Inhibition of Escherichia coli respiratory complex I by Zn(2+).

The energy-converting NADH:ubiquinone oxidoreductase, respiratory complex I, couples NADH oxidation and quinone reduction with the translocation of protons across the membrane. Complex I exhibits a unique L shape with a peripheral arm extending in the aqueous phase and a membrane arm embedded in the lipid bilayer. Both arms have a length of ∼180 Å. The electron transfer reaction is catalyzed by a series of cofactors in the peripheral arm, while the membrane arm catalyzes proton translocation. We used the inhibition of complex I by zinc to shed light on the coupling of the two processes, which is not yet understood. Enzyme kinetics revealed the presence of two high-affinity binding sites for Zn(2+) that are attributed to the proton translocation pathways in the membrane arm. Electrochemically induced Fourier transform infrared difference spectroscopy demonstrated that zinc binding involves at least two protonated acidic residues. Electron paramagnetic resonance spectroscopy showed that one of the cofactors is only partially reduced by NADH in the presence of Zn(2+). We conclude that blocking the proton channels in the membrane arm leads to a partial block of the electron transfer in the peripheral arm, indicating the long-range coupling between both processes.

Characterization and inhibition of AF10-mediated interaction.

The non-random chromosomal translocations t(10;11)(p13;q23) and t(10;11)(p13;q14-21) result in leukemogenic fusion proteins comprising the coiled coil domain of the transcription factor AF10 and the proteins MLL or CALM, respectively, and subsequently cause certain types of acute leukemia. The AF10 coiled-coil domain, which is crucial for the leukemogenic effect, has been shown to interact with GAS41, a protein previously identified as the product of an amplified gene in glioblastoma. Using sequential synthetic peptides, we mapped the potential AF10/GAS41 interaction site, which was subsequently be used as scaffold for a library targeting the AF10 coiled-coil domain. Using phage display, we selected a peptide that binds the AF10 coiled-coil domain with higher affinity than the respective coiled-coil region of wild-type GAS41, as demonstrated by phage ELISA, CD, and PCAs. Furthermore, we were able to successfully deploy the inhibitory peptide in a mammalian cell line to lower the expression of Hoxa genes that have been described to be overexpressed in these leukemias. This work dissects molecular determinants mediating AF10-directed interactions in leukemic fusions comprising the N-terminal parts of the proteins MLL or CALM and the C-terminal coiled-coil domain of AF10. Furthermore, it outlines the first steps in recognizing and blocking the leukemia-associated AF10 interaction in histiocytic lymphoma cells and therefore, may have significant implications in future diagnostics and therapeutics.

Selection of peptides interfering with protein-protein interaction.

Cell physiology depends on a fine-tuned network of protein-protein interactions, and misguided interactions are often associated with various diseases. Consequently, peptides, which are able to specifically interfere with such adventitious interactions, are of high interest for analytical as well as medical purposes. One of the most abundant protein interaction domains is the coiled-coil motif, and thus provides a premier target. Coiled coils, which consist of two or more alpha-helices wrapped around each other, have one of the simplest interaction interfaces, yet they are able to confer highly specific homo- and heterotypic interactions involved in virtually any cellular process. While there are several ways to generate interfering peptides, the combination of library design with a powerful selection system seems to be one of the most effective and promising approaches. This chapter guides through all steps of such a process, starting with library options and cloning, detailing suitable selection techniques and ending with purification for further down-stream characterization. Such generated peptides will function as versatile tools to interfere with the natural function of their targets thereby illuminating their down-stream signaling and, in general, promoting understanding of factors leading to specificity and stability in protein-protein interactions. Furthermore, peptides interfering with medically relevant proteins might become important diagnostics and therapeutics.