistance improvement in plants. <i>Cellular and Molecular Life Sciences</i> 72:673−89</p> 10.1007/s00018-014-1767-0
[3]
<p>Kim KS, Park SH, Kim DK, Jenks MA. 2007. Influence of water deficit on leaf cuticular waxes of soybean (<i>Glycine max</i> [L.] Merr.). <i>International Journal of Plant Sciences</i> 168:307−16</p> 10.1086/510496
[4]
<p>Martin StPaul N, Delzon S, Cochard H. 2017. Plant resistance to drought depends on timely stomatal closure. <i>Ecology Letters</i> 20:1437−47</p> 10.1111/ele.12851
[5]
<p>Martin LBB, Rose JKC. 2013. There's more than one way to skin a fruit: formation and functions of fruit cuticles. <i>Journal of Experimental Botany</i> 65:4639−51</p> 10.1093/jxb/eru301
[6]
<p>Chen Z, Chen G, Dai F, Wang Y, Hills A, et al. 2017. Molecular evolution of grass stomata. <i>Trends in Plant Science</i> 22:124−39</p> 10.1016/j.tplants.2016.09.005
[7]
<p>Yeats TH, Rose JKC. 2013. The formation and function of plant cuticles. <i>Plant Physiology</i> 163:5−20</p> 10.1104/pp.113.222737
[8]
<p>Samdur MY, Manivel P, Jain VK, Chikani BM, Gor HK, et al. 2003. Genotypic differences and water-deficit induced enhancement in epicuticular wax load in peanut. <i>Crop Science</i> 43:1294−99</p> 10.2135/cropsci2003.1294
[9]
<p>Javelle M, Vernoud V, Rogowsky PM, Ingram GC. 2011. Epidermis: the formation and functions of a fundamental plant tissue. <i>New Phytologist</i> 189:17−39</p> 10.1111/j.1469-8137.2010.03514.x
[10]
<p>Wang Y, Wang M, Sun Y, Hegebarth D, Li T, et al. 2015. Molecular characterization of <i>TaFAR1</i> involved in primary alcohol biosynthesis of cuticular wax in hexaploid wheat. <i>Plant and Cell Physiology</i> 56:1944−61</p> 10.1093/pcp/pcv112
[11]
<p>Kunst L, Samuels AL. 2003. Biosynthesis and secretion of plant cuticular wax. <i>Progress in Lipid Research</i> 42:51−80</p> 10.1016/s0163-7827(02)00045-0
[12]
<p>Baker EA. 1974. The influence of environment on leaf wax development in <i>Brassica oleracea</i> var. <i>gemmifera</i>. <i>New Phytologist</i> 73:955−66</p> 10.1111/j.1469-8137.1974.tb01324.x
[13]
<p>Li H, Guo Y, Cui Q, Zhang Z, Yan X, et al. 2020. Alkanes (C29 and C31)-mediated intracuticular wax accumulation contributes to melatonin-and ABA-induced drought tolerance in watermelon. <i>Journal of Plant Growth Regulation</i> 39:1441−50</p> 10.1007/s00344-020-10099-z
[14]
<p>Huang H, Wang L, Qiu D, Zhang N, Bi F. 2021. Changes of morphology, chemical compositions, and the biosynthesis regulations of cuticle in response to chilling injury of banana fruit during storage. <i>Frontiers in Plant Science</i> 12:792384</p> 10.3389/fpls.2021.792384
[15]
<p>Bi H, Kovalchuk N, Langridge P, Tricker PJ, Lopato S, et al. 2017. The impact of drought on wheat leaf cuticle properties. <i>BMC Plant Biology</i> 17:85</p> 10.1186/s12870-017-1033-3
[16]
Molecular, chemical, and physiological analyses of sorghum leaf wax under post-flowering drought stress

Sepideh Sanjari, Zahra-Sadat Shobbar, Faezeh Ghanati et al.

Plant Physiology and Biochemistry 10.1016/j.plaphy.2021.01.001
[17]
<p>Jian L, Kang K, Choi Y, Suh MC, Paek NC. 2022. Mutation of <i>OsMYB60</i> reduces rice resilience to drought stress by attenuating cuticular wax biosynthesis. <i>The Plant Journal</i> 112:339−51</p> 10.1111/tpj.15947
[18]
<p>Lewandowska M, Keyl A, Feussner I. 2020. Wax biosynthesis in response to danger: its regulation upon abiotic and biotic stress. <i>New Phytologist</i> 227:698−713</p> 10.1111/nph.16571
[19]
<p>Kunst L, Samuels L. 2009. Plant cuticles shine: advances in wax biosynthesis and export. <i>Current Opinion in Plant Biology</i> 12:721−27</p> 10.1016/j.pbi.2009.09.009
[20]
<p>Hegebarth D, Buschhaus C, Wu M, Bird D, Jetter R. 2016. The composition of surface wax on trichomes of <i>Arabidopsis thaliana</i> differs from wax on other epidermal cells. <i>The Plant Journal</i> 88:762−74</p> 10.1111/tpj.13294
[21]
Increased Cuticle Waxes by Overexpression of WSD1 Improves Osmotic Stress Tolerance in Arabidopsis thaliana and Camelina sativa

Hesham M. Abdullah, Jessica Rodriguez, Jeffrey M. Salacup et al.

