Functional Consequences of Conjugating Polymers to Protein and Study of Biomarkers for Cell Death Pathway

Rahman, Monica Sharfin

14 July 2022

No description available.

Polymer Chemistry

Biochemistry

Analytical Chemistry

Protein-polymer bioconjugation

Protein activity

Protein stability

Protein-protein interaction inhibition

Spike protein capture

Cell death

Biomarker

Molecular Imprinting Technology Towards the Development of a Novel Biosensor

Avalos, Abraham

January 2014

No description available.

Biomedical Engineering

Molecular imprinting

protein detection

protein imprinting

surface plasmon resonance

crosslinked polymers

functional monomers

template removal

protein-polymer interaction

artificial antibody

Application and characterization of polymer-protein and polymer-membrane interactions

Burridge, Kevin Michael

28 June 2021

No description available.

Biochemistry

Chemistry

Polymer Chemistry

Polymers

Biophysics

Lipid nanoparticles

nanodisks

macromolecular surfactants

antiviral

self-disinfecting

polymerization

RAFT

ATRP

RDRP

bioconjugates

membrane proteins

protein-polymer conjugates

grafting-from

grafting-to

paramagnetic relaxation enhancement

Fluorescence studies of complex systems : organisation of biomolecules

Marushchak, Denys

January 2007

The homo and hetero dimerisation of two spectroscopically different chromophores were studied, namely: 4,4-difluoro-4-bora-3a,4a-diazas-indacene (g-BODIPY) and its 5-styryl-derivative (r-BODIPY). Various spectroscopic properties of the r-BODIPY in different common solvents were determined. It was shown that g- and r-BODIPY in the ground state can form homo- as well as hetero dimers. We demonstrate that the ganglioside GM1 in lipid bilayers of 1,2-dioleoyl-sn-glycero-3-phosphocholine (DOPC) exhibits a non-uniform lateral distribution, which is an argument in favour of self-aggregation of GM1 being an intrinsic property of the GM1. This was concluded from energy transfer/migration studies of BODIPY-labelled gangliosides. An algorithm is presented that quantitatively accounts for donor–donor energy migration (DDEM) among fluorophore-labelled proteins forming regular non-covalent polymers. The DDEM algorithm is based on Monte Carlo (MC) and Brownian dynamics (BD) simulations and applies to the calculation of fluorescence depolarisation data, such as the fluorescence anisotropy. Thereby local orientations, as well as reorienting motions of the fluorescent groups are considered in the absence and presence of DDEM among them. A new method, in which a genetic algorithm (GA) was combined with BD and MC simulations, was developed to analyse fluorescence depolarisation data collected by the time-correlated single photon counting technique. It was applied to study g-BODIPY-labelled filamentous actin (F-actin). The technique registered the local order and reorienting motions of the fluorophores, which were covalently coupled to cysteine 374 (C374) in actin and interacted by means of electronic energy migration within the polymer. Analyses of F-actin samples composed of different fractions of labelled actin molecules revealed the known helical organiszation of F-actin, and demonstrated the usefulness of this technique for structure determination of complex protein polymers. The distance from the filament axis to the fluorophore was found to be considerably less than expected from the proposed position of C374 at a high filament radius. In addition, polymerisation experiments with BODIPY-actin suggest a 25-fold more efficient signal for filament formation than pyrene-actin.

Fluorescence anisotropy

BODIPY

homo and hetero dimerisation

protein aggregates

protein polymer structures

actin polymerisation

FRET

donor–acceptor energy transfer DAET

donor-donor energy migration DDEM

homotransfer

Monte Carlo simulation

MC

Brownian dynamics

BD

Genetic Algorithm

GA.

Ganglioside GM1

Biophysical chemistry

Biofysikalisk kemi