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Articles 1 - 24 of 24
Full-Text Articles in Molecular Biology
Multicopy Suppression Of Ribosomal Protein Deletion Mutants, Jacqualine Cerbone
Multicopy Suppression Of Ribosomal Protein Deletion Mutants, Jacqualine Cerbone
Senior Honors Projects
To suppress the ribosome assembly defective phenotype of a ribosomal protein uS17- deficient mutant, various ribosomal proteins were used to act as multicopy suppressors. Ribosomal protein uS17 is a highly conserved component of the 30S (small) ribosomal subunit and is important for 30S subunit assembly. Mutants with a deletion of rpsQ (the gene encoding uS17) are viable but have a severe 30S subunit assembly defect and a temperature-sensitive (ts) phenotype. While fully assembled 30S subunits do form, incomplete ("20S") particles lacking several proteins accumulate. We hypothesized that increasing the intracellular concentration of one or more of the proteins missing from …
Establishing A Biochemical System For The Purification And Atpase Activity Of Gst-Dbp5, Sarah R. Utley, Rachel E. Rigsby Phd, Rebecca L. Adams Phd
Establishing A Biochemical System For The Purification And Atpase Activity Of Gst-Dbp5, Sarah R. Utley, Rachel E. Rigsby Phd, Rebecca L. Adams Phd
Science University Research Symposium (SURS)
The export of mRNA out of the nucleus is a crucial step for eukaryotic gene expression. The export of mRNA transcripts is aided by Mex67, which allows export through the nuclear pore complex doorways in the nuclear envelope. Once out of the nucleus, a protein known as Dbp5, bound to ATP, Gle1, and Nup42 aids in the directionality of mRNA export by helping remove Mex67 from the mRNA strand. Following interaction with RNA, Dbp5 then hydrolyzes ATP so that it unbinds the mRNA, allowing for enzyme recycling. Previous efforts worked towards the purification of Dbp5, but the attempts were unsuccessful …
Development Of High Value Oil Traits Using The Model Oilseed Crop Camelina Sativa, Evan Updike
Development Of High Value Oil Traits Using The Model Oilseed Crop Camelina Sativa, Evan Updike
Department of Biochemistry: Dissertations, Theses, and Student Research
Plant oils are an important source of food, fuel, and feed in our society today. The oil found in the seeds of plants is composed almost entirely of triacylglycerol (TAG) molecules, which consist of three fatty acids esterified to a glycerol backbone. As crude oil supplies decline, vegetable oils are gaining traction as a renewable substitute to petroleum-based materials in fuels, lubricants, and specialty oleochemicals. However, as it currently stands vegetable oils do not possess the properties necessary to fill the void of a petroleum free world.
To address this problem, plant biotechnologists have done extensive work on genetic engineering …
High And Low Toxin Producing Strains Of Karenia Brevis Differ Significantly In The Redox Proteome, Lipid Profiles, And Xanthophyll Cycle Pigments, Ricardo Colon
FIU Electronic Theses and Dissertations
The dinoflagellate Karenia brevis, blooms annually in the Gulf of Mexico, producing a suite of neurotoxins known as the brevetoxins. The cellular toxin content of K. brevis, however, is highly variable between or even within strains. I investigated biochemical differences between high (KbHT) and low (KbLT) toxin producing cultures both derived from the Wilson strain, related to energy-dependent quenching (qE) by photosystem II, and the content of reduced thiols of the proteome. By characterizing the xanthophyll content of the two strains I was able to determine that KbLT performs qE inconsistently. To investigate the …
Structure And Mechanism Of Mycobacterial Topoisomerase I, Nan Cao
Structure And Mechanism Of Mycobacterial Topoisomerase I, Nan Cao
FIU Electronic Theses and Dissertations
The enzyme DNA topoisomerase I is an essential enzyme that plays an important role in eukaryotic and prokaryotic cellular processes such as DNA replication, transcription, recombination and repair. Mycobacterium tuberculosistopoisomerase I (MtTOP1) is a validated drug target for antituberculosis treatment. Mycobacterial topoisomerase I regulates the topological constraints in chromosomes and helps in maintaining the growth of mycobacteria. The N- terminal domain (NTD) of mycobacterial topoisomerase I contains conserved catalytic domains that along with the active site Tyrosine are involved in cleaving and rejoining a single strand of DNA. Magnesium is required in DNA cleavage activity of type IA topoisomerases. …
A Multisession, Undergraduate Molecular Biology Lab Experiment Using Green Fluorescent Protein Including Subcloning And Color Changing Mutagenesis, Nathan S. Winter
A Multisession, Undergraduate Molecular Biology Lab Experiment Using Green Fluorescent Protein Including Subcloning And Color Changing Mutagenesis, Nathan S. Winter
Chemistry Faculty Publications
This paper describes a series of experiments involving handling and manipulating the DNA coding for Green Fluorescent Protein (GFP) including the subcloning of this gene, and mutating the DNA so that Cyan Fluorescent Protein (CFP) or Blue Fluorescent protein (BFP) are expressed. The primers needed for the PCR based subcloning of GFP are presented, as are those needed to mutate the GFP to either CFP or BFP.
