Identification of genes encoding squalestatin S1 biosynthesis and in vitro production of new squalestatin analogues

ABSTRACTOne mechanism by which bacteria and fungi produce bioactive natural products is the use of nonribosomal peptide synthetases (NRPSs). Many NRPSs in bacteria require members of the MbtH-like protein (MLP) superfamily for their solubility or function. Although MLPs are known to interact with the adenylation domains of NRPSs, the role MLPs play in NRPS enzymology has yet to be elucidated. MLPs are nearly always encoded within the biosynthetic gene clusters (BGCs) that also code for the NRPSs that interact with the MLP. Here, we identify 50 orphan MLPs from diverse bacteria. An orphan MLP is one that is encoded by a gene that is not directly adjacent to genes predicted to be involved in nonribosomal peptide biosynthesis. We targeted the orphan MLP MXAN_3118 fromMyxococcus xanthusDK1622 for characterization. TheM. xanthusDK1622 genome contains 15 NRPS-encoding BGCs but only one MLP-encoding gene (MXAN_3118). We tested the hypothesis that MXAN_3118 interacts with one or more NRPS using a combination ofin vivoandin vitroassays. We determined that MXAN_3118 interacts with at least seven NRPSs from distinct BGCs. We show that one of these BGCs codes for NRPS enzymology that likely produces a valine-rich natural product that inhibits the clumping ofM. xanthusDK1622 in liquid culture. MXAN_3118 is the first MLP to be identified that naturally interacts with multiple NRPS systems in a single organism. The finding of an MLP that naturally interacts with multiple NRPS systems suggests it may be harnessed as a “universal” MLP for generating functional hybrid NRPSs.IMPORTANCEMbtH-like proteins (MLPs) are essential accessory proteins for the function of many nonribosomal peptide synthetases (NRPSs). We identified 50 MLPs from diverse bacteria that are coded by genes that are not located near any NRPS-encoding biosynthetic gene clusters (BGCs). We define these as orphan MLPs because their NRPS partner(s) is unknown. Investigations into the orphan MLP fromMyxococcus xanthusDK1622 determined that it interacts with NRPSs from at least seven distinct BGCs. Support for these MLP-NRPS interactions came from the use of a bacterial two-hybrid assay and copurification of the MLP with various NRPSs. The flexibility of this MLP to naturally interact with multiple NRPSs led us to hypothesize that this MLP may be used as a “universal” MLP during the construction of functional hybrid NRPSs.

Download Full-text

In Vitro CRISPR/Cas9 System for Efficient Targeted DNA Editing

mBio ◽

10.1128/mbio.01714-15 ◽

2015 ◽

Vol 6 (6) ◽

Cited By ~ 28

Author(s):

Yunkun Liu ◽

Weixin Tao ◽

Shishi Wen ◽

Zhengyuan Li ◽

Anna Yang ◽

...

Keyword(s):

Dna Polymerase ◽

Gene Clusters ◽

Specific Gene ◽

Dna Fragments ◽

Biosynthetic Gene ◽

Biosynthetic Gene Clusters ◽

Highly Efficient ◽

Dna Editing

ABSTRACT The clustered regularly interspaced short palindromic repeat (CRISPR)/CRISPR-associated protein 9 (Cas9) system, an RNA-guided nuclease for specific genome editing in vivo, has been adopted in a wide variety of organisms. In contrast, the in vitro application of the CRISPR/Cas9 system has rarely been reported. We present here a highly efficient in vitro CRISPR/Cas9-mediated editing (ICE) system that allows specific refactoring of biosynthetic gene clusters in Streptomyces bacteria and other large DNA fragments. Cleavage by Cas9 of circular pUC18 DNA was investigated here as a simple model, revealing that the 3′→5′ exonuclease activity of Cas9 generates errors with 5 to 14 nucleotides (nt) randomly missing at the editing joint. T4 DNA polymerase was then used to repair the Cas9-generated sticky ends, giving substantial improvement in editing accuracy. Plasmid pYH285 and cosmid 10A3, harboring a complete biosynthetic gene cluster for the antibiotics RK-682 and holomycin, respectively, were subjected to the ICE system to delete the rkD and homE genes in frame. Specific insertion of the ampicillin resistance gene (bla) into pYH285 was also successfully performed. These results reveal the ICE system to be a rapid, seamless, and highly efficient way to edit DNA fragments, and a powerful new tool for investigating and engineering biosynthetic gene clusters. IMPORTANCE Recent improvements in cloning strategies for biosynthetic gene clusters promise rapid advances in understanding and exploiting natural products in the environment. For manipulation of such biosynthetic gene clusters to generate valuable bioactive compounds, efficient and specific gene editing of these large DNA fragments is required. In this study, a highly efficient in vitro DNA editing system has been established. When combined with end repair using T4 DNA polymerase, Cas9 precisely and seamlessly catalyzes targeted editing, including in-frame deletion or insertion of the gene(s) of interest. This in vitro CRISPR editing (ICE) system promises a step forward in our ability to engineer biosynthetic pathways.

