Global ETD Search

31	Structural and Functional Studies of the KCNQ1-KCNE K<sup>+</sup> Channel Complex: A Dissertation Gage, Steven D. 09 September 2008 (has links) KCNQ1 is a homotetrameric voltage-gated potassium channel expressed in cardiomyocytes and epithelial tissues. However, currents arising from KCNQ1 have never been physiologically observed. KCNQ1 is able to provide the diverse potassium conductances required by these distinct cell types through coassembly with and modulation by type I transmembrane β-subunits of the KCNE gene family. KCNQ1-KCNE K+ channels play important physiological roles. In cardiac tissues the association of KCNQ1 with KCNE1 gives rise to IKs, the slow delayed outwardly rectifying potassium current. IKs is in part responsible for repolarizing heart muscle, and is therefore crucial in maintaining normal heart rhymicity. IKschannels help terminate each action potential and provide cardiac repolarization reserve. As such, mutations in either subunit can lead to Romano-Ward Syndrome or Jervell and Lange-Nielsen Syndrome, two forms of Q-T prolongation. In epithelial cells, KCNQ1-KCNE1, KCNQ1-KCNE2 and KCNQ1-KCNE3 give rise to potassium currents required for potassium recycling and secretion. These functions arise because the biophysical properties of KCNQ1 are always dramatically altered by KCNE co-expression. We wanted to understand how KCNE peptides are able to modulate KCNQ1. In Chapter II, we produce partial truncations of KCNE3 and demonstrate the transmembrane domain is necessary and sufficient for both assembly with and modulation of KCNQ1. Comparing these results with published results obtained from chimeric KCNE peptides and partial deletion mutants of KCNE1, we propose a bipartite modulation residing in KCNE peptides. Transmembrane modulation is either active (KCNE3) or permissive (KCNE1). Active transmembrane KCNE modulation masks juxtamembranous C-terminal modulation of KCNQ1, while permissive modulation allows C-terminal modulation of KCNQ1 to express. We test our hypothesis, and demonstrate C-terminal Long QT point mutants in KCNE1 can be masked by active trasnsmembrane modulation. Having confirmed the importance the C-terminus of KCNE1, we continue with two projects designed to elucidate KCNE1 C-terminal structure. In Chapter III we conduct an alanine-perturbation scan within the C-terminus. C-terminal KCNE1 alanine point mutations result in changes in the free energy for the KCNQ1-KCNE1 channel complex. High-impact point mutants cluster in an arrangement consistent with an alphahelical secondary structure, "kinked" by a single proline residue. In Chapter IV, we use oxidant-mediated disulfide bond formation between non-native cysteine residues to demonstrate amino acid side chains residing within the C-terminal domain of KCNE1 are close and juxtaposed to amino acid side chains on the cytoplasmic face of the KCNQ1 pore domain. Many of the amino acids identified as high impact through alanine perturbation correspond with residues identified as able to form disulfide bonds with KCNQ1. Taken together, we demonstrate that the interaction between the C-terminus of KCNE1 and the pore domain of KCNQ1 is required for the proper modulation of KCNQ1 by KCNE1, and by extension, normal IKs function and heart rhymicity. KCNQ1 Potassium Channel Ion Channel Gating Membrane Potentials KCNQ Potassium Channels Potassium Channels Voltage-Gated Protein Structure Secondary Amino Acids, Peptides, and Proteins Genetic Phenomena Inorganic Chemicals
32	Role of Disulfide Bond Rearrangement in Newcastle Disease Virus Entry: A Dissertation Jain, Surbhi 26 June 2008 (has links) Newcastle disease virus (NDV), an avian paramyxovirus, enters the host cell by fusion of viral and host cell membranes. The fusion of two membranes is mediated by the viral fusion (F) protein. The F protein, like other class I fusion proteins, is thought to undergo major conformational changes during the fusion process. The exact mechanism that leads to major refolding of F protein is not clear. Recently, it has been proposed that disulfide bond reduction in the fusion protein of some viruses may be involved in the conformational changes in fusion proteins. In some viruses, the reduction of disulfide bonds in the fusion protein is mediated by host cell disulfide isomerases belonging to the protein