Changes in the morphology traits, anatomical structure of the leaves and transcriptome in Lycium barbarum L. under salt stress

Salt stress directly affects the growth of plants. The limitation of leaf grow is among the earliest visible effects of salt stress. However, the regulation mechanism of salt treatments on leaf shape has not been fully elucidated. We measured the morphological traits and anatomical structure. In com...

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Published inFrontiers in plant science Vol. 14; p. 1090366
Main Authors Yao, Xiao-Cui, Meng, Li-Fang, Zhao, Wang-Li, Mao, Gui-Lian
Format Journal Article
LanguageEnglish
Published Switzerland Frontiers Media S.A 20.02.2023
Subjects
expansin
leaf thickness
Lycium barbarum L
Plant Science
salt stress
transcriptome
salt stress
leaf thickness
expansin
Lycium barbarum L
transcriptome
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Abstract Salt stress directly affects the growth of plants. The limitation of leaf grow is among the earliest visible effects of salt stress. However, the regulation mechanism of salt treatments on leaf shape has not been fully elucidated. We measured the morphological traits and anatomical structure. In combination with transcriptome analysis, we analyzed differentially expressed genes (DEGs) and verified the RNA-seq data by qRT-PCR. Finally, we analyzed correlation between leaf microstructure parameters and expansin genes. We show that the leaf thickness, the width, and the leaf length significantly increased at elevated salt concentrations after salt stress for 7 days. Low salt mainly promoted the increase in leaves length and width, but high salt concentration accelerated the leaf thickness. The anatomical structure results indicated that palisade mesophyll tissues contribute more to leaf thickness than spongy mesophyll tissues, which possibly contributed to the increase in leaf expansion and thickness. Moreover, a total of 3,572 DEGs were identified by RNA-seq. Notably, six of the DEGs among 92 identified genes concentrated on cell wall synthesis or modification were involved in cell wall loosening proteins. More importantly, we demonstrated that there was a strong positive correlation between the upregulated EXLA2 gene and the thickness of the palisade tissue in L. barbarum leaves. These results suggested that salt stress possibly induced the expression of EXLA2 gene, which in turn increased the thickness of L. barbarum leaves by promoting the longitudinal expansion of cells of the palisade tissue. This study lays a solid knowledge for revealing the underlying molecular mechanisms of leaf thickening in L. barbarum in response to salt stresses.
AbstractList Salt stress directly affects the growth of plants. The limitation of leaf grow is among the earliest visible effects of salt stress. However, the regulation mechanism of salt treatments on leaf shape has not been fully elucidated. We measured the morphological traits and anatomical structure. In combination with transcriptome analysis, we analyzed differentially expressed genes (DEGs) and verified the RNA-seq data by qRT-PCR. Finally, we analyzed correlation between leaf microstructure parameters and expansin genes. We show that the leaf thickness, the width, and the leaf length significantly increased at elevated salt concentrations after salt stress for 7 days. Low salt mainly promoted the increase in leaves length and width, but high salt concentration accelerated the leaf thickness. The anatomical structure results indicated that palisade mesophyll tissues contribute more to leaf thickness than spongy mesophyll tissues, which possibly contributed to the increase in leaf expansion and thickness. Moreover, a total of 3,572 DEGs were identified by RNA-seq. Notably, six of the DEGs among 92 identified genes concentrated on cell wall synthesis or modification were involved in cell wall loosening proteins. More importantly, we demonstrated that there was a strong positive correlation between the upregulated gene and the thickness of the palisade tissue in leaves. These results suggested that salt stress possibly induced the expression of gene, which in turn increased the thickness of leaves by promoting the longitudinal expansion of cells of the palisade tissue. This study lays a solid knowledge for revealing the underlying molecular mechanisms of leaf thickening in in response to salt stresses.
