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L-Asparaginase (ASNase) has proved its use in medical and food industries. Sequence-based screening showed the thermophilic Streptomyces strain Streptomyces thermoluteus subsp. fuscus NBRC 14270 (14270 ASNase) to positive against predicted ASNase primary sequences. The 14270 ASNase gene and four L-asparaginase genes from Streptomyces coelicolor, Streptomyces avermitilis, and Streptomyces griseus (SGR ASNase) were expressed in Streptomyces lividans using a hyperexpression vector: pTONA5a. Among those genes, only 14270 ASNase and SGR ASNase were successful for overexpression and detected in culture supernatants without an artificial signal peptide. Comparison of the two Streptomyces enzymes described above demonstrated that 14270 ASNase was superior to SGR ASNase in terms of optimum temperature, thermal stability, and pH stability.

The rising use of plastic results in an appalling amount of waste which is scattered into the environment. One of these plastics is PET which is mainly used for bottles. We have identified and characterized an esterase from Streptomyces , annotated as LipA, which can efficiently degrade the PET-derived oligomer BHET. The Streptomyces coelicolor Sc LipA enzyme exhibits varying sequence similarity to several BHETase/PETase enzymes, including Is PETase, Tf Cut2, LCC, PET40 and PET46. Of 96 Streptomyces strains, 18% were able to degrade BHET via one of three variants of LipA, named Sc LipA , S2 LipA and S92 LipA. SclipA was deleted from S. coelicolor resulting in reduced BHET degradation. Overexpression of all LipA variants significantly enhanced BHET degradation. All variants were expressed in E. coli for purification and biochemical analysis. The optimum conditions were determined as pH 7 and 25 °C for all variants. The activity on BHET and amorphous PET film was investigated. S 2LipA efficiently degraded BHET and caused roughening and indents on the surface of PET films, comparable to the activity of previously described Tf Cut2 under the same conditions. The abundance of the S2 LipA variant in Streptomyces suggests an environmental advantage towards the degradation of more polar substrates including these polluting plastics. A comprehensive study on the identification and characterization of PETase-like enzymes in Streptomyces indicates the presence of strain specific variants of a conserved BHET-degrading esterase.

With the impending increase of the world population by 2050, more activities have been directed toward the improvement of crop yield and a safe environment. The need for chemical-free agricultural practices is becoming eminent due to the effects of these chemicals on the environment and human health. Actinomycetes constitute a significant percentage of the soil microbial community. The Streptomyces genus, which is the most abundant and arguably the most important actinomycetes, is a good source of bioactive compounds, antibiotics, and extracellular enzymes. These genera have shown over time great potential in improving the future of agriculture. This review highlights and buttresses the agricultural importance of Streptomyces through its biocontrol and plant growth-promoting activities. These activities are highlighted and discussed in this review. Some biocontrol products from this genus are already being marketed while work is still ongoing on this productive genus. Compared to more focus on its biocontrol ability, less work has been done on it as a biofertilizer until recently. This genus is as efficient as a biofertilizer as it is as a biocontrol.

Actinobacteria, a large group of Gram-positive bacteria, secrete a wide range of extracellular enzymes involved in the degradation of organic compounds and biopolymers including the ubiquitous aminopolysaccharides chitin and chitosan. While chitinolytic enzymes are distributed in all kingdoms of life, actinobacteria are recognized as particularly good decomposers of chitinous material and several members of this taxon carry impressive sets of genes dedicated to chitin and chitosan degradation. Degradation of these polymers in actinobacteria is dependent on endo- and exo-acting hydrolases as well as lytic polysaccharide monooxygenases. Actinobacterial chitinases and chitosanases belong to nine major families of glycosyl hydrolases that share no sequence similarity. In this paper, the distribution of chitinolytic actinobacteria within different ecosystems is examined and their chitinolytic machinery is described and compared to those of other chitinolytic organisms.

