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Biological Physics and Bioinformatics Seminar

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Prof. dr hab. Dariusz Plewczynski (Wydział Matematyki i Nauk Informacyjnych - Politechnika Warszawska, Centrum Nowych Technologii - Uniwersytet Warszawski)

Loop Extrusion Model (LEM) at the large scale: training Artiﬁcial Intelligence (AI) to understand the link between sequence, structure, and function of human genome

https://zoom.us/j/91976153012?pwd=azNiMWE4UnhPN3lRQlY2UHZHOXVkQT09
Meeting ID: 919 7615 3012
Passcode: 747922
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+48223987356,,91976153012#,,,,*747922# Poland
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Bogdan Lesyng (UW)
Anna Niedźwiecka (IF PAN)
Piotr Zielenkiewicz (IBB)

Abstract
Loop extrusion is a model that aims to describe the process by which chromatin loops are formed and maintained within the three-dimensional (3D) structure of the genome. This model is particularly relevant for understanding the organization and function of Topologically Associating Domains (TADs), which are self-interacting genomic regions that have been implicated in gene regulation, chromatin organization, and other nuclear processes. The loop extrusion model provides a theoretical framework to explain how chromatin loops are dynamically formed, stabilized, and disassembled, as well as the role of key protein factors such as cohesin and CTCF in this process.
According to the loop extrusion model, chromatin loops are generated by the action of a molecular complex called the extrusion complex, composed of the ring-shaped cohesin protein and other associated factors. The extrusion complex is loaded onto the chromatin ﬁber and starts to extrude the chromatin by translocating along the DNA, progressively enlarging the loop. As the extrusion complex moves, it brings together distant genomic regions, thereby facilitating their spatial proximity and interactions.
The loop extrusion process continues until the extrusion complex encounters a boundary element, often formed by the binding of the CCCTC-binding factor (CTCF) protein to speciﬁc DNA sequences. CTCF acts as a barrier or insulator, preventing the extrusion complex from progressing further and deﬁning the borders of TADs. This leads to the formation of stable chromatin loops, which can bring together regulatory elements such as enhancers and promoters, thus inﬂuencing gene expression.
Loop extrusion modeling has several important implications for our understanding of genome organization and function:
1. Formation and stabilization of TADs: The loop extrusion model provides a mechanistic explanation for the formation and stabilization of TADs, which are essential for maintaining proper chromatin organization and ensuring accurate gene regulation.
2. Dynamic nature of chromatin loops: Loop extrusion emphasizes the dynamic nature of chromatin loop formation and disassembly, which is crucial for understanding how the 3D genome structure adapts to diﬀerent cellular contexts and changes during development.
3. Role of cohesin and CTCF: The model highlights the critical role of cohesin and CTCF proteins in shaping the 3D genome structure by mediating loop extrusion and deﬁning TAD boundaries, respectively.
4. Implications for gene regulation: Loop extrusion can bring together distant genomic regions, such as enhancers and promoters, facilitating their interaction and potentially inﬂuencing gene expression.
5. Relevance for disease: Disruptions in the loop extrusion process or the factors involved may contribute to various diseases, including developmental disorders and cancer, by aﬀecting chromatin organization and gene regulation.
6. Artiﬁcial Intelligence: our comprehensive approach combining machine learning models, polymer biophysical simulations, and experimental 3D genomics methods provides a powerful tool for studying human genome topology at the single chromatin loop scale. It has enabled us to gain new insights into the relationship between DNA sequence, structure, and function, with important implications for understanding disease development and potential therapeutic interventions.
In summary, loop extrusion modeling provides a comprehensive framework for understanding the formation and maintenance of chromatin loops and their role in the 3D organization of the genome. This model has important implications for gene regulation, genome function, and the molecular basis of various diseases.

