Structural and Functional Evolution of Positively Selected Sites in Pine Glutathione S-Transferase Enzyme Family*

Xiao-Ru Wang,Ting Lan,Qing-Yin Zeng

doi:10.1074/jbc.m113.456863

Abstract

Phylogenetic analyses have identified positive selection as an important driver of protein evolution, both structural and functional. However, the lack of appropriate combined functional and structural assays has generally hindered attempts to elucidate patterns of positively selected sites and their effects on enzyme activity and substrate specificity. In this study we investigated the evolutionary divergence of the glutathione S-transferase (GST) family in Pinus tabuliformis, a pine that is widely distributed from northern to central China, including cold temperate and drought-stressed regions. GSTs play important roles in plant stress tolerance and detoxification. We cloned 44 GST genes from P. tabuliformis and found that 26 of the 44 belong to the largest (Tau) class of GSTs and are differentially expressed across tissues and developmental stages. Substitution models identified five positively selected sites in the Tau GSTs. To examine the functional significance of these positively selected sites, we applied protein structural modeling and site-directed mutagenesis. We found that four of the five positively selected sites significantly affect the enzyme activity and specificity; thus their variation broadens the GST family substrate spectrum. In addition, positive selection has mainly acted on secondary substrate binding sites or sites close to (but not directly at) the primary substrate binding site; thus their variation enables the acquisition of new catalytic functions without compromising the protein primary biochemical properties. Our study sheds light on selective aspects of the functional and structural divergence of the GST family in pine and other organisms.

Highlights

The functional significance of positive selection in enzyme families is largely unknown
The Tau glutathione S-transferase (GST) were most numerous (26 members) followed by the Phi and Lambda classes, Zeta, DHAR, and EF1B␥ classes, and Theta and TCHQD classes. Phylogenetic analysis of these P. tabuliformis GSTs with the GST family from Populus trichocarpa showed that GSTs of each subfamily class from both genomes grouped as a single clade with high bootstrap support, which further supports the subfamily designations among the 44 P. tabuliformis GSTs
Expression Patterns of GST Gene Family in Pine—The expression patterns of 44 P. tabuliformis GST genes were examined in the radicle, seedlings, and mature tree in normal conditions

Summary

Background

The functional significance of positive selection in enzyme families is largely unknown. Positive Selection in Pine GSTs tionary and experimental approach to elucidate evolution and selection in the GST gene family in Pinus tabuliformis, a pine that is widely distributed from northern to central China including cold temperate and drought regions. It grows from 0 to 2700 m above sea level and forms extensive forests [16]. Through analyses of substitution and gene expression patterns, enzyme assays, site-directed mutagenesis, and structural comparisons, we examined 1) the selective context and functional divergence in the GST family in the pine and 2) the structural and functional importance of positively selected sites

EXPERIMENTAL PROCEDURES

RESULTS

DISCUSSION