The bacteriostatic natural product enterocin from the marine microbe \"Streptomyces maritimus\" has an unprecedented carbon skeleton that is derived from an aromatic polyketide biosynthetic pathway. Its caged tricyclic, nonaromatic core is derived from a linear poly-β-ketide precursor that formally undergoes a Favorskii-like oxidative rearrangement. In vivo characterization of the gene encM through mutagenesis and heterologous biosynthesis demonstrated that its protein product not only is solely responsible for the oxidative C-C rearrangement, but also facilitates two aldol condensations plus two heterocycle forming reactions. In total, at least five chiral centers and four rings are generated by this multifaceted flavoprotein. Heterologous expression of the enterocin biosynthesis genes encABCDLMN in Streptomyces lividans resulted in the formation of the rearranged metabolite desmethyl-5-deoxyenterocin and the shunt products wailupemycins D-G. Addition of the methyltransferase gene encK, which was previously proposed through mutagenesis to additionally assist EncM in the Favorskii rearrangement, shifted the production to the O-methyl derivative 5-dexyenterocin. The O-methyltransferase EncK seems to be specific for the pyrone ring of enterocin, because bicyclic polyketides bearing pyrone rings are not methylated in vivo. Expression of encM with different combinations of homologous actinorhodin biosynthesis genes did not result in the production of oxidatively rearranged enterocin-actinorhodin hybrid compounds as anticipated, suggesting that wild-type EncM may be specific for its endogenous type II polyketide synthase or for benzoyl-primed polyketide precursors.

Type I polyketide synthases (T1PKSs) are one of the most extensively studied PKSs, which can act either iteratively or via an assembly-line mechanism. Domains in the T1PKSs can readily be predicted by computational tools based on their highly conserved sequences. However, to distinguish between iterative and noniterative at the module level remains an overwhelming challenge, which may account for the seemingly biased distribution of T1PKSs in fungi and bacteria: small iterative monomodular T1PKSs that are responsible for the enormously diverse fungal natural products exist almost exclusively in fungi. Here we report the discovery of iterative T1PKSs that are unexpectedly both abundant and widespread in Streptomyces. Seven of 11 systematically selected T1PKS monomodules from monomodular T1PKS biosynthetic gene clusters (BGCs)were experimentally confirmed to be iteratively acting, synthesizing diverse branched/nonbranched linear intermediates, and two of them produced bioactive allenic polyketides and citreodiols as end products, respectively. This study indicates the huge potential of iterative T1PKS BGCs from streptomycetes in the discovery of novel polyketides.

In this review, we chart the major milestones in the research progress on the DyP-type peroxidase family over the past decade. Though mainly distributed among bacteria and fungi, this family actually exhibits more widespread diversity. Advanced tertiary structural analyses have revealed common and different features among members of this family. Notably, the catalytic cycle for the peroxidase activity of DyP-type peroxidases appears to be different from that of other ubiquitous heme peroxidases. DyP-type peroxidases have also been reported to possess activities in addition to peroxidase function, including hydrolase or oxidase activity. They also show various cellular distributions, functioning not only inside cells but also outside of cells. Some are also cargo proteins of encapsulin. Unique, noteworthy functions include a key role in life-cycle switching in Streptomyces and the operation of an iron transport system in Staphylococcus aureus, Bacillus subtilis and Escherichia coli. We also present several probable physiological roles of DyP-type peroxidases that reflect the widespread distribution and function of these enzymes. Lignin degradation is the most common function attributed to DyP-type peroxidases, but their activity is not high compared with that of standard lignin-degrading enzymes. From an environmental standpoint, degradation of natural antifungal anthraquinone compounds is a specific focus of DyP-type peroxidase research. Considered in its totality, the DyP-type peroxidase family offers a rich source of diverse and attractive materials for research scientists.