Salt stress directly affects the growth of plants. The limitation of leaf grow is among the earliest visible effects of salt stress. However, the regulation mechanism of salt treatments on leaf shape has not been fully elucidated. We measured the morphological traits and anatomical structure. In combination with transcriptome analysis, we analyzed differentially expressed genes (DEGs) and verified the RNA-seq data by qRT-PCR. Finally, we analyzed correlation between leaf microstructure parameters and expansin genes. We show that the leaf thickness, the width, and the leaf length significantly increased at elevated salt concentrations after salt stress for 7 days. Low salt mainly promoted the increase in leaves length and width, but high salt concentration accelerated the leaf thickness. The anatomical structure results indicated that palisade mesophyll tissues contribute more to leaf thickness than spongy mesophyll tissues, which possibly contributed to the increase in leaf expansion and thickness. Moreover, a total of 3,572 DEGs were identified by RNA-seq. Notably, six of the DEGs among 92 identified genes concentrated on cell wall synthesis or modification were involved in cell wall loosening proteins. More importantly, we demonstrated that there was a strong positive correlation between the upregulated EXLA2 gene and the thickness of the palisade tissue in L. barbarum leaves. These results suggested that salt stress possibly induced the expression of EXLA2 gene, which in turn increased the thickness of L. barbarum leaves by promoting the longitudinal expansion of cells of the palisade tissue. This study lays a solid knowledge for revealing the underlying molecular mechanisms of leaf thickening in L. barbarum in response to salt stresses.
Salt stress directly affects the growth of plants. The limitation of leaf grow is among the earliest visible effects of salt stress. However, the regulation mechanism of salt treatments on leaf shape has not been fully elucidated. We measured the morphological traits and anatomical structure. In combination with transcriptome analysis, we analyzed differentially expressed genes (DEGs) and verified the RNA-seq data by qRT-PCR. Finally, we analyzed correlation between leaf microstructure parameters and expansin genes. We show that the leaf thickness, the width, and the leaf length significantly increased at elevated salt concentrations after salt stress for 7 days. Low salt mainly promoted the increase in leaves length and width, but high salt concentration accelerated the leaf thickness. The anatomical structure results indicated that palisade mesophyll tissues contribute more to leaf thickness than spongy mesophyll tissues, which possibly contributed to the increase in leaf expansion and thickness. Moreover, a total of 3,572 DEGs were identified by RNA-seq. Notably, six of the DEGs among 92 identified genes concentrated on cell wall synthesis or modification were involved in cell wall loosening proteins. More importantly, we demonstrated that there was a strong positive correlation between the upregulated EXLA2 gene and the thickness of the palisade tissue in L. barbarum leaves. These results suggested that salt stress possibly induced the expression of EXLA2 gene, which in turn increased the thickness of L. barbarum leaves by promoting the longitudinal expansion of cells of the palisade tissue. This study lays a solid knowledge for revealing the underlying molecular mechanisms of leaf thickening in L. barbarum in response to salt stresses.Salt stress directly affects the growth of plants. The limitation of leaf grow is among the earliest visible effects of salt stress. However, the regulation mechanism of salt treatments on leaf shape has not been fully elucidated. We measured the morphological traits and anatomical structure. In combination with transcriptome analysis, we analyzed differentially expressed genes (DEGs) and verified the RNA-seq data by qRT-PCR. Finally, we analyzed correlation between leaf microstructure parameters and expansin genes. We show that the leaf thickness, the width, and the leaf length significantly increased at elevated salt concentrations after salt stress for 7 days. Low salt mainly promoted the increase in leaves length and width, but high salt concentration accelerated the leaf thickness. The anatomical structure results indicated that palisade mesophyll tissues contribute more to leaf thickness than spongy mesophyll tissues, which possibly contributed to the increase in leaf expansion and thickness. Moreover, a total of 3,572 DEGs were identified by RNA-seq. Notably, six of the DEGs among 92 identified genes concentrated on cell wall synthesis or modification were involved in cell wall loosening proteins. More importantly, we demonstrated that there was a strong positive correlation between the upregulated EXLA2 gene and the thickness of the palisade tissue in L. barbarum leaves. These results suggested that salt stress possibly induced the expression of EXLA2 gene, which in turn increased the thickness of L. barbarum leaves by promoting the longitudinal expansion of cells of the palisade tissue. This study lays a solid knowledge for revealing the underlying molecular mechanisms of leaf thickening in L. barbarum in response to salt stresses.
