高粱苗期耐盐性转录组分析和基因挖掘

doi:10.3864/j.issn.0578-1752.2019.22.005

Abstract

Abstract:

【Object】The primary aim of this study was to identify salt tolerance genes and explore the tolerance response mechanism under salt stress in sorghum, which may provide a theoretical basis for sorghum salt tolerance breeding. 【Method】Two sorghum varieties, L-Tian, salt-sensitive and Shihong 137, salt-tolerant were employed as plant materials. The sorghum seedlings were treated with 2% NaCl solution at three-leaf and one heart stage. Three treatments including 0 h (CK), 1 h and 24 h were conducted. The plant height, root length, dry matter weight, Na ⁺ content and relative content of chlorophyll (SPAD value) were determined, and the transcriptome sequencing was performed on Illumina HiSeq 2000 platform. The FPKM method was employed to calculate the gene expression level. Both the differential expression fold (Fold Change) ≥ 2 and FDR<0.001 were used as screening criteria to detect the differentially expressed genes. The Gene Ontology and KEGG Pathway databases were used to analyze the differentially expressed genes involved in salt stress at different time points. 【Result】Salt stress had no significant effect on plant height, root length and dry matter weight of sorghum, but had significant effect on Na ⁺ content and SPAD value. The plant height, root length, Na ⁺ content and SPAD value of Shihong 137 were higher than those of L-tian. Totally 26628 known genes and 866 new genes have been identified from RNA-seq, of which, the number of differentially expressed genes from Shihong 137 is higher than that from L-tian. 375, 4206 and 3750 differentially expressed genes in 0 h VS 1 h, 0 h VS 24 h and 1 h VS 24 h groups had been identified from Shihong 137 respectively. The number of differentially expressed genes of 0 h VS 1 h, 0 h VS 24 h, and 1 h VS 24 h of L-tian was 167, 2534 and 1612, respectively. GO and KEGG analysis revealed that plant hormones such as abscisic acid, auxin, cytokinin, gibberellin and ethylene were involved in the salt tolerance of sorghum at an early stage of salt stress (1h), while Lhca, Lhcb, phosphoenolpyruvate carboxylase, and ribulose phosphate kinase were involved in the salt tolerance at a late stage of salt stress (24 h). The difference in salt tolerance between Shihong 137 and L-tian was mainly caused by the flavonoid biosynthetic metabolic pathway. 【Conclusion】The sorghum response to salt stress is a complex biological process that relies on the balanced expression of multiple genes in complex networks. Under salt stress, sorghum response to environmental stimuli was controlled by both hormonal signal transduction and photosynthesis. The flavonoid biosynthesis pathway played an important role in salt-tolerant varieties.

Key words: sorghum (Sorghum bicolor L.), salt stress, transcriptome, gene mining

DONG Ming, KUERBAN Zaituniguli, Lü Peng, DU RuiHeng, YE Kai, HOU ShengLin, LIU GuoQing. Transcriptome Analysis and Gene Mining of Salt Tolerance in Sorghum Seedlings (Sorghum bicolor L. Moench)[J].Scientia Agricultura Sinica, 2019, 52(22): 3987-4001.

Figures/Tables 13

Table 1

Fig. 1

Table 2

Fig. 2

Table 3

Table 4

Fig. 3

Table 5

GO enrichment analysis of s DEGs in sorghum leaves"

