Developing Dirhodium-Complexes for Protein Inhibition and Modification & Copper-Catalyzed Remote Chlorination of Alkyl-Hydroperoxides

Kundu, Rituparna

16 September 2013

The work describes the development of a new class of protein-inhibitors for protein-protein interactions, based on metallopeptides comprised of a dirhodium metal center. The metal incorporation in the peptide sequence leads to high increase in binding affinity of the inhibitors. The source of this strong affinity is the interaction of histidine on the protein surface with the rhodium center. In addition to this work, rhodium-based small molecule inhibitors for FK-506 binding proteins are investigated. Also, methodology for rhodium-catalyzed modification of proteins containing surface cysteine has been developed where a simple rhodium(II) complex catalyzes cysteine modification with diazo reagents. The reaction is marked by clean cysteine selectivity and mild reaction conditions. The resulting linkage is significantly more stable in human plasma serum, when compared to common maleimide reagents. Apart from this body of work in chemical-biology, the thesis contains the discussion of development of copper-catalyzed remote chlorination of alkyl hydroperoxides. The atom transfer chlorination utilizes simple ammonium chloride salts as the chlorine source and the internal redox process requires no external redox reagents.

metallopeptides

protein–protein interactions

inhibitors

cysteine modification

rhodium

sp3 remote C-H activation

Emergence, survival, and selection of metal-binding peptides in the prebiotic environment

Rossetto, Daniele

26 October 2022

Metabolism is a subset of chemistry that allows cells to defy thermodynamic equilibrium, a fundamental process that must have been in place from the very beginning of biology. Before evolution produced efficient catalysts in the form of complex protein machinery, short metal binding peptides might have preceded modern metalloproteins. Such prebiotic, metal-binding motifs have been hypothesized to have existed through analyses of extant protein sequences. However, it is unclear how metal-binding motifs might have evolved in the harsh prebiotic environment. Here, we show how certain environments, in particular seawater-like environments rich in divalent cations and especially Mg2+, support the survival of short peptides upon extreme temperatures as high as 150 °C. Moreover, while Mg2+ does not offer the same protection from UV light, peptides are protected from both heat and irradiation when bound to a metal ion. The results suggest that specific environments rich in metal ions may be better suited for the emergence of complex systems in the path toward life. Additionally, the conditional degradation of peptides depending on their ability of binding metals might have enabled a selection mechanism that would favor the survival of metal-binding motifs which resemble the motifs found in modern proteins. These short sequences could have acted as early, simple catalysts able to facilitate a restricted set of chemical reactions, which would shape the emergence and biology of the Last Universal Common Ancestor.

Settore BIO/10 - Biochimica