Mitochondrial tyrosyl-DNA phosphodiesterase 2 and its TDP2 short isoform.

Tyrosyl-DNA phosphodiesterase 2 (TDP2) repairs abortive topoisomerase II cleavage complexes. Here, we identify a novel short isoform of TDP2 (TDP2) expressed from an alternative transcription start site. TDP2 contains a mitochondrial targeting sequence, contributing to its enrichment in the mitochondria and cytosol, while full-length TDP2 contains a nuclear localization signal and the ubiquitin-associated domain in the N-terminus.

Mitochondrial Targeting of Doxorubicin Eliminates Nuclear Effects Associated with Cardiotoxicity.

The highly effective anticancer agent doxorubicin (Dox) is a frontline drug used to treat a number of cancers. While Dox has a high level of activity against cancer cells, its clinical use is often complicated by dose-limiting cardiotoxicity. While this side effect has been linked to the drug's direct activity in the mitochondria of cardiac cells, recent studies have shown that these result primarily from downstream effects of nuclear DNA damage.

Cellular uptake of substrate-initiated cell-penetrating poly(disulfide)s.

Substrate-initiated, self-inactivating, cell-penetrating poly(disulfide)s (siCPDs) are introduced as general transporters for the covalent delivery of unmodified substrates of free choice. With ring-opening disulfide-exchange polymerization, we show that guanidinium-rich siCPDs grow on fluorescent substrates within minutes under the mildest conditions. The most active siCPD transporters reach the cytosol of HeLa cells within 5 min and depolymerize in less than 1 min to release the native substrate.

Molecular vehicles for mitochondrial chemical biology and drug delivery.

The mitochondria within human cells play a major role in a variety of critical processes involved in cell survival and death. An understanding of mitochondrial involvement in various human diseases has generated an appreciable amount of interest in exploring this organelle as a potential drug target. As a result, a number of strategies to probe and combat mitochondria-associated diseases have emerged.

Targeted delivery of doxorubicin to mitochondria.

Several families of highly effective anticancer drugs are selectively toxic to cancer cells because they disrupt nucleic acid synthesis in the nucleus. Much less is known, however, about whether interfering with nucleic acid synthesis in the mitochondria would have significant cellular effects. In this study, we explore this with a mitochondrially targeted form of the anticancer drug doxorubicin, which inhibits DNA topoisomerase II, an enzyme that is both in mitochondria and nuclei of human cells.

Design, expression, and purification of de novo transmembrane "hairpin" peptides.

While our understanding of the folding and structure of water-soluble proteins has progressed to the point where they can be artificially designed and produced from first principles, there has been only limited work toward the de novo design of membrane proteins. Such studies have been hindered in large part due to the practical challenges in the production and characterization of multispanning transmembrane (TM) proteins that arise from their highly hydrophobic character. In this work, we used molecular biology cloning techniques to produce a library of partially randomized Ala- and Ile-rich de novo helix-loop-helix (hairpin) TM constructs as models for tertiary TM-TM folding.

Effects of a polar amino acid substitution on helix formation and aggregate size along the detergent-induced peptide folding pathway.

Membrane proteins constitute a significant fraction of the proteome and are important drug targets. While the transmembrane (TM) segments of these proteins are primarily composed of hydrophobic residues, the inclusion of polar residues-either naturally occurring or as a consequence of a disease-related mutation-places a significant folding burden in this environment, potentially impacting bilayer insertion and/or association of neighboring TM helices. Here we investigate the role of an anionic detergent, sodium dodecylsulfate (SDS), and a zwitterionic detergent, dodecylphosphocholine (DPC), in the folding process, and the effects induced by a single polar substitution, on structure and topology of model α-helical TM segments.

Efficiency of detergents at maintaining membrane protein structures in their biologically relevant forms.

High-resolution structural analysis of membrane proteins by X-ray crystallography or solution NMR spectroscopy often requires their solubilization in the membrane-mimetic environments of detergents. Yet the choice of a detergent suitable for a given study remains largely empirical. In the present work, we considered the micelle-crystallized structures of lactose permease (LacY), the sodium/galactose symporter (vSGLT), the vitamin B(12) transporter (BtuCD), and the arginine/agmatine antiporter (AdiC).

Positions of polar amino acids alter interactions between transmembrane segments and detergents.

α-Helical transmembrane (TM) segments in membrane proteins are comprised primarily of hydrophobic amino acids that accommodate insertion from water into the nonpolar membrane bilayer. In many such segments, however, polar residues are also present for structural or functional reasons. These latter residues impair the local favorable acyl interactions required for solvation by hydrophobic media such as phospholipids in native bilayers or detergents used for in vitro characterization.

SDS micelles as a membrane-mimetic environment for transmembrane segments.

An inherent dilemma in the study of the structural biology of membrane proteins is that it is often necessary to use detergents to mimic the native lipid bilayer environment. This situation is of particular interest because the generation of high-resolution structures (through X-ray crystallography and solution NMR) has overwhelmingly relied upon identification of detergents in which membrane proteins may be solubilized without denaturation into a nonbiological state. While sodium dodecyl sulfate (SDS) is perhaps the most widely employed micelle-forming detergent for laboratory procedures involving membrane proteins, it has generally been regarded as a "harsh" detergent synonymous with membrane protein denaturation.

Peptide models of membrane protein folding.

Given the central roles of membrane proteins in cellular processes ranging from nutrient uptake to cell-cell communication, as well as the importance of these proteins as drug targets, efforts to understand and control their structures are vital in human health and disease. The rational design of membrane proteins with modified properties is thus a highly desirable goal in molecular medicine and biotechnology. However, experimental data showing how individual transmembrane (TM) residues and/or segments direct the packing and folding of membrane proteins into biologically functional entities remain sparse.