Optimized Production of Disulfide-Bonded Fungal Effectors in Escherichia coli Using CyDisCo and FunCyDisCo Coexpression Approaches.

Effectors are a key part of the arsenal of plant-pathogenic fungi and promote pathogen virulence and disease. Effectors typically lack sequence similarity to proteins with known functional domains and motifs, limiting our ability to predict their functions and understand how they are recognized by plant hosts. As a result, cross-disciplinary approaches involving structural biology and protein biochemistry are often required to decipher and better characterize effector function. These approaches are reliant on high yields of relatively pure protein, which often requires protein production using a heterologous expression system. For some effectors, establishing an efficient production system can be difficult, particularly those that require multiple disulfide bonds to achieve their naturally folded structure. Here, we describe the use of a coexpression system within the heterologous host Escherichia coli, termed CyDisCo (cytoplasmic disulfide bond formation in E. coli) to produce disulfide bonded fungal effectors. We demonstrate that CyDisCo and a naturalized coexpression approach termed FunCyDisCo (Fungi CyDisCo) can significantly improve the production yields of numerous disulfide-bonded effectors from diverse fungal pathogens. The ability to produce large quantities of functional recombinant protein has facilitated functional studies and crystallization of several of these reported fungal effectors. We suggest this approach could be broadly useful in the investigation of the function and recognition of a broad range of disulfide bond-containing effectors.[Formula: see text] Copyright © 2022 The Author(s). This is an open access article distributed under the CC BY-NC-ND 4.0 International license.

Identification of a gene cluster for the synthesis of the plant hormone abscisic acid in the plant pathogen Leptosphaeria maculans.

Leptosphaeria maculans is an ascomycetous fungus that causes the disease blackleg on Brassica napus (canola). In spite of the importance of the disease worldwide, the mechanisms of disease development are poorly understood. Secondary metabolites, which are one of the common virulence factors of pathogenic fungi, have not been extensively explored from this fungus. An RNA-seq dataset was examined to find genes responsible for secondary metabolite synthesis by this fungus during infection. One polyketide synthase gene, pks5, was found to be upregulated during the early biotrophic stage of development. In addition to pks5, six other genes adjacent to the pks5 gene, including one encoding a Zn(II)2Cys6 transcription factor abscisic acid-like 7 gene (abl7), were also upregulated during that time. A striking feature of the L. maculans genome is that it contains large AT-rich regions that are gene-poor and large GC-rich regions that are gene rich. This set of seven co-regulated genes is embedded within and separated by two such AT-rich regions. Three of the genes in the cluster have similarities to those known to be involved in the synthesis of abscisic acid (ABA) in other fungi. When L. maculans is grown in axenic culture the genes in this cluster are not expressed and ABA is not produced. Overexpressing abl7, encoding the putative transcription factor, resulted in the transcription of the six adjacent genes in axenic culture and in the production of ABA, as detected by liquid chromatography quadrupole-time-of-flight mass spectrometry analysis. Mutation of two genes of the cluster using CRISPR/Cas9 did not affect pathogenicity on canola cotyledons. The characterization of the ABA gene cluster has led to the discovery of the co-regulation of genes within an AT-rich region by a transcription factor, and the first report of the plant hormone abscisic acid being produced by L. maculans.