Salt stress directly affects the growth of plants. The limitation of leaf grow is among the earliest visible effects of salt stress. However, the regulation mechanism of salt treatments on leaf shape has not been fully elucidated. We measured the morphological traits and anatomical structure. In combination with transcriptome analysis, we analyzed differentially expressed genes (DEGs) and verified the RNA-seq data by qRT-PCR. Finally, we analyzed correlation between leaf microstructure parameters and expansin genes. We show that the leaf thickness, the width, and the leaf length significantly increased at elevated salt concentrations after salt stress for 7 days. Low salt mainly promoted the increase in leaves length and width, but high salt concentration accelerated the leaf thickness. The anatomical structure results indicated that palisade mesophyll tissues contribute more to leaf thickness than spongy mesophyll tissues, which possibly contributed to the increase in leaf expansion and thickness. Moreover, a total of 3,572 DEGs were identified by RNA-seq. Notably, six of the DEGs among 92 identified genes concentrated on cell wall synthesis or modification were involved in cell wall loosening proteins. More importantly, we demonstrated that there was a strong positive correlation between the upregulated EXLA2 gene and the thickness of the palisade tissue in L. barbarum leaves. These results suggested that salt stress possibly induced the expression of EXLA2 gene, which in turn increased the thickness of L. barbarum leaves by promoting the longitudinal expansion of cells of the palisade tissue. This study lays a solid knowledge for revealing the underlying molecular mechanisms of leaf thickening in L. barbarum in response to salt stresses.
Author Zhao, Wang-Li
Meng, Li-Fang
Mao, Gui-Lian
Yao, Xiao-Cui
AuthorAffiliation School of Life Sciences, Ningxia University , Yinchuan , China
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Cites_doi 10.1016/j.plaphy.2020.06.010
10.1016/j.jia.2022.08.030
10.3109/07388551.2014.889080
10.1007/s00299-020-02565-5
10.1016/j.plaphy.2020.03.033
10.1104/pp.004259
10.1104/pp.16.01514
10.1007/s00425-021-03665-6
10.1186/gb-2005-6-12-242
10.1093/pcp/pcy155
10.1104/pp.17.01541
10.3390/ijms22052317
10.1104/pp.010345
10.1007/s00709-022-01793-8
10.1371/journal.pone.0191081
10.1016/j.plaphy.2021.03.054
10.1016/j.scienta.2022.111430
10.1016/j.jplph.2015.05.005
10.4161/psb.6.5.15144
10.1186/s12870-022-03783-7
10.1098/rsta.2017.0048
10.1104/pp.125.3.1419
10.1007/s10709-021-00136-4
10.1111/mpp.12049
10.3389/fpls.2021.643555
10.1104/pp.63.4.700
10.1016/j.jplph.2013.07.008
10.1104/pp.18.00263
10.1134/S1021443721020035
10.1016/j.jplph.2015.09.007
10.1007/s11032-016-0451-5
10.1007/978-1-4939-7672-0-25
10.1007/s00425-015-2315-3
10.11829/j.issn1001-0629.2015-0526
10.1111/nph.12046
10.1007/s00299-016-1948-4
10.3390/genes12020249
10.1016/j.phytochem.2022.113178
10.3390/ijms22094609
10.1016/j.phytochem.2020.112582
10.1111/pce.14405
10.1016/j.cub.2017.05.025
10.1111/pce.13391
10.1134/s1022795417060084
10.3390/plants10102208
10.1093/jxb/eru358
10.1016/j.plaphy.2019.12.004
10.1007/s11104-009-9911-6
10.1007/s00344-015-9480-2
10.1016/j.tplants.2012.02.003
10.1016/j.plantsci.2006.10.006
10.1080/01904167.2021.1936036
10.3389/fgene.2019.00247
10.1104/pp.46.2.250
10.1111/j.1365-3040.2011.02437
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Keywords salt stress
leaf thickness
expansin
Lycium barbarum L
transcriptome
Language English
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Reviewed by: Samar Gamal Thabet, Fayoum University, Egypt; Umashankar Chandrasekaran, Seoul National University, Republic of Korea
Edited by: Muhammad Waseem, Hainan University, China
This article was submitted to Plant Abiotic Stress, a section of the journal Frontiers in Plant Science