The Effects Of Mercury Exposure On The Cytochrome C Oxidase 1 Gene Of Larval Dragonflies, Megan C. Little
The Effects Of Mercury Exposure On The Cytochrome C Oxidase 1 Gene Of Larval Dragonflies, Megan C. Little
Honors College
Mercury is an environmental pollutant; its most toxic form is methylmercury. Once mercury is converted to methylmercury in a body of water it is able to bioaccumulate in organisms and biomagnify up the food chain. Mercury is able to cause DNA damage through the generation of free radicals and binding to sulfhydryl groups of cysteines in zinc finger DNA binding domains, inhibiting DNA repair machinery. In this study the potential mutagenic effects of mercury were investigated on larval dragonflies (Odonta: Anisoptera) collected from national parks across the United States. Since mercury is a known mutagen it was hypothesized that the …
Gene Expression Studies For The Analysis Of Domoic Acid Production In The Marine Diatom Pseudo-Nitzschia Multiseries, Katie Boissonneault, Brooks M. Henningsen, Stephen S. Bates, Deborah L. Robertson, Sean Milton, Jerry Pelletier, Deborah A. Hogan, David E. Housman
Gene Expression Studies For The Analysis Of Domoic Acid Production In The Marine Diatom Pseudo-Nitzschia Multiseries, Katie Boissonneault, Brooks M. Henningsen, Stephen S. Bates, Deborah L. Robertson, Sean Milton, Jerry Pelletier, Deborah A. Hogan, David E. Housman
Dartmouth Scholarship
Pseudo-nitzschia multiseries Hasle (Hasle) (Ps-n) is distinctive among the ecologically important marine diatoms because it produces the neurotoxin domoic acid. Although the biology of Ps-n has been investigated intensely, the characterization of the genes and biochemical pathways leading to domoic acid biosynthesis has been limited. To identify transcripts whose levels correlate with domoic acid production, we analyzed Ps-n under conditions of high and low domoic acid production by cDNA microarray technology and reverse-transcription quantitative PCR (RT-qPCR) methods. Our goals included identifying and validating robust reference genes for Ps-n RNA expression analysis under these conditions.
Novel Adaptor-Dependent Domains Promote Processive Degradation By Clpxp, Keith L. Rood
Novel Adaptor-Dependent Domains Promote Processive Degradation By Clpxp, Keith L. Rood
Masters Theses 1911 - February 2014
Protein degradation by ATP dependent proteases is a universally conserved process. Recognition of substrates by such proteases commonly occurs via direct interaction or with the aid of a regulatory adaptor protein. An example of this regulation is found in Caulobacter crescentus, where key regulatory proteins are proteolysed in a cell-cycle dependent fashion. Substrates include essential transcription factors, structural proteins, and second messenger metabolism components. In this study, we explore sequence and structural requirements for regulated adaptor mediated degradation of PdeA, an important regulator of cyclic-di-GMP levels.