International Journal of Molecular Sciences 10.3390/ijms22105173
[22]
<p>Huang H, Ayaz A, Zheng M, Yang X, Zaman W, et al. 2022. <i>Arabidopsis KCS5</i> and <i>KCS6</i> play redundant roles in wax synthesis. <i>International Journal of Molecular Sciences</i> 23:4450</p> 10.3390/ijms23084450
[23]
<p>Lee SB, Suh MC. 2013. Recent advances in cuticular wax biosynthesis and its regulation in <i>Arabidopsis</i>. <i>Molecular Plant</i> 6:246−49</p> 10.1093/mp/sss159
[25]
<p>Pighin JA, Zheng H, Balakshin LJ, Goodman IP, Western TL, et al. 2004. Plant cuticular lipid export requires an ABC transporter. <i>Science</i> 306:702−04</p> 10.1126/science.1102331
[26]
The MYB96 Transcription Factor Regulates Cuticular Wax Biosynthesis under Drought Conditions inArabidopsis 

Pil Joon Seo, Saet Buyl Lee, Mi Chung Suh et al.

The Plant Cell 10.1105/tpc.111.083485
[27]
<p>Hrmova M, Hussain SS. 2021. Plant transcription factors involved in drought and associated stresses. <i>International Journal of Molecular Sciences</i> 22:5662</p> 10.3390/ijms22115662
[28]
<p>Kosma DK, Bourdenx B, Bernard A, Parsons EP, Lü S, et al. 2009. The impact of water deficiency on leaf cuticle lipids of <i>Arabidopsis</i>. <i>Plant Physiology</i> 151:1918−29</p> 10.1104/pp.109.141911
[29]
<p>Bi H, Luang S, Li Y, Bazanova N, Borisjuk N, et al. 2017. Wheat drought-responsive <i>WXPL</i> transcription factors regulate cuticle biosynthesis genes. <i>Plant Molecular Biology</i> 94:15−32</p> 10.1007/s11103-017-0585-9
[30]
Comparative analysis of alfalfa (Medicago sativa L.) seedling transcriptomes reveals genotype-specific drought tolerance mechanisms

Qiaoli Ma, Xing Xu, Wenjing Wang et al.

Plant Physiology and Biochemistry 10.1016/j.plaphy.2021.05.008
[31]
<p>Hanna WW, Burton GW. 1978. Cytology, reproductive behavior, and fertility characteristics of centipedegrass. <i>Crop Science</i> 18:835−37</p> 10.2135/cropsci1978.0011183x001800050038x
[32]
<p>Islam MA, Hirata M. 2005. Centipedegrass (<i>Eremochloa ophiuroides</i> (Munro) Hack.): growth behavior and multipurpose usages. <i>Grassland Science</i> 51:183−90</p> 10.1111/j.1744-697x.2005.00014.x
[33]
<p>Hook JE, Hanna WW, Maw BW. 1992. Quality and growth response of centipedegrass to extended drought. <i>Agronomy Journal</i> 84:606−12</p> 10.2134/agronj1992.00021962008400040013x
[34]
<p>Li J, Guo H, Zong J, Chen J, Li D, et al. 2020. Genetic diversity in centipedegrass [<i>Eremochloa ophiuroides</i> (Munro) Hack.]. <i>Horticulture Research</i> 7:4</p> 10.1038/s41438-019-0228-1
[35]
<p>Wang J, Zi H, Wang R, Liu J, Wang H, et al. 2021. A high-quality chromosome-scale assembly of the centipedegrass [<i>Eremochloa ophiuroides</i> (Munro) Hack.] genome provides insights into chromosomal structural evolution and prostrate growth habit. <i>Horticulture Research</i> 8:201</p> 10.1038/s41438-021-00636-6
[36]
<p>Li J, Ma J, Guo H, Zong J, Chen J, et al. 2018. Growth and physiological responses of two phenotypically distinct accessions of centipedegrass (<i>Eremochloa ophiuroides</i> (Munro) Hack.) to salt stress. <i>Plant Physiology and Biochemistry</i> 126:1−10</p> 10.1016/j.plaphy.2018.02.018
[37]
<p>Huang B, Duncan RR, Carrow RN. 1997. Drought-resistance mechanisms of seven warm-season turfgrasses under surface soil drying: II. Root aspects. <i>Crop Science</i> 37:1863−69</p> 10.2135/cropsci1997.0011183x003700060033x
[38]
<p>Kim KS, Beard JB. 2018. Comparative drought resistances among eleven warm-season turfgrasses and associated plant parameters. <i>Weed &amp; Turfgrass Science</i> 7:239−45</p> 10.5660/wts.2018.7.3.239
[39]
<p>Hu S, Liu L, Cao J, Chen N, Wang Z. 2019. Water resilience by centipedegrass green roof: a case study. <i>Buildings</i> 9:141</p> 10.3390/buildings9060141
[40]
<p>Katuwal KB, Xiao B, Jespersen D. 2020. Root physiological and biochemical responses of seashore paspalum and centipedegrass exposed to iso-osmotic salt and drought stresses. <i>Crop Science</i> 60:1077−89</p> 10.1002/csc2.20029
[41]
<p>Katuwal KB, Yang H, Huang B. 2023. Evaluation of phenotypic and photosynthetic indices to detect water stress in perennial grass species using hyperspectral, multispectral and chlorophyll fluorescence imaging. <i>Grass Research</i> 3:16</p> 10.48130/gr-2023-0016
[42]
<p>Song Y, Yu J, Xu M, Wang S, He J, et al. 2024. Physiological factors associated with interspecific variations in drought tolerance in centipedegrass. <i>Agronomy</i> 14:1624</p> 10.3390/agronomy14081624
[43]
A Re-Examination of the Relative Turgidity Technique for Estimating Water Deficits in Leaves

