Ribosomal engineering is a technique that can improve the biosynthesis of secondary metabolites in the antibiotics-resistant mutants by attacking the bacterial RNA polymerase or ribosome units using the corresponding antibiotics. Ribosomal engineering can be used to discover and increase the production of valuable bioactive secondary metabolites from almost all actinomycetes strains regardless of their genetic accessibility. As a consequence, ribosomal engineering has been widely applied to genome mining and production optimization of secondary metabolites in actinomycetes. To date, more than a dozen of new molecules were discovered and production of approximately 30 secondary metabolites were enhanced using actinomycetes mutant strains generated by ribosomal engineering. This review summarized the mechanism, development, and protocol of ribosomal engineering, highlighting the application of ribosomal engineering in actinomycetes, with the aim to facilitate future development of ribosomal engineering and discovery of actinomycetes secondary metabolites.
Actinobacteria/metabolism* ; Actinomyces/genetics* ; Anti-Bacterial Agents/metabolism* ; Multigene Family ; Ribosomes/genetics*

In recent years, two novel proteins in the ribosomes of mycobacteria have been discovered by cryo-electron microscopy. The protein bS22 is located near the decoding center of the 30S subunit, and the protein bL37 is located near the peptidyl transferase center of the 50S subunit. Since these two proteins bind to conserved regions of the ribosome targeted by antibiotics, it is speculated that they might affect the binding of related drugs to these targets. Therefore, we knocked out the genes encoding these two proteins in wild-type Mycolicibacterium smegmatis mc²155 through homologous recombination, and then determined the growth curves of these mutants and their sensitivity to related antibiotics. The results showed that compared with the wild-type strain, the growth rate of these two mutants did not change significantly. However, mutant ΔbS22 showed increased sensitivity to capreomycin, kanamycin, amikacin, streptomycin, gentamicin, paromomycin, and hygromycin B, while mutant ΔbL37 showed increased sensitivity to linezolid. These changes in antibiotics sensitivity were restored by gene complementation. This study hints at the possibility of using ribosomal proteins bS22 and bL37 as targets for drug design.
Anti-Bacterial Agents/pharmacology* ; Cryoelectron Microscopy ; Mycobacterium/genetics* ; Ribosomal Proteins/genetics* ; Ribosomes/metabolism*

Carrimycin (CAM) is a new antibiotics with isovalerylspiramycins (ISP) as its major components. It is produced by Streptomyces spiramyceticus integrated with a heterogenous 4″-O-isovaleryltransferase gene (ist). However, the present CAM producing strain carries two resistant gene markers, which makes it difficult for further genetic manipulation. In addition, isovalerylation of spiramycin (SP) could be of low efficiency as the ist gene is located far from the SP biosynthesis gene cluster. In this study, ist and its positive regulatory gene acyB2 were inserted into the downstream of orf54 gene neighboring to SP biosynthetic gene cluster in Streptomyces spiramyceticus 1941 by using the CRISPR-Cas9 technique. Two new markerless CAM producing strains, 54IA-1 and 54IA-2, were obtained from the homologous recombination and plasmid drop-out. Interestingly, the yield of ISP in strain 54IA-2 was much higher than that in strain 54IA-1. Quantitative real-time PCR assay showed that the ist, acyB2 and some genes associated with SP biosynthesis exhibited higher expression levels in strain 54IA-2. Subsequently, strain 54IA-2 was subjected to rifampicin (RFP) resistance selection for obtaining high-yield CAM mutants by ribosome engineering. The yield of ISP in mutants resistant to 40 μg/mL RFP increased significantly, with the highest up to 842.9 μg/mL, which was about 6 times higher than that of strain 54IA-2. Analysis of the sequences of the rpoB gene of these 7 mutants revealed that the serine at position 576 was mutated to alanine existed in each sequenced mutant. Among the mutants carrying other missense mutations, strain RFP40-6-8 which carries a mutation of glutamine (424) to leucine showed the highest yield of ISP. In conclusion, two markerless novel CAM producing strains, 54IA-1 and 54IA-2, were successfully developed by using CRISPR-Cas9 technique. Furthermore, a novel CAM high-yielding strain RFP40-6-8 was obtained through ribosome engineering. This study thus demonstrated a useful combinatory approach for improving the production of CAM.
CRISPR-Cas Systems/genetics* ; Genetic Engineering ; Ribosomes ; Spiramycin ; Streptomyces/genetics*

Cryoelectron Microscopy ; Mycobacterium smegmatis ; genetics ; ultrastructure ; RNA, Ribosomal ; ultrastructure ; Ribosomal Proteins ; genetics ; isolation & purification ; Ribosomes ; genetics ; ultrastructure

