Your search keyword '"Qamar, Seema"' showing total 6 results

1. Biomolecular condensates undergo a generic shear-mediated liquid-to-solid transition

Author

Shen, Yi, Ruggeri, Francesco Simone, Vigolo, Daniele, Kamada, Ayaka, Qamar, Seema, Levin, Aviad, Iserman, Christiane, Alberti, Simon, George-Hyslop, Peter St, and Knowles, Tuomas P. J.

Abstract

Membrane-less organelles resulting from liquid–liquid phase separation of biopolymers into intracellular condensates control essential biological functions, including messenger RNA processing, cell signalling and embryogenesis1–4. It has recently been discovered that several such protein condensates can undergo a further irreversible phase transition, forming solid nanoscale aggregates associated with neurodegenerative disease5–7. While the irreversible gelation of protein condensates is generally related to malfunction and disease, one case where the liquid-to-solid transition of protein condensates is functional, however, is that of silk spinning8,9. The formation of silk fibrils is largely driven by shear, yet it is not known what factors control the pathological gelation of functional condensates. Here we demonstrate that four proteins and one peptide system, with no function associated with fibre formation, have a strong propensity to undergo a liquid-to-solid transition when exposed to even low levels of mechanical shear once present in their liquid–liquid phase separated form. Using microfluidics to control the application of shear, we generated fibres from single-protein condensates and characterized their structural and material properties as a function of shear stress. Our results reveal generic backbone–backbone hydrogen bonding constraints as a determining factor in governing this transition. These observations suggest that shear can play an important role in the irreversible liquid-to-solid transition of protein condensates, shed light on the role of physical factors in driving this transition in protein aggregation-related diseases and open a new route towards artificial shear responsive biomaterials.

Published

2020

2. Thermodynamics of temperature modulation in biomolecular phase separation

Author

Fischer, Charlotte M., Ausserwöger, Hannes, Sneideris, Tomas, Qian, Daoyuan, Scrutton, Rob, Qamar, Seema, St George-Hyslop, Peter, and Knowles, Tuomas P.

Published

2024

3. Human H+ATPase a4 subunit mutations causing renal tubular acidosis reveal a role for interaction with phosphofructokinase-1

Author

Su, Ya, Blake-Palmer, Katherine G., Sorrell, Sara, Javid, Babak, Bowers, Katherine, Zhou, Aiwu, Chang, Simon H., Qamar, Seema, and Karet, Fiona E.

Abstract

The vacuolar-type ATPase (H+ATPase) is a ubiquitously expressed multisubunit pump whose regulation is poorly understood. Its membrane-integral a-subunit is involved in proton translocation and in humans has four forms, a1–a4. This study investigated two naturally occurring point mutations in a4's COOH terminus that cause recessive distal renal tubular acidosis (dRTA), R807Q and G820R. Both lie within a domain that binds the glycolytic enzyme phosphofructokinase-1 (PFK-1). We recreated these disease mutations in yeast to investigate effects on protein expression, H+ATPase assembly, targeting and activity, and performed in vitro PFK-1 binding and activity studies of mammalian proteins. Mammalian studies revealed complete loss of binding between the COOH terminus of a4 containing the G-to-R mutant and PFK-1, without affecting PFK-1's catalytic activity. In yeast expression studies, protein levels, H+ATPase assembly, and targeting of this mutant were all preserved. However, severe (78%) loss of proton transport but less decrease in ATPase activity (36%) were observed in mutant vacuoles, suggesting a requirement for the a-subunit/PFK-1 binding to couple these two functions. This role for PFK in H+ATPase function was supported by similar functional losses and uncoupling ratio between the two proton pump domains observed in vacuoles from a PFK-null strain, which was also unable to grow at alkaline pH. In contrast, the R-to-Q mutation dramatically reduced a-subunit production, abolishing H+ATPase function completely. Thus in the context of dRTA, stability and function of the metabolon composed of H+ATPase and glycolytic components can be compromised by either loss of required PFK-1 binding (G820R) or loss of pump protein (R807Q).

Published

2008

4. Investigating the Interaction Between Characterized Amyloid-Beta Oligomers and the Prion Protein Receptor in Live Cells

Author

Narayan, Priyanka, Ganzinger, Kristina A., McColl, James, Drews, Anna, Clarke, Richard W., Qamar, Seema, George-Hyslop, Peter St., and Klenerman, David

Published

2012

5. Novel 2,5‐Dideoxystreptamine Derivatives Targeting the Ribosomal Decoding Site RNA.

Author

Vourloumis, Dionisios, Takahashi, Masayuki, Winters, Geoffrey C., Simonsen, Klaus B., Ayida, Benjamin K., Barluenga, Sofia, Qamar, Seema, Shandrick, Sarah, Zhao, Qiang, and Hermann, Thomas

Abstract

For Abstract see ChemInform Abstract in Full Text.

Published

2003

6. Novel Paromamine Derivatives Exploring Shallow‐Groove Recognition of Ribosomal‐Decoding‐Site RNA.

Author

Simonsen, Klaus B., Ayida, Benjamin K., Vourloumis, Dionisios, Takahashi, Masayuki, Winters, Geoffrey C., Barluenga, Sofia, Qamar, Seema, Shandrick, Sarah, Zhao, Qiang, and Hermann, Thomas

Published

2003