Download Full-text

Zn-dependent bifunctional proteases are responsible for leader peptide processing of class III lanthipeptides

Proceedings of the National Academy of Sciences ◽

10.1073/pnas.1815594116 ◽

2019 ◽

Vol 116 (7) ◽

pp. 2533-2538 ◽

Cited By ~ 23

Author(s):

Shaoming Chen ◽

Bing Xu ◽

Erquan Chen ◽

Jiaqi Wang ◽

Jingxia Lu ◽

...

Keyword(s):

Gene Clusters ◽

Leader Peptide ◽

Biosynthetic Gene ◽

Class Iii ◽

Biosynthetic Gene Clusters ◽

Peptide Processing ◽

Leader Peptides ◽

Biochemical Studies ◽

Modified Peptides

Lanthipeptides are an important subfamily of ribosomally synthesized and posttranslationally modified peptides, and the removal of their N-terminal leader peptides by a designated protease(s) is a key step during maturation. Whereas proteases for class I and II lanthipeptides are well-characterized, the identity of the protease(s) responsible for class III leader processing remains unclear. Herein, we report that the class III lanthipeptide NAI-112 employs a bifunctional Zn-dependent protease, AplP, with both endo- and aminopeptidase activities to complete leader peptide removal, which is unprecedented in the biosynthesis of lanthipeptides. AplP displays a broad substrate scope in vitro by processing a number of class III leader peptides. Furthermore, our studies reveal that AplP-like proteases exist in the genomes of all class III lanthipeptide-producing strains but are usually located outside the biosynthetic gene clusters. Biochemical studies show that AplP-like proteases are universally responsible for the leader removal of the corresponding lanthipeptides. In addition, AplP-like proteases are phylogenetically correlated with aminopeptidase N from Escherichia coli, and might employ a single active site to catalyze both endo- and aminopeptidyl hydrolysis. These findings solve the long-standing question as to the mechanism of leader peptide processing during class III lanthipeptide biosynthesis, and pave the way for the production and bioengineering of this class of natural products.

Download Full-text

Mining of Cyanobacterial Genomes Indicates That Plasmids Are Involved in the Production of Natural Products

10.21203/rs.3.rs-121751/v1 ◽

2020 ◽

Author(s):

Rafael Popin ◽

Danillo Alvarenga ◽

Raquel Castelo-Branco ◽

David Fewer ◽

Kaarina Sivonen

Keyword(s):

Natural Products ◽

Natural Product ◽

Biological Activities ◽

Gene Clusters ◽

Biosynthetic Pathways ◽

Biosynthetic Gene ◽

Biosynthetic Gene Clusters ◽

Chemical Structures ◽

Wide Range ◽

Genes Encoding

Abstract Background Microbial natural products have unique chemical structures and diverse biological activities. Cyanobacteria commonly possess a wide range of biosynthetic gene clusters to produce natural products. Several studies have mapped the distribution of natural product biosynthetic gene clusters in cyanobacterial genomes. However, little attention has been paid to natural product biosynthesis in plasmids. Some genes encoding cyanobacterial natural product biosynthetic pathways are believed to be dispersed by plasmids through horizontal gene transfer. Thus, we examined complete cyanobacterial genomes to assess if plasmids are involved in the production and dissemination of natural products by cyanobacteria.Results The 185 analyzed genomes possessed 1 to 42 gene clusters and an average of 10. In total, 1816 biosynthetic gene clusters were found. Approximately 95% of these clusters were present in chromosomes. The remaining 5% were present in plasmids, from which homologs of the biosynthetic pathways for aeruginosin, anabaenopeptin, ambiguine, cryptophycin, hassallidin, geosmin, and microcystin were manually curated. The cryptophycin pathway was previously described as active while the other gene cluster include all genes for biosynthesis. Approximately 12% of the 424 analyzed cyanobacterial plasmids contained homologs of genes involved in conjugation. Large plasmids, previously named as “chromids”, were also observed to be widespread in cyanobacteria. Sixteen cryptic natural product biosynthetic gene clusters and geosmin biosynthetic gene clusters were located in those mobile plasmids.Conclusion Homologues of genes involved in the production of toxins, protease inhibitors, odorous compounds, antimicrobials, antitumorals, and other unidentified natural products are located in cyanobacterial plasmids. Some of these plasmids are predicted to be conjugative. The present study provides in silico evidence that plasmids are involved in the distribution of natural product biosynthetic pathways in cyanobacteria.