处理 Treatments	GO编号 GO ID	GO分类 Term	注释基因数Annotated	显著基因数Significant	期望值 Expected	显著性 KS
nCK VS n1h	GO:0060416	生长激素响应Response to growth hormone	48	1	0.68	1.80E-08
	GO:0006749	谷胱甘肽代谢Glutathione metabolic process	88	1	1.25	2.20E-07
	GO:0006569	色氨酸分解代谢Tryptophan catabolic process	129	2	1.83	5.00E-07
	GO:0009684	吲哚乙酸生物合成Indoleacetic acid biosynthetic process	210	3	2.99	6.10E-07
	GO:0080148	缺水反应负调节过程Negative regulation of response to water deprivation	56	1	0.80	8.20E-07
	GO:0015824	脯氨酸转运Proline transport	164	3	2.33	2.10E-06
	GO:0016036	磷缺失细胞响应过程 Cellular response to phosphate starvation	319	7	4.53	2.60E-06
	GO:0051260	蛋白质同源寡聚化Protein homooligomerization	43	2	0.61	6.20E-06
	GO:0033506	硫代葡萄糖苷生物合成过程 Glucosinolate biosynthetic process from homomethionine	11	0	0.16	1.00E-05
	GO:0071475	细胞高渗盐反应Cellular hyperosmotic salinity response	10	1	0.14	1.60E-05
nCK VS n24h	GO:0010207	光系统II组装Photosystem II assembly	257	123	39.38	1.40E-25
	GO:0006364	核糖体RNA加工rRNA processing	403	161	61.75	8.30E-24
	GO:0010027	类囊体膜组织Thylakoid membrane organization	366	149	56.08	1.00E-21
	GO:0009773	光系统I中的光合电子输运 Photosynthetic electron transport in photosystem I	70	43	10.73	1.10E-17
	GO:0000023	麦芽糖代谢过程Maltose metabolic process	217	93	33.25	2.50E-16
	GO:0019252	淀粉合成过程Starch biosynthetic process	280	110	42.90	5.70E-16
	GO:0010114	红光响应过程Response to red light	299	119	45.82	9.60E-15
	GO:0019344	半胱氨酸生物合成Cysteine biosynthetic process	389	129	59.61	8.60E-13
	GO:0080167	karrikin响应过程Response to karrikin	493	124	75.54	2.20E-12
	GO:0006569	色氨酸分解代谢Tryptophan catabolic process	129	38	19.77	9.20E-11
gCK VS g1h	GO:0060416	生长激素响应Response to growth hormone	48	0	0.28	9.70E-09
	GO:0006749	谷胱甘肽代谢Glutathione metabolic process	88	1	0.52	4.10E-08
	GO:0080148	缺水反应负调节过程Negative regulation of response to water deprivation	56	0	0.33	4.60E-07
	GO:0009684	吲哚乙酸生物合成Indoleacetic acid biosynthetic process	210	1	1.23	4.70E-07
	GO:0006569	色氨酸分解代谢Tryptophan catabolic process	129	1	0.76	5.80E-07
	GO:0015824	脯氨酸转运Proline transport	164	2	0.96	8.10E-07
	GO:0016036	磷缺失细胞响应过程Cellular response to phosphate starvation	319	1	1.87	2.10E-06
	GO:0051260	蛋白质同源寡聚化Protein homooligomerization	43	0	0.25	4.70E-06
	GO:0033506	硫代葡萄糖苷生物合成过程 Glucosinolate biosynthetic process from homomethionine	11	0	0.06	8.10E-06
	GO:0009704	去乙醇De-etiolation	86	0	0.51	1.20E-05
gCK VS g24h	GO:0006098	戊糖磷酸支路Pentose-phosphate shunt	325	134	30.72	6.40E-30
	GO:0019288	异戊烯二磷酸生物合成过程Isopentenyl diphosphate biosynthetic process. 甲基赤藓糖醇4-磷酸通路Methylerythritol 4-phosphate pathway	392	123	37.06	3.80E-19
	GO:0010207	光系统II组装Photosystem II assembly	257	89	24.29	2.30E-17
	GO:0000023	麦芽糖代谢Maltose metabolic process	217	77	20.51	5.00E-14
	GO:0019252	淀粉生物合成Starch biosynthetic process	280	89	26.47	1.80E-13
	GO:0009773	光系统I中的光合电子输运 Photosynthetic electron transport in photosystem I	70	38	6.62	4.00E-13
	GO:0080167	karrikin响应过程Response to karrikin	493	94	46.6	1.30E-11
	GO:0010114	红光反应系统Response to red light	299	90	28.26	3.20E-11
	GO:0060416	生长激素响应Response to growth hormone	48	12	4.54	1.60E-10
	GO:0010027	类囊体膜组织Thylakoid membrane organization	366	93	34.60	3.60E-10

