The polymerization of serpins is at the root of a large class of diseases; the molecular structure of serpin polymers has been recently debated. In this work, we study the polymerization kinetics of human neuroserpin by Fourier Transform Infra Red spectroscopy and by time-lapse Size Exclusion Chromatography. First, we show that two distinct neuroserpin polymers, formed at 45 and 85 °C, display the same isosbestic points in the Amide I band, and therefore share common secondary structure features. We also find a concentration independent polymerization rate at 45 °C suggesting that the polymerization rate limiting step is the formation of an activated monomeric species. The polymer structures are consistent with a model that predicts the bare insertion of portions of the reactive center loop into the A b-sheet of neighboring serpin molecule, although with different extents at 45 and 85 °C. Further studies are currently addressing the structure of monomeric neuroserpin conformers.
Santangelo, M.G., Noto, R., Levantino, M., Cupane, A., Ricagno, S., Pezzullo, M., et al. (2012). On the molecular structure of human neuroserpin polymers. Coagulation, fragmentation and latentization control serpin aggregation. ??????? it.cilea.surplus.oa.citation.tipologie.CitationProceedings.prensentedAt ??????? XXI Congresso Nazionale della Società Italiana di Biofisica Pura ed Applicata (SIBPA), Ferrara.
On the molecular structure of human neuroserpin polymers. Coagulation, fragmentation and latentization control serpin aggregation
SANTANGELO, Maria Grazia;LEVANTINO, Matteo;CUPANE, Antonio;
2012-01-01
Abstract
The polymerization of serpins is at the root of a large class of diseases; the molecular structure of serpin polymers has been recently debated. In this work, we study the polymerization kinetics of human neuroserpin by Fourier Transform Infra Red spectroscopy and by time-lapse Size Exclusion Chromatography. First, we show that two distinct neuroserpin polymers, formed at 45 and 85 °C, display the same isosbestic points in the Amide I band, and therefore share common secondary structure features. We also find a concentration independent polymerization rate at 45 °C suggesting that the polymerization rate limiting step is the formation of an activated monomeric species. The polymer structures are consistent with a model that predicts the bare insertion of portions of the reactive center loop into the A b-sheet of neighboring serpin molecule, although with different extents at 45 and 85 °C. Further studies are currently addressing the structure of monomeric neuroserpin conformers.
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