Chemical Evolution of Natural Product Structure.

Natural products are the result of Nature's exploration of biologically relevant chemical space through evolution and an invaluable source of bioactive small molecules for chemical biology and medicinal chemistry. Novel concepts for the discovery of new bioactive compound classes based on natural product structure may enable exploration of wider biologically relevant chemical space. The pseudo-natural product concept merges the relevance of natural product structure with efficient exploration of chemical space by means of fragment-based compound development to inspire the discovery of new bioactive chemical matter through de novo combination of natural product fragments in unprecedented arrangements. The novel scaffolds retain the biological relevance of natural products but are not obtainable through known biosynthetic pathways which can lead to new chemotypes that may have unexpected or unprecedented bioactivities. Herein, we cover the workflow of pseudo-natural product design and development, highlight recent examples, and discuss a cheminformatic analysis in which a significant portion of biologically active synthetic compounds were found to be pseudo-natural products. We compare the concept to natural evolution and discuss pseudo-natural products as the human-made equivalent, i.e. the chemical evolution of natural product structure.

Pseudo Natural Products-Chemical Evolution of Natural Product Structure.

Pseudo-natural products (PNPs) combine natural product (NP) fragments in novel arrangements not accessible by current biosynthesis pathways. As such they can be regarded as non-biogenic fusions of NP-derived fragments. They inherit key biological characteristics of the guiding natural product, such as chemical and physiological properties, yet define small molecule chemotypes with unprecedented or unexpected bioactivity. We iterate the design principles underpinning PNP scaffolds and highlight their syntheses and biological investigations. We provide a cheminformatic analysis of PNP collections assessing their molecular properties and shape diversity. We propose and discuss how the iterative analysis of NP structure, design, synthesis, and biological evaluation of PNPs can be regarded as a human-driven branch of the evolution of natural products, that is, a chemical evolution of natural product structure.

Optical Control of Transcription: Genetically Encoded Photoswitchable Variants of T7 RNA Polymerase.

Light-sensing protein domains that link an exogenous light signal to the activity of an enzyme have attracted much attention for the engineering of new regulatory mechanisms into proteins and for studying the dynamic behavior of intracellular reactions and reaction cascades. Light-oxygen-voltage (LOV) photoreceptors are blue-light-sensing modules that have been intensely characterized for this purpose and linked to several proteins of interest. For the successful application of these tools, it is crucial to identify appropriate fusion strategies for combining sensor and enzyme domains that sustain activity and light-induced responsivity. Terminal fusion of LOV domains is the natural strategy; however, this is not transferrable to T7 RNA polymerase because both of its termini are involved in catalysis. It is shown herein that it is possible to covalently insert LOV domains into the polymerase protein, while preserving its activity and generating new light-responsive allosteric coupling.

LOV Domains in the Design of Photoresponsive Enzymes.

In nature, a multitude of mechanisms have emerged for regulating biological processes and, specifically, protein activity. Light as a natural regulatory element is of outstanding interest for studying and modulating protein activity because it can be precisely applied with regard to a site of action, instant of time, or intensity. Naturally occurring photoresponsive proteins, predominantly those containing a light-oxygen-voltage (LOV) domain, have been characterized structurally and mechanistically and also conjugated to various proteins of interest. Immediate advantages of these new photoresponsive proteins such as genetic encoding, no requirement of chemical modification, and reversibility are paid for by difficulties in predicting the envisaged activity or type and site of domain fusion. In this article, we summarize recent advances and give a survey on currently available design concepts for engineering photoswitchable proteins.

The double mutation L109M and R448M of HIV-1 reverse transcriptase decreases fidelity of DNA synthesis by promoting mismatch elongation.