HD Barrs, PE Weatherley

Australian Journal of Biological Sciences 10.1071/bi9620413
[44]
<p>Ristic Z, Jenks MA. 2002. Leaf cuticle and water loss in maize lines differing in dehydration avoidance. <i>Journal of Plant Physiology</i> 159:645−51</p> 10.1078/0176-1617-0743
[45]
<p>Hu L, Wang Z, Du H, Huang B. 2010. Differential accumulation of dehydrins in response to water stress for hybrid and common bermudagrass genotypes differing in drought tolerance. <i>Journal of Plant Physiology</i> 167:103−09</p> 10.1016/j.jplph.2009.07.008
[46]
<p>Yu J, Liu M, Yang Z, Huang B. 2015. Growth and physiological factors involved in interspecific variations in drought tolerance and postdrought recovery in warm-and cool-season turfgrass species. <i>Journal of the American Society for Horticultural Science</i> 140:459−65</p> 10.21273/jashs.140.5.459
[47]
<p>Li Y, Liu J, Li J, Xiao H, Xu Y, et al. 2023. Chemical characterization and discovery of novel quality markers in <i>Citrus aurantium</i> L. fruit from traditional cultivation areas in China using GC–MS-based cuticular waxes analysis. <i>Food Chemistry: X</i> 20:100890</p> 10.1016/j.fochx.2023.100890
[48]
<p>Kang Y, Han Y, Torres-Jerez I, Wang M, Tang Y, et al. 2011. System responses to long-term drought and re-watering of two contrasting alfalfa varieties. <i>The Plant Journal</i> 68:871−89</p> 10.1111/j.1365-313x.2011.04738.x
[49]
<p>Tate TM, Cross JW, Wang R, Bonos SA, Meyer WA. 2023. Inheritance of summer stress tolerance in tall fescue. <i>Grass Research</i> 3:14</p> 10.48130/gr-2023-0014
[50]
<p>Sun J, Gu J, Zeng J, Han S, Song A, et al. 2013. Changes in leaf morphology, antioxidant activity and photosynthesis capacity in two different drought-tolerant cultivars of chrysanthemum during and after water stress. <i>Scientia Horticulturae</i> 161:249−58</p> 10.1016/j.scienta.2013.07.015

Showing 50 of 71 references

Metrics
1
Citations
71
References
Details
Published
Jan 01, 2025
Vol/Issue
5(1)
Pages
0-0
Authors
J
Jinyue Gao
T
Tian Hao
Q
Qiuguo Li
N
Ningli Fan
Z
Zhimin Yang
J
Jingjin Yu
Cite This Article
Jinyue Gao, Tian Hao, Qiuguo Li, et al. (2025). Water retention capacity in association with the accumulation and composition of cuticular wax contributing to drought tolerance in centipedegrass. Grass Research, 5(1), 0-0. https://doi.org/10.48130/grares-0025-0012