Provided is a method which can produce a target protein while stably maintaining a vector without any special genetic manipulation of host cells and without use of a drug resistance gene or the like. A method for producing a target protein including culturing cells transformed with a vector, the vector containing a gene of the target protein and not containing an antibiotic resistance gene, a recombinase recognition sequence, or a gene essential for cell survival.

Provided is a method which can produce a target protein while stably maintaining a vector without any special genetic manipulation of host cells and without use of a drug resistance gene or the like. A method for producing a target protein including culturing cells transformed with a vector, the vector containing a gene of the target protein and not containing an antibiotic resistance gene, a recombinase recognition sequence, or a gene essential for cell survival.

Disclosed herein are recombinant methods of activating expression of one or more biosynthetic gene clusters comprising more than one gene, the method comprising a recombinant DNA expression vector that possess two opposable inducible promoters that drives expression of a biosynthetic gene cluster exogenously from outside of the cluster to produce polyketides or non-ribosomal peptides in a heterologous host.

The present invention relates to a method of preparing a gene cluster construct including a plurality of genes encoding a multi-modular biosynthetic enzyme, the method including (A) a step of preparing a plurality of DNA fragments which are capable of reconstructing the gene cluster construct and have structures that can be ligated to each other and (B) a step of ligating the plurality of DNA fragments prepared in the step (A) to each other by mixing the plurality of DNA fragments in a solution to obtain the gene cluster construct.

The present invention relates to a method for preparing a plasmid containing DNA that encodes a Type I polyketide synthase (PKS), the method including a step of introducing a DNA construct containing tandem repeats of DNA that encodes a PKS into a Bacillus subtilis competent cell.

The present invention relates to a method for preparing a plasmid containing DNA that encodes a Type I polyketide synthase (PKS), the method including a step of introducing a DNA construct containing tandem repeats of DNA that encodes a PKS into a Bacillus subtilis competent cell.

A heterologous gene cassette useful for creating Streptomyces species with enhanced capability of growing on a cellulosic polysaccharide substrate, wherein the cassette comprises at least two members of the following categories: a) a GH6 gene, b) an AA10 gene, c) a GH48 gene, d) a GH5 gene and e) either (i) a GH9 gene, (ii) a GH9 gene and a GH12 gene, or (iii) a GH12 gene is disclosed.

A heterologous gene cassette useful for creating Streptomyces species with enhanced capability of growing on a cellulosic polysaccharide substrate, wherein the cassette comprises at least two members of the following categories: a) a GH6 gene, b) an AA10 gene, c) a GH48 gene, d) a GH5 gene and e) either (i) a GH9 gene, (ii) a GH9 gene and a GH12 gene, or (iii) a GH12 gene is disclosed.

The genomic DNA of Streptoverticillium sp. 3-7, which produces UK-2, was analyzed to identify a region expected to be a UK-2 biosynthetic gene cluster. Moreover, by colony hybridization, DNAs in the region were successfully isolated. Further, the DNAs were used to prepare a strain in which the genes present in the region were disrupted. The strain was found not to produce UK-2. It was verified that the genomic region was the UK-2 biosynthetic gene cluster. Furthermore, Streptoverticillium sp. 3-7 was transformed by introduction of a vector in which the isolated UK-2 biosynthetic gene cluster was inserted. It was also found out that the UK-2 productivity by the transformant was improved about 10 to 60 times or more in comparison with that of the parental strain. Moreover, it was revealed that 2 copies of the UK-2 biosynthetic gene cluster were present per cell in these transformants, respectively.

The genomic DNA of Streptoverticillium sp. 3-7, which produces UK-2, was analyzed to identify a region expected to be a UK-2 biosynthetic gene cluster. Moreover, by colony hybridization, DNAs in the region were successfully isolated. Further, the DNAs were used to prepare a strain in which the genes present in the region were disrupted. The strain was found not to produce UK-2. It was verified that the genomic region was the UK-2 biosynthetic gene cluster. Furthermore, Streptoverticillium sp. 3-7 was transformed by introduction of a vector in which the isolated UK-2 biosynthetic gene cluster was inserted. It was also found out that the UK-2 productivity by the transformant was improved about 10 to 60 times or more in comparison with that of the parental strain. Moreover, it was revealed that 2 copies of the UK-2 biosynthetic gene cluster were present per cell in these transformants, respectively.