Changes of Leu109 and Arg448 of human immunodeficiency virus type 1 (HIV-1) reverse transcriptase (RT) have as yet not been associated with altered fitness. However, in a recent study, we described that the simultaneous substitution of L109 and R448 by methionine leads to an error-producing polymerase phenotype that is not observed for the isolated substitutions. The double mutant increased the error rate of DNA-dependent DNA synthesis 3.1-fold as compared to the wildtype enzyme and showed a mutational spectrum with a fraction of 28% frameshift mutations and 48% transitions. We show here that weaker binding of DNA:DNA primer-templates as indicated by an increased dissociation rate constant (koff) could account for the higher frameshift error rate. Furthermore, we were able to explain the prevalence of transition mutations with the finding that HIV-1 RT variant L109M/R448M preferred misincorporation of C opposite A and elongation of C:A mismatches.

Identification of a T7 RNA polymerase variant that permits the enzymatic synthesis of fully 2'-O-methyl-modified RNA.

T7 RNA polymerase is an important biocatalyst that is used in diverse biotechnological applications such as in vitro transcription or protein expression. The enzyme displays high substrate specificity which is payed by significant limitations regarding incorporation of synthetic nucleotide analogs. Of specific interest is enzymatic synthesis of 2'-O-methyl-modified RNA as these nucleic acids exhibit improved biochemical and pharmacokinetic properties that make them attractive for diagnostic and therapeutic purposes. We report here on the development of an activity-based selection/screening approach for assessing polymerase activities in the presence of 2'-O-methyl-modified nucleotides, and on the identification of one variant T7 RNA polymerase which is capable of synthesizing all-2'-O-methyl RNA.

Exonucleolytic degradation of high-density labeled DNA studied by fluorescence correlation spectroscopy.

The exonucleolytic degradation of high-density labeled DNA by exonuclease III was monitored using two-color fluorescence correlation spectroscopy (FCS). One strand of the double stranded template DNA was labeled on either one or two base types and additionally at one end via a 5' Cy5 tagged primer. Exonucleolytic degradation was followed via the diffusion time, the brightness of the remaining DNA as well as the concentration of released labeled bases. We found a hydrolyzation rate of about 11 to 17 nucleotides per minute per enzyme (nt/min/enzyme) for high-density labeled DNA, which is by a factor of about 4 slower than for unlabeled DNA. The exonucleolytic degradation of a 488 base pair long double stranded DNA resulted in a short double stranded DNA segment of 112 ± 40 base pairs (bp) length with two single-stranded tails.

Directed evolution of an error-prone T7 DNA polymerase that attenuates viral replication.

Experimental evidence exists that RNA viruses replicate with extremely high mutation rates that result in significant genetic diversity. The diverse nature of viral populations allows rapid adaptation to dynamic environments, and evolution of resistances to vaccines as well as antiviral substances. For DNA viruses that replicate at much greater fidelities, as yet, neither diverse structures in the population nor their responses to increased mutation rates have been sufficiently described. By using the example of DNA bacteriophage T7, we describe the identification of virus-specific DNA polymerase variants with decreased replication fidelities, and their impact on the efficiency of the viral infection cycle.

Activity-based selection of HIV-1 reverse transcriptase variants with decreased polymerization fidelity.

HIV-1 reverse transcriptase (HIV-1 RT) copies the RNA genome of HIV-1 into DNA, thereby committing errors at an exceptionally high frequency. Viral offspring evolve rapidly and consequently are capable of evading the immune response as well as antiviral treatment. However, error-prone viral replication could drive HIV close to extinction owing to an intolerable load of deleterious mutations. We applied a genetic selection scheme to identify variants of HIV-1 RT with a further increased error rate to study the relationship between error rate and viral replication. Using this approach, we identified 16 mutator candidates, two of which were purified and further studied in vitro. One of these variant enzymes showed a generally increased mutation frequency as compared with the reference enzyme. A single amino acid residue, R448, is probably responsible for the observed effect. Mutation of this residue, which is located within the RNase H domain of HIV-1 RT, seems to perturb the interaction with template RNA and consequently affects polymerase activity and fidelity.