Streptomyces are renowned in pharmaceutical and medical fields for their ability to produce antibiotics and other bioactive secondary metabolites. In order to reduce industrial production costs, it is crucial to find suitable and cheaper raw materials as carbon and nitrogen sources for microbial growth processes. This study investigated the substrate preference of Streptomyces sp. F-3 using functional proteomic analysis. Streptomyces sp. F-3 exhibited varying degradation and utilization rates for different nitrogen source. The results indicated that the strain F-3 could not efficiently degrade intact globular proteins, but preferred to degrade peptone or protein hydrolysate, especially for waste-yeast. The strain F-3 could utilize waste-yeast to grow rapidly and produced a large amount of extracellular protein. The substrate-binding patterns of three S8 proteases secreted by Streptomyces sp. F-3 determined the nitrogen source degradation preference of the strain. In addition, the strain F-3 could secrete large amounts of β-glucanase and chitinase to utilize cell wall polysaccharides. Thus, waste-yeast, rich in peptone, β-glucan, and chitin, could be the superior substrate for culturing Streptomyces. This study not only broadens the application scenarios for waste-yeast, but also provides valuable insights for rapid and cost-effective industrial microbial cultivation. Key points The substrate preference of Streptomyces sp. F-3 was analyzed by integrative omics. Structural omics revealed the hydrolysis specificity of S8 proteases from F-3. Waste-yeast served as the superior substrate for culturing Streptomyces .

The DagA product of Streptomyces coelicolor is an agarase with a primary translation product (35 kDa) of 309 amino acids, including a 30-amino acid signal peptide. Although dagA expression in Streptomyces lividans under the control of its own set of promoters was previously reported, its enzymatic properties have never been elucidated. To develop an improved expression system for dagA, three types of strong promoters for the Streptomyces host were linked to dagA, and their efficiencies in DagA production were compared in S. lividans TK24. All of the transformants with dagA grew at improved rates and produced larger amounts of DagA in the modified R2YE medium containing 0.5% agar as the sole carbon source. Of the three transformants, the S. lividans TK24/pUWL201-DagA (ermE promoter) produced the highest agarase activity (A ^sub 540^=4.24), and even the S. lividans TK24/pHSEV1-DagA (tipA promoter) and S. lividans TK24/pWHM3-DagA (sprT promoter) produced higher agarase activity (A ^sub 540^=0.24 and 0.12, respectively) than the control (A ^sub 540^=0.01) in the modified R2YE medium. The mature form of DagA protein (32 kDa) was successfully purified by one-step affinity column chromatography by using agarose beads with excellent yield. The purified DagA was found to exhibit maximal agarase activity at 40°C and pH 7.0. The K ^sub m^, V ^sub max^, and K ^sub cat^ values for agarose were 2.18 mg/ml (approximately 1.82×10^sup -5^ M), 39.06 U/mg of protein, and 9.5×10^sup 3^/s, respectively. Thin layer chromatography (TLC) analysis, matrix-assisted laser desorption/ionization-time-of-flight (MALDI-TOF) mass spectrometry, and Fourier transform nuclear magnetic resonance (FT-NMR) spectrometry of the hydrolyzed products of agarose by DagA revealed that DagA is an endo-type β-agarase that degrades agarose into neoagarotetraose and neoagarohexaose.[PUBLICATION ABSTRACT]

Mithramycin A is an antitumor compound used for treatment of several types of cancer including chronic and acute myeloid leukemia, testicular carcinoma, hypercalcemia and Paget’s disease. Selective modifications of this molecule by combinatorial biosynthesis and biocatalysis opened the possibility to produce mithramycin analogues with improved properties that are currently under preclinical development. The mithramycin A biosynthetic gene cluster from Streptomyces argillaceus ATCC12956 was cloned by transformation assisted recombination in Saccharomyces cerevisiae and heterologous expression in Streptomyces lividans TK24 was evaluated. Mithramycin A was efficiently produced by S. lividans TK24 under standard fermentation conditions. To improve the yield of heterologously produced mithramycin A, a collection of derivative strains of S. lividans TK24 were constructed by sequential deletion of known potentially interfering secondary metabolite gene clusters using a protocol based on the positive selection of double crossover events with blue pigment indigoidine-producing gene. Mithramycin A production was evaluated in these S. lividans strains and substantially improved mithramycin A production was observed depending on the deleted gene clusters. A collection of S. lividans strains suitable for heterologous expression of actinomycetes secondary metabolites were generated and efficient production of mithramycin A with yields close to 3 g/L, under the tested fermentation conditions was achieved using these optimized collection of strains.