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Articles 1 - 7 of 7
Full-Text Articles in Molecular Biology
Rna-Seq And Mechanistic Enzymology Confirm Rna Self-Templated Extension By T7 Rna Polymerase And Suggest Novel Approaches Towards Improved In Vitro Rna Synthesis, Yasaman Gholamalipour
Rna-Seq And Mechanistic Enzymology Confirm Rna Self-Templated Extension By T7 Rna Polymerase And Suggest Novel Approaches Towards Improved In Vitro Rna Synthesis, Yasaman Gholamalipour
Doctoral Dissertations
Synthetic RNA is widely used in basic science, nanotechnology and therapeutics research. The vast majority of this RNA is synthesized in vitro by T7 RNA polymerase. However, the desired RNA is generally contaminated with products longer and shorter than the DNA-encoded product. To better understand these undesired byproducts and the processes that generate them, we analyzed in vitro transcription reactions using RNA-Seq as a tool. The results unambiguously confirmed that product RNA rebinds to the polymerase and self-primes (in cis) generation of a hairpin duplex, a process that favorably competes with promoter driven synthesis under high yield reaction conditions. …
The Spatial Organization Of Mycobacterial Membrane, Julia Puffal
The Spatial Organization Of Mycobacterial Membrane, Julia Puffal
Doctoral Dissertations
Mycobacteria comprises a large group of organisms including the pathogenic species Mycobacterium tuberculosis, the causative agent of tuberculosis. A fast- growing saprophytic member of this genus, however, Mycobacterium smegmatis, is oftentimes used as a model organism for the pathogenic species. With a unique cell envelope architecture and unconventional polar growth, spatial coordination of cell envelope biosynthesis is vital for proper assembly of this complex structure. Here, we provide a comprehensive overview of known lateral heterogeneities in mycobacterial plasma membrane, with a particular focus on the intracellular membrane domain (IMD), a spatially distinct region of the plasma membrane with diverse functions. …
Probing Apoptotic Caspase Allostery And Exosite Interactions For Alternative Regulation, Derek J. Macpherson
Probing Apoptotic Caspase Allostery And Exosite Interactions For Alternative Regulation, Derek J. Macpherson
Doctoral Dissertations
Programmed cell death, or apoptosis is a critical homeostatic pathway that monitors the balance of cell life and death. Apoptosis is regulated by a class of enzymes known as the cysteine aspartic proteases, or the caspases. The 12 human caspases that play important roles in the progression and regulation of apoptosis and inflammation. Caspases are tightly regulated by numerous factors including enzymatic activation, post-translational modifications, metal ligand binding, and protein modulation. Aberrant caspase activation and regulation has been implicated in the progression of numerous diseases such as proliferative diseases and neurodegeneration. The deeply entwined nature of caspases and apoptosis makes …
Building The Outer Membrane Protein G (Ompg) Nanopore Library: From The Discrimination Of Biotin-Binding Proteins In Serum To Resolving Human Carbonic Anhydrase From Human Red Blood Cells, Bib Yang
Doctoral Dissertations
The use of pore-forming proteins (PFPs) in nanopore sensing has been fruitful largely due to their nanoscale size and the ease with which protein nanopores can be manipulated and consistently reproduced at a large scale. Nanopore sensing relies heavily on a steady ionic current afforded by rigid nanopores, as the change in current is indicative of analyte detection, revealing characteristics of the analyte such as its relative size, concentration, and charge, as well as the nanopore:analyte interaction. Rigid PFPs have been used in applications such as DNA sequencing, kinetic studies, analyte discrimination, and protein conformation dynamics at the single-molecule level. …
Nascent Dna Proteomics Analysis Uncovers Dna Replication Dynamics In The Human Pathogen Trypanosoma Brucei, Maria Rocha Granados
Nascent Dna Proteomics Analysis Uncovers Dna Replication Dynamics In The Human Pathogen Trypanosoma Brucei, Maria Rocha Granados
Doctoral Dissertations
DNA is the substrate of many cellular processes including DNA replication, transcription and chromatin remodeling. These processes are coordinated to maintain genome integrity and ensure accurate duplication of genetic and epigenetic information. Genome-wide studies have provided evidence of the relationship between transcription and DNA replication timing. A global analysis of DNA replication initiation in T. brucei showed that TbORC1 (subunit of the origin recognition complex, ORC) binding sites are located at the boundaries of transcription units. Although recent studies in T. brucei indicate functional links among DNA replication and transcription, the underlying mechanisms remain unknown. In this study, we adapted …
Protein Degradation Regulates Phospholipid Biosynthetic Gene Expression In Saccharomyces Cerevisiae, Bryan Salas-Santiago
Protein Degradation Regulates Phospholipid Biosynthetic Gene Expression In Saccharomyces Cerevisiae, Bryan Salas-Santiago
Doctoral Dissertations
Transcriptional regulation of most phospholipid biosynthetic genes in Saccharomyces cerevisiae is coordinated by inositol and choline. Inositol affects phosphatidic acid (PA) intracellular levels. Opi1p interacts physically with PA and is the main repressor of the phospholipid biosynthetic genes. It is localized in the endoplasmic reticulum (ER) bound to the ER membrane protein Scs2p. When PA levels drop, Opi1p is translocated into the nucleus repressing most phospholipid biosynthetic genes. The OPI1 locus was identified in a screen looking for overproduction and excretion of inositol (Opi-). Opi- mutants are generally associated with a defect in …
Enhancing Nanopore Based Biosensening Technology Using Pore Forming Proteins, Christina M. Chisholm
Enhancing Nanopore Based Biosensening Technology Using Pore Forming Proteins, Christina M. Chisholm
Doctoral Dissertations
Pore forming proteins (PFPs) are membrane channels that are essential for various biological processes. For example, some PFPs act as gatekeepers of the cell, controlling the traffic of ions and macromolecules flowing into and out of cells; while others are involved in causing cell death (Reiner et al., 2012). Our fundamental understanding of PFPs determines our ability to employ these proteins for use in biomedical research and nanopore technology. Given their nanoscale dimensions, reproducibility and functionality these PFPs are widely used in the growing field of nanopore technology, particularly nanopore sensing (Reiner et al., 2012; Feng et al., 2015). These …