Robust degradation of PdeA is dependent on the response regulator CpdR in vivo …
Resonance Assignments And Secondary Structure Predictions Of The As(Iii) Metallochaperone Arsd In Solution, Jun Ye, Yanan He, Jack Skalicky, Barry P. Rosen, Timothy L. Stemmler
Resonance Assignments And Secondary Structure Predictions Of The As(Iii) Metallochaperone Arsd In Solution, Jun Ye, Yanan He, Jack Skalicky, Barry P. Rosen, Timothy L. Stemmler
Biochemistry and Molecular Biology Faculty Publications
ArsD is a metallochaperone that delivers As(III) to the ArsA ATPase, the catalytic subunit of the ArsAB pump encoded by the arsRDABC operon of Escherichia coli plasmid R773. Conserved ArsD cysteine residues (Cys12, Cys13 and Cys18) construct the As(III) binding site of the protein, however a global structural understanding of this arsenic binding remains unclear. We have obtained NMR assignments for ArsD as a starting point for probing structural changes on the protein that occur in response to metalloid binding and upon formation of a complex with ArsA. The predicted solution structure of ArsD is in agreement with recently published …
Frataxin And Mitochondrial Fes Cluster Biogenesis, Timothy L. Stemmler, Emmanuel Lesuisse, Debumar Pain, Andrew Dancis
Frataxin And Mitochondrial Fes Cluster Biogenesis, Timothy L. Stemmler, Emmanuel Lesuisse, Debumar Pain, Andrew Dancis
Biochemistry and Molecular Biology Faculty Publications
Friedreich’s ataxia is an inherited neurodegenerative disease caused by frataxin deficiency. Frataxin is a conserved mitochondrial protein that plays a role in Fe-S cluster assembly in mitochondria. Fe-S clusters are modular cofactors that perform essential functions throughout the cell. They are synthesized by a multi-step and multi-subunit mitochondrial machinery that includes a scaffold protein Isu for assembling a protein bound Fe-S cluster intermediate. Frataxin interacts with Isu, iron, and with the cysteine desulfurase Nfs1 that supplies sulfur, thus placing it at the center of mitochondrial Fe-S cluster biosynthesis.
Oxidation Of Methane By A Biological Dicopper Centre, Ramakrishnan Balasubramanian, Stephen M. Smith, Swati Rawat, Liliya A. Yatsunyk, Timothy L. Stemmler, Amy C. Rosenzweig
Oxidation Of Methane By A Biological Dicopper Centre, Ramakrishnan Balasubramanian, Stephen M. Smith, Swati Rawat, Liliya A. Yatsunyk, Timothy L. Stemmler, Amy C. Rosenzweig
Biochemistry and Molecular Biology Faculty Publications
Vast world reserves of methane gas are underutilized as a feedstock for the production of liquid fuels and chemicals owing to the lack of economical and sustainable strategies for the selective oxidation of methane to methanol1. Current processes to activate the strong C–H bond (104 kcal mol−1) in methane require high temperatures, are costly and inefficient, and produce waste2. In nature, methanotrophic bacteria perform this reaction under ambient conditions using metalloenzymes called methane monooxygenases (MMOs). MMOs thus provide the optimal model for an efficient, environmentally sound catalyst3. There are two types of MMO. Soluble MMO (sMMO),expressed by several strains of …
Nmr Assignments Of A Stable Processing Intermediate Of Human Frataxin, Kalyan C. Kondapalli, Krisztina Z. Bencze, Eric Dizin, James A. Cowan, Timothy L. Stemmler
Nmr Assignments Of A Stable Processing Intermediate Of Human Frataxin, Kalyan C. Kondapalli, Krisztina Z. Bencze, Eric Dizin, James A. Cowan, Timothy L. Stemmler
Biochemistry and Molecular Biology Faculty Publications