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References Palchetti (B38) 2021; 163
Geilfus (B12) 2012; 197
Turner (B47) 2018; 376
Li (B24) 2022; 199
Spartz (B45) 2016; 173
Wang (B49) 2019; 10
Cosgrove (B10) 2017; 176
Qin (B40) 2021; 181
Geilfus (B11) 2011; 35
Polak (B39) 2021; 22
Abuqamar (B1) 2013; 14
Li (B25) 2022; 306
Lee (B23) 2001; 127
İncili (B18) 2022
Rayle (B41) 1970; 46
Valenzuela-Riffo (B48) 2020; 154
Chen (B9) 2018; 59
Chen (B8) 2022; 21
Kalve (B19) 2014; 65
Zeng (B54) 2018; 41
Hameed (B15) 2009; 322
Liu (B26) 2021; 149
Bulle (B5) 2016; 36
Gonzalez (B14) 2012; 17
Acosta-Motos (B2) 2015; 183
Hu (B17) 2022; 45
Santiago (B43) 2018; 13
Chalekaei (B6) 2021; 68
Marowa (B31) 2016; 35
Kumar (B22) 2018; 177
Yuan (B52) 2016; 10
Lv (B29) 2019; 147
Ma (B30) 2021; 12
Shen (B44) 2022; 22
Longstreth (B28) 1979; 63
Kong (B20) 2018; 1744
Mu (B35) 2021; 254
Acosta-Motos (B3) 2015; 242
Neves-Piestun (B37) 2001; 32
Sampedro (B42) 2005; 6
Wei (B50) 2011; 6
Marowa (B32) 2020; 151
Navarro (B36) 2007; 172
Liu (B27) 2021; 12
Zhao (B55) 2021; 22
Avestan (B4) 2021; 44
Yuan (B53) 2015; 34
Höfte (B16) 2017; 27
Moll (B34) 2002; 130
Tang (B46) 2015; 35
Kuluev (B21) 2017; 53
Mohammed (B33) 2021; 10
Chen (B7) 2014; 171
Yan (B51) 2020; 39
Gómez-Bellot (B13) 2015; 188
References_xml – volume: 154
  start-page: 581
  year: 2020
  ident: B48
  article-title: Molecular and structural insights into FaEXPA5, an alpha-expansin protein related with cell wall disassembly during ripening of strawberry fruit
  publication-title: Plant Physiol. Biochem.
  doi: 10.1016/j.plaphy.2020.06.010
– volume: 21
  start-page: 3578
  year: 2022
  ident: B8
  article-title: Overexpression of the apple expansin-like gene MdEXLB1 accelerates the softening of fruit texture in tomato
  publication-title: J. Integr. Agric
  doi: 10.1016/j.jia.2022.08.030
– volume: 35
  start-page: 425
  year: 2015
  ident: B46
  article-title: Global plant-responding mechanisms to salt stress: Physiological and molecular levels and implications in biotechnology
  publication-title: Crit. Rev. Biotechnol.
  doi: 10.3109/07388551.2014.889080
– volume: 39
  start-page: 1301
  year: 2020
  ident: B51
  article-title: The CsGPA1-CsAQPs module is essential for salt tolerance of cucumb er seedlings
  publication-title: Plant Cell Rep.
  doi: 10.1007/s00299-020-02565-5
– volume: 151
  start-page: 477
  year: 2020
  ident: B32
  article-title: Overexpression of NtEXPA11 modulates plant growth and development and enhances stress tolerance in tobacco
  publication-title: Plant Physiol. Biochem.
  doi: 10.1016/j.plaphy.2020.03.033
– volume: 130
  start-page: 47
  year: 2002
  ident: B34
  article-title: Cell-specific expression of homospermidine synthase, the entry enzyme of the pyrrolizidine alkaloid pathway in Senecio vernalis, in comparison with its ancestor, deoxyhypusine synthase
  publication-title: Plant Physiol
  doi: 10.1104/pp.004259
– volume: 173
  start-page: 1453
  year: 2016
  ident: B45
  article-title: Constitutive expression of arabidopsis SMALL AUXIN UP RNA19 (SAUR19) in tomato confers auxin-independent hypocotyl elongation
  publication-title: Plant Physiol.
  doi: 10.1104/pp.16.01514
– volume: 254
  year: 2021
  ident: B35
  article-title: Characterization of expansin genes and their transcriptional regulation by histone modifications in strawberry
  publication-title: Planta
  doi: 10.1007/s00425-021-03665-6
– volume: 6
  year: 2005
  ident: B42
  article-title: The expansin superfamily
  publication-title: Genome Biol.
  doi: 10.1186/gb-2005-6-12-242
– volume: 59
  start-page: 2317
  year: 2018
  ident: B9
  article-title: α-expansin EXPA4 positively regulates abiotic stress tolerance but negatively regulates pathogen resistance in nicotiana tabacum
  publication-title: Plant Cell Physiol.
