Engineered biosynthesis of the peptide antibiotic bacitracin in the surrogate host Bacillus subtilis.

Nonribosomal peptides are processed on multifunctional enzymes called nonribosomal peptide synthetases (NRPSs), whose modular multidomain arrangement allowed the rational design of new peptide products. However, the lack of natural competence and efficient transformation methods for most of nonribosomal peptide producer strains prevented the in vivo manipulation of these biosynthetic gene clusters. In this study, we present methods for the construction of a genetically engineered Bacillus subtilis surrogate host for the integration and heterologous expression of foreign NRPS genes. In the B. subtilis surrogate host, we deleted the resident 26-kilobase srfA gene cluster encoding the surfactin synthetases and subsequently used the same chromosomal location for integration of the entire 49-kilobase bacitracin biosynthetic gene cluster from Bacillus licheniformis by a stepwise homologous recombination method. Synthesis of the branched cyclic peptide antibiotic bacitracin in the engineered B. subtilis strain was achieved at high level, indicating a functional production and proper posttranslational modification of the bacitracin synthetases BacABC, as well as the expression of the associated bacitracin self-resistance genes. This engineered and genetically amenable B. subtilis strain will facilitate the rational design of new bacitracin derivatives.     

Portability of epimerization domain and role of peptidyl carrier protein on epimerization activity in nonribosomal peptide synthetases.

Incorporation of nonproteinogenic amino acids in small polypeptides synthesized by nonribosomal peptide synthetases (NRPS) significantly contributes to their biological activity. In these peptides, conversion of L-amino acids to the corresponding D-isomer is catalyzed by specialized NRPS modules that utilize an epimerization (E) domain. To understand the basis for the specific interaction of E domains with PCP domains (peptidyl carrier proteins, also described as T domains) and to investigate their substrate tolerance, we constructed a set of eight fusion proteins. The gene fragments encoding E and PCP-E domains of TycA (A-PCP-E), the one module tyrocidine synthetase A, were fused to different gene fragments encoding A and A-PCP domains, resulting in A/PCP-E and A-PCP/E types of fusion proteins (slash indicates site of fusion). We were able to show that the E domain of TycA, usually epimerizing Phe, does also accept the alternate substrates Trp, Ile, and Val, although with reduced efficiency. Interestingly, however, an epimerization activity was only observed in the case of fusion proteins where the PCP domain originates from modules containing an E domain. Sequence comparison revealed that such PCPs possess significant differences in the signature Ppant binding motif (CoreT: [GGDSI]), when compared to those carrier proteins, originating from ordinary C-A-PCP elongation modules (CoreT: [GGHSL]). By means of mutational analysis, we could show that epimerization activity is influenced by the nature of amino acid residues in proximity to the cofactor Ppant binding site. The aspartate residue in front of the invariant serine (Ppant binding site) especially seems to play an important role for the proper interaction between PCP and the E domain, as well as the presentation of the aminoacyl-S-Ppant substrate in the course of substrate epimerization. In conclusion, specialized PCP domains are needed for a productive interaction with E domains when constructing hybrid enzymes.     

Biosynthesis of natural products on modular peptide synthetases

Microbial nonribosomally processed peptides represent a large class of natural products including numerous important pharmaceutical agents, as well as other representatives that play a prevalent role in pathogenicity of certain microorganisms [M. A. Marahiel, T. Stachelhaus, and H. D. Mootz (1997). Chem. Rev. 97, 2651-2673]. Although diverse in structure, nonribosomally synthesized peptides have a common mode of biosynthesis. They are assembled on very large protein templates called peptide synthetases that exhibit a modular organization, allowing polymerization of monomers in an assembly-line-like mechanism.     