Frataxin, a nuclear encoded protein targeted to the mitochondrial matrix, has recently been implicated as an iron chaperone that delivers ferrous iron to the iron-sulfur assembly enzyme IscU. During transport across the mitochondrial membrane, the N-terminal mitochondrial targeting sequence of frataxin is cleaved in a two-step process to produce the mature protein found in the matrix, however N-terminal extended forms of the protein have also been observed in vivo. The recent structural characterization studies of the human frataxin ortholog were performed on a truncated variant of the protein. Here we report the NMR spectral assignment of an extended form of …
Self-Assembly And Disassembly Of The Snare Complex: Examined Using Circular Dichroism And Atomic Force Microscopy, Jeremy D. Cook, Won Jin Cho, Timothy L. Stemmler, Bhanu P. Jena
Self-Assembly And Disassembly Of The Snare Complex: Examined Using Circular Dichroism And Atomic Force Microscopy, Jeremy D. Cook, Won Jin Cho, Timothy L. Stemmler, Bhanu P. Jena
Biochemistry and Molecular Biology Faculty Publications
In this study, we report for the first time that both t-SNAREs and v-SNARE and their complexes in buffered suspension, exhibit defined peaks at CD signals of 208 and 222 nm wavelengths, consistent with a higher degree of helical secondary structure. Surprisingly, when incorporated in lipid membrane, both SNAREs and their complexes exhibit reduced folding. In presence of NSF-ATP, the SNARE complex disassembles, as reflected from the CD signals demonstrating elimination of α-helices within the structure.
Structure And Dynamics Of Metalloproteins In Live Cells, Jeremy D. Cook, James E. Penner-Hahn, Timothy L. Stemmler
Structure And Dynamics Of Metalloproteins In Live Cells, Jeremy D. Cook, James E. Penner-Hahn, Timothy L. Stemmler
Biochemistry and Molecular Biology Faculty Publications
X-ray absorption spectroscopy (XAS) has emerged as one of the premier tools for investigating the structure and dynamic properties of metals in cells and in metal containing biomolecules. Utilizing the high flux and broad energy range of X-rays supplied by synchrotron light sources, one can selectively excite core electronic transitions in each metal. Spectroscopic signals from these electronic transitions can be used to dissect the chemical architecture of metals in cells, in cellular components and in biomolecules at varying degrees of structural resolution. With the development of ever-brighter X-ray sources, X-ray methods have grown into applications that can be utilized …
Evolution Of Metal(Loid) Binding Sites In Transcriptional Regulators, Efrén Ordóñez, Saravanamuthu Thiyagarajan, Jeremy D. Cook, Timothy L. Stemmler, José A. Gil., Luís M. Mateos, Barry P. Rosen
Evolution Of Metal(Loid) Binding Sites In Transcriptional Regulators, Efrén Ordóñez, Saravanamuthu Thiyagarajan, Jeremy D. Cook, Timothy L. Stemmler, José A. Gil., Luís M. Mateos, Barry P. Rosen
Biochemistry and Molecular Biology Faculty Publications
Expression of the genes for resistance to heavy metals and metalloids is transcriptionally regulated by the toxic ions themselves. Members of the ArsR/SmtB family of small metalloregulatory proteins respond to transition metals, heavy metals and metalloids, including As(III), Sb(III), Cd(II), Pb(II), Zn(II), Co(II) and Ni(II). These homodimeric repressors bind to DNA in absence of inducing metal(loid) ion and dissociate from the DNA when inducer is bound. The regulatory sites are often three- or four-coordinate metal binding sites composed of cysteine thiolates. Surprisingly, in two different As(III)-responsive regulators, the metalloid binding sites were in different locations in the repressor, and the …
A Cytosolic Iron Chaperone That Delivers Iron To Ferritin, Haifeng Shi, Krisztina Z. Bencze, Timothy L. Stemmler, Caroline C. Philpott
A Cytosolic Iron Chaperone That Delivers Iron To Ferritin, Haifeng Shi, Krisztina Z. Bencze, Timothy L. Stemmler, Caroline C. Philpott