  doi: 10.1093/pcp/pcy155
– volume: 176
  start-page: 16
  year: 2017
  ident: B10
  article-title: Diffuse growth of plant cell walls
  publication-title: Plant Physiol.
  doi: 10.1104/pp.17.01541
– volume: 22
  year: 2021
  ident: B39
  article-title: Some new methodological and conceptual aspects of the “Acid growth theory” for the auxin action in maize (Zea mays l.) coleoptile segments: Do acid- and auxin-induced rapid growth differ in their mechanisms
  publication-title: Int. J. Mol. Sci.
  doi: 10.3390/ijms22052317
– volume: 127
  start-page: 645
  year: 2001
  ident: B23
  article-title: Expression of beta-expansins is correlated with internodal elongation in deepwater rice
  publication-title: Plant Physiol
  doi: 10.1104/pp.010345
– start-page: 1
  year: 2022
  ident: B18
  article-title: Comparative bioinformatics analysis and abiotic stress responses of expansin proteins in cucurbitaceae members: watermelon and melon
  publication-title: Protoplasma
  doi: 10.1007/s00709-022-01793-8
– volume: 13
  year: 2018
  ident: B43
  article-title: Genome-wide identification, characterization and expression profile analysis of expansins gene family in sugarcane (Saccharum spp.)
  publication-title: PLoS One
  doi: 10.1371/journal.pone.0191081
– volume: 163
  start-page: 166
  year: 2021
  ident: B38
  article-title: New insights into the salt tolerance of the extreme halophytic species Lycium humile (Lycieae, solanaceae)
  publication-title: Plant Physiol. Biochem.
  doi: 10.1016/j.plaphy.2021.03.054
– volume: 306
  start-page: 111430
  year: 2022
  ident: B25
  article-title: Strategies used by two goji species, lycium ruthenicum and lycium barbarum, to defend against salt stress
  publication-title: Scientia Hortic.
  doi: 10.1016/j.scienta.2022.111430
– volume: 183
  start-page: 41
  year: 2015
  ident: B2
  article-title: NaCl-Induced physiological and biochemical adaptative mechanisms in the ornamental Myrtus communis l. plants
  publication-title: J. Plant Physiol.
  doi: 10.1016/j.jplph.2015.05.005
– volume: 6
  start-page: 740
  year: 2011
  ident: B50
  article-title: Regulation of stomatal opening by the guard cell expansin AtEXPA1
  publication-title: Plant Signaling Behavior.
  doi: 10.4161/psb.6.5.15144
– volume: 22
  start-page: 390
  year: 2022
  ident: B44
  article-title: Effects of silicon application on leaf structure and physiological characteristics of glycyrrhiza uralensis fisch. and glycyrrhiza inflata bat. under salt treatment
  publication-title: BMC Plant Biol.
  doi: 10.1186/s12870-022-03783-7
– volume: 376
  year: 2018
  ident: B47
  article-title: Cellulose synthase complex organization and cellulose microfibril structure
  publication-title: Philos. Trans. A Math Phys. Eng. Sci.
  doi: 10.1098/rsta.2017.0048
– volume: 32
  start-page: 141
  year: 2001
  ident: B37
  article-title: Salinity-induced inhibition of leaf elongation in maize is not mediated by changes in cell wall acidification capacity
  publication-title: Plant Physiol.
  doi: 10.1104/pp.125.3.1419
– volume: 149
  start-page: 283
  year: 2021
  ident: B26
  article-title: Genome-wide identification of expansin gene family in barley and drought-related expansins identification based on RNA-seq
  publication-title: Genetica
  doi: 10.1007/s10709-021-00136-4
– volume: 14
  start-page: 813
  year: 2013
  ident: B1
  article-title: A mutation in the expansin-like A2 gene enhances resistance to necrotrophic fungi and hypersensitivity to abiotic stress in arabidopsis thaliana
  publication-title: Mol. Plant Pathol.
  doi: 10.1111/mpp.12049
– volume: 12
  year: 2021
  ident: B30
  article-title: Effects of elevated CO2 on photosynthetic accumulation, sucrose metabolism-related enzymes, and genes identification in goji berry (Lycium barbarum l.)
  publication-title: Front. Plant Sci.
