Genome-Wide Analysis of the Pear () Family and the Functional Characterization of , an Orthologue Gene, Involved in Cell Wall and Lignin Biosynthesis.

Stone cells are a characteristic trait of pear fruit, but the contents and sizes of stone cells negatively correlate with fruit texture and flavor. Secondary cell wall thickening and lignification have been established as key steps of stone cell development. KNOTTED-LIKE HOMEOBOX (KNOX) proteins play important roles in plant cell growth and development, including cell wall formation and lignification. Although the characteristics and biological functions of KNOX proteins have been investigated in other plants, this gene family has not been functionally characterized in pear. Eighteen genes were identified in the present study, and all of the identified family members contained the KNOX I and/or KNOX II domains. Based on the phylogenetic tree and chromosomal localization, the 18 genes were divided into five subfamilies [ ()-like, ()-like, ()-like, -like, and -like] and were distributed among 10 chromosomes. In addition, we identified 9, 11, and 11 genes in the genomes of grape, mei, and strawberry, respectively, and the greatest number of collinear gene pairs formed between pears and peaches. Analyses of the spatiotemporal expression patterns showed that the tissue specificity of gene expression was not very significant and that the level of the transcript showed an opposite trend to the levels of stone cells and lignin accumulation. Furthermore, PbKNOX1 has high sequence identity and similarity with BP. Compared with wild-type , plants overexpressing not only showed an approximately 19% decrease in the secondary cell wall thickness of vessel cells but also exhibited an approximately 13% reduction in the lignin content of inflorescence stems. Moreover, the expression of several genes involved in lignin biosynthesis was downregulated in transgenic lines. Based on our results, / participates in cell wall-thickening and lignin biosynthesis and represses the transcription of key structural genes involved in lignin synthesis, providing genetic evidence for the roles of in cell wall thickening and lignin biosynthesis in pear.