Susanne Brakmann

Sequencing Single DNA Molecules in Real Time

Ones 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.

Single-molecule analysis: A ribosome in action

The manufacture of proteins by ribosomes involves complex interactions of diverse nucleic-acid and protein ligands. Single-molecule studies allow us, for the first time, to follow the synthesis of full-length proteins in real time.

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.

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.

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.

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.