Overcoming Barriers in Structural Biology Through Method Development of Serial Crystallography

January 2016

abstract: Serial crystallography (SX) is a relatively new structural biology technique that collects X-ray diffraction data from microcrystals via femtosecond pulses produced by an X-ray free electron laser (X-FEL) or by synchrotron radiation, allowing for challenging protein structures to be solved from microcrystals at room temperature. Because of the youth of this technique, method development is necessary for it to achieve its full potential. Most serial crystallography experiments have relied on delivering sample in the mother liquor focused into a stream by compressed gas. This liquid stream moves at a fast rate, meaning that most of the valuable sample is wasted. For this reason, the liquid jet can require 10-100 milligrams of sample for a complete data set. Agarose has been developed as a slow moving microcrystal carrier to decrease sample consumption and waste. The agarose jet provides low background, no Debye-Sherrer rings, is compatible for sample delivery in vacuum environments, and is compatible with a wide variety of crystal systems. Additionally, poly(ethylene oxide) which is amenable for data collection in atmosphere has been developed for synchrotron experiments. Thus this work allows sample limited proteins of difficult to crystallize systems to be investigated by serial crystallography. Time-resolved serial X-ray crystallography (TR-SX) studies have only been employed to study light-triggered reactions in photoactive systems. While these systems are very important, most proteins in Nature are not light-driven. However, fast mixing of two liquids, such as those containing enzyme protein crystals and substrates, immediately before being exposed to an X-ray beam would allow conformational changes and /or intermediates to be seen by diffraction. As a model, 3-deoxy-D-manno-2-octulosonate-8-phosphate synthase (KDO8PS), has been developed for TR-SX. This enzyme initializes the first step of lipopolysaccharide synthesis by a net aldol condensation between arabinose-5-phosphate, phosphoenol pyruvate, and water. During this reaction, a short lived intermediate is formed and has been observed on a millisecond timescale using other methods. Thus KDO8PS is an ideal model protein for studying diffusion times into a crystal and short mixing times (<10 ms). For these experiments, microcrystals diffracting to high resolution have been developed and characterized. / Dissertation/Thesis / Doctoral Dissertation Chemistry 2016

Chemistry

KDO8PS

serial crystallography

viscous sample delivery

XFEL

X-ray crystallography

Ultrathin Liquid-Sheet Jets for X-ray Imaging : Gas-Accelerated Liquid-Sheet Jet Nozzles for Sample Delivery

Mehlig, Robert Daniel

January 2024

X-ray free-electron lasers (XFELs) can achieve near-atomic resolution in imaging organic molecules. As a fourth-generation light source, modern XFELs can generate brilliant ultrashort X-ray pulses at MHz repetition rates. This allows XFELs to image single molecules with great detail, obtaining information about their dynamics and states through the interaction of the electrons within the molecule with the X-rays. A key challenge when imaging biomolecules (e.g. proteins, viruses, or bacteria) is to image the sample within its native environment, in solution. 3D-printed gas-accelerated liquid-sheet jet nozzles for liquid sample-delivery have yielded promising results in this respect, demonstrating that liquid sheets can be a reliable alternative to conventional sample-delivery methods, e.g. electrospray. Although the nozzles that this project uses have been successfully used for measurements at XFELs, the effect of nozzle design and liquid material-properties have not previously been explored. Therefore, the present report aims to explore different flow regimes of gas-accelerated liquid-sheet jets, and to study how the generated sheet jet depends upon different parameters, such as gas and liquid flow-rates, sample solution, and nozzle geometry. The findings suggest that low surface tension is crucial for producing large jets, and that higher viscosity may help to generate more stable sheet jets. However, further studies are required to draw definite conclusions.

Liquid Jet

Liquid Sheet

Liquid-sheet jet

Nozzle

Molecular biophysics

X-ray diffraction

XFEL

Sample delivery

X-Ray Free-Electron Laser

Biophysics

Biofysik

Physical Sciences

Fysik

Coherent Diffractive Imaging with X-ray Lasers

Hantke, Max Felix

January 2016

The newly emerging technology of X-ray free-electron lasers (XFELs) has the potential to revolutionise molecular imaging. XFELs generate very intense X-ray pulses and predictions suggest that they may be used for structure determination to atomic resolution even for single molecules. XFELs produce femtosecond pulses that outrun processes of radiation damage and permit the study of structures at room temperature and of structural dynamics. While the first demonstrations of flash X-ray diffractive imaging (FXI) on biological particles were encouraging, they also revealed technical challenges. In this work we demonstrated how some of these challenges can be overcome. We exemplified, with heterogeneous cell organelles, how tens of thousands of FXI diffraction patterns can be collected, sorted, and analysed in an automatic data processing pipeline. We improved  image resolution and reduced problems with missing data. We validated, described, and deposited the experimental data in the Coherent X-ray Imaging Data Bank. We demonstrated that aerosol injection can be used to collect FXI data at high hit ratios and with low background. We reduced problems with non-volatile sample contaminants by decreasing aerosol droplet sizes from ~1000 nm to ~150 nm. We achieved this by adapting an electrospray aerosoliser to the Uppsala sample injector. Mie scattering imaging was used as a diagnostic tool to measure positions, sizes, and velocities of individual injected particles. XFEL experiments generate large amounts of data at high rates. Preparation, execution, and data analysis of these experiments benefits from specialised software. In this work we present new open-source software tools that facilitates prediction, online-monitoring, display, and pre-processing of XFEL diffraction data. We hope that this work is a valuable contribution in the quest of transitioning FXI from its first experimental demonstration into a technique that fulfills its potentials.

coherent diffractive X-ray imaging

lensless imaging

coherent X-ray diffractive imaging

flash diffractive imaging

single particle imaging

aerosol injection

electrospray injection

substrate-free sample delivery

carboxysome

phase retrieval

X-ray diffraction software

X-ray free-electron laser

XFEL

FEL

CXI

CDI

CXDI

FXI