The effect of sucrose on protein stability and fibrillation of prion and S6 protein

Aggregation and fibrillation of proteins have a great importance in medicine and industry. Misfolding and aggregation are the basis of many neurodegenerative diseases like Alzheimer and Parkinson. Osmolytes are molecules that can accumulate within cells and act as protective agents and they can inclusively act as protein stabilizers when cells are exposed to stress conditions. Osmolytes can also act as protein stabilizers in vitro. In this work, two different proteins were studied, the ribosomal protein from Thermus thermophilus and the mouse prion protein. The existence of an unstructured N-terminal on the prion protein does not affect its stability. The effect of the osmolyte sucrose on the fibrillation and stabilization of these two proteins was studied through kinectic and equilibrium measurements. It was shown that sucrose is able to compact the native structure of S6 protein in fibrillization conditions. Sucrose affects also folding and unfolding kinetic of S6 protein, delaying unfolding and increasing folding rate constants. The mechanism of stabilization by sucrose is non-specific because it is distributed for all protein structure, as it was demonstrated by a protein engineering approach. Sucrose delays the process of formation and elongation of S6 and prion protein from mouse. This delay is the result of the compaction of the native structure refered above. However, cellular toxicity studies have shown that fibrils formed in the presence of sucrose are more toxic to neuronal cells.

Insights into molecular and cellular events involved in normal and pathological vertebral development and fusion using zebrafish as model organism

The vertebral column and its units, the vertebrae, are fundamental features, characteristic of all vertebrates. Developmental segregation of the vertebral bodies as articulated units is an intrinsic requirement to guarantee the proper function of the spine. Whenever these units become fused either during development or postsegmentation, movement is affected in a more or less severe manner, depending on the number of vertebrae affected. Nevertheless, fusion may occur as part of regular development and as a physiological requirement, like in the tetrapod sacrum or in fish posterior vertebrae forming the urostyle. In order to meet the main objective of this PhD project, which aimed to better understand the molecular and cellular events underlying vertebral fusion under physiological and pathological conditions, a detailed characterization of the vertebral fusion occurring in zebrafish caudal fin region was conducted. This showed that fusion in the caudal fin region comprised 5 vertebral bodies, from which, only fusion between [PU1++U1] and ural2 [U2+] was still traceable during development. This involved bone deposition around the notochord sheath while fusion within the remaining vertebral bodies occur at the level of the notochord sheath, as during the early establishment of the vertebral bodies. A comparison approach between the caudal fin vertebrae and the remaining vertebral column showed conserved features such as the presence of mineralization related proteins as Osteocalcin were identified throughout the vertebral column, independently on the mineralization patterns. This unexpected presence of Osteocalcin in notochord sheath, here identified as Oc1, suggested that this gene, opposing to Oc2, generally associated with bone formation and mature osteoblast activity, is potentially associated with early mineralization events including chordacentrum formation. Nevertheless, major differences between caudal fin region and anterior vertebral bodies considering arch histology and mineralization patterns, led us to use RA as an inductive factor for vertebral fusion, allowing a direct comparison of equivalent structures under normal and fusion events. This fusion phenotype was associated with notochord sheath ectopic mineralization instead of ectopic perichordal bone formation related with increased osteoblast activity, as suggested in previous reports. Additionally, alterations in ECM content, cell adhesion and blood coagulation were discussed as potentially related with the fusion phenotype. Finally, Matrix gla protein, upregulated upon RA treatment and shown to be associated with chordacentrum mineralization sites in regular development, was further described considering its potential function in vertebral formation and pathological fusion. Therefore with this work we propose zebrafish caudal fin vertebral fusion as a potential model to study both congenital and postsegmentation fusion and we present candidate factors and genes that may be further explored in order to clarify whether we can prevent vertebral fusion.