Chelcie H. Eller scite author profile

Peptides can be developed as effective antagonists of protein-protein interactions, but conventional peptides (i.e., oligomers of L-α-amino acids) suffer from significant limitations in vivo. Short half-lives due to rapid proteolytic degradation and an inability to cross cell membranes often preclude biological applications of peptides. Oligomers that contain both α- and β-amino acid residues (“α/β-peptides”) manifest decreased susceptibility to proteolytic degradation, and when properly designed these unnatural oligomers can mimic the protein-recognition properties of analogous “α-peptides”. This report documents an extension of the α/β-peptide approach to target intracellular protein-protein interactions. Specifically, we have generated α/β-peptides based on a “stapled” Bim BH3 α-peptide, which contains a hydrocarbon crosslink to enhance α-helix stability. We show that a stapled α/β-peptide can structurally and functionally mimic the parent stapled α-peptide in its ability to enter certain types of cells and block protein-protein interactions associated with apoptotic signaling. However, the α/β-peptide is nearly 100-fold more resistant to proteolysis than is the parent α-peptide. These results show that backbone modification, a strategy that has received relatively little attention in terms of peptide engineering for biomedical applications, can be combined with more commonly deployed peripheral modifications such as side chain crosslinking to produce synergistic benefits.

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Ferroplasma acidarmanus RPA2 Facilitates Efficient Unwinding of Forked DNA Substrates by Monomers of FacXPD Helicase

Pugh

Lin

Eller

et al. 2008

Journal of Molecular Biology

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Rational Design and Evaluation of Mammalian Ribonuclease Cytotoxins

Lomax

Eller

Raines

2012

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Mammalian pancreatic-type ribonucleases (ptRNases) comprise an enzyme family that is remarkably well suited for therapeutic exploitation. ptRNases are robust and prodigious catalysts of RNA cleavage that can naturally access the cytosol. Instilling cytotoxic activity requires endowing them with the ability to evade a cytosolic inhibitor protein while retaining other key attributes. These efforts have informed our understanding of ptRNase-based cytotoxins, as well as the action of protein-based drugs with cytosolic targets. Here, we address the most pressing problems encountered in the design of cytotoxic ptRNases, along with potential solutions. In addition, we describe assays that can be used to evaluate a successful design in vitro, in cellulo, and in vivo. The emerging information validates the continuing development of ptRNases as chemotherapeutic agents.

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Bovine Brain Ribonuclease Is the Functional Homolog of Human Ribonuclease 1

Eller

Lomax

Raines

2014

Journal of Biological Chemistry

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Background: RNase 1 is an RNA-degrading enzyme conserved in mammals and with unknown biological function. Results: RNase 1 homologs in human and cow display different biochemical and biological properties, implying divergent physiology. Conclusion: Bovine brain ribonuclease, not RNase A, is the functional homolog of human RNase 1. Significance: Fundamental insight into the biology and evolution of human RNase 1 is attained from analyses of homologous proteins.

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Comparative functional analysis of ribonuclease 1 homologs: molecular insights into evolving vertebrate physiology

Lomax

Eller

Raines

2017

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Pancreatic-type ribonucleases (ptRNases) comprise a class of highly conserved secretory endoribonucleases in vertebrates. The prototype of this enzyme family is ribonuclease 1 (RNase 1). Understanding the physiological roles of RNase 1 is becoming increasingly important, as engineered forms of the enzyme progress through clinical trials as chemotherapeutic agents for cancer. Here we present an in-depth biochemical characterization of RNase 1 homologs from a broad range of mammals (human, bat, squirrel, horse, cat, mouse, and cow) and non-mammalian species (chicken, lizard, and frog). We discover that the human homolog of RNase 1 has a pH optimum for catalysis, ability to degrade double-stranded RNA, and affinity for cell-surface glycans that are distinctly higher than those of its homologs. These attributes have relevance for human health. Moreover, the functional diversification of the ten RNase 1 homologs illuminates the regulation of extracellular RNA and other aspects of vertebrate evolution.

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Chelcie H. Eller

α/β-Peptide Foldamers Targeting Intracellular Protein–Protein Interactions with Activity in Living Cells

Ferroplasma acidarmanus RPA2 Facilitates Efficient Unwinding of Forked DNA Substrates by Monomers of FacXPD Helicase

Rational Design and Evaluation of Mammalian Ribonuclease Cytotoxins

Bovine Brain Ribonuclease Is the Functional Homolog of Human Ribonuclease 1

Comparative functional analysis of ribonuclease 1 homologs: molecular insights into evolving vertebrate physiology

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