Neuroserpin is an inhibitory enzyme, belonging to the family of serpins and involved in several pathologies, such as ischemia, Alzheimer disease, and FENIB (Familial Encephalopathy with Neuroserpin Inclusion Body). Here, we study the mechanism of neuroserpin inactivation and polymerization by different experimental techniques (static and dynamic light scattering, liquid chromatography, Fourier transform infrared spectroscopy, emission spectroscopy). Our results show that at intermediate temperatures (45-55 °C) neuroserpin forms flexible polymers with a size from a few tens to a few hundreds of nanometers. At high temperatures, above 80 °C, our results reveal a different polymeric form, reached through an analogous loop-sheet mechanism, with considerably larger size and higher chemical stability. Our observations highlight the role of the different processes involved in serpin self-assembly, namely inactivating conformational changes, oligomer formation, polymer elongation and fragmentation.
Manno, A., Santangelo, M.G., Mangione, M.R., Levantino, M., Ricagno, S., Pezzullo, M., et al. (2010). Inactivation and polymerization of human neuroserpin. ??????? it.cilea.surplus.oa.citation.tipologie.CitationProceedings.prensentedAt ??????? XX Congresso Nazionale della Società Italiana di Biofisica Pura ed Applicata (SIBPA), Arcidosso.
Inactivation and polymerization of human neuroserpin
SANTANGELO, Maria Grazia;LEVANTINO, Matteo;
2010-01-01
Abstract
Neuroserpin is an inhibitory enzyme, belonging to the family of serpins and involved in several pathologies, such as ischemia, Alzheimer disease, and FENIB (Familial Encephalopathy with Neuroserpin Inclusion Body). Here, we study the mechanism of neuroserpin inactivation and polymerization by different experimental techniques (static and dynamic light scattering, liquid chromatography, Fourier transform infrared spectroscopy, emission spectroscopy). Our results show that at intermediate temperatures (45-55 °C) neuroserpin forms flexible polymers with a size from a few tens to a few hundreds of nanometers. At high temperatures, above 80 °C, our results reveal a different polymeric form, reached through an analogous loop-sheet mechanism, with considerably larger size and higher chemical stability. Our observations highlight the role of the different processes involved in serpin self-assembly, namely inactivating conformational changes, oligomer formation, polymer elongation and fragmentation.
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