Han-Na Lee

Interspecies DNA Microarray Analysis Identifies WblA as a Pleiotropic Down-Regulator of Antibiotic Biosynthesis in Streptomyces

Using Streptomyces coelicolor microarrays to discover regulators of gene expression in other Streptomyces species, we identified wblA, a whiB-like gene encoding a putative transcription factor, as a down-regulator of doxorubicin biosynthesis in Streptomyces peucetius. Further analysis revealed that wblA functions pleiotropically to control antibiotic production and morphological differentiation in streptomycetes. Our results reveal a novel biological role for wblA and show the utility of interspecies microarray analysis for the investigation of streptomycete gene expression.

Isolation and genetic manipulation of the antibiotic down-regulatory gene, wblA ortholog for doxorubicin-producing Streptomyces strain improvement

Cross-genome comparative transcriptome analyses were previously conducted using the sequenced Streptomyces coelicolor genome microarrays to understand the genetic nature of doxorubicin (DXR) and daunorubicin (DNR) overproducing industrial mutant (OIM) of Streptomyces peucetius. In this previous work, a whiB-like putative transcription factor (wblAsco) was identified as a global antibiotic down-regulator in S. coelicolor (Kang et al., J Bacteriol 189:4315-4319, 2007). In this study, a total genomic DNA library of a DXR/DNR-overproducing S. peucetius OIM was constructed and screened using wblAsco as a probe, resulting in the isolation of a wblA ortholog (wblAspe) that had 95% amino acid identity to wblAsco. Gene disruption of wblAspe from the S. peucetius OIM resulted in an approximately 70% increase in DXR/DNR productivity, implying that the DXR/DNR production in the S. peucetius OIM could be further improved via comparative transcriptomics-guided target gene manipulation. Furthermore, several putative wblAspe-dependent genes were also identified using S. coelicolor interspecies DNA microarray analysis between the S. peucetius OIM and wblAspe-disrupted S. peucetius OIM. Among the genes whose expressions were significantly stimulated in the absence of wblAspe, the overexpression of a conserved hypothetical protein (SCO4967) further stimulated the total production of DXR/DNR/akavinone by 1.3-fold in the wblAspe-disrupted S. peucetius OIM, implying that the sequential genetic manipulation of target genes identified from interspecies comparative microarray analysis could provide an efficient and rational strategy for Streptomyces strain improvement.

Transcriptome Analysis of an Antibiotic Downregulator Mutant and Synergistic Actinorhodin Stimulation via Disruption of a Precursor Flux Regulator in Streptomyces coelicolor

ABSTRACT Through microarray analysis of an antibiotic-downregulator-deleted Streptomyces coelicolor ΔwblA ΔSCO1712 mutant, 28 wblA- and SCO1712-dependent genes were identified and characterized. Among 14 wblA- and SCO1712-independent genes, a carbon flux regulating 6-phosphofructokinase SCO5426 was additionally disrupted in the ΔwblA ΔSCO1712 mutant and further stimulated actinorhodin production in S. coelicolor, implying that both regulatory and precursor flux pathways could be synergistically optimized for antibiotic production.

Putative TetR Family Transcriptional Regulator SCO1712 Encodes an Antibiotic Downregulator in Streptomyces coelicolor

ABSTRACT A tetR family transcriptional regulatory gene (SCO1712) was identified as a global antibiotic regulatory gene from a Streptomyces interspecies DNA microarray analysis. SCO1712 disruption in Streptomyces coelicolor not only upregulated antibiotic biosynthesis through pathway-specific regulators when a previously identified pleiotropic downregulatory wblA was expressed but also further stimulated antibiotic production in a wblA deletion mutant, implying that SCO1712 might encode a novel antibiotic downregulator.

Repression of Antibiotic Downregulator WblA by AdpA in Streptomyces coelicolor

ABSTRACT The upstream region of antibiotic downregulatory wblA in Streptomyces coelicolor was found to contain AdpA binding motifs. A key morphological regulator, AdpA was shown to specifically bind these motifs by electrophoretic mobility shift assay. An adpA disruption mutant exhibited increased wblA transcription, suggesting that AdpA negatively regulates wblA transcription in S. coelicolor.

Identification and Biotechnological Application of Novel Regulatory Genes Involved in Streptomyces Polyketide Overproduction through Reverse Engineering Strategy

Polyketide belongs to a family of abundant natural products typically produced by the filamentous soil bacteria Streptomyces. Similar to the biosynthesis of most secondary metabolites produced in the Streptomyces species, polyketide compounds are synthesized through tight regulatory networks in the cell, and thus extremely low levels of polyketides are typically observed in wild-type strains. Although many Streptomyces polyketides and their derivatives have potential to be used as clinically important pharmaceutical drugs, traditional strain improvement strategies such as random recursive mutagenesis have long been practiced with little understanding of the molecular basis underlying enhanced polyketide production. Recently, identifying, understanding, and applying a novel polyketide regulatory system identified from various Omics approaches, has become an important tool for rational Streptomyces strain improvement. In this paper, DNA microarray-driven reverse engineering efforts for improving titers of polyketides are briefly summarized, primarily focusing on our recent results of identification and application of novel global regulatory genes such as wblA, SCO1712, and SCO5426 in Streptomyces species. Sequential targeted gene manipulation involved in polyketide biosynthetic reguation synergistically provided an efficient and rational strategy for Streptomyces strain improvement. Moreover, the engineered regulation-optimized Streptomyces mutant strain was further used as a surrogate host for heterologous expression of polyketide pathway.

Minimal polyketide pathway expression in an actinorhodin cluster-deleted and regulation-stimulated Streptomyces coelicolor

Along with traditional random mutagenesis-driven strain improvement, cloning and heterologous expression of Streptomyces secondary metabolite gene clusters have become an attractive complementary approach to increase its production titer, of which regulation is typically under tight control via complex multiple regulatory networks present in a metabolite low-producing wild-type strain. In this study, we generated a polyketide non-producing strain by deleting the entire actinorhodin cluster from the chromosome of a previously generated S. coelicolor mutant strain, which was shown to stimulate actinorhodin biosynthesis through deletion of two antibiotic downregulators as well as a polyketide precursor flux downregulator (Kim et al. in Appl Environ Microbiol 77:1872–1877, 2011). Using this engineered S. coelicolor mutant strain as a surrogate host, a model minimal polyketide pathway for aloesaponarin II, an actinorhodin shunt product, was cloned in a high-copy conjugative plasmid, followed by functional pathway expression and quantitative metabolite analysis. Aloesaponarin II production was detected only in the presence of a pathway-specific regulatory gene, actII-ORF4, and its production level was the highest in the actinorhodin cluster-deleted and downregulator-deleted mutant strain, implying that this engineered polyketide pathway-free and regulation-optimized S. coelicolor mutant strain could be used as a general surrogate host for efficient expression of indigenous or foreign polyketide pathways derived from diverse actinomycetes in nature.