Cloning and Preliminary Functional Analysis of CaPI Gene in Capsicum annuum L.

doi:10.13560/j.cnki.biotech.bull.1985.2023-0957

Abstract

Abstract:

【Objective】 The PISTILLATA（PI）gene belongs to the typical type II MADS-box gene family and is a class B gene in the ABC（D）E model, and plays an important role in plant development. However, functions of the PI homologous genes in pepper（Capsicum annuum L.）have not been reported. This study explored the function of pepper PI gene, laying a foundation for in-depth research on the functional mechanism of plant PI homologs.【Method】 We cloned a PI homologous gene CaPI from the cDNA of floral organ tissues of pepper using RT-PCR, and analyzed its physicochemical properties, subcellular localization, protein structure, and phylogenetic relationship through bioinformatics methods. The expression pattern of CaPI in different tissues of pepper was performed using real-time quantitative PCR（RT-qPCR）method. A plant overexpression vector of 35S:CaPI was constructed and transformed into Arabidopsis using floral-dipping method.【Result】 The CaPI gene contains an open reading frame of 648 bp and encodes a peptide of 215 amino acids with a relative molecular weight of 25.13 kD. Multiple amino acid sequence alignment indicated that the N-terminus of CaPI contains a conserved motif of ‘MGRGKIEIKRIEN’. Phylogenetic tree analysis with homologous proteins of other species showed that the CaPI gene was closely related to the PI homologous genes of potato, tomato, and petunia. The RT-qPCR analysis showed that CaPI was predominantly expressed in flowers, with the highest expression level in the sepals, followed by petals, with low expression in stamens and almost no expression in pistils. The overexpression of CaPI in Arabidopsis revealed that, compared to wild type（Col-0）plant, the 35S:CaPI transgenic plants exhibited phenotypes such as increased number of rosette leaves and branches, but did not affect the development of floral organs.【Conclusion】 CaPI in the pepper functions in promoting plant branching development.

Key words: CaPI, Capsicum annuum L., MADS-box, gene expression

WU Xing-xing, HONG Hai-bo, GAN Zhi-cheng, LI Rui-ning, HUANG Xian-zhong. Cloning and Preliminary Functional Analysis of CaPI Gene in Capsicum annuum L.[J]. Biotechnology Bulletin, 2024, 40(3): 193-201.

Figures/Tables 8

Table 1 Primer information used in this study

引物名称 Primer name	引物序列 Primer sequence（5'-3'）	引物用途 Primer purpose
CaPI-R	$\text{GGG}\underline{\text{GTACC}}\text{ATGGGGAGAGGGAAAATAGAGATAAA}$	35S:CaPI载体35S:CaPI Vector
CaPI-F	$\text{GC}\underline{\text{TCTAG}}\text{ACTACATTCTTTCATGTAGATTTGGCT}$	35S:CaPI载体35S:CaPI Vector
qCaPI-R	CTTCTGGGAGGAGGCTATGG	RT-qPCR
qCaPI-F	AAGATCTCAGACTGCTTGGC	RT-qPCR
qCaUBI3-R	TGTCCATCTGCTCTCTGTTG	RT-qPCR
qCaUBI3-F	CACCCCAAGCACAATAAGAC	RT-qPCR
qAtactin2-R	CCTGGACCTGCCTCATCATAC	RT-qPCR
qAtactin2-F	CTGGATCGGTGGTTCCATTC	RT-qPCR

Fig. 1 Analysis of phosphorylation sites of CaPI protein in C. annuum L.

Fig. 2 Structural analysis of CaPI protein A: Secondary structure of CaPI protein. B: Comparison of spatial structures between CaPI（left）and AtPI（right）proteins

Fig. 3 Multiple amino-acid sequence alignments of the plant PI-like proteins

Fig. 4 Phylogenetic tree of the CaPI proteins in C. annuum L. and other plant species AT: Arabidopsis thaliana, AT5G20240.1; Ca: Capsicum annuum, CaPI, CaMADS74 and CaMADS53; SMEL: Solanum melongena, SMEL4.1_08g015360.1.01, SMEL4.1_02g021760.1.01; Solyc: Solanum lycopersicum, Solyc06g059970.4.1, Solyc02g084630.3.1; Peaxi: Petunia hybrida, Peaxi162Scf00922g00026.1, Peaxi162Scf00591g00074.1; PGSC: Solanum tuberosum, PGSC0003DMG401007392; TRAES: Triticum aestivum, TRAES3BF021600020CFD t1, TRAES3BF048900050CFD t1, TRAES3BF068500020CFD t1, TRAES3BF009000010CFD t1; Os: Oryza sativa, Os01t0883100-01, Os05t0423400-0

Fig. 5 Tissue expression pattern of the CaPI gene using RT-qPCR A: Expression profiles of the CaPI gene in different tissues of C. annuum L.. B: Expression profiles of the CaPI gene in four tissues: sepals, petals, stamens, and pistils. Lowercase letters indicate significant differences at P=0.01 level. The same below

Fig. 6 Phenotype survey of the 35S:CaPI transgenic plants in Arabidopsis thaliana A: Comparisons of phenotypes between the 35S:CaPI transgenic lines and wild type（Col-0）plants grown for 30 d. #1 and #2 represent two independent transgenic plants, respectively. B: Statistics on the number of rosette leaves during flowering stages. C: Statistics of flowering times. D: Statistics of branch numbers during flowering stages. E: RT-qPCR analysis of the relative expression level of the CaPI gene

Fig. 7 Comparison of flower morphologies between the wild-type（Col-0）and 35S:CaPI transgenic Arabi-dopsis plants

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