Identification and Characterization of Two New S-Adenosylmethionine-Dependent Methyltransferase Encoding Genes Suggested Their Involvement in Stipe Elongation of

Overview

Journal Mycobiology

Date 2020 Feb 4

PMID 32010465

Citations 4

Authors

Qianhui Huang

Irum Mukhtar

Yelin Zhang

Zhongyang Wei

Xing Han

Rongmei Huang

Junjie Yan

Baogui Xie

Affiliations

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Abstract

Two new SAM-dependent methyltransferase encoding genes ( and ) were identified from the genome of . In order to make a comprehensive characterization of both genes, we performed analysis of both genes and used qRT-PCR to reveal their expression patterns during the development of . There are 4 and 6 exons with total length of 693 and 978 bp in and , respectively. The deduced proteins, i.e., FVSMT1 and FVSMT2 contained 325 and 230 amino acids with molecular weight 36297 and 24894 Da, respectively. Both proteins contained a SAM-dependent catalytic domain with signature motifs (I, p-I, II, and III) defining the SAM fold. SAM-dependent catalytic domain is located either in the middle or at the N-terminal of FVSMT2 and FVSMT1, respectively. Alignment and phylogenic analysis showed that FVSMT1 is a homolog to a protein-arginine omega--methyltransferase, while FVSMT2 is of cinnamoyl CoA -methyltransferase type and predicted subcellular locations of these proteins are mitochondria and cytoplasm, respectively. qRT-PCR showed that and expression was regulated in different developmental stages. The maximum expression levels of and were observed in stipe elongation, while no difference was found in mycelium and pileus. These results positively demonstrate that both the methyltransferase encoding genes are involved in the stipe elongation of .

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