A gateway to realm of structural data for biochemists, biophysicists, molecular biologist, and all scientists whose research benefits from accurate structure determination of biological macromolecules, assemblies, and complex molecular machineries at atomic resolution.
Open access to 10 high-end core facilities and assisted expertise in NMR, X-ray crystallography and crystallization, cryo-electron microscopy and tomography, biophysical characterization of biomolecular interaction, nanobiotechnology, proteomics and structural mass spectrometry.
A distributed infrastructure constituted by Core Facilities of CEITEC (Central European Institute of Technology), located in Brno, and BIOCEV (Biotechnology and Biomedicine Centre), located in Vestec near Prague, Central Bohemia.
N. Labajová, et al.: Membrane remodeling and higher-order structure formation by DivIVA, International Journal of Biological Macromolecules, 354 (2026) 151388, 10.1016/j.ijbiomac.2026.151388
P. Ryzhaya, et al.: Enhanced plant bottom-up histone proteomics, Journal of Experimental Botany, 2026, 10.1093/jxb/erag100
M. Rivero, et al.: Tyrosine residues at the substrate binding site in human NQO1 homodimer: Protein conformational dynamics and optimization of substrate binding geometry, The FEBS Journal, 2026, 10.1111/febs.70511
J. Stromska, et al.: Ceramides versus standard methods in prediction of subclinical atherosclerosis, Biomedical Papers, 2026, 10.5507/bp.2026.005
F. Svěrák, et al.: Dual-organoid biosensor for monitoring cardiac conduction disturbances in vitro, Analytica Chimica Acta, 1383 (2026) 344874, 10.1016/j.aca.2025.344874
G. Salai, et al.: Proteomics-Based Study of Potential Emphysema Biomarkers Reveals Systemic Redox System and Extracellular Matrix Component Dysregulation, Diagnostics, 16 (2026) 6 931, 10.3390/diagnostics16060931
M. Kotik, et al.: Redirecting a Fungal Quercetin 2,3-Dioxygenase Toward Artificial Flavonols, ChemCatChem, 18 (2026) 6, 10.1002/cctc.202501823
D. A. Kabanov, et al.: A comprehensive system of algorithms for characterization of cardiomyocyte mechanical and electrical function, Biomedical Signal Processing and Control, 120 (2026) 110125, 10.1016/j.bspc.2026.110125
D. Skoda, et al.: Microwave-assisted one-pot sol–gel synthesis of tungsten silicate microspheres with dispersed WOx and their activity in ethanol dehydration, Journal of Materials Chemistry A, 2026, 10.1039/d5ta08046k
M. Grunová, et al.: A Bambusuril That Responds to Anion Binding in Its Absorption Spectrum, The Journal of Organic Chemistry, 91 (2026) 15 5298–5304, 10.1021/acs.joc.5c03154
the best of science obtained using CIISB Core Facilities
Light and scanning electron microscopy comparison of silique size between αKNL2-C-EYFP and αKNL2-CMut-SUMO-EYFP plants.
Significance
The centromere is a specialized domain that facilitates chromosome segregation during mitosis and serves as the site of kinetochore formation. KINETOCHORE NULL2 (alpha KNL2) is essential for the recognition and loading of the centromeric histone H3 variant CENH3 at centromeres. A yeast two-hybrid screen for alpha KNL2 interactors identified components of the SUMOylation pathway. However, the role of alpha KNL2 SUMOylation in Arabidopsis has not yet been determined. In this study, we demonstrated that the C-terminal region of alpha KNL2 (designated alpha KNL2-C) interacts with small ubiquitin-like modifier 3 (SUMO3) and ULP1d, as shown by bimolecular fluorescence complementation and co-immunoprecipitation assays. Bioinformatic and functional analyses of alpha KNL2-C identified three SUMOylation sites and two SUMO-interacting motifs, which were shown to be critical for growth, fertility, and chromosome alignment. Of the three SUMOylation sites, Lys474 and Lys511 are the most critical for the centromeric localization of alpha KNL2, underscoring the importance of alpha KNL2 SUMOylation for its function. Additionally, both in vitro and in vivo assays showed that alpha KNL2-C undergoes SUMOylation by SUMO1 or SUMO3. The Arabidopsis SUMO protease mutant ulp1d-2 exhibits a mild accumulation of SUMOylated alpha KNL2. We further showed that SUMOylation of alpha KNL2 promotes its binding to CENH3 and controls protein stability. Our findings demonstrate that C-terminal SUMOylation of alpha KNL2 is crucial for its centromeric localization, interaction with CENH3, and kinetochore assembly, emphasizing the significance of post-translational modifications in chromosome segregation and cell division in plants.
Kalidass M. et al.: The C-terminal SuMOylation-dependent regulation of aKNL2 governs its centromere targeting and interaction with CENH3
Plant Communications, DOI: 10.1016/j.xplc.2025.101617
Electron diffraction tomography data of in cellulo MgHEX-1 crystal.
V. Polovinkin research group
Significance
Intracellular crystallization is an emerging approach in structural biology that bypasses the need for protein purification. In 2024, the InCellCryst pipeline was introduced for structural studies of intracellular crystals by serial X-ray crystallography. Serial crystallography requires the exposure of tens of thousands of cells containing intracellular crystals, precluding high-resolution studies on proteins that crystallize only in a few cells. Here we introduce IncelluloED, a method that combines intracellular crystallization with in situ 3D electron diffraction in cells and achieves high-resolution structures from just one crystal inside one cell. Experiments on a microcrystal of the HEX-1 protein from Magnaporthe grisea, grown inside an insect cell, give a structure at 1.9 angstrom resolution from a volume of similar to 1.6 mu m(3) as compared to 1.8 angstrom resolution achieved by serial X-ray crystallography from a combined volume exceeding eleven million mu m(3). IncelluloED uses widely available cryo-EM tools and brings high-resolution structural biology into home laboratories while also advancing a vision for a "single-cell structural laboratory".
Bila S. et al.: Single-cell structural biology with intracellular electron crystallography
Nature Communications, DOI: 10.1038/s41467-026-69205-6
Analytical ultracentrifugation characterization of wt-CTTN.
Significance
Lysine acetylation within the tandem repeat region of cortactin (CTTN) regulates its actin-binding function and has been linked to cancer cell migration and neuronal development. While several lysine deacetylases (KDACs) have been implicated in modulating CTTN acetylation in cells, their site specificity and direct enzymatic roles remain poorly defined. Here, we use genetic code expansion to generate seven site-specifically acetylated CTTN variants and assess their deacetylation by human KDACs in a fully reconstituted in vitro system. Our results identify HDAC6 as the primary CTTN deacetylase, acting via its second catalytic domain (DD2), and demonstrate that SIRT1 and SIRT2 also directly deacetylate CTTN at overlapping sites in an NAD+-dependent manner. In contrast, other zinc-dependent HDACs, including HDAC8, displayed negligible or very weak activity on full-length CTTN. These findings provide new mechanistic insight into KDAC substrate preferences and highlight the value of biochemical reconstitution for dissecting complex acetylation networks.
Komarek J. et al.: Selective targeting of cortactin tandem repeat acetylation by human lysine deacetylases
FEBS Journal, DOI: 10.1111/febs.70430
“If you want to understand function, study structure.”
— Francis Crick