Biochemistry and Molecular Biology Faculty Publications
Ferritins are the main iron storage proteins found in animals, plants and bacteria. The capacity to store iron in ferritin is essential for life in mammals, but the mechanism by which cytosolic iron is delivered to ferritin is unknown. Human ferritins expressed in yeast contain little iron. The human Poly r(C)-Binding Protein 1 (PCBP1) increased the amount of iron loaded into ferritin when expressed in yeast. PCBP1 bound to ferritin in vivo, and bound iron and facilitated iron loading into ferritin in vitro. Depletion of PCBP1 in human cells inhibited ferritin iron loading and increased cytosolic iron pools. Thus, PCBP1 …
Characterization And Structure Of A Zn2+ And [2fe-2s]-Containing Copper Chaperone From Archaeoglobus Fulgidus, Matthew H. Sazinsky, Benjamin Lemoine, Maria Orofino, Roman Davydov, Krisztina Z. Bencze, Timothy L. Stemmler, Brian M. Hoffman, José M. Argüello, Amy C. Rosenzweig
Characterization And Structure Of A Zn2+ And [2fe-2s]-Containing Copper Chaperone From Archaeoglobus Fulgidus, Matthew H. Sazinsky, Benjamin Lemoine, Maria Orofino, Roman Davydov, Krisztina Z. Bencze, Timothy L. Stemmler, Brian M. Hoffman, José M. Argüello, Amy C. Rosenzweig
Biochemistry and Molecular Biology Faculty Publications
Bacterial CopZ proteins deliver copper to P1B-type Cu+-ATPases that are homologous to the human Wilson and Menkes disease proteins. The genome of the hyperthermophile Archaeoglobus fulgidus encodes a putative CopZ copper chaperone that contains an unusual cysteine rich N-terminal domain of 130 amino acids in addition to a C-terminal copper-binding domain with a conserved CXXC motif. The N-terminal domain (CopZ-NT) is homologous to proteins found only in extremophiles and is the only such protein that is fused to a copper chaperone. Surprisingly, optical, electron paramagnetic resonance, and X-ray absorption spectroscopic data indicate the presence of a [2Fe-2S] cluster in CopZ-NT. …
Human Frataxin: Iron And Ferrochelatase Binding Surface, Krisztina Z. Bencze, Taejin Yoon, CéSar MilláN-Pacheco, Patrick B. Bradley, Nina Pastor, J. A. Cowan, Timothy L. Stemmler
Human Frataxin: Iron And Ferrochelatase Binding Surface, Krisztina Z. Bencze, Taejin Yoon, CéSar MilláN-Pacheco, Patrick B. Bradley, Nina Pastor, J. A. Cowan, Timothy L. Stemmler
Biochemistry and Molecular Biology Faculty Publications
The coordinated iron structure and ferrochelatase binding surface of human frataxin have been characterized to provide insight into the protein’s ability to serve as the iron chaperone during heme biosynthesis.
The Structure And Function Of Frataxin, Krisztina Z. Bencze, Kalyan C. Kondapalli, Jeremy D. Cook, Stephen Mcmahon, César Millán-Pacheco, Nina Pastor, Timothy L. Stemmler
The Structure And Function Of Frataxin, Krisztina Z. Bencze, Kalyan C. Kondapalli, Jeremy D. Cook, Stephen Mcmahon, César Millán-Pacheco, Nina Pastor, Timothy L. Stemmler
Biochemistry and Molecular Biology Faculty Publications
Frataxin, a highly conserved protein found in prokaryotes and eukaryotes, is required for efficient regulation of cellular iron homeostasis. Humans with a frataxin deficiency have the cardio- and neurodegenerative disorder Friedreich’s ataxia, commonly resulting from a GAA trinucleotide repeat expansion in the frataxin gene. While frataxin’s specific function remains a point of controversy, a general consensus is the protein assists in controlling cellular iron homeostasis by directly binding iron. This review focuses on the structural and biochemical aspects of iron binding by the frataxin orthologs and outlines molecular attributes that may help explain the protein’s role in different cellular pathways.