Exonuclease III action on microarrays: observation of DNA degradation by fluorescence correlation spectroscopy.

DNA with all cytosines, thymines, or all pyrimidines of one strand substituted by fluorescently labeled analogs shows diminished solubility in aqueous media and a strong tendency to aggregation that hampers enzymatic downstream processing. In this study, immobilization of fully fluorescently labeled DNA on microarrays was shown to resolve the named problems and to enable successive DNA degradation by exonuclease III. Fluorescence correlation spectroscopy and single-molecule counting for monitoring the course of DNA hydrolysis in real time revealed the virtually processive degradation of labeled DNA that occurred at an average rate of approximately 4 nt/s.

Sequencing single DNA molecules in real time.

One's enough: The direct observation of a DNA-polymerase-based "sequencing engine" using single-molecule detection recently allowed single-molecule sequencing by synthesis in real time. Nucleotides with a fluorescent marker at the 5'-phosphate unit and zero-mode waveguides are crucial components of this approach, which at last promises low-cost genome-scale sequencing.

Expression and purification of histidine-tagged bacteriophage T7 DNA polymerase.

The formation of inclusion bodies is a frequent consequence of high-level production of foreign protein in the cytoplasm of Escherichia coli. This phenomenon is also observed with bacteriophage T7 gene 5 protein, the phage-encoded subunit of T7 DNA polymerase, if expression is based on the T5 promoter/lac operator transcription-translation system present in a vector with ColE1 origin of replication. To avoid tedious procedures for recovering protein from insoluble aggregates, we studied the expression of T7 gene 5 protein using a series of E. coli strains, and optimized the yield of soluble, histidine-tagged (His-tagged) protein by varying the respective growth conditions (temperature, amount of inducer isopropyl-beta-d-thiogalactopyranoside, and presence of organic osmolytes). Although the expression levels in three different strains (BL21, SG13009, and XL1-Blue) were almost comparable with a given set of growth conditions, the yields of soluble protein differed markedly. The largest quantities of soluble, His-tagged T7 gene 5 protein were achieved using "cloning strain" XL1-Blue which benefitted significantly from the presence of sorbitol and glycine betaine-in contrast to the expression strains BL21 and SG13009. Purification of His-tagged T7 gene 5 protein was achieved using single-step metal-affinity chromatography that yielded large amounts of highly active polymerase (97% homogeneity). The application of this expression/purification approach represents not only a useful method to purify large quantities of T7 DNA polymerase for structural investigations but also, provides a fast and efficient protocol for the parallel purification of T7 DNA polymerase variants, e.g., for automated screenings or directed evolution experiments.

High-density labeling of DNA for single molecule sequencing.

Two unusual enzymatic activities are required for the realization of a single molecule sequencing: a polymerase for copying a deoxyribonuclease (DNA) target into complementary flurophore-labeled DNA, and an exonuclease for the successive hydrolysis of the completely dye-labeled DNA. Recently, we found that the wild-type Klenow fragment of Escherichia coli DNA polymerase I is well-suited for the synthesis of DNA in a reaction set-up that contains exclusively specific rhodamine-labeled analogs of the natural pyrimidine nucleotides (dCTP and dTTP). This protocol describes the procedure used for the preparation of DNA that is labeled at all pyrimidine bases of one strand, as well as an example of enzymatic downstream processing of the DNA product.

Optimal enzymes for single-molecule sequencing.

Much research effort has been made to realize a single-molecule sequencing. Central to this project are two enzymatic tasks that challenged several biochemists during the last years. They searched for polymerases for copying a DNA target into completely fluorophore-labeled DNA as well as for handling this new DNA derivative. Furthermore, they studied exonucleases for the sequential hydrolysis of completely dye-labeled DNA and explored optimal conditions for future application on the single-molecule level. In this article, the recent advances will be summarized from the biochemist's point of view.