  doi: 10.3389/fpls.2021.643555
– volume: 63
  start-page: 700
  year: 1979
  ident: B28
  article-title: Salinity effects on leaf anatomy: Consequences for photosynthesis
  publication-title: Plant Physiol
  doi: 10.1104/pp.63.4.700
– volume: 171
  start-page: 235
  year: 2014
  ident: B7
  article-title: Proteomic analysis of arabidopsis thaliana leaves in response to acute boron deficiency and toxicity reveals effects on photosynthesis, carbohydrate metabolism, and protein synthesis
  publication-title: J. Plant Physiol.
  doi: 10.1016/j.jplph.2013.07.008
– volume: 177
  start-page: 151
  year: 2018
  ident: B22
  article-title: Exploiting CELLULOSE SYNTHASE (CESA) class specificity to probe cellulose microfibril biosynthesis
  publication-title: Plant Physiol.
  doi: 10.1104/pp.18.00263
– volume: 68
  start-page: 274
  year: 2021
  ident: B6
  article-title: Over-expression of AtEXPB2 alleviates salt stress damage in transgenic tobacco plants
  publication-title: Russ J. Plant Physiol.
  doi: 10.1134/S1021443721020035
– volume: 188
  start-page: 96
  year: 2015
  ident: B13
  article-title: Influence of arbuscular mycorrhizal fungi and treated wastewater on water relations and leaf structure alterations of Viburnum tinus l. plants during both saline and recovery periods
  publication-title: J. Plant Physiol.
  doi: 10.1016/j.jplph.2015.09.007
– volume: 36
  year: 2016
  ident: B5
  article-title: Enhanced salinity stress tolerance in transgenic chilli pepper (Capsicum annuum l.) plants overexpressing the wheat antiporter (TaNHX2) gene
  publication-title: Mol. Breeding.
  doi: 10.1007/s11032-016-0451-5
– volume: 1744
  start-page: 313
  year: 2018
  ident: B20
  article-title: Plant cell walls: Isolation and monosaccharide composition analysis
  publication-title: Methods Mol. Biol.
  doi: 10.1007/978-1-4939-7672-0-25
– volume: 242
  start-page: 829
  year: 2015
  ident: B3
  article-title: Physiological and biochemical mechanisms of the ornamental Eugenia myrtifolia l. plants for coping with NaCl stress and recovery
  publication-title: Planta.
  doi: 10.1007/s00425-015-2315-3
– volume: 10
  start-page: 681
  year: 2016
  ident: B52
  article-title: The differences between two cultivars of lycium barbarum in osmotic stress tolerance and salt tolerance
  publication-title: Pratacultural Sci.
  doi: 10.11829/j.issn1001-0629.2015-0526
– volume: 197
  start-page: 1117
  year: 2012
  ident: B12
  article-title: Ratiometric monitoring of transient apoplastic alkalinizations in the leaf apoplast of living vicia faba plants: Chloride primes and PM-H+-ATPase shapes NaCl-induced systemic alkalinizations
  publication-title: New Phytologist.
  doi: 10.1111/nph.12046
– volume: 35
  start-page: 949
  year: 2016
  ident: B31
  article-title: Expansins: roles in plant growth and potential applications in crop improvement
  publication-title: Plant Cell Rep.
  doi: 10.1007/s00299-016-1948-4
– volume: 12
  year: 2021
  ident: B27
  article-title: Two expansin genes, AtEXPA4 and AtEXPB5, are redundantly required for pollen tube growth and AtEXPA4 is involved in primary root elongation in arabidopsis thaliana
  publication-title: Genes.
  doi: 10.3390/genes12020249
– volume: 199
  start-page: 113178
  year: 2022
  ident: B24
  article-title: Overexpression of DsEXLA2 gene from dendrocalamus sinicus accelerates the plant growth rate of arabidopsis
  publication-title: Phytochemistry.
  doi: 10.1016/j.phytochem.2022.113178
– volume: 22
  year: 2021
  ident: B55
  article-title: Regulation of plant responses to salt stress
  publication-title: Int. J. Mol. Sci.
  doi: 10.3390/ijms22094609
– volume: 181
  year: 2021
  ident: B40
  article-title: Comparative transcriptome analysis reveals the regulatory effects of acetylcholine on salt tolerance of nicotiana benthamiana
  publication-title: Phytochemistry
  doi: 10.1016/j.phytochem.2020.112582
– volume: 45
  start-page: 2987
  year: 2022
  ident: B17
  article-title: Potassium availability influences the mesophyll structure to coordinate the conductance of CO2 and H2O during leaf expansion
  publication-title: Plant Cell Environment.
