From Electronic Sequence to Purified Protein Using Automated Gene Synthesis and In Vitro Transcription/Translation.

De novo gene synthesis is the state-of-the-art method used to obtain genetic material adapted to the requirements of the host organism and a cornerstone for modern synthetic biology. Yet, little progress has been made regarding downstream processes of protein production from synthetic genetic material. The production of recombinant proteins traditionally requires extensive preparatory work including gene amplification, cloning, sequencing, transformation or transfection of the expression host, cultivation of living cells, and purification of the overexpressed protein. In this work we describe a fast and automated workflow for cell-free production of proteins starting from an electronic protein sequence or accession number. PRESTO (protein expression starting from oligonucleotides) seamlessly combines a tailored in silico sequence optimization with the assembly of short oligonucleotides into synthetic linear DNA expression cassettes, mammalian in vitro transcription/translation, and protein purification thereof. Integrated on a small liquid handling system it provides a hands-free high throughput source for functional synthetic proteins within 1 day.

Bypass of DNA lesions generated during anticancer treatment with cisplatin by DNA polymerase eta.

DNA polymerase eta (Pol eta) is a eukaryotic lesion bypass polymerase that helps organisms to survive exposure to ultraviolet (UV) radiation, and tumor cells to gain resistance against cisplatin-based chemotherapy. It allows cells to replicate across cross-link lesions such as 1,2-d(GpG) cisplatin adducts (Pt-GG) and UV-induced cis-syn thymine dimers. We present structural and biochemical analysis of how Pol eta copies Pt-GG-containing DNA. The damaged DNA is bound in an open DNA binding rim. Nucleotidyl transfer requires the DNA to rotate into an active conformation, driven by hydrogen bonding of the templating base to the dNTP. For the 3'dG of the Pt-GG, this step is accomplished by a Watson-Crick base pair to dCTP and is biochemically efficient and accurate. In contrast, bypass of the 5'dG of the Pt-GG is less efficient and promiscuous for dCTP and dATP as a result of the presence of the rigid Pt cross-link. Our analysis reveals the set of structural features that enable Pol eta to replicate across strongly distorting DNA lesions.

In vivo biocombinatorial synthesis of lipopeptides by COM domain-mediated reprogramming of the surfactin biosynthetic complex.

The intermolecular communication within NRPS complexes relies on the coordinated interplay of donor and acceptor communication-mediating (COM) domains. In this study, the potential of COM domains was exploited in vivo by establishing a system for the true biocombinatorial synthesis of lipopeptides via directed reprogramming of a natural NRP biosynthetic assembly line (i.e., surfactin). By means of COM domain swapping, these experiments verified the decisive role of COM domains for the control of protein-protein interactions between NRPSs, demonstrated the functionality of COM domain pairs even in the context of a heterologous host and NRPS system, and allowed for the intended skipping of a biosynthetic enzyme within a multienzymatic biosynthetic complex. Ultimately, abrogation of the selectivity barrier provided by COM domains afforded the successful simultaneous, biocombinatorial synthesis of distinct lipopeptide products.

Isolation of high molecular weight DNA from soil for cloning into BAC vectors.

Isolation of high molecular weight DNA fragments from soil, in excess of 1 Mb, and of sufficient quality for cloning into an Escherichia coli-streptomycete artificial chromosome vector is described. The combination of indirect extraction of cells, using a nycodenz extraction technique, followed by lysis of biomass immobilised in agarose plugs, allowed fragments in excess of 1 Mb to be purified.

Microbial technologies for the discovery of novel bioactive metabolites.

Soil microbes represent an important source of biologically active compounds. These molecules present original and unexpected structure and are selective inhibitors of their molecular targets. At Biosearch Italia, discovery of new bioactive molecules is mostly carried out through the exploitation of a proprietary strain collection of over 50000 strains, mostly unusual genera of actinomycetes and uncommon filamentous fungi. A critical element in a drug discovery based on microbial extracts is the isolation of unexploited groups of microorganisms that are at the same time good producers of secondary metabolites. Molecular genetics can assist in these efforts. We will review the development and application of molecular methods for the detection of uncommon genera of actinomycetes in soil DNA and for the rapid dereplication of actinomycete isolates. The results indicate a substantial presence in many soils of the uncommon genera and a large diversity of isolated actinomycetes. However, while uncommon actinomycete strains may provide an increased chance of yielding novel structures, their genetics and physiology are poorly understood. To speed up their manipulation, we have developed vectors capable of stably maintaining large segments of actinomycete DNA in Escherichia coli and of integrating site specifically in the Streptomyces genome. These vectors are suitable for the reconstruction of gene clusters from smaller segment of cloned DNA, the preparation of large-insert libraries from unusual actinomycete strains and the construction of environmental libraries.

New PCR primers for the selective amplification of 16S rDNA from different groups of actinomycetes.

Actinomycetes play a relevant role in soil ecology and are also of important biotechnological interest as they produce several bioactive metabolites. Within the filamentous actinomycetes, it would be desirable to recognize and characterize environmental samples containing unusual genera. To this end, we have developed selective primer sets for polymerase chain reaction (PCR) amplification of 16S rDNA from the Actinomycetales families Micromonosporaceae, Streptomycetaceae, Streptosporangiaceae and Thermomonosporaceae, and from the genus Dactylosporangium. Each primer set, evaluated on genomic DNA from reference strains, showed high specificity and good sensitivity. After amplification of DNA extracted from soil samples, the sequence of the cloned PCR products confirmed the specific amplification of the desired group of sequences in at least 95% of the clones for each primer set. The application of these primers to environmental samples showed the frequent occurrence of these groups in soil samples and also revealed sequences that can be attributed to new groups of actinomycetes.