Jes Kristian Jacobsen

BioXTAS RAW, a software program for high- throughput automated small-angle X-ray scattering data reduction and preliminary analysis

A fully open source software program for automated two-dimensional and one-dimensional data reduction and preliminary analysis of isotropic small-angle X-ray scattering (SAXS) data is presented. The program is freely distributed, following the open-source philosophy, and does not rely on any commercial software packages. BioXTAS RAW is a fully automated program that, via an online feature, reads raw two-dimensional SAXS detector output files and processes and plots data as the data files are created during measurement sessions. The software handles all steps in the data reduction. This includes mask creation, radial averaging, error bar calculation, artifact removal, normalization and q calibration. Further data reduction such as background subtraction and absolute intensity scaling is fast and easy via the graphical user interface. BioXTAS RAW also provides preliminary analysis of one-dimensional data in terms of the indirect Fourier transform using the objective Bayesian approach to obtain the pair-distance distribution function, PDDF, and is thereby a free and open-source alternative to existing PDDF estimation software. Apart from the TIFF input format, the program also accepts ASCII-format input files and is currently compatible with one-dimensional data files from SAXS beamlines at a number of synchrotron facilities. BioXTAS RAW is written in Python with C++ extensions.

High-throughput small angle X-ray scattering from proteins in solution using a microfluidic front-end.

This manuscript presents, for the first time, the method of automated structural analysis of biomolecules in solution on a microfluidic chip. A polymer-based micrototal analysis system for high-throughput Small-Angle X-ray Scattering (SAXS) data collection from biological macromolecules has been developed. The bioXTAS chip features an integrated X-ray transparent 200 nL sample chamber and diffusion-based mixing of protein and buffer solutions. Software for fully automated fluidic control, data acquisition, and data analysis has been developed. The proof-of concept is based on data using bovine serum albumin as the model system. It confirms the quality of SAXS data generated from small sample volumes and furthermore validates the on-chip mixing capabilities. SAXS data on the gradual unfolding of BSA induced by an anionic surfactant exemplifies how the bioXTAS chip can be used to follow and identify structural changes and proves the feasibility of high-throughput structural analysis in solution. In total, this shows that the bioXTAS chip has the potential for becoming a powerful tool for automated high-throughput structural analysis of macromolecular systems.

Generation of Gla-domainless FVIIa by cathepsin G-mediated cleavage.

Cougulation factor VII contains ten λ‐carboxyglutamic acid residues in the N‐terminal region (Gla‐domain) which are essential for the hemostatic function of FVII. The present study shows that granulocyte cathepsin G degrades the Gla‐domain of FVIIa in vitro. Characterization of the truncated FVIIa by SDS‐PAGE and N‐terminal amino acid sequence analysis revealed that cleavage had occurred between Tyr‐44 and Ser‐45 and that further cleavage was only obtained on extensive cathepsin G exposure. Cleavage of vitamin K‐dependent coagulation factors by cathepsin G may play a role in vivo, and it offers a convenient way of obtaining proteins deprived of their Gla‐domain for functional and structural studies.

Automated microfluidic sample-preparation platform for high-throughput structural investigation of proteins by small-angle X-ray scattering

A new microfluidic sample-preparation system is presented for the structural investigation of proteins using small-angle X-ray scattering (SAXS) at synchrotrons. The system includes hardware and software features for precise fluidic control, sample mixing by diffusion, automated X-ray exposure control, UV absorbance measurements and automated data analysis. As little as 15 µl of sample is required to perform a complete analysis cycle, including sample mixing, SAXS measurement, continuous UV absorbance measurements, and cleaning of the channels and X-ray cell with buffer. The complete analysis cycle can be performed in less than 3 min. Bovine serum albumin was used as a model protein to characterize the mixing efficiency and sample consumption of the system. The N2 fragment of an adaptor protein (p120-RasGAP) was used to demonstrate how the device can be used to survey the structural space of a protein by screening a wide set of conditions using high-throughput techniques.

FVIIa derivatives obtained by autolytic and controlled cathepsin G mediated cleavage.

The heavy chain of coagulation factor VII contains a serine esterase entity. A partial cleavage in the heavy chain occurs during purification and activation of the single‐chain zymogen, presumably as a result of autolysis. Neutrophil cathepsin G initially generates a Gla‐domainless FVIIa without coagulant activity. However, on extended exposure cleavage also occurs in the heavy chain, resulting in a complete loss of enzyme activity. Four cleavage sites on the heavy chain, two susceptible to trypsin‐like autolysis and two susceptible to chymotrypsin‐like cathepsin G‐mediated catalysis have been identified. The hydrolysis of peptide bonds in the heavy chain might contribute to regulation of the coagulation process in vivo.

Self-association of long-acting insulin analogues studied by size exclusion chromatography coupled to multi-angle light scattering.

Two structurally very different insulin analogues analysed here, belong to a class of analogues of which two have been reported to have a protracted action through self-assembly to high molar mass in subcutis. The process of self-association of insulin analogues Lys(B29) (N(ε)ω-carboxyheptadecanoyl) des(B30) human insulin and Lys(B29) (N(ε)-lithocholyl) des(B30) human insulin was investigated using size exclusion chromatography (SEC) in connection with multi-angle light-scattering. Self-assembly to high molar mass was obtained by exchanging the formulation containing phenolic preservatives with an isotonic eluent during SEC. It was shown that increasing amounts of zinc in the formulations of the two analogues increased the size of the self assemblies formed during gel filtration. The addition of 0.2 mM phenol to the elution buffer slowed down the self-association process of zinc containing formulations and shed light on the initial association process. The results indicated that a dihexamer is a possible building block during self-association of Lys(B29) (N(ε)ω-carboxyheptadecanoyl) des(B30) human insulin. Surprisingly, in the absence of zinc the two analogues behaved very differently. Lys(B29) (N(ε)ω-carboxyheptadecanoyl) des(B30) human insulin was in equilibrium between oligomers smaller than a hexamer, whereas Lys(B29) (N(ε)-lithocholyl) des(B30) human insulin self-associated and formed even larger complexes than in the presence of zinc.