  doi: 10.1111/pce.14405
– volume: 27
  start-page: 865
  year: 2017
  ident: B16
  article-title: Plant cell walls
  publication-title: Curr. Biol.
  doi: 10.1016/j.cub.2017.05.025
– volume: 41
  start-page: 2654
  year: 2018
  ident: B54
  article-title: Revealing mechanisms of salinity tissue tolerance in succulent halophytes: A case study for carpobrotus rossi
  publication-title: Plant Cell Environ.
  doi: 10.1111/pce.13391
– volume: 53
  start-page: 651
  year: 2017
  ident: B21
  article-title: The role of expansin genes PtrEXPA3 and PnEXPA3 in the regulation of leaf growth in poplar
  publication-title: Russ J. Genet.
  doi: 10.1134/s1022795417060084
– volume: 10
  year: 2021
  ident: B33
  article-title: Comparative phytochemical profile and biological activity of four major medicinal halophytes from qassim flora
  publication-title: Plants (Basel)
  doi: 10.3390/plants10102208
– volume: 65
  start-page: 6385
  year: 2014
  ident: B19
  article-title: Three-dimensional patterns of cell division and expansion throughout the development of Arabidopsis thaliana leaves
  publication-title: J. Experimental Botany
  doi: 10.1093/jxb/eru358
– volume: 147
  start-page: 43
  year: 2019
  ident: B29
  article-title: A WRKY transcription factor, FtWRKY46, from tartary buckwheat improves salt tolerance in transgenic arabidopsis thaliana
  publication-title: Plant Physiol. Biochem.
  doi: 10.1016/j.plaphy.2019.12.004
– volume: 322
  start-page: 229
  year: 2009
  ident: B15
  article-title: Anatomical adaptations to salinity in cogon grass [Imperata cylindrica (L.) raeuschel] from the salt range, Pakistan
  publication-title: Plant Soil
  doi: 10.1007/s11104-009-9911-6
– volume: 34
  start-page: 451
  year: 2015
  ident: B53
  article-title: Effects of exogenous putrescine on leaf anatomy and carbohydrate metabolism in cucumber (Cucumis sativus l.) under salt stress
  publication-title: J. Plant Growth Regulation.
  doi: 10.1007/s00344-015-9480-2
– volume: 17
  start-page: 332
  year: 2012
  ident: B14
  article-title: Leaf size control: complex coordination of cell division and expansion
  publication-title: Trends Plant Sci.
  doi: 10.1016/j.tplants.2012.02.003
– volume: 172
  start-page: 473
  year: 2007
  ident: B36
  article-title: Effects of sodium chloride on water potential components, hydraulic conductivity, gas exchange and leaf ultrastructure of arbutus unedo plants
  publication-title: Plant Sci.
  doi: 10.1016/j.plantsci.2006.10.006
– volume: 44
  start-page: 3005
  year: 2021
  ident: B4
  article-title: Effects of nanosilicon dioxide on leaf anatomy, chlorophyll fluorescence, and mineral element composition of strawberry under salinity stress
  publication-title: J. Plant Nutr.
  doi: 10.1080/01904167.2021.1936036
– volume: 10
  year: 2019
  ident: B49
  article-title: iTRAQ-based quantitative proteomics and transcriptomics provide insights into the importance of expansins during root development in carrot
  publication-title: Front. Genet.
  doi: 10.3389/fgene.2019.00247
– volume: 46
  start-page: 250
  year: 1970
  ident: B41
  article-title: Enhancement of wall loosening and elongation by acid solutions
  publication-title: Plant Physiol.
  doi: 10.1104/pp.46.2.250
– volume: 35
  start-page: 578
  year: 2011
  ident: B11
  article-title: Transient alkalinization in the leaf apoplast of vicia faba l. depends on NaCl stress intensity: An in situ ratio imaging study
  publication-title: Plant Cell Environ.
  doi: 10.1111/j.1365-3040.2011.02437
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Snippet Salt stress directly affects the growth of plants. The limitation of leaf grow is among the earliest visible effects of salt stress. However, the regulation...
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StartPage 1090366
SubjectTerms expansin
leaf thickness
Lycium barbarum L
Plant Science
salt stress
transcriptome
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Title Changes in the morphology traits, anatomical structure of the leaves and transcriptome in Lycium barbarum L. under salt stress
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