Scientia Agricultura Sinica ›› 2023, Vol. 56 ›› Issue (22): 4506-4522.doi: 10.3864/j.issn.0578-1752.2023.22.012

• HORTICULTURE • Previous Articles     Next Articles

Screening Regulatory Genes Related to Luffa Fruit Length and Diameter Development Based on Transcriptome and WGCNA

CHEN MinDong(), WANG Bin, LIU JianTing, LI YongPing, BAI ChangHui, YE XinRu, QIU BoYin, WEN QingFang(), ZHU HaiSheng()   

  1. Fujian Key Laboratory of Vegetable Genetics and Breeding/Fujian Engineering Research Center for Vegetables/Crops Research Institute, Fujian Academy of Agricultural Sciences, Fuzhou 350013
  • Received:2023-04-10 Accepted:2023-09-05 Online:2023-11-16 Published:2023-11-17

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Abstract:

【Objective】 The aim of this study was to identify the co expression modules of luffa fruit length and diameter development and to screen key regulatory genes, so as to provide the theoretical basis for subsequent research on the molecular mechanism of fruit shape control in luffa. 【Method】 The luffa fruits in 9 fruit development stages (2 days before anthesis, and 0, 2, 4, 6, 8, 10, 15, and 20 days after anthesis) were applied as research materials. The fruit length and diameter of each stage were measured. The WGCNA method was used to jointly analyze transcriptome and fruit length and diameter data, to identify co-expressed gene modules of fruit length and diameter development, and to screen out key regulatory genes.【Result】A total of 14 co expression modules were identified by WGCNA, among which two modules (Turquoise and Lightpink4) were significantly correlated with fruit length and diameter (absolute value of correlation coefficient=0.9); Turquoise module was significantly positively correlated, while Lightpink4 module was significantly negatively correlated. KEGG enrichment analysis found that the Turquoise module was significantly enriched in endocytosis and phenylpropanoid biosynthesis pathways, which were closely related to fruit enlargement and growth regulation, and could be used as a key gene module for studying fruit length and diameter in luffa. According to the connectivity and functional annotation of genes in Turquoise module, ten key regulatory genes were screened, including xyloglucan endotransglucosylase/hydrolase gene XTH23, actin-depolymerizing factor gene ADF2, chaperone protein gene DnaJ10, expansin gene (EXPA1, EXPA4 and EXLA5), kinesin gene kinesin-13A, auxin response genes SAUR21, and Aux/IAA11. The RT-qPCR results showed that the expression levels of ten regulatory genes significantly increased after the fruit entered the rapid growth period (8 day after anthesis), with an increase of 2-50 times approximately. Through constructing a gene interaction network, it was found that some candidate genes interacted with the WRKY, bHLH, and HSF transcription factor families.【Conclusion】The Turquoise module, an important co expression module of luffa fruit length and diameter was obtained, and ten potential candidate genes for luffa fruit shape control were screened. It was found that luffa fruit length and diameter development regulation mainly involved the processes of cell wall reconstruction, cell development and differentiation, and auxin regulation.

Key words: transcriptome, WGCNA, Luffa cylindrica L., fruit length, fruit diameter, regulatory genes

Table 1

RT-qPCR Primers used in this study"

基因ID Gene ID 上游引物 Upstream primer(5'-3') 下游引物 Downstream primer(5'-3')
Maker00007620 GAACCAGCCGATGAGGAT TAGGACGCAGTGAAGGGA
Maker00033581 TGATTTCGACTTTGTTACTG TGAATCTGTCTTTGGAGC
Maker00000726 CAGATGGACGAGTTTGTG TCCCGAGTTCCTTAGCAG
Maker00000768 ATGCTCTTCCCAACGACA CCTGATTCCTCCCTGCTT
Maker00039481 TCGCAGCCAATCTTTCAG ACCGCCCACGTTTGTTAT
Maker00026031 GCCTTGGTTTCCTCTGTT TGTTCCATAGCCTTGACTG
Maker00009740 GCCCTCCGAACTACGCTCTT TGAACCTGATTCCTCCCTGT
Maker00024997 TTTCTTCAGTTCCGTCTATT TCTGCAACCCTTCTACCC
Maker00001372 TTTCAAGGACCTGCTAAG ATAGTCAAGCCTCCCATA
Maker00038241 GCGATTCCGCACGCAAGA TCCACGAAGCGACGACGAG
18sRNA GCTTGGGTGCTCGACAAACT TCCACAGAGCAATGTCAATGG

Fig. 1

Changes in fruit morphology during the development of luffa -2DAA: 2th day before anthesis; 0, 2, 4, 6, 8, 10, 15, 20 DAA: 0, 2th, 4th, 6th, 8th, 10th, 15th, 20th day after anthesis. The same as below"

Fig. 2

Dynamic changes in fruit length and diameter during the development of luffa ***indicate extremely significant correlation (P<0.001)"

Fig. 3

Gene number of each module"

Fig. 4

Correlation analysis between modules and traits The abscissa represents different trait, and the ordinate represents different modules. Each group of data represents the R value of the correlation coefficient between the module and the phenotype and the significance P value (in parentheses). Red means the positive correlation between module and trait, red means the negative correlation between module and trait"

Fig. 5

KEGG enrichment analysis of Lightpink4 (A) and Turquoise (B) gene co expression modules"

Fig. 6

Analysis of gene expression trends in Turquoise module The number in the box denoting the P-value"

Table 2

Candidate genes for regulating the development of fruit length and diameter in luffa"

基因名
Gene ID		 染色体
Chromosome		 基因功能描述
Gene description		 基因连通性在Turquoise模块的排名
Gene connectivity in turquoise
module ranking
Maker00007620 2 木葡聚糖内转葡糖基酶/水解酶23
Xyloglucan endotransglucosylase/hydrolase protein 23 (XTH23)		 1
Maker00033581 5 肌动蛋白解聚因子2 Actin-depolymerizing factor 2 (ADF2) 4
Maker00000726 8 伴侣蛋白DnaJ10 Chaperone protein DnaJ10 (DnaJ10) 7
Maker00026031 7 扩展蛋白A1 Expansin-A1 (EXPA1) 50
Maker00009740 7 扩展蛋白A4 Expansin-A4 (EXPA4) 155
Maker00024997 12 驱动蛋白13A Kinesin-13A (Kinesin-13A) 266
Maker00000768 8 扩展蛋白A4 Expansin-A4 (EXPA4) 351
Maker00039481 10 类扩展蛋白A5 Expansin-like-A5 (EXLA5) 373
Maker00001372 8 生长素反应蛋白SAUR21 Auxin-responsive protein SAUR21 (SAUR21) 416
Maker00038241 12 生长素反应蛋白IAA11 Auxin-responsive protein IAA11 (AUX/IAA11) 453

Fig. 7

RT-qPCR and RNA seq results of 10 regulatory genes"

Fig. 8

Interaction network of 10 regulatory genes The color of the line in the figure represents the type of correlation between regulatory genes and associated genes.Red represents positive correlation and blue represents negative correlation; The thickness of the line represents the magnitude of the correlation value. The regulatory genes and their associated transcription factors are highlighted in yellow"

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