Your search keyword '"Demetrios T. Braddock"' showing total 3 results

1. MicroRNA silencing for cancer therapy targeted to the tumour microenvironment

Author

Peter M. Glazer, Donald M. Engelman, Christopher J. Cheng, W. Mark Saltzman, Zachary Pincus, Francisco N. Barrera, Alexander A. Svoronos, Demetrios T. Braddock, Imran A. Babar, Frank J. Slack, Raman Bahal, and Connie Liu

Subjects

Male, Peptide Nucleic Acids, Cell Membrane Permeability, Lymphoma, Biology, Bioinformatics, Mice, Drug Delivery Systems, microRNA, Tumor Microenvironment, medicine, Animals, Gene silencing, Gene Silencing, Molecular Targeted Therapy, Regulation of gene expression, Tumor microenvironment, Multidisciplinary, Cell Membrane, Cancer, Oncogenes, Hydrogen-Ion Concentration, Oncomir, medicine.disease, 3. Good health, Gene Expression Regulation, Neoplastic, Disease Models, Animal, MicroRNAs, Targeted drug delivery, Drug delivery, Cancer research, Nanoparticles, Female, Acids

Abstract

MicroRNAs are short non-coding RNAs expressed in different tissue and cell types that suppress the expression of target genes. As such, microRNAs are critical cogs in numerous biological processes, and dysregulated microRNA expression is correlated with many human diseases. Certain microRNAs, called oncomiRs, play a causal role in the onset and maintenance of cancer when overexpressed. Tumours that depend on these microRNAs are said to display oncomiR addiction. Some of the most effective anticancer therapies target oncogenes such as EGFR and HER2; similarly, inhibition of oncomiRs using antisense oligomers (that is, antimiRs) is an evolving therapeutic strategy. However, the in vivo efficacy of current antimiR technologies is hindered by physiological and cellular barriers to delivery into targeted cells. Here we introduce a novel antimiR delivery platform that targets the acidic tumour microenvironment, evades systemic clearance by the liver, and facilitates cell entry via a non-endocytic pathway. We find that the attachment of peptide nucleic acid antimiRs to a peptide with a low pH-induced transmembrane structure (pHLIP) produces a novel construct that could target the tumour microenvironment, transport antimiRs across plasma membranes under acidic conditions such as those found in solid tumours (pH approximately 6), and effectively inhibit the miR-155 oncomiR in a mouse model of lymphoma. This study introduces a new model for using antimiRs as anti-cancer drugs, which can have broad impacts on the field of targeted drug delivery.

Published

2014

2. Metformin suppresses gluconeogenesis by inhibiting mitochondrial glycerophosphate dehydrogenase

Author

Hui-Young Lee, Richard G. Kibbey, Derek M. Erion, Joao Paulo Camporez, Anila K. Madiraju, Yasmeen Rahimi, Xian-Man Zhang, Michael J. MacDonald, John L. Wood, Gary W. Cline, Gerald I. Shulman, Varman T. Samuel, Michael J. Jurczak, Demetrios T. Braddock, Brett J. Prigaro, Ronald A. Albright, and Sanjay Bhanot

Subjects

Blood Glucose, Male, medicine.medical_specialty, endocrine system diseases, medicine.medical_treatment, Glycerolphosphate Dehydrogenase, Type 2 diabetes, Mitochondrion, Biology, Article, Rats, Sprague-Dawley, Internal medicine, Diabetes mellitus, Insulin Secretion, medicine, Animals, Humans, Hypoglycemic Agents, Insulin, Lactic Acid, Cells, Cultured, Mice, Knockout, Gene knockdown, Multidisciplinary, Gluconeogenesis, medicine.disease, Metformin, Mitochondria, Rats, 3. Good health, Cytosol, Endocrinology, Diabetes Mellitus, Type 2, Liver, Oxidation-Reduction, medicine.drug

Abstract

Metformin is considered to be one of the most effective therapeutics for treating type 2 diabetes because it specifically reduces hepatic gluconeogenesis without increasing insulin secretion, inducing weight gain or posing a risk of hypoglycaemia. For over half a century, this agent has been prescribed to patients with type 2 diabetes worldwide, yet the underlying mechanism by which metformin inhibits hepatic gluconeogenesis remains unknown. Here we show that metformin non-competitively inhibits the redox shuttle enzyme mitochondrial glycerophosphate dehydrogenase, resulting in an altered hepatocellular redox state, reduced conversion of lactate and glycerol to glucose, and decreased hepatic gluconeogenesis. Acute and chronic low-dose metformin treatment effectively reduced endogenous glucose production, while increasing cytosolic redox and decreasing mitochondrial redox states. Antisense oligonucleotide knockdown of hepatic mitochondrial glycerophosphate dehydrogenase in rats resulted in a phenotype akin to chronic metformin treatment, and abrogated metformin-mediated increases in cytosolic redox state, decreases in plasma glucose concentrations, and inhibition of endogenous glucose production. These findings were replicated in whole-body mitochondrial glycerophosphate dehydrogenase knockout mice. These results have significant implications for understanding the mechanism of metformin's blood glucose lowering effects and provide a new therapeutic target for type 2 diabetes.

Published

2014

3. Structure and dynamics of KH domains from FBP bound to single-stranded DNA

Author

John M. Louis, G. Marius Clore, Demetrios T. Braddock, David Levens, and James L. Baber

Subjects

Models, Molecular, Protein Folding, Magnetic Resonance Spectroscopy, Macromolecular Substances, Protein Conformation, Base pair, Molecular Sequence Data, Genes, myc, DNA, Single-Stranded, Biology, DNA-binding protein, chemistry.chemical_compound, Protein structure, Transcription (biology), Humans, Amino Acid Sequence, Peptide sequence, Multidisciplinary, DNA Helicases, RNA-Binding Proteins, Hydrogen Bonding, Protein Structure, Tertiary, DNA-Binding Proteins, Crystallography, Gene Expression Regulation, chemistry, Transcription factor II H, Biophysics, Nucleic Acid Conformation, Protein folding, DNA, Protein Binding

Abstract

Gene regulation can be tightly controlled by recognition of DNA deformations that are induced by stress generated during transcription1,2,3. The KH domains of the FUSE-binding protein (FBP), a regulator of c-myc expression1,4, bind in vivo and in vitro to the single-stranded far-upstream element (FUSE), 1,500 base pairs upstream from the c-myc promoter4,5,6. FBP bound to FUSE acts through TFIIH at the promoter4. Here we report the solution structure of a complex between the KH3 and KH4 domains of FBP and a 29-base single-stranded DNA from FUSE. The KH domains recognize two sites, 9–10 bases in length, separated by 5 bases, with KH4 bound to the 5′ site and KH3 to the 3′ site. The central portion of each site comprises a tetrad of sequence 5′d-ATTC for KH4 and 5′d-TTTT for KH3. Dynamics measurements show that the two KH domains bind as articulated modules to single-stranded DNA, providing a flexible framework with which to recognize transient, moving targets.

Published

2002