Date |
Session |
Time |
Author |
Abstract title |
3.7. |
S1-L1 |
09:50 |
Xu |
H Eric |
An X-Ray Laser Structure of
Rhodopsin-Arrestin Complex |
3.7. |
S1-L2 |
10:20 |
Carpenter |
Byron |
Engineering Heterotrimeric G Proteins to
Facilitate Crystallisation of GPCRs in their Active Conformation |
3.7. |
S1-L3 |
10:50 |
Caffrey |
Martin |
New and Improved Features of the Lipid
Cubic Phase (In Meso) Method for Crystallizing Membrane and Soluble
Proteins and Complexes |
3.7. |
S1-L4 |
11:10 |
Pryor |
Edward |
The importance of detergent selection: Are
you choosing the right detergent for your membrane protein? |
3.7. |
KN-2 |
12:00 |
Chayen |
Naomi |
Enhancing the success of crystallising
biological macromolecules |
3.7. |
S2-L1 |
14:00 |
Kossiakoff |
Anthony |
Generation of antibody-Fab reagents to
capture and stabilize functionally important conformational states of
proteins to facilitate their structure determination by crystallography
and single particle Cryo-EM |
3.7. |
S2-L2 |
14:30 |
Thomae |
Nicolas |
Macromolecular machines in genome
maintenance |
3.7. |
S2-L3 |
15:00 |
Tan |
Song |
Crystallization of chromatin complexes |
3.7. |
S2-L4 |
15:30 |
Rubin |
Seth |
X-ray Crystallography Studies of Protein
Complexes Controlling Cell Cycle Gene Expression |
3.7. |
S3-L1 |
16:20 |
Xu |
Fei |
Structural investigation of APJ: one
receptor with two endogenous ligands |
3.7. |
S3-L2 |
16:50 |
Kapoor |
Khyati |
Mechanism of inhibition of hGLUT1 is
conserved between cytochalasin B and phenylalanine amides |
3.7. |
S3-L3 |
17:10 |
Chen |
Chun Jung |
Purification and Crystallization of an
Antigenic Outer-Membrane Protein from Salmonella Typhi |
3.7. |
S3-L4 |
17:30 |
Shaw Stewart |
Patrick |
Microseed matrix-screening (rMMS):
introduction, theory, practice and a new technique for membrane protein
crystallization in LCP |
3.7. |
KN-1 |
9:00 |
Nureki |
Osamu |
High-resolution X-ray Crystallography of
Membrane Proteins and Molecular Mechanisms of Membrane Transporters |
4.7. |
S4-L1 |
08:30 |
Marquez |
Jose Antonio |
Automated crystal mounting and processing
through laser photoablation. New opportunities for integrated
macromolecular crystallography pipelines. |
4.7. |
S4-L2 |
09:00 |
Hunkeler |
Moritz |
Advanced Imaging in Lab-Scale Protein
Crystallization |
4.7. |
S4-L3 |
09:30 |
Dekker |
Carien |
TeXRank: Texture Image Analysis and Machine
Learning for Crystallizing Difficult Proteins |
4.7. |
S4-L4 |
10:00 |
Gerard |
Charline |
Microfluidic platform for optimisation of
crystallisation conditions |
4.7. |
S4-L5 |
10:20 |
Mueller Dieckman |
Jochen |
Advancements in Automated Imaging |
4.7. |
S5-L1 |
11:10 |
Oberthuer |
Dominik |
Changing concepts: Crystallization for
serial and time-resolved crystallography |
4.7. |
S5-L2 |
11:40 |
Dods |
Robert |
Micro-crystallisation of Photosynthetic
Reaction Center for Time-Resolved Serial Femtosecond Crystallography at
an X-ray Free Electron Laser |
4.7. |
S5-L3 |
12:10 |
Stagno |
Jason |
Advantages of Serial Femtosecond
Crystallography for RNA Structure Determination |
4.7. |
S5-L4 |
12:30 |
Perry |
Sarah |
Graphene-Based Microfluidics for Serial
Crystallography |
4.7. |
S6-L1 |
14:00 |
Meents |
Alke |
A low background sample holder for fixed
target serial crystallography experiments |
4.7. |
S6-L2 |
14:30 |
Weierstall |
Uwe |
Microcrystal sample delivery for serial
crystallography in a high viscosity medium |
4.7. |
S6-L3 |
15:00 |
Betzel |
Christian |
Distinguishing Protein Nanocrystals from
Amorphous Precipitate by Depolarized Dynamic Light Scattering |
4.7. |
S6-L4 |
15:30 |
Orville |
Allen |
Acoustic droplet ejection: from
crystallisation through time-resolved SFX |
4.7. |
S6-L5 |
16:00 |
Smith |
Vernon |
The changing role of in-house
crystallography |
4.7. |
KN |
18:45 |
Yonath |
Ada |
The Recent Resolution Revolution & Friendly
Medicine |
5.7. |
S7-L1 |
08:30 |
Bergfors |
Terese |
Strategies and stories for the small-scale
crystallization laboratory |
5.7. |
S7-L2 |
09:00 |
Saridakis |
Emmanuel |
Thermodynamic stabilisation, entropy, and
crystallisation of proteins. |
5.7. |
S7-L3 |
09:30 |
Bruder |
Lisza |
Glycerol alters substrate binding in
PTPLP:IP complexes |
5.7. |
S7-L4 |
09:50 |
Hasek |
Jindrich |
CONTROLLING THE GRYSTAL GROWTH. WHY IS
POLY(ETHYLENEGLYCOL) THE MOST EFFECTIVE PRECIPITANT FOR PROTEIN
CRYSTALLIZATION? |
5.7. |
S7-L5 |
10:10 |
McPherson |
Alexander |
Experiments on the Diffusion of Dyes and
Ions into Protein Crystals |