Under different red (R):blue (B) photon flux ratios, the growth performance of rapeseed (Brassica napus L.) is significantly different. Rapeseed under high R ratios shows shade response, while under high B ratios it shows sun-type morphology. Rapeseed under monochromatic red or blue light is seriously stressed. Transcriptomic and proteomic methods were used to analyze the metabolic pathway change of rapeseed (cv. "Zhongshuang 11") leaves under different R:B photon flux ratios (including 100R:0B%, 75R:25B%, 25R:75B%, and 0R:100B%), based on digital gene expression (DGE) and two-dimensional gel electrophoresis (2-DE). For DGE analysis, 2054 differentially expressed transcripts (|log₂(fold change)|≥1, q<0.005) were detected among the treatments. High R ratios (100R:0B% and 75R:25B%) enhanced the expression of cellular structural components, mainly the cell wall and cell membrane. These components participated in plant epidermis development and anatomical structure morphogenesis. This might be related to the shade response induced by red light. High B ratios (25R:75B% and 0R:100B%) promoted the expression of chloroplast-related components, which might be involved in the formation of sun-type chloroplast induced by blue light. For 2-DE analysis, 37 protein spots showed more than a 2-fold difference in expression among the treatments. Monochromatic light (ML; 100R:0B% and 0R:100B%) stimulated accumulation of proteins associated with antioxidation, photosystem II (PSII), DNA and ribosome repairs, while compound light (CL; 75R:25B% and 25R:75B%) accelerated accumulation of proteins associated with carbohydrate, nucleic acid, amino acid, vitamin, and xanthophyll metabolisms. These findings can be useful in understanding the response mechanisms of rapeseed leaves to different R:B photon flux ratios.
Brassica napus/radiation effects* ; Brassica rapa/radiation effects* ; Carbon/chemistry* ; Chloroplasts/radiation effects* ; Computational Biology ; Electrophoresis, Gel, Two-Dimensional ; Gene Expression Regulation, Plant/radiation effects* ; Image Processing, Computer-Assisted ; Light ; Mass Spectrometry ; Metabolic Networks and Pathways ; Nitrogen/chemistry* ; Photons ; Photosystem II Protein Complex/genetics* ; Plant Leaves/radiation effects* ; Plant Proteins/genetics* ; Proteome ; Ribosomes ; Transcription, Genetic ; Transcriptome

Through introducing mutations into ribosomes by obtaining spontaneous drug resistance of microorganisms, ribosome engineering technology is an effective approach to develop mutant strains that overproduce secondary metabolites. In this study, ribosome engineering was used to improve the yield of butenyl-spinosyns produced by Saccharopolyspora pogona by screening streptomycin resistant mutants. The yields of butenyl-spinosyns were then analyzed and compared with the parent strain. Among the mutants, S13 displayed the greatest increase in the yield of butenyl-spinosyns, which was 1.79 fold higher than that in the parent strain. Further analysis of the metabolite profile of S13 by mass spectrometry lead to the discovery of Spinosyn α1, which was absent from the parent strain. DNA sequencing showed that there existed two point mutations in the conserved regions of rpsL gene which encodes ribosomal protein S12 in S13. The mutations occurred a C to A and a C to T transversion mutations occurred at nucleotide pair 314 and 320 respectively, which resulted in the mutations of Proline (105) to Gultamine and Alanine (107) to Valine. It also demonstrated that S13 exhibited genetic stability even after five passages.
Genetic Engineering ; Macrolides ; metabolism ; Point Mutation ; Ribosomal Proteins ; genetics ; Ribosomes ; metabolism ; Saccharopolyspora ; metabolism

OBJECTIVETo re-analyze the data published in order to explore plausible biological pathways that can be used to explain the anti-aging effect of curcumin.

METHODSMicroarray data generated from other study aiming to investigate effect of curcumin on extending lifespan of Drosophila melanogaster were further used for pathway prediction analysis. The differentially expressed genes were identified by using GeneSpring GX with a criterion of 3.0-fold change. Two Cytoscape plugins including BisoGenet and molecular complex detection (MCODE) were used to establish the protein-protein interaction (PPI) network based upon differential genes in order to detect highly connected regions. The function annotation clustering tool of Database for Annotation, Visualization and Integrated Discovery (DAVID) was used for pathway analysis.

RESULTSA total of 87 genes expressed differentially in D. melanogaster melanogaster treated with curcumin were identified, among which 50 were up-regulated significantly and 37 were remarkably down-regulated in D. melanogaster melanogaster treated with curcumin. Based upon these differential genes, PPI network was constructed with 1,082 nodes and 2,412 edges. Five highly connected regions in PPI networks were detected by MCODE algorithm, suggesting anti-aging effect of curcumin may be underlined through five different pathways including Notch signaling pathway, basal transcription factors, cell cycle regulation, ribosome, Wnt signaling pathway, and p53 pathway.