Download Full-text

Distribution and diversity of dimetal-carboxylate halogenases in cyanobacteria

10.1101/2021.01.05.425448 ◽

2021 ◽

Author(s):

Nadia Eusebio ◽

Adriana Rego ◽

Nathaniel R. Glasser ◽

Raquel Castelo-Branco ◽

Emily P. Balskus ◽

...

Keyword(s):

Genome Mining ◽

Gene Clusters ◽

Culture Collection ◽

Acid Activation ◽

Type I ◽

Biosynthetic Gene ◽

Biosynthetic Gene Clusters ◽

Genes Encoding ◽

Fatty Acid Activation ◽

Biological Catalysis

AbstractHalogenation is a recurring feature in natural products, especially those from marine organisms. The selectivity with which halogenating enzymes act on their substrates renders halogenases interesting targets for biocatalyst development. Recently, CylC – the first predicted dimetal-carboxylate halogenase to be characterized – was shown to regio- and stereoselectively install a chlorine atom onto an unactivated carbon center during cylindrocyclophane biosynthesis. Homologs of CylC are also found in other characterized cyanobacterial secondary metabolite biosynthetic gene clusters. Due to its novelty in biological catalysis, selectivity and ability to perform C-H activation, this halogenase class is of considerable fundamental and applied interest. However, little is known regarding the diversity and distribution of these enzymes in bacteria. In this study, we used both genome mining and PCR-based screening to explore the genetic diversity and distribution of CylC homologs. While we found non-cyanobacterial homologs of these enzymes to be rare, we identified a large number of genes encoding CylC-like enzymes in publicly available cyanobacterial genomes and in our in-house culture collection of cyanobacteria. Genes encoding CylC homologs are widely distributed throughout the cyanobacterial tree of life, within biosynthetic gene clusters of distinct architectures. Their genomic contexts feature a variety of biosynthetic partners, including fatty-acid activation enzymes, type I or type III polyketide synthases, dialkylresorcinol-generating enzymes, monooxygenases or Rieske proteins. Our study also reveals that dimetal-carboxylate halogenases are among the most abundant types of halogenating enzymes in the phylum Cyanobacteria. This work will help to guide the search for new halogenating biocatalysts and natural product scaffolds.Data statementAll supporting data and methods have been provided within the article or through a Supplementary Material file, which includes 14 supplementary figures and 4 supplementary tables.

Download Full-text

Caries-Associated Biosynthetic Gene Clusters in Streptococcus mutans

Journal of Dental Research ◽

10.1177/0022034520914519 ◽

2020 ◽

Vol 99 (8) ◽

pp. 969-976 ◽

Cited By ~ 1

Author(s):

S.S. Momeni ◽

S.M. Beno ◽

J.L. Baker ◽

A. Edlund ◽

T. Ghazal ◽

...

Keyword(s):

Streptococcus Mutans ◽

Genome Sequencing ◽

Large Scale ◽

Biological Activities ◽

Gene Clusters ◽

Biosynthetic Gene ◽

Biosynthetic Gene Clusters ◽

Microbial Diseases ◽

High Caries Risk

Early childhood caries (ECC) is a chronic disease affecting the oral health of children globally. This disease is multifactorial, but a primary factor is cariogenic microorganisms such as Streptococcus mutans. Biosynthetic gene clusters (BGCs) encode small molecules with diverse biological activities that influence the development of many microbial diseases, including caries. The purpose of this study was to identify BGCs in S. mutans from a high-caries risk study population using whole-genome sequencing and assess their association with ECC. Forty representative S. mutans isolates were selected for genome sequencing from a large-scale epidemiological study of oral microbiology and dental caries in children from a localized Alabama population. A total of 252 BGCs were identified using the antiSMASH BGC-mining tool. Three types of BGCs identified herein—butyrolactone-like, ladderane-like, and butyrolactone-ladderane-like hybrid (BL-BGC)—have not been reported in S. mutans. These 3 BGCs were cross-referenced against public transcriptomics data, and were found to be highly expressed in caries subjects. Furthermore, based on a polymerase chain reaction screening for core BL genes, 93% of children with BL-BGC had ECC. The role of BL-BGC was further investigated by examining cariogenic traits and strain fitness in a deletion mutant using in vitro biofilm models. Deletion of the BL-BGC significantly increased biofilm pH as compared to the parent strain, while other virulence and fitness properties remained unchanged. Intriguingly, BL-BGC containing strains produced more acid, a key cariogenic feature, and less biofilm than the model cariogenic strain S. mutans UA159, suggesting the importance of this BL-BGC in S. mutans–mediated cariogenesity. The structure of any BL-BGC derived metabolites, their functions, and mechanistic connection with acid production remain to be elucidated. Nevertheless, this study is the first to report the clinical significance of a BL-BGC in S. mutans. This study also highlights pangenomic diversity, which is likely to affect phenotype and virulence.

