Your search keyword '"Vallone B"' showing total 6 results

1. Engineering the internal cavity of neuroglobin demonstrates the role of the haem-sliding mechanism.

Author

Avella, G., Ardiccioni, C., Scaglione, A., Moschetti, T., Rondinelli, C., Montemiglio, L. C., Savino, C., Giuffrè, A., Brunori, M., and Vallone, B.

Subjects

HEMOPROTEINS, CRYSTAL structure, MOLECULAR dynamics, MUTAGENESIS, CRYSTALLOGRAPHY

Abstract

Neuroglobin is a member of the globin family involved in neuroprotection; it is primarily expressed in the brain and retina of vertebrates. Neuroglobin belongs to the heterogeneous group of hexacoordinate globins that have evolved in animals, plants and bacteria, endowed with the capability of reversible intramolecular coordination, allowing the binding of small gaseous ligands (O2, NO and CO). In a unique fashion among haemoproteins, ligand-binding events in neuroglobin are dependent on the sliding of the haem itself within a preformed internal cavity, as revealed by the crystal structure of its CO-bound derivative. Point mutants of the neuroglobin internal cavity have been engineered and their functional and structural characterization shows that hindering the haem displacement leads to a decrease in CO affinity, whereas reducing the cavity volume without interfering with haem sliding has negligible functional effects. [ABSTRACT FROM AUTHOR]

Published

2014

2. Neuroglobin, seven years after.

Author

Brunori, M. and Vallone, B.

Subjects

VERTEBRATES, BRAIN, NERVOUS system, BIOSYNTHESIS, PHYSIOLOGICAL transport of oxygen, NEUROSCIENCES

Abstract

Neuroglobin is expressed in vertebrates brain and belongs to a branch of the globin family that diverged early in evolution. Sequence conservation suggests a relevant role in the nervous system, with tight structural restraints. Experiments in vivo and in vitro showed increased hypoxic stress damage upon repressing neuroglobin biosynthesis and improved recovery following overexpression. Neuroglobin shows internal heme hexacoordination, which controls oxygen affinity and kinetics. Neuroglobin concentration, oxygen affinity and enhanced autooxidation question a role in oxygen delivery; thus it was proposed that the neuroprotective effect might be due to radical scavenging or activation of protection mechanisms. Neuroglobin’s structure shows a peculiar internal cavity of very large size. Binding of heme ligands is associated to a conformational change involving the heme that “slides” into the pre-existing cavity and makes the sixth coordination position available. These features may pave the way to an understanding of neuroprotection by neuroglobin. [ABSTRACT FROM AUTHOR]

Published

2007

3. A globin for the brain.

Author

Brunori, M. and Vallone, B.

Subjects

HEMOPROTEINS, BIOCHEMISTRY, PATHOLOGICAL physiology, HYPOXEMIA, ISCHEMIA, GLOBIN, CELLULAR signal transduction

Abstract

The discovery that a myoglobin-like hemeprotein (called neuroglobin) is expressed in our brain raised considerable curiosity from the stand-points of biochemistry and pathophysiology alike. Neuroglobin is involved in neuroprotection from damage due to hypoxia or ischemia in vitro and in vivo; overexpression of neuroglobin ameliorates the recovery from stroke in experimental animals. The mechanism underlying this remarkable effect is still mysterious. Structural studies revealed that neuroglobin has a typical globin fold, and despite being hexacoordinated, it binds reversibly O2, CO, and NO, undergoing a substantial conformational change of the heme and of the protein. The possible mechanisms involved in neuroprotection are briefly reviewed. Neuroglobin is unlikely to be involved in O2 transport (like myoglobin), although it seems to act as a sensor of the O2/NO ratio in the cell, possibly regulating the GDP/GTP exchange rate forming a specific complex with the Gαβγ-protein when oxidized but not when bound to a gaseous ligand. Thus it appears that neuroglobin is a stress-responsive sensor for signal transduction in the brain, mediated by a ligand-linked conformational change of the protein. [ABSTRACT FROM AUTHOR]

Published

2006

4. Identification of a pattern in protein structure based on energetic and statistical considerations.

Author

Amadei, A. and Vallone, B.

Published

1996

5. Refining and testing a nursing patient classification instrument in ambulatory care.

Author

Parrinello K, Brenner PS, and Vallone B

Published

1988

6. ChemInform Abstract: Structure and Function of Cytochrome c Oxidase.

Author

MALATESTA, F., ANTONINI, G., SARTI, P., VALLONE, B., and BRUNORI, M.

Published

1991