5.7. |
S8-L1 |
11:00 |
Ennifar |
Eric |
ITC-assisted crystallization of
protein-ligand complexes |
5.7. |
S8-L2 |
11:30 |
Luecke |
Hartmut |
Membrane Protein Crystallization Using
Cubic Lipid Phases, Bicelles and Vapor Diffusion |
5.7. |
S8-L3 |
12:00 |
Moreno |
Abel |
Myths and realities about the influence of
electric and magnetic fields on protein crystallization and protein
crystal growth |
5.7. |
S8-L4 |
12:20 |
Ristic |
Marko |
Computational tools to aid crystallization |
5.7. |
S8-L5 |
12:40 |
Jocks |
Thomas |
How light scattering can contribute to
purification, characterization and crystallization of proteins |
5.7. |
S9-L1 |
14:00 |
Newman |
Janet |
What’s in a drop? Moving from images to
outcomes. |
5.7. |
S9-L2 |
14:30 |
Wilson |
Julie |
Automated scoring of crystallisation
experiments using multiple images |
5.7. |
S9-L3 |
15:00 |
Acharya |
Samyam |
A Genetic Algorithm for the Optimization of
Protein Crystallization Screening |
5.7. |
S9-L4 |
15:20 |
Criswell |
Angela |
An add-on device for automated in situ
diffraction screening |
5.7. |
S10-L1 |
16:10 |
Sauter |
Claude |
Biological crystallization: from the
classroom to the bench |
5.7. |
S10-L2 |
16:40 |
Caffrey |
Martin |
A Laboratory Course on Crystallizing
Membrane and Soluble Proteins and Complexes by the Lipid Cubic Phase (In
Meso) Method |
5.7. |
S10-L3 |
17:10 |
Veesler |
Stephane |
Teaching (macromolecular) crystallization
with movies |
5.7. |
S10-L4 |
17:30 |
Spano |
Monika |
Optimization of Crystallization using
Dialysis Combined with Temperature Control |
5.7. |
S10-L5 |
17:50 |
Garcia Ruiz |
Juan Manuel |
Teaching protein crystallization at the
Laboratory for Crystallographic Studies (Granada, Spain) |
6.7. |
KN-3 |
08:30 |
Garcia Ruiz |
Juan Manuel |
The impact of crystals and crystallography
in art and culture |
6.7. |
S11-L1 |
09:20 |
Sugiyama |
Shigeru |
Growth of Protein Seed Crystals with
High-Strength Hydrogels |
6.7. |
S11-L2 |
09:50 |
Blakeley |
Matthew |
Neutron cryo-crystallography: methods,
applications and challenges |
6.7. |
S11-L3 |
10:20 |
Meilleur |
Flora |
Crystallization of a fungal polysaccharide
monooxygenase for neutron crystallography |
6.7. |
S11-L4 |
10:50 |
Junius |
Niels |
Crystallization with an automated apparatus
for temperature-controlled flow-cell dialysis with real-time
visualization |
6.7. |
KN-4 |
11:40 |
Giege |
Richard |
What biocrystallogenesis tells us – What is
needed in the future |
7.7. |
S12-L1 |
08:30 |
Vekilov |
Peter |
Are the protein pre-nucleation clusters
equilibrium structures or irreversible aggregates? |
7.7. |
S12-L2 |
08:50 |
Hargreaves |
David |
Antibodies as Chaperones in
Crystallisation: Parameters for Success. |
7.7. |
S12-L3 |
09:10 |
Gavira |
Jose Antonio |
Protein crystallization in hydrogels,
current status and future prospect |
7.7. |
S12-L4 |
09:30 |
Thaw |
Paul |
Flying through optimization screening with
dragonfly |
7.7. |
S12-L5 |
09:50 |
Urbániková |
Lubica |
Protein crystallisation - tricks and
practise |
7.7. |
S12-L6 |
10:10 |
Calero |
Guillermo |
Transmission electron microscopy for the
evaluation and optimization of crystal growth |
7.7. |
S13-L1 |
11:00 |
DArcy |
Allan |
A rational approach to crystallising
proteins in the pharmaceutical industry, the impact of micro seed matrix
seeding |
7.7. |
S13-L2 |
11:30 |
Oster Landgren |
Linda |
Successful generation of structural
information for fragment-based drug discovery |
7.7. |
S13-L3 |
11:50 |
Peignier |
Thomas |
XRayLab: an X-ray diffraction facility for
the International Space Station dedicated to the study of space-grown
crystals |
7.7. |
S13-L4 |
12:10 |
Hou |
Hai |
A comparative study on the diffraction
quality of protein crystals obtained using the cross-diffusion
microbatch and sitting-drop vapor diffusion methods |
7.7. |
S14-L1 |
13:30 |
Kowacz |
Magdalena |
Ionic liquids (ILs)-water interplay in
protein crystallization. From IL additives to nucleants to … |
7.7. |
S14-L2 |
14:00 |
Pusey |
Marc |
Ionic Liquids as Protein Crystallization
Additives |
7.7. |
S14-L3 |
14:30 |
Maes |
Dominique |
The artificial protein Octarellin
challenges crystallographers and modellers |
7.7. |
S14-L4 |
14:50 |
Charbonneau |
Patrick |
Water in Protein Crystals |
7.7. |
S14-L5 |
15:10 |
Petri |
Edward |
Use of X-ray crystallographic data for
computational modelling of receptor-ligand interactions: design of
steroidal inhibitors of breast and prostate cancer cell growth |