Your search keyword '"Kassem, Noah"' showing total 12 results

1. Yeast recombinant production of intact human membrane proteins with long intrinsically disordered intracellular regions for structural studies

Author

Kassem, Noah, Kassem, Maher M., Pedersen, Stine F., Pedersen, Per Amstrup, and Kragelund, Birthe B.

Published

2020

2. Checkpoint activation by Spd1: a competition-based system relying on tandem disordered PCNA binding motifs

Author

0000-0002-5459-9608, 0000-0001-9224-0543, 0000-0001-7440-5201, 0000-0002-7454-1761, Olsen, Johan G., Prestel, Andreas, Kassem, Noah, Broendum, Sebastian S., Shamim, Hossain Mohammad, Simonsen, Signe, Grysbæk, Martin, Mortensen, Josefine, Rytkjær, Louise Lund, Haxholm, Gitte W., Marabini, Riccardo, Holmberg, Christian, Carr, Antony M., Crehuet, Ramon, Nielsen, Olaf, Kragelund, Birthe B., 0000-0002-5459-9608, 0000-0001-9224-0543, 0000-0001-7440-5201, 0000-0002-7454-1761, Olsen, Johan G., Prestel, Andreas, Kassem, Noah, Broendum, Sebastian S., Shamim, Hossain Mohammad, Simonsen, Signe, Grysbæk, Martin, Mortensen, Josefine, Rytkjær, Louise Lund, Haxholm, Gitte W., Marabini, Riccardo, Holmberg, Christian, Carr, Antony M., Crehuet, Ramon, Nielsen, Olaf, and Kragelund, Birthe B.

Abstract

DNA regulation, replication and repair are processes fundamental to all known organisms and the sliding clamp proliferating cell nuclear antigen (PCNA) is central to all these processes. S-phase delaying protein 1 (Spd1) from S. pombe, an intrinsically disordered protein that causes checkpoint activation by inhibiting the enzyme ribonucleotide reductase, has one of the most divergent PCNA binding motifs known. Using NMR spectroscopy, in vivo assays, X-ray crystallography, calorimetry, and Monte Carlo simulations, an additional PCNA binding motif in Spd1, a PIP-box, is revealed. The two tandemly positioned, low affinity sites exchange rapidly on PCNA exploiting the same binding sites. Increasing or decreasing the binding affinity between Spd1 and PCNA through mutations of either motif compromised the ability of Spd1 to cause checkpoint activation in yeast. These results pinpoint a role for PCNA in Spd1-mediated checkpoint activation and suggest that its tandemly positioned short linear motifs create a neatly balanced competition-based system, involving PCNA, Spd1 and the small ribonucleotide reductase subunit, Suc22R2. Similar mechanisms may be relevant in other PCNA binding ligands where divergent binding motifs so far have gone under the PIP-box radar.

Published

2024

3. Checkpoint activation by Spd1:a competition-based system relying on tandem disordered PCNA binding motifs

Author

Olsen, Johan G, Prestel, Andreas, Kassem, Noah, Broendum, Sebastian S, Shamim, Hossain Mohammad, Simonsen, Signe, Grysbæk, Martin, Mortensen, Josefine, Rytkjær, Louise Lund, Haxholm, Gitte W, Marabini, Riccardo, Holmberg, Christian, Carr, Antony M, Crehuet, Ramon, Nielsen, Olaf, Kragelund, Birthe B, Olsen, Johan G, Prestel, Andreas, Kassem, Noah, Broendum, Sebastian S, Shamim, Hossain Mohammad, Simonsen, Signe, Grysbæk, Martin, Mortensen, Josefine, Rytkjær, Louise Lund, Haxholm, Gitte W, Marabini, Riccardo, Holmberg, Christian, Carr, Antony M, Crehuet, Ramon, Nielsen, Olaf, and Kragelund, Birthe B

Abstract

DNA regulation, replication and repair are processes fundamental to all known organisms and the sliding clamp proliferating cell nuclear antigen (PCNA) is central to all these processes. S-phase delaying protein 1 (Spd1) from S. pombe, an intrinsically disordered protein that causes checkpoint activation by inhibiting the enzyme ribonucleotide reductase, has one of the most divergent PCNA binding motifs known. Using NMR spectroscopy, in vivo assays, X-ray crystallography, calorimetry, and Monte Carlo simulations, an additional PCNA binding motif in Spd1, a PIP-box, is revealed. The two tandemly positioned, low affinity sites exchange rapidly on PCNA exploiting the same binding sites. Increasing or decreasing the binding affinity between Spd1 and PCNA through mutations of either motif compromised the ability of Spd1 to cause checkpoint activation in yeast. These results pinpoint a role for PCNA in Spd1-mediated checkpoint activation and suggest that its tandemly positioned short linear motifs create a neatly balanced competition-based system, involving PCNA, Spd1 and the small ribonucleotide reductase subunit, Suc22R2. Similar mechanisms may be relevant in other PCNA binding ligands where divergent binding motifs so far have gone under the PIP-box radar., DNA regulation, replication and repair are processes fundamental to all known organisms and the sliding clamp proliferating cell nuclear antigen (PCNA) is central to all these processes. S-phase delaying protein 1 (Spd1) from S. pombe, an intrinsically disordered protein that causes checkpoint activation by inhibiting the enzyme ribonucleotide reductase, has one of the most divergent PCNA binding motifs known. Using NMR spectroscopy, in vivo assays, X-ray crystallography, calorimetry, and Monte Carlo simulations, an additional PCNA binding motif in Spd1, a PIP-box, is revealed. The two tandemly positioned, low affinity sites exchange rapidly on PCNA exploiting the same binding sites. Increasing or decreasing the binding affinity between Spd1 and PCNA through mutations of either motif compromised the ability of Spd1 to cause checkpoint activation in yeast. These results pinpoint a role for PCNA in Spd1-mediated checkpoint activation and suggest that its tandemly positioned short linear motifs create a neatly balanced competition-based system, involving PCNA, Spd1 and the small ribonucleotide reductase subunit, Suc22R2. Similar mechanisms may be relevant in other PCNA binding ligands where divergent binding motifs so far have gone under the PIP-box radar.

Published

2024

4. Checkpoint activation by Spd1: a competition-based system relying on tandem disordered PCNA binding motifs

Author

Olsen, Johan G, primary, Prestel, Andreas, additional, Kassem, Noah, additional, Broendum, Sebastian S, additional, Shamim, Hossain Mohammad, additional, Simonsen, Signe, additional, Grysbæk, Martin, additional, Mortensen, Josefine, additional, Rytkjær, Louise Lund, additional, Haxholm, Gitte W, additional, Marabini, Riccardo, additional, Holmberg, Christian, additional, Carr, Antony M, additional, Crehuet, Ramon, additional, Nielsen, Olaf, additional, and Kragelund, Birthe B, additional

Published

2024

5. The PCNA interaction motifs revisited: thinking outside the PIP-box

Author

Prestel, Andreas, Wichmann, Nanna, Martins, Joao M., Marabini, Riccardo, Kassem, Noah, Broendum, Sebastian S., Otterlei, Marit, Nielsen, Olaf, Willemoës, Martin, Ploug, Michael, Boomsma, Wouter, and Kragelund, Birthe B.

Published

2019

6. Checkpoint activation by Spd1: a competition-based system relying on tandem disordered PCNA binding motifs

Author

Olsen, Johan G., primary, Prestel, Andreas, additional, Kassem, Noah, additional, Broendum, Sebastian Sven, additional, Shamim, Hossein Mohammad, additional, Simonsen, Signe, additional, Grysbaek, Martin, additional, Mortensen, Josefine, additional, Rytkjaer, Louise Lund, additional, Haxholm, Gitte W., additional, Marabini, Riccardo, additional, Carr, Anthony, additional, Crehuet, Ramon, additional, Nielsen, Olaf, additional, and Kragelund, Birthe B., additional

Published

2023

7. Order and disorder—An integrative structure of the full-length human growth hormone receptor

Author

Kassem, Noah, primary, Araya-Secchi, Raul, additional, Bugge, Katrine, additional, Barclay, Abigail, additional, Steinocher, Helena, additional, Khondker, Adree, additional, Wang, Yong, additional, Lenard, Aneta J., additional, Bürck, Jochen, additional, Sahin, Cagla, additional, Ulrich, Anne S., additional, Landreh, Michael, additional, Pedersen, Martin Cramer, additional, Rheinstädter, Maikel C., additional, Pedersen, Per Amstrup, additional, Lindorff-Larsen, Kresten, additional, Arleth, Lise, additional, and Kragelund, Birthe B., additional

Published

2021

8. Order and disorder - An integrative structure of the full-length human growth hormone receptor

Author

Kassem, Noah, Araya-Secchi, Raul, Bugge, Katrine, Barclay, Abigail, Steinocher, Helena, Khondker, Adree, Wang, Yong, Lenard, Aneta J., Bürck, Jochen, Sahin, Cagla, Ulrich, Anne S., Landreh, Michael, Pedersen, Martin Cramer, Rheinstädter, Maikel C., Pedersen, Per Amstrup, Lindorff-Larsen, Kresten, Arleth, Lise, Kragelund, Birthe B., Kassem, Noah, Araya-Secchi, Raul, Bugge, Katrine, Barclay, Abigail, Steinocher, Helena, Khondker, Adree, Wang, Yong, Lenard, Aneta J., Bürck, Jochen, Sahin, Cagla, Ulrich, Anne S., Landreh, Michael, Pedersen, Martin Cramer, Rheinstädter, Maikel C., Pedersen, Per Amstrup, Lindorff-Larsen, Kresten, Arleth, Lise, and Kragelund, Birthe B.

Abstract

Because of its small size (70 kilodalton) and large content of structural disorder (>50%), the human growth hormone receptor (hGHR) falls between the cracks of conventional high-resolution structural biology methods. Here, we study the structure of the full-length hGHR in nanodiscs with small-angle x-ray scattering (SAXS) as the foundation. We develop an approach that combines SAXS, x-ray diffraction, and NMR spectroscopy data obtained on individual domains and integrate these through molecular dynamics simulations to interpret SAXS data on the full-length hGHR in nanodiscs. The hGHR domains reorient freely, resulting in a broad structural ensemble, emphasizing the need to take an ensemble view on signaling of relevance to disease states. The structure provides the first experimental model of any full-length cytokine receptor in a lipid membrane and exemplifies how integrating experimental data from several techniques computationally may access structures of membrane proteins with long, disordered regions, a widespread phenomenon in biology.

Published

2021

9. Order and disorder – an integrative structure of the full-length human growth hormone receptor

Author

Kassem, Noah, primary, Araya-Secchi, Raul, additional, Bugge, Katrine, additional, Barclay, Abigail, additional, Steinocher, Helena, additional, Khondker, Adree, additional, Lenard, Aneta J., additional, Bürck, Jochen, additional, Ulrich, Anne S., additional, Pedersen, Martin Cramer, additional, Wang, Yong, additional, Rheinstädter, Maikel C., additional, Pedersen, Per Amstrup, additional, Lindorff-Larsen, Kresten, additional, Arleth, Lise, additional, and Kragelund, Birthe B., additional

Published

2020

10. From single-pass to multi-pass membrane proteins:Expression, purification and structural characterization by integrative methods

Author

Kassem, Noah and Kassem, Noah

Abstract

The cell membrane and organellar membranes are instrumental in processes including compartmentalization, protecting cells and transducing signals between compartments. Membrane proteins reside within these membranes and they represent an important class of proteins that have many cellular functions. It is estimated the 22% of the human genome consists of genes encoding membrane proteins. Additionally, 60% of therapeutic drugs target membrane proteins. Unfortunately, due to difficulties at the experimental level, an understanding of membrane protein structures is lagging heavily behind compared to water soluble proteins. This impairs our understanding of the functions and mechanisms of membrane proteins, thus preventing further applied biomedical and biotechnological research. This has led to increasing advances in recombinant production systems, membrane protein carrier systems, and in structural biology methods. Two potential prime drug targets for cancer and cardiovascular diseases are the human sodium-proton exchanger 1 (hNHE1) and the human growth hormone receptor (hGHR). They are widely different, only sharing characteristics as having large intrinsically disordered C-terminal domains. However, only limited structural studies of the full-length hNHE1 and the full-length hGHR exist. Therefore, in the work of this thesis we developed novel protocols to express both hGHR and hNHE1 in an eukaryotic yeast expression system, tested their functionality and purified them to homogeneity in amounts needed for structural characterization. We studied hNHE1 by cryoEM suggesting that hNHE1 forms dimers. We also succeeded in reconstituting hNHE1 in nanodiscs, which laid the foundation for future studies of hNHE1 in nanodiscs by cryoEM. To study the full-length hGHR we reconstituted it into nanodiscs and studied it by combining SAXS, SANS, NMR spectroscopy, and computational modeling in an integrative process to provide a novel full-length structure of the hGHR. This structure

Published

2019

11. The PCNA interaction motifs revisited:thinking outside the PIP-box

Author

Prestel, Andreas, Wichmann, Nanna, Martins, Joao M., Marabini, Riccardo, Kassem, Noah, Broendum, Sebastian S., Otterlei, Marit, Nielsen, Olaf, Willemoës, Martin, Ploug, Michael, Boomsma, Wouter, Kragelund, Birthe B., Prestel, Andreas, Wichmann, Nanna, Martins, Joao M., Marabini, Riccardo, Kassem, Noah, Broendum, Sebastian S., Otterlei, Marit, Nielsen, Olaf, Willemoës, Martin, Ploug, Michael, Boomsma, Wouter, and Kragelund, Birthe B.

Abstract

Proliferating cell nuclear antigen (PCNA) is a cellular hub in DNA metabolism and a potential drug target. Its binding partners carry a short linear motif (SLiM) known as the PCNA-interacting protein-box (PIP-box), but sequence-divergent motifs have been reported to bind to the same binding pocket. To investigate how PCNA accommodates motif diversity, we assembled a set of 77 experimentally confirmed PCNA-binding proteins and analyzed features underlying their binding affinity. Combining NMR spectroscopy, affinity measurements and computational analyses, we corroborate that most PCNA-binding motifs reside in intrinsically disordered regions, that structure preformation is unrelated to affinity, and that the sequence-patterns that encode binding affinity extend substantially beyond the boundaries of the PIP-box. Our systematic multidisciplinary approach expands current views on PCNA interactions and reveals that the PIP-box affinity can be modulated over four orders of magnitude by positive charges in the flanking regions. Including the flanking regions as part of the motif is expected to have broad implications, particularly for interpretation of disease-causing mutations and drug-design, targeting DNA-replication and -repair.

Published

2019

12. Kassem, Noah

Author

Kassem, Noah and Kassem, Noah

Published

2016