CONCLUSIONGenes and their associated pathways in D. melanogaster melanogaster treated with anti-aging agent curcumin were identified using PPI network and MCODE algorithm, suggesting that curcumin may be developed as an alternative therapeutic medicine for treating aging-associated diseases.

Aging ; drug effects ; genetics ; Animals ; Cell Cycle ; drug effects ; genetics ; Curcumin ; pharmacology ; Drosophila Proteins ; genetics ; metabolism ; Drosophila melanogaster ; drug effects ; genetics ; Gene Expression Regulation ; drug effects ; Gene Regulatory Networks ; drug effects ; Genes, Insect ; Protein Biosynthesis ; drug effects ; genetics ; Protein Interaction Maps ; drug effects ; genetics ; Receptors, Notch ; genetics ; metabolism ; Ribosomes ; drug effects ; metabolism ; Signal Transduction ; drug effects ; genetics ; Tumor Suppressor Protein p53 ; metabolism ; Wnt Signaling Pathway ; drug effects ; genetics

Various artificial riboswitches have been constructed by utilization of designed aptamers or by modification of natural riboswitch systems, because they can regulate gene expression in a highly efficient, precise and fast way, and promise to supply simple cis-acting, modular, and non-immunogenic system for use in future gene therapy applications. In this review, we present an overview of currently available technologies to design and select engineered riboswitches, and discuss some possible technologies that would allow them highly responsive to non-natural ligands, and dynamic control of gene expression in mammalian cells. Though how to bring custom-designed riboswitches as a novel and versatile tool box to gene control system is still a great challenge, the combination of structure-activity relationship information, computer based molecular design, in vitro selection, and high-through screening will serve as powerful tools for further development of riboswitch based gene regulatory systems.
Aptamers, Nucleotide ; genetics ; Gene Expression Regulation ; genetics ; Genetic Engineering ; Genetic Therapy ; Humans ; Protein Biosynthesis ; RNA, Catalytic ; chemistry ; genetics ; Ribosomes ; genetics ; Riboswitch ; genetics

We used ribosome engineering technology, with which antibiotic-resistant strains are resulted from mutations on microbial ribosome, to screen a high butanol-producing Clostridium strain. A novel mutant strain S3 with high butanol production and tolerance was obtained from the original Clostridium acetobutylicum L7 with the presence of mutagen of streptomycin. Butanol of 12.48 g/L and ethanol of 1.70 g/L were achieved in S3, 11.2% and 50%, respectively higher than the parent strain. The conversion rate of glucose to butanol increased from 0.19 to 0.22, and fermentation time was 9 h shorter. This caused an increase in butanol productivity by 30.5%, reaching 0.24 g/(Lh). The mutant butanol tolerance was increased from 12 g/L to 14 g/L, the viscosity of fermentation broth was dramatically decreased to 4 mPa/s, 60% lower than the parent strain. In addition, the genetic stability of mutant strain S3 was also favorable. These results demonstrate that ribosome engineering technology may be a promising process for developing high butanol-producing strains.
Butanols ; metabolism ; Clostridium acetobutylicum ; drug effects ; genetics ; metabolism ; Fermentation ; Genetic Engineering ; Mutation ; Recombinant Proteins ; biosynthesis ; genetics ; Ribosomes ; genetics ; Streptomycin ; pharmacology

This experimental study was aimed to construct the recombinant bisbicistronic eukaryotic expression vector containing endocrine and exocrine protein (EECP) gene associated with breast cancer and enhanced green fluorescent protein (EGFP) gene. And then we transfected it into breast cancer cells MCF-7 to detect the expression of EECP protein and study preliminary biological function of EECP gene. The EECP sequence was cloned to pBluescript II SK (+) plasmid. After restriction endonuclease reaction of pBluescript II SK(+) plasmid, the EECP fragment was cloned to pIRES2-EGFP vector forming a recombinant eukaryotic expression vector named pEECP-IRES2-EGFP. The potential vector was identified by restriction endonuclease digestion and sequencing. Correct plasmid was extracted and transfected into breast cancer cells MCF-7. The expression of EECP protein was detected by western blot analysis. Its biological function was studied by MTT and Flow-cytometry. It turns out that the recombinant eukaryotic expression vector containing EECP gene and EGFP gene was constructed successfully, and it could transfect MCF-7 cells efficiently. It can get higher expression of EECP protein and higher cell proliferation, thus providing an important and convenient tool for studying the function of EECP gene in vitro and in vivo.
Base Sequence ; Breast Neoplasms ; genetics ; pathology ; Female ; Genetic Vectors ; genetics ; Green Fluorescent Proteins ; biosynthesis ; genetics ; Humans ; MCF-7 Cells ; Molecular Sequence Data ; Proteins ; analysis ; genetics ; metabolism ; Recombinant Fusion Proteins ; biosynthesis ; genetics ; Ribosomes ; chemistry ; metabolism