Heterologous expression of nonribosomal peptide synthetases in B. subtilis: construction of a bi-functional B subtilis/E coli shuttle vector system

A major obstacle in investigating the biosynthesis of pharmacologically important peptide antibiotics is the heterologous expression of the giant biosynthetic genes. Recently, the genetically engineered strain Bacillus subtilis KE30 has been reported as an excellent surrogate host for the heterologous expression of an entire nonribosomal peptide synthetase (NRPS) gene cluster. In this study, we expand the applicability of this strain, by the development of four Escherichia coli/B. subtilis shuttle expression vectors. Comparative overproduction of hybrid NRPS proteins derived from both organisms revealed a significant beneficial effect of overproducing proteins in B. subtilis KE30 as underlined by the production of stable nondegradative proteins, as well as the formation of active phosphopantetheinylated holo-proteins.     

Molecular and Biochemical Characterization of the Protein Template Controlling Biosynthesis of the Lipopeptide Lichenysin

Lichenysins are surface-active lipopeptides with antibiotic properties produced nonribosomally by several strains of Bacillus licheniformis. Here, we report the cloning and sequencing of an entire 26.6-kb lichenysin biosynthesis operon from B. licheniformis ATCC 10716. Three large open reading frames coding for peptide synthetases, designated licA, licB (three modules each), and licC (one module), could be detected, followed by a gene, licTE, coding for a thioesterase-like protein. The domain structure of the seven identified modules, which resembles that of the surfactin synthetases SrfA-A to -C, showed two epimerization domains attached to the third and sixth modules. The substrate specificity of the first, fifth, and seventh recombinant adenylation domains of LicA to -C (cloned and expressed in Escherichia coli) was determined to be Gln, Asp, and Ile (with minor Val and Leu substitutions), respectively. Therefore, we suppose that the identified biosynthesis operon is responsible for the production of a lichenysin variant with the primary amino acid sequence l-Gln–l-Leu–d-Leu–l-Val–l-Asp–d-Leu–l-Ile, with minor Leu and Val substitutions at the seventh position.Many strains of Bacillus are known to produce lipopeptides with remarkable surface-active properties (11). The most prominent of these powerful lipopeptides is surfactin from Bacillus subtilis (1). Surfactin is an acylated cyclic heptapeptide that reduces the surface tension of water from 72 to 27 mN m⁻¹ even in a concentration below 0.05% and shows some antibacterial and antifungal activities (1). Some B. subtilis strains are also known to produce other, structurally related lipoheptapeptides (Table ​(Table1),1), like iturin (32, 34) and bacillomycin (3, 27, 30), or the lipodecapeptides fengycin (50) and plipastatin (29).

TABLE 1

Lipoheptapeptide antibiotics of Bacillus spp.

Construction of hybrid peptide synthetases for the production of alpha-l-aspartyl-l-phenylalanine, a precursor for the high-intensity sweetener aspartame.

Microorganisms produce a large number of pharmacologically and biotechnologically important peptides by using nonribosomal peptide synthetases (NRPSs). Due to their modular arrangement and their domain organization NRPSs are particularly suitable for engineering recombinant proteins for the production of novel peptides with interesting properties. In order to compare different strategies of domain assembling and module fusions we focused on the selective construction of a set of peptide synthetases that catalyze the formation of the dipeptide alpha-l-aspartyl-l-phenylalanine (Asp-Phe), the precursor of the high-intensity sweetener alpha-l-aspartyl-l-phenylalanine methyl ester (aspartame). The de novo design of six different Asp-Phe synthetases was achieved by fusion of Asp and Phe activating modules comprising adenylation, peptidyl carrier protein and condensation domains. Product release was ensured by a C-terminally fused thioesterase domains and quantified by HPLC/MS analysis. Significant differences of enzyme activity caused by the fusion strategies were observed. Two forms of the Asp-Phe dipeptide were detected, the expected alpha-Asp-Phe and the by-product beta-Asp-Phe. Dependent on the turnover rates ranging from 0.01-0.7 min-1, the amount of alpha-Asp-Phe was between 75 and 100% of overall product, indicating a direct correlation between the turnover numbers and the ratios of alpha-Asp-Phe to beta-Asp-Phe. Taken together these results provide useful guidelines for the rational construction of hybrid peptide synthetases.