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Dr Emilia Lubecka (Instytut Fizyki PAN, Warszawa)

Early Stages of RNA-Mediated Conversion of Human Prions

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Dr hab. Sergey Samsonov, prof. UG (Wydział Chemii, Uniwersytet Gdański)

Computational approaches to model glycosaminoglycan containing, biologically relevant systems

Proteins gain their functional structure in the process of protein folding. Most proteins begin to fold co-translationally on the ribosome while they emerge from its exit tunnel during protein biosynthesis. This is a fundamental process for maintaining cellular proteostasis, failure of which results in polypeptide misfolding and diseases such as Parkinson’s, Alzheimer’s or other proteinopathies. Despite its importance, it remains poorly understood as it is a significant challenge to obtain high-resolution structural data of co-translational protein folding (coTF) using structural biology methods alone; particularly the description of the folding pathways is missing. Consequently, the use of accurate and efficient computational techniques, especially in combination with NMR and cryo-EM experimental data used as restraints, for reweighting or validation, is imperative for a detailed understanding of protein folding in the cell. In this presentation, I will describe an integrative structural biology approach to study co-translational protein folding, combining bioinformatics, all-atom and coarse-grained molecular dynamics (MD) simulations with structural restraints from various experimental data (NMR chemical shifts, RDCs and cryo-EM maps) and applied it to provide a high-resolution description of snapshots of the protein biosynthesis. I will present the characterisation of the dynamics and interactions of both folded and intrinsically disordered nascent chains on the wild-type bacterial ribosome and the rationally designed ribosome based on bioinformatics analysis. Finally, I will provide the first structural insights into the co-translational folding intermediate that were experimentally confirmed and are the first step to fully characterising the co-translational folding pathway.

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Dr Tomasz Włodarski (Department of Structural and Molecular Biology, University College London, UK)

A computational microscope to study co-translational protein folding

Proteins gain their functional structure in the process of protein folding. Most proteins begin to fold co-translationally on the ribosome while they emerge from its exit tunnel during protein biosynthesis. This is a fundamental process for maintaining cellular proteostasis, failure of which results in polypeptide misfolding and diseases such as Parkinson's, Alzheimer's or other proteinopathies. Despite its importance, it remains poorly understood as it is a significant challenge to obtain high-resolution structural data of co-translational protein folding (coTF) using structural biology methods alone; particularly the description of the folding pathways is missing. Consequently, the use of accurate and efficient computational techniques, especially in combination with NMR and cryo-EM experimental data used as restraints, for reweighting or validation, is imperative for a detailed understanding of protein folding in the cell. In this presentation, I will describe an integrative structural biology approach to study co-translational protein folding, combining bioinformatics, all-atom and coarse-grained molecular dynamics (MD) simulations with structural restraints from various experimental data (NMR chemical shifts, RDCs and cryo-EM maps) and applied it to provide a high-resolution description of snapshots of the protein biosynthesis. I will present the characterisation of the dynamics and interactions of both folded and intrinsically disordered nascent chains on the wild-type bacterial ribosome and the rationally designed ribosome based on bioinformatics analysis. Finally, I will provide the first structural insights into the co-translational folding intermediate that were experimentally confirmed and are the first step to fully characterising the co-translational folding pathway.

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Prof. dr hab. Małgorzata Lekka (Department of Biophysical Microstructures, Institute of Nuclear Physics, Polish Academy of Sciences, Kraków)

Mechanics and rheology of cells and tissues in diseases

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Dr Beata Kliszcz (Instytut Biologii Doświadczalnej im. M. Nenckiego PAN, Warszawa; obecna afiliacja: Instytut Fizyki PAN, Warszawa)

The mechanism of microtubule-pair sliding driven by kinesin-1 in vitro

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Dr hab. Michał Rode (Instytut Fizyki PAN, Warszawa)

Intramolecular mechanisms in photochromic organic molecules

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Prof. Krzysztof Kuczera (Chemistry and Molecular Biosciences, University of Kansas at Lawrence)

Thermodynamics and kinetics of GB1 hairpin folding from replica-exchange and molecular dynamics simulations

Abstract
We have performed molecular dynamics (MD) and replica-exchange (REMD) simulations of folding for the 16-residue GB1 hairpin peptide in explicit solvent. REMD predicts a folded hairpin fraction of 39-41% at 320 K and a statistical folding pathway consistent with a zipper model. Based on 120 microseconds of MD trajectories at 320 K, the two slowest relaxation times were 1,800 and 170 ns, with the slower one assigned to global folding. MD trajectories also followed the zipper mechanism, with nucleation at the central turn followed by consecutive hydrogen bond formation/breaking in a highly cooperative manner. Backbone and hydrophobic sidechain aggregation were highly correlated as well. We also constructed coarse-grained kinetic models with the Optimal Dimensionality Reduction (ODR) approach. Besides the 1,800 ns folding process, additional relaxation times in the 130-170 ns range could be assigned to formation/decay of the transition state and off-path intermediates. The ‘coil’ state was the most highly populated and also most heterogenous, including primarily extended and turn structures. The ‘hairpin’ state was also heterogenous, , involving fully folded and partially folded in-register hairpins along the zipper pathway. The transition state corresponded to the nucleated hairpin. Overall, our simulations were in excellent agreement with experimental data on folded fraction, relaxation time and folding mechanism. Additionally, the kinetic modeling allowed identification of a nascent hairpin as a transition state for folding and a faster relaxation time of ~100 ns related to formation of off-path intermediates and the transition state.

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Presentation by prof. dr hab. Piotr Paneth (Faculty of Chemistry, Technical University of Łódź)

"Non-covalent isotope effects" Mateusz Pokora, Agata Paneth, Piotr Paneth

Abstract
While isotope effects are, by the Bigeleisen equation, understood as the result of changes in force constants involving the isotopic atom, a plethora of observed isotope effects result from processes that apparently do not introduce such changes. These include secondary kinetic isotope effects, as well as isotope effects on chromatographic retention times, vapor pressure isotope effects, isotope effects on diffusion, miscibility of liquids, and many other physical processes. They are important from the practical point of view as they are used in the technological processes of isotopic enrichment that finds their place in the newest applications in nanomaterials. In this presentation, we'll provide several examples and address the origins of these phenomena from the computational point of view.

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Łukasz Charzewski (PhD student, Faculty of Physics, University of Warsaw)

Structural characterization of MMP‐9 forms and their implications for activity regulation

Abstract
Matrix metalloproteinase 9 (MMP-9) is one of the most intensively studied zinc-dependent endopeptidases. As an exocellular proteolytic enzyme MMP-9 takes part in a vast number of physiological processes including angiogenesis, neural plasticity, or modulation of inflammatory processes. However, its overactivity can lead to neuronal damage, blood-brain-barrier opening, cancer progression or autoimmune diseases. The activity of secreted MMP-9 is controlled mainly on two levels: its proteolytic activation and inhibition by Tissue Inhibitors of MMP (TIMP) proteins. This talk will focus on structural aspects of a range of MMP-9 forms – monomers, homotrimers and NGAL-bound heterodimers in a context of interaction with TIMP-1, the primary MMP-9 inhibitor.

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prof. Mai Suan Li (Institute of Physics, Polish Academy of Sciences)

https://zoom.us/j/91976153012?pwd=azNiMWE4UnhPN3lRQlY2UHZHOXVkQT09
Meeting ID: 919 7615 3012
Passcode: 747922
One tap mobile
+48223073488,,91976153012#,,,,*747922# Poland
+48223987356,,91976153012#,,,,*747922# Poland
Dial by your location
+48 22 307 3488 Poland
+48 22 398 7356 Poland
+48 22 306 5342 Poland
Join by Skype for Business
https://zoom.us/skype/91976153012
Bogdan Lesyng (UW)
Anna Niedźwiecka (IF PAN)
Piotr Zielenkiewicz (IBB)

Biological Physics and Bioinformatics Seminar

Loop Extrusion Model (LEM) at the large scale: training Artiﬁcial Intelligence (AI) to understand the link between sequence, structure, and function of human genome

Early Stages of RNA-Mediated Conversion of Human Prions

Computational approaches to model glycosaminoglycan containing, biologically relevant systems

A computational microscope to study co-translational protein folding

Mechanics and rheology of cells and tissues in diseases

The mechanism of microtubule-pair sliding driven by kinesin-1 in vitro

Intramolecular mechanisms in photochromic organic molecules

Thermodynamics and kinetics of GB1 hairpin folding from replica-exchange and molecular dynamics simulations

"Non-covalent isotope effects" Mateusz Pokora, Agata Paneth, Piotr Paneth

Structural characterization of MMP‐9 forms and their implications for activity regulation

Protein Folding and Dimerization on Ribosomes

Experimental Charge Density Studies in Crystals - Requirements and Possibilities

Hidden, short-lived players of biological copper transport