LMD proteomics provides evidence for hippocampus field-specific motor protein abundance changes with relevance to Alzheimer's disease.

BACKGROUND: Human hippocampal area Cornu Ammonis (CA) 1 is one of the first fields in the human telencephalon showing Alzheimer disease (AD)-specific neuropathological changes. In contrast, CA2 and CA3 are far later affected pointing to functional differences, which may be accompanied by differences in proteome endowment and changes. METHODS: Human pyramidal cell layers of hippocampal areas CA1, CA2, and CA3 from neurologically unaffected individuals were excised using laser microdissection. The proteome of each individual sample was analyzed and differentially abundant proteins were validated by immuno-histochemistry. RESULTS: Comparison of CA1 to CA2 revealed 223, CA1 to CA3 197 proteins with differential abundance, among them we found motor proteins MYO5A and DYNC1H1. Extension of the study to human hippocampus slices from AD patients revealed extensive depletion of these proteins in CA1 area compared to unaffected controls. CONCLUSION: High abundance of motor proteins in pyramidal cell layers CA1 compared to CA2 and CA3 points the specific vulnerability of this hippocampal area to transport-associated changes based on microtubule dysfunction and destabilization in AD.

A One-Pot Cascade Reaction Combining an Encapsulated Decarboxylase with a Metathesis Catalyst for the Synthesis of Bio-Based Antioxidants.

The combination of enzymes with traditional chemical catalysts unifies the high selectivity of the former with the versatility of the latter. A major challenge of this approach is the difference in the optimal reaction conditions for each catalyst type. In this work, we combined a cofactor-free decarboxylase with a ruthenium metathesis catalyst to produce high-value antioxidants from bio-based precursors. As suitable ruthenium catalysts did not show satisfactory activity under aqueous conditions, the reaction required the use of an organic solvent, which in turn significantly reduced enzyme activity. Upon encapsulation of the decarboxylase in a cryogel, the decarboxylation could be conducted in an organic solvent, and the recovery of the enzyme after the reaction was facilitated. After an intermediate drying step, the subsequent metathesis in pure organic solvent proved to be straightforward. The synthetic utility of the cascade was demonstrated by the synthesis of the antioxidant 4,4'-dihydroxystilbene in an overall yield of 90 %.