Scientia Agricultura Sinica ›› 2024, Vol. 57 ›› Issue (19): 3848-3869.doi: 10.3864/j.issn.0578-1752.2024.19.011

• HORTICULTURE • Previous Articles     Next Articles

Identification of Ginger (Zingiber officinale Roscoe) NHX Gene Family Members and Characterization of Their Expression Patterns in Silicon Alleviating Salt Stress

YIN JunLiang1,2(), LI JingYi1, HAN Shuo1, YANG PeiHua2, MA JiaWei2, LIU YiQing2, HU HaiJun2, ZHU YongXing1,2()   

  1. 1 College of Agriculture, Yangtze University, Jingzhou 434025, Hubei
    2 College of Horticulture and Gardening, Yangtze University/ Hubei Key Laboratory of Spices & Horticultural Plant Germplasm Innovation & Utilization/Engineering Research Center of Wetland Ecology and Agricultural Use, Ministry of Education, Jingzhou 434025, Hubei
  • Received:2024-06-09 Accepted:2024-07-22 Online:2024-10-01 Published:2024-10-09
  • Contact: ZHU YongXing

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Abstract:

【Objective】 Systematic analysis of the basic features of the ZoNHX family members in ginger and exploration of their expression patterns in different tissues and treatments of ginger can provide a theoretical foundation for further research on the function of ZoNHXs. 【Method】The Arabidopsis thaliana NHX protein sequences were used as reference sequences to compare with the ginger genome to obtain the ginger ZoNHXs. The phylogenetic tree containing Arabidopsis and ginger NHX family members were constructed based on the neighbor-joining method by MEGA 7.0. Physicochemical properties, gene structure, conserved motifs, secondary structure and tertiary structure of ZoNHXs were analyzed by using ExPASy ProtParam software, GSDS, MEME online website, PHYRE 2 and SOPMA, while chromosomal localization, intragenomic covariance and expression patterns of ZoNHXs were analyzed by using TBtools software. The gene expression levels of ZoNHXs in different treatments including CK, NaCl, and NaCl+SiNP100, and different ginger tissues were analyzed using RT-qPCR. The Na+ and K+ contents of ginger tissues was determined. 【Result】A total of 15 NHX gene family members were identified from the ginger genome, and were named as ZoNHX1-ZoNHX15 based on their chromosomal locations. The ZoNHXs were classified into three subgroups according to phylogenetic relationship and subcellular localization, including vesicular membranes (Vac, vacuole), endosomal membranes in the nucleus (Endo, endosome) and plasma membranes (PM, plasma). Protein characterization analysis showed that the relative molecular weights of ZoNHXs ranged from 26.01 kDa to 163.59 kDa, and the protein lengths ranged from 231 to 1 459 aa. The results of subcellular localization prediction showed that 11 ZoNHXs were distributed on the vacuole, ZoNHX14 were distributed both on the cell membrane and nucleus, ZoNHX1, ZoNHX7 and ZoNHX9 were respectively distributed on cytoplasm, cell membrane, and chloroplast. Signal peptide prediction showed that only ZoNHX1 contained a signal peptide and was a secreted protein, while other ZoNHX family members were non-secretory proteins. Cis-acting element analysis showed that the promoter regions of the ZoNHXs contain growth and development response elements, hormone response elements, and stress response elements. Transcriptome analysis showed that all ZoNHXs were detected to be expressed in ginger leaf and root, among which, ZoNHX12 was highly expressed in all tissues of ginger and under different abiotic stresses, and ZoNHX14 was significantly up-regulated in all growth periods of ginger and at low temperatures. RT-qPCR results showed that, compared with the CK, all genes were significantly up-regulated in roots and leaves after salt stress except for ZoNHX8 and ZoNHX11. Compared with the NaCl treatment alone, NaCl+SiNP100 decreased the expression levels of all genes except for ZoNHX8 and ZoNHX11, the expression levels of which were significantly up-regulated. These indicated that ZoNHXs were involved in the response process of ginger to salt stress and the expression of ZoNHXs were also regulated by exogenous SiNP100. The results of Na+, K+ ion content, K+/Na+ ratio and transport selection coefficient SK+/Na+ showed that the Na+ content in ginger rhizomes, stems, and leaves under salt treatment was increased compared with CK, and the K+/Na+ ratio and transport selection coefficient were decreased. NaCl+SiNP100 treatment significantly decreased Na+ content in roots, rhizomes, stems and leaves, whereases increased K+/Na+ ratio and transport selection coefficient. 【Conclusion】 The ginger genome contains 15 ZoNHXs and divides into three subgroups. RT-qPCR results showed that the expression of ZoNHX1-ZoNHX15 were all induced by salt stress. SiNP100 pretreatment could alleviate plant salt stress through reducing the Na+ content and increase the K+/Na+ ratio and K+ and Na+ content of the ginger roots, rhizomes, stems, and leaves by regulating the expression of ZoNHXs.

Key words: ginger, NHX gene family, salt stress, expression analysis, transcriptome

Table 1

RT-qPCR primers for expression analysis of ginger ZoNHXs"

基因ID
Gene ID		 名称
Name		 引物序列Primer sequence (5′-3′) 长度
Length (bp)
正向Forword 反向Reverse
Maker00056825 ZoNHX1 AATGCCTGGTTTGCTTCCTC GCTTGTTGGGCTTGCTGTG 99
Maker00009627 ZoNHX2 AGATGGGAGGGTTCACGAG GACAATGTACCCCCGATCC 116
Maker00078687 ZoNHX3 CAAACCCTTCCGCTTCTCC GACGACGAGGCTCCGACTA 133
Maker00077763 ZoNHX4 TGCCCTGGCATTTAGTCAG AGGTCGTCCGACTTCCATC 166
Maker00035912 ZoNHX5 GACAAGAGGTTACAGAGGGATATG CACCGAAAGTGTAGAAGGAAAG 151
Maker00016804 ZoNHX6 TTGACTCGTCGGCTTTGATC CTGACCCATGACTATTTGGTAGAA 131
Maker00016508 ZoNHX7 CGATGGTGGTTCACAGAGG ACCGACGCTGAGCTACCTT 155
Maker00016634 ZoNHX8 ATCCTGTTGCTGTCGTTGC ATTGCAGTCCCATCGTTCA 143
Maker00016696 ZoNHX9 AGCATGTCGGTTTGCTCAG TTCTGCAATGGCTTCTTGG 162
Maker00029358 ZoNHX10 TTGTGCATCCCCACTGTTT AATAGGGGGCAGCAAGAAC 177
Maker00028403 ZoNHX11 CTGGTCGCATGTTGGATTC TGAAGGGCAAGTGCAAAAG 134
Maker00058140 ZoNHX12 GCTGGGGATCTCTCAGCTC CAGGTGGCCAATAACGATG 154
Maker00022420 ZoNHX13 TGGAATGGATGCATTGGAC CAAGCCATGTCCATTTTCG 119
Maker00061543 ZoNHX14 TTTCTCCCGACCATTCTCC GACGTCGTCAACACCAACC 170
Maker00007292 ZoNHX15 GCTGCGTCTTCCACTCAAC CCCTCCCCGAAGACAATAC 149
MTCONS_00009943 RBP CCTATGAAGCGTAGAAACACAAG GGAAGGACAACATCCCAAATC 123

Fig. 1

Phylogenic analysis of NHX family members from ginger and Arabidopsis"

Table 2

Information and physicochemical properties of ginger ZoNHX family members"

基因名称
Gene name		 基因ID
Gene ID		 蛋白长度
Protein length (aa)		 分子量
Molecular weight (kDa)		 等电点
pI		 亲水指数
Gravy		 不稳定系数
Instability index		 亚细胞预测
Predicted location		 信号肽
Signal
ZoNHX1 Maker00056825 231 26.01 5.96 0.238 39.92 细胞质 Cytoplasm 有 Yes
ZoNHX2 Maker00009627 1459 163.59 8.88 -0.036 42.16 液泡 Vacuole 无 No
ZoNHX3 Maker00078687 315 34.76 7.08 0.388 46.86 液泡 Vacuole 无 No
ZoNHX4 Maker00077763 425 47.62 8.96 0.394 44.93 液泡 Vacuole 无 No
ZoNHX5 Maker00035912 539 58.62 5.43 0.306 44.86 液泡 Vacuole 无 No
ZoNHX6 Maker00016804 543 60.23 8.99 -0.049 43.39 液泡 Vacuole 无 No
ZoNHX7 Maker00016508 990 111.68 9.08 -0.055 47.28 细胞膜 Cell membrane 无 No
ZoNHX8 Maker00016634 318 34.14 5.42 0.745 33.06 液泡 Vacuole 无 No
ZoNHX9 Maker00016696 833 93.58 6.13 -0.137 41.12 叶绿体 Chloroplast 无 无
No
ZoNHX10 Maker00029358 257 28.72 5.27 0.854 46.73 液泡 Vacuole 无 No
ZoNHX11 Maker00028403 292 32.51 6.66 0.273 42.53 液泡 Vacuole 无 No
ZoNHX12 Maker00058140 617 68.4 6.64 0.521 36.21 液泡 Vacuole 无 No
ZoNHX13 Maker00022420 324 36.19 9.24 -0.008 53.85 细胞膜、细胞核
Cell membrane, Nucleus		 无 No
ZoNHX14 Maker00061543 683 75.61 9.47 0.443 44.91 液泡 Vacuole 无 No
ZoNHX15 Maker00007292 450 49.88 8.48 0.420 34.1 液泡 Vacuole 无 No

Fig. 2

Chromosome locations of ZoNHXs"

Fig. 3

Gene structures of ZoNHXs"

Fig. 4

Conserved motifs of ZoNHXs"

Fig. 5

Motif sequences of ZoNHX family members"

Fig. 6

Structure domains of ginger ZoNHX family members across the membrane"

Fig. 7

Tertiary structure of ginger ZoNHX proteins"

Table 3

Comparative analysis of secondary structure of ZoNHXs"

蛋白Protein α-螺旋 Alpha helix (%) 延伸链 Extended strand (%) β-转角 Beta turn (%) 不规则卷曲 Random coil (%)
ZoNHX3 39.05 21.59 10.48 28.89
ZoNHX1 44.16 19.91 6.93 29.00
ZoNHX9 45.74 12.48 5.28 36.49
ZoNHX7 45.96 16.77 9.70 27.58
ZoNHX6 41.25 18.23 9.02 31.49
ZoNHX8 54.09 19.81 6.29 19.81
ZoNHX10 42.80 20.23 3.50 33.46
ZoNHX11 48.63 11.30 4.45 35.62
ZoNHX5 44.34 16.88 3.15 35.62
ZoNHX13 40.12 19.75 9.26 30.86
ZoNHX15 41.56 18.67 4.22 35.56
ZoNHX4 46.12 19.29 3.53 31.06
ZoNHX14 40.56 18.74 4.69 36.02
ZoNHX12 41.98 22.37 5.53 30.31
ZoNHX2 34.82 23.92 11.38 29.88

Fig. 8

Cis-acting elements of ginger ZoNHX family members Red indicates an increase in the number of cis-acting elements, and a numerical value indicates the number of cis-acting elements"

Fig. 9

Intraspecific and interspecific collinear analysis of NHXs A: Collinear analysis of ginger ZoNHXs; B: Analysis of NHX gene covariance between ginger and plantain. The red lines are the gene pairs copied in large fragments, and the gray lines are all the collinear blocks in the ginger genome"

Fig. 10

Expression patterns of ginger ZoNHXs in different tissues and under various treatments A: Expression of ZoNHXs in different growth stages, root and stem of ginger. R1-R5: 5 growth periods of ginger; G: root; S: stem. B: Expression of ZoNHXs in Root (R), Stem (S), Leaf (L) and rhizome (Rh-90) of 90 d ginger. C: Expression of ZoNHXs in ginger tuber at 25 ℃, 4 ℃ and 12 ℃. D: Expression of ZoNHXs in ginger seedlings inoculated with Ralstonia solanacearum in different soil pore water content. HI: 40% porosity inoculated with Penicillium; HUN: 40% porosity inoculated with sterile water; LI: 10% porosity inoculated with Penicillium; LUN: 10% porosity inoculated with sterile water. E: Expression of ZoNHXs in ginger treated with 26 ℃ (CK), cold (LT), melatonin (CK-MT) and melatonin-cold (LT-MT). F: Expression of ZoNHXs in ginger rhizomes 0, 1, and 2 d after CTS treatment (CK0, CK1, and CK2) and in ginger rhizomes inoculated with Fusarium roqueforti + chitosan 0, 1, and 2 d (CS0, CS1, and CS2). G. Expression of ZoNHXs in roots (R), stems (S), leaves (L), and rhizomes (Rh) of ginger under different abiotic stresses. NaCl, PEG, WL, and WL+Si: salt stress, drought stress, flooding stress, and flooding+Nano-Si. Different colors in the legend represent different Log2(FPKM+1) values, red represents the largest log2(FPKM+1) value, and blue represents the smallest value"

Fig. 11

Expression patterns of ginger ZoNHXs in response to salt stress Different lowercase letters indicate the significant different between treatments at P<0.05 level. The same as below"

Fig. 12

K+ and Na+ content in four parts of ginger under salt stress (15 d)"

Table 4

Effects of exogenous SiNP100 on K+/Na+ in root, tuber, stem and leaf of ginger under salt stress"

处理 Treatment 根Root 根茎Tuber 茎Stem 叶Leaf
CK 278.93±27.39a 64.59±2.77a 2779.50±17.65a 4040.83±1206.794a
NaCl 7.00±0.67b 4.87±0.21c 17.65±1.25b 16.84±3.20b
SiNP100+NaCl 14.10±0.43b 12.18±1.35b 46.74±4.75b 105.96±7.55b

Table 5

Effects of exogenous SiNP100 on transport selectivity coefficient of K+ and Na+ between different parts of ginger under salt stress"

处理 Treatment 根→根茎(SK+/Na+) Root→Tuber 根茎→茎(SK+/Na+) Tuber→Stem 茎→叶(SK+/Na+) Stem→Leaf
CK 0.23±0.02c 43.16±7.10a 1.44±0.33b
NaCl 0.70±0.06b 3.63±0.37b 0.97±0.24b
SiNP100+NaCl 0.86±0.08a 3.87±0.60b 2.28±0.19a
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