Biochemical analysis of the Cas6-1 RNA endonuclease associated with the subtype I-D CRISPR-Cas system in Synechocystis sp. PCC 6803.

Specialized RNA endonucleases are critical for efficient activity of the CRISPR-Cas defense mechanisms against invading DNA or RNA. Cas6-type enzymes are the RNA endonucleases in many type I and type III CRISPR-Cas systems. These enzymes are diverse and critical residues involved in the recognition and cleavage of RNA substrates are not universally conserved. Cas6 endonucleases associated with the CRISPR-Cas subtypes I-A, I-B, I-C, I-E and I-F, as well as III-B have been studied from three archaea and four bacteria thus far. However, until now information about subtype I-D specific Cas6 endonucleases has remained scarce. Here, we report the biochemical analysis of Cas6-1, which is specific for the crRNA maturation from the subtype I-D CRISPR-Cas system of Synechocystis sp. PCC 6803. Assays of turnover kinetics suggest a single turnover mechanism for Cas6-1. The mutation of conserved amino acids R29A, H32A-S33A and H51A revealed these as essential, whereas the parallel mutation of R175A-R176A led to a pronounced and the K155A mutation to a slight reduction in enzymatic activity. In contrast, the mutations R67A, R81A and K231A left the enzymatic activity unchanged. These results are in accordance with the predominant role of histidine residues in the active site and of positively charged residues in RNA binding. Nevertheless, the protein-RNA interaction site seems to differ from other known systems, since imidazole could not restore the mutated histidine site.

Multiplexed antibody detection from blood sera by immobilization of in vitro expressed antigens and label-free readout via imaging reflectometric interferometry (iRIf).

The detection of antibodies from blood sera is crucial for diagnostic purposes. Miniaturized protein assays in combination with microfluidic setups hold great potential by enabling automated handling and multiplexed analyses. Yet, the separate expression, purification, and storage of many individual proteins are time consuming and limit applicability. In vitro cell-free expression has been proposed as an alternative procedure for the generation of protein assays. We report the successful in vitro expression of different model proteins from DNA templates with an optimized expression mix. His10-tagged proteins were specifically captured and immobilized on a Ni-NTA coated sensor surface directly from the in vitro expression mix. Finally, the specific binding of antibodies from rabbit-derived blood sera to the immobilized proteins was monitored by imaging reflectometric interferometry (iRIf). Antibodies in the blood sera could be identified by binding to the respective epitopes with minimal cross reactivity. The results show the potential of in vitro expression and label-free detection for binding assays in general and diagnostic purposes in specific.