Table 5

Fig. 4

Table 6

Fig. 5

Fig.6

Fig. 7

References 31

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基因ID Gene ID	正向引物 Forward primer (5′-3′)	反向引物 Reverse primer(5′-3′)
Sobic.006G018400	CATCAATGGTTACCGTGTGC	CGCTCAGTGATGGTGATCTC
Sobic.006G034300	AGGAAGCGAAGGGAGTTAAAG	TCTGGAACATGGAAAGGCTC
Sobic.004G300300	ACGGCTACGGCTACGACTAC	ATGCCACCGCGTTCCACTC
Sobic.004G227400	TCATGTTCCAGCCGTCGTCG	AAGAGGCCGTGGGCGTTG
GADPH	TCACTGCTACCCAAAAGACG	AGACATCAACGGTAGGAACAC

处理 Treatment	株高 Plant height (cm)	根长 Root length (cm)	干物重 Dry weight (g)
gCK	5.24	4.86	0.18
g1h	5.21	4.83	0.18
g24h	5.20	4.77	0.22
nCK	6.56	6.23	0.25
n1h	6.69	6.22	0.26
n24h	6.59	6.22	0.28

分类Classification	最大值Maximum	最小值Minimum	平均值Average
总序列标签Total reads	56174902	42082348	48578108
比对到基因组序列标签Mapped reads	44513494	33795753	37417638
比对到基因组序列标签比例Ratio of mapped reads (%)	79.74	76.27	78.33
GC含量GC content (%)	58.67	55.73	57.30
Q30碱基百分比Percentage of Q30 base (%)	93.29	92.40	92.89
已知转录本数Number of known gene	26628
新转录本数Number of novel gene	866

处理DEG Set	差异表达基因数DEG Number	上调表达基因数Up-regulated gene number	下调表达基因数Down-regulated gene number
nCK VS n1h	375	332	43
nCK VS n24h	4206	1947	2259
n1h VS n24h	3750	1711	2039
gCK VS g1h	167	149	18
gCK VS g24h	2534	1259	1275
g1h VS g24h	1612	715	897
gCK VS nCK	1240	576	664
g1h VS n1h	1184	540	644
g24h VS n24h	1910	783	1127

基因名称 Gene name	基因ID Gene ID	FPKM 值FPKM value
基因名称 Gene name	基因ID Gene ID	gCK	g1h	g24h	nCK	n1h	n24h
Lhca1	Sobic.004G056900	6845.75	5277.53	549.64	7487.56	6519.72	268.80
Lhca2	Sobic.002G215000	1138.05	1161.23	68.34	1049.57	1109.62	20.12
Lhca2	Sobic.002G352100	4759.34	3627.86	260.80	4158.43	3828.06	73.90
Lhca3	Sobic.010G189300	4871.52	3711.42	392.95	5321.69	4030.16	151.76
Lhca4	Sobic.007G136900	4332.36	3332.85	194.35	5032.23	4230.89	67.37
Lhca5	Sobic.004G308700	728.38	595.98	75.06	842.51	805.12	35.45
Lhcb1	Sobic.002G288300	3292.48	3102.02	307.94	3037.17	2900.42	181.03
Lhcb1	Sobic.003G209900	6389.25	4984.08	49.64	3469.75	3574.07	4.02
Lhcb1	Sobic.009G234600	5809.76	5237.89	653.41	4791.33	4965.73	479.47
Lhcb2	Sobic.001G177000	8469.69	6247.14	446.28	13066.13	9860.12	175.30
Lhcb3	Sobic.002G339200	1714.88	1482.53	72.21	1275.63	1696.12	42.19
Lhcb4	Sobic.002G338000	3871.83	3342.85	250.40	3352.35	3419.74	74.70
Lhcb5	Sobic.005G087000	3613.05	3154.13	108.67	3800.17	3639.70	34.51
Lhcb6	Sobic.006G264200	2859.62	2414.96	84.85	1956.43	2112.88	67.85
PPC	Sobic.002G167000	22.50	22.36	85.39	13.85	12.02	71.82
PPC	Sobic.010G160700	5064.26	4230.24	932.75	4640.39	4269.74	262.15
PPC	Sobic.004G106900	66.57	55.44	537.14	71.04	145.90	649.27
PPC	Sobic.007G106500	29.54	15.39	23.77	15.24	16.67	71.67
PRK	Sobic.004G272100	1162.80	1074.55	96.36	1050.45	1166.71	20.26
PRK	Sobic.006G200800	35.80	25.69	4.21	32.01	26.04	3.00

Transcriptome Analysis and Gene Mining of Salt Tolerance in Sorghum Seedlings (Sorghum bicolor L. Moench)

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