Download Full-text

A Systematic Analysis of Mosquito-Microbiome Biosynthetic Gene Clusters Reveals Antimalarial Siderophores that Reduce Mosquito Reproduction Capacity

10.1101/2020.04.09.034280 ◽

2020 ◽

Author(s):

Jack G. Ganley ◽

Ashmita Pandey ◽

Kayla Sylvester ◽

Kuan-Yi Lu ◽

Maria Toro-Moreno ◽

...

Keyword(s):

Small Molecules ◽

Genetic Manipulation ◽

Control Strategies ◽

Gene Clusters ◽

Blood Feeding ◽

Biosynthetic Gene ◽

Biosynthetic Gene Clusters ◽

Systematic Analysis ◽

Depth Analysis

ABSTRACTAdvances in infectious disease control strategies through genetic manipulation of insect microbiomes have heightened interest in microbially produced small molecules within mosquitoes. Herein, 33 mosquito-associated bacterial genomes were mined and over 700 putative biosynthetic gene clusters (BGCs) were identified, 135 of which belong to known classes of BGCs. After an in-depth analysis of the 135 BGCs, iron-binding siderophores were chosen for further investigation due to their high abundance and well-characterized bioactivities. Through various metabolomic strategies, eight siderophore scaffolds were identified in six strains of mosquito-associated bacteria. Among these, serratiochelin A and pyochelin were found to reduce female Anopheles gambiae overall fecundity likely by lowering their blood feeding rate. Serratiochelin A and pyochelin were further found to inhibit the Plasmodium parasite asexual blood and liver stages in vitro. Our work supplies a bioinformatic resource for future mosquito microbiome studies and highlights an understudied source of bioactive small molecules.

Download Full-text

Presence, Mode of Action, and Application of Pathway Specific Transcription Factors in Aspergillus Biosynthetic Gene Clusters

International Journal of Molecular Sciences ◽

10.3390/ijms22168709 ◽

2021 ◽

Vol 22 (16) ◽

pp. 8709

Author(s):

Wenjie Wang ◽

Yuchao Yu ◽

Nancy P. Keller ◽

Pinmei Wang

Keyword(s):

Transcription Factor ◽

Secondary Metabolites ◽

Gene Clusters ◽

Fungal Species ◽

Relative Location ◽

Biosynthetic Gene ◽

Biosynthetic Gene Clusters ◽

Genes Encoding ◽

Depth View ◽

Fungal Secondary Metabolites

Fungal secondary metabolites are renowned toxins as well as valuable sources of antibiotics, cholesterol-lowering drugs, and immunosuppressants; hence, great efforts were levied to understand how these compounds are genetically regulated. The genes encoding for the enzymes required for synthesizing secondary metabolites are arranged in biosynthetic gene clusters (BGCs). Often, BGCs contain a pathway specific transcription factor (PSTF), a valuable tool in shutting down or turning up production of the BGC product. In this review, we present an in-depth view of PSTFs by examining over 40 characterized BGCs in the well-studied fungal species Aspergillus nidulans and Aspergillus fumigatus. Herein, we find BGC size is a predictor for presence of PSTFs, consider the number and the relative location of PSTF in regard to the cluster(s) regulated, discuss the function and the evolution of PSTFs, and present application strategies for pathway specific activation of cryptic BGCs.

Download Full-text

Distribution and diversity of dimetal-carboxylate halogenases in cyanobacteria

BMC Genomics ◽

10.1186/s12864-021-07939-x ◽

2021 ◽

Vol 22 (1) ◽

Author(s):

Nadia Eusebio ◽

Adriana Rego ◽

Nathaniel R. Glasser ◽

Raquel Castelo-Branco ◽

Emily P. Balskus ◽

...

Keyword(s):

Genome Mining ◽

Gene Clusters ◽

Culture Collection ◽

Type I ◽

Biosynthetic Gene ◽

Biosynthetic Gene Clusters ◽

Rieske Proteins ◽

Number Of Genes ◽

Genes Encoding ◽

Biological Catalysis

Abstract Background Halogenation is a recurring feature in natural products, especially those from marine organisms. The selectivity with which halogenating enzymes act on their substrates renders halogenases interesting targets for biocatalyst development. Recently, CylC – the first predicted dimetal-carboxylate halogenase to be characterized – was shown to regio- and stereoselectively install a chlorine atom onto an unactivated carbon center during cylindrocyclophane biosynthesis. Homologs of CylC are also found in other characterized cyanobacterial secondary metabolite biosynthetic gene clusters. Due to its novelty in biological catalysis, selectivity and ability to perform C-H activation, this halogenase class is of considerable fundamental and applied interest. The study of CylC-like enzymes will provide insights into substrate scope, mechanism and catalytic partners, and will also enable engineering these biocatalysts for similar or additional C-H activating functions. Still, little is known regarding the diversity and distribution of these enzymes. Results In this study, we used both genome mining and PCR-based screening to explore the genetic diversity of CylC homologs and their distribution in bacteria. While we found non-cyanobacterial homologs of these enzymes to be rare, we identified a large number of genes encoding CylC-like enzymes in publicly available cyanobacterial genomes and in our in-house culture collection of cyanobacteria. Genes encoding CylC homologs are widely distributed throughout the cyanobacterial tree of life, within biosynthetic gene clusters of distinct architectures (combination of unique gene groups). These enzymes are found in a variety of biosynthetic contexts, which include fatty-acid activating enzymes, type I or type III polyketide synthases, dialkylresorcinol-generating enzymes, monooxygenases or Rieske proteins. Our study also reveals that dimetal-carboxylate halogenases are among the most abundant types of halogenating enzymes in the phylum Cyanobacteria. Conclusions Our data show that dimetal-carboxylate halogenases are widely distributed throughout the Cyanobacteria phylum and that BGCs encoding CylC homologs are diverse and mostly uncharacterized. This work will help guide the search for new halogenating biocatalysts and natural product scaffolds.

Download Full-text

Impact on Multiple Antibiotic Pathways Reveals MtrA as a Master Regulator of Antibiotic Production in Streptomyces spp. and Potentially in Other Actinobacteria

Applied and Environmental Microbiology ◽

10.1128/aem.01201-20 ◽

2020 ◽

Vol 86 (20) ◽

Cited By ~ 1

Author(s):

Yanping Zhu ◽

Peipei Zhang ◽

Jing Zhang ◽

Jiao Wang ◽

Yinhua Lu ◽

...

Keyword(s):

Antibiotic Production ◽

Gene Clusters ◽

Type I ◽

Biosynthetic Gene ◽

Regulatory Factor ◽

Biosynthetic Gene Clusters ◽

Master Regulator ◽

Altered Expression ◽

Content Type

ABSTRACT Regulation of antibiotic production by Streptomyces is complex. We report that the response regulator MtrA is a master regulator for antibiotic production in Streptomyces. Deletion of MtrA altered production of actinorhodin, undecylprodigiosin, calcium-dependent antibiotic, and the yellow-pigmented type I polyketide and resulted in altered expression of the corresponding gene clusters in S. coelicolor. Integrated in vitro and in vivo analyses identified MtrA binding sites upstream of cdaR, actII-orf4, and redZ and between cpkA and cpkD. MtrA disruption also led to marked changes in chloramphenicol and jadomycin production and in transcription of their biosynthetic gene clusters (cml and jad, respectively) in S. venezuelae, and MtrA sites were identified within cml and jad. MtrA also recognized predicted sites within the avermectin and oligomycin pathways in S. avermitilis and in the validamycin gene cluster of S. hygroscopicus. The regulator GlnR competed for several MtrA sites and impacted production of some antibiotics, but its effects were generally less dramatic than those of MtrA. Additional potential MtrA sites were identified in a range of other antibiotic biosynthetic gene clusters in Streptomyces species and other actinobacteria. Overall, our study suggests a universal role for MtrA in antibiotic production in Streptomyces and potentially other actinobacteria. IMPORTANCE In natural environments, the ability to produce antibiotics helps the producing host to compete with surrounding microbes. In Streptomyces, increasing evidence suggests that the regulation of antibiotic production is complex, involving multiple regulatory factors. The regulatory factor MtrA is known to have additional roles beyond controlling development, and using bioassays, transcriptional studies, and DNA-binding assays, our study identified MtrA recognition sequences within multiple antibiotic pathways and indicated that MtrA directly controls the production of multiple antibiotics. Our analyses further suggest that this role of MtrA is evolutionarily conserved in Streptomyces species, as well as in other actinobacterial species, and also suggest that MtrA is a major regulatory factor in antibiotic production and in the survival of actinobacteria in nature.

Download Full-text