ZIB

Treffer pro Seite

Treffer 1 - 2 | 2 Treffer

Sortierung

Digitale Medien

The role of solvent-induced forces in biomolecular function and stability (1993)

Bulone, D. ; San Biagio, P. L. ; Palma-Vittorelli, M. B. ; [weitere]

Springer

Il nuovo cimento della Società Italiana di Fisica 15 (1993), S. 443-450

zur Merkliste hinzufügen auf der Merkliste

Details

ISSN: 0392-6737

Schlagwort(e): Molecular biophysics ; Thermodynamics of solutions ; Liquid-liquid transitions ; Macromolecular and polymer solutions

Quelle: Springer Online Journal Archives 1860-2000

Thema: Physik

Notizen: Summary Solvent-induced forces (SIFs) have been for a long time erroneously related to the presence of more or less uniform “hydration shells”, consisting of more or less permanently bound water molecules. As such misconceptions fade away, it becomes clear that hydration should be viewed statistically and in terms of topological rather than geometric order, and that minor changes (due to solutes) in the structural-rearrangement times of the solvent can reflect major effects in SIFs. Recent work on SIFs at our laboratory, here critically summarized, shows: i) Precisely localized average intramolecular SIFs adjusting the operation of a protein to just what is physiologically required. ii) The involvement of SIFs in the thermodynamic stability of biomelecular solutions and “soups” and related fluctuation behaviour. Sustained, undamped fluctuations occurring in the instability region, and also subcritical ones, occurring close to (yet, not in) the instability region, have been shown to be capable of triggering important concentration- dependent biomolecular processes, iii) The involvement of large numbers of water molecules (of the order of 100) in intra- and interbiomolecular SIFs. This dramatically expands the dimensionality and extension of the functional phase space and helps understand for the first time the extraordinary thermodynamic functional stability of biomolecules.

Materialart: Digitale Medien

URL: http://dx.doi.org/10.1007/BF02456926

Permalink

Bibliothek	Standort	Signatur	Band/Heft/Jahr	Verfügbarkeit

Andere fanden auch interessant ...

Artikel (Nationallizenzen)

Volltext

Digitale Medien

Time-Resolved study of network self-organization from a biopolymeric solution (1991)

Emanuele, A. ; Di Stefano, L. ; Giacomazza, D. ; [weitere]

New York : Wiley-Blackwell

Biopolymers 31 (1991), S. 859-868

zur Merkliste hinzufügen auf der Merkliste

Details

ISSN: 0006-3525

Schlagwort(e): Chemistry ; Polymer and Materials Science

Quelle: Wiley InterScience Backfile Collection 1832-2000

Thema: Chemie und Pharmazie

Notizen: Time-resolved studies of network self-organization from homogeneous solutions of the representative biostructural polymer agarose are presented. Solutions are temperature quenched and observed by several techniques. Consistent with previous suggestions by the authors, experiments at concentrations up to about 1.75% w/v provide direct kinetic evidence for the occurrence of at least two distinct processes, leading, in sequence, to self-assembly. These are as follows: (a) a liquid-liquid phase separation of the solution occurring via spinodal demixing and resulting in two sets of regions that have, respectively, higher and lower than average concentrations of random-coiled polymers; and (b) the subsequent 2 coils → double helix transition and accompanying cross-linking and gelation (due to branching of double helices), occurring in the high-concentration regions. The size of the high-concentration regions depends upon agarose concentration and quenching temperature, and is in the range from a fraction of micrometers to a few micrometers, in agreement with earlier experiments. Bundling of the double-helical segments is known to follow self-assembly and can be considered as a third step (gel curing). This follows from the thermo-dynamic instability of the helical segments in the solvent, behaving as a system of rod-like particles connected by more or less flexible joints.The two processes leading in succession to self-assembly are discussed in terms of a phase diagram consistent with available data. Their time scales differ remarkably. At the end of the first process, all polymers remain random coiled and freely drifting. Much later coil-helix transition is observed, always in coincidence with polymer cross-linking and gelation. The enhancement of concentration of random-coiled polymers in specific regions of the sol caused by spinodal demixing is thus a prerequisite for self-assembly of these biostructural gels in the concentration interval studied. Conceptually, concentration enhancements of this type can provide a new pathway for promotion of functional biomolecular interactions even at very low average concentrations. The mechanism will work identically if the region of instability is reached by varying the polymer concentration (e.g., by biosynthesis), rather than by temperature quenching.

Zusätzliches Material: 4 Ill.