Three-Dimensional Structure Of The Bacterial Cell Wall Peptidoglycan, Samy O. Meroueh, Krisztina Z. Bencze, Dusan Hesek, Mijoon Lee, Timothy L. Stemmler, Shahriar Mobashery
Three-Dimensional Structure Of The Bacterial Cell Wall Peptidoglycan, Samy O. Meroueh, Krisztina Z. Bencze, Dusan Hesek, Mijoon Lee, Timothy L. Stemmler, Shahriar Mobashery
Biochemistry and Molecular Biology Faculty Publications
The 3D structure of the bacterial peptidoglycan, the major constit- uent of the cell wall, is one of the most important, yet still unsolved, structural problems in biochemistry. The peptidoglycan comprises alternating N-acetylglucosamine (NAG) and N-acetylmu- ramic disaccharide (NAM) saccharides, the latter of which has a peptide stem. Adjacent peptide stems are cross-linked by the transpeptidase enzymes of cell wall biosynthesis to provide the cell wall polymer with the structural integrity required by the bacte- rium. The cell wall and its biosynthetic enzymes are targets of antibiotics. The 3D structure of the cell wall has been elusive because of its …
The Importance Of A Critical Protonation State And The Fate Of The Catalytic Steps In Class A Β-Lactamases And Penicillin-Binding Proteins, Dasantila Golemi-Kotra, Samy O. Meroueh, Choonkeun Kim, Sergei B. Vakulenko, Alexey Bulychev, Ann J. Stemmler, Timothy L. Stemmler, Shahriar Mobashery
The Importance Of A Critical Protonation State And The Fate Of The Catalytic Steps In Class A Β-Lactamases And Penicillin-Binding Proteins, Dasantila Golemi-Kotra, Samy O. Meroueh, Choonkeun Kim, Sergei B. Vakulenko, Alexey Bulychev, Ann J. Stemmler, Timothy L. Stemmler, Shahriar Mobashery
Biochemistry and Molecular Biology Faculty Publications
b-Lactamases and penicillin-binding proteins are bacterial enzymes involved in antibiotic resistance to b-lactam antibiotics and biosynthetic assembly of cell wall, respectively. Members of these large families of enzymes all experience acylation by their respective substrates at an active-site serine as the first step in their catalytic activities. A Ser-X-X-Lys sequence motif is seen in all these proteins and crystal structures demonstrate that the side chain functions of the serine and lysine are in contact with one another. Three independent methods were used in this report to address the question of the protonation state of this important lysine (Lys73) in the …
Core Concepts In Biochemistry And Molecular Biology In An Integrated Mbbs Curriculum, M P. Iqbal
Core Concepts In Biochemistry And Molecular Biology In An Integrated Mbbs Curriculum, M P. Iqbal
Department of Biological & Biomedical Sciences
No abstract provided.
Purified Particulate Methane Monooxygenase From Methylococcus Capsulatus (Bath) Is A Dimer With Both Mononuclear Copper And A Copper-Containing Cluster, Raquel L. Lieberman, Deepak B. Shrestha, Peter E. Doan, Brian M. Hoffman, Timothy L. Stemmler, Amy C. Rosenzweig
Purified Particulate Methane Monooxygenase From Methylococcus Capsulatus (Bath) Is A Dimer With Both Mononuclear Copper And A Copper-Containing Cluster, Raquel L. Lieberman, Deepak B. Shrestha, Peter E. Doan, Brian M. Hoffman, Timothy L. Stemmler, Amy C. Rosenzweig
Biochemistry and Molecular Biology Faculty Publications
Particulate methane monooxygenase (pMMO) is a membrane-bound enzyme that catalyzes the oxidation of methane to methanol in methanotropic bacteria. Understanding how this enzyme hydroxylates methane at ambient temperature and pressure is of fundamental chemical and potential commercial importance. Difficulties in solubilizing and purifying active pMMO have led to conflicting reports regarding its biochemical and biophysical properties, however. We have purified pMMO from Methylococcus capsulatus (Bath) and detected activity. The purified enzyme has a molecular mass of ~200 kDa, probably corresponding to an a2b2g2 polypeptide arrangement. Each 200 kDa pMMO complex contains 4.8 ± 0.8 copper ions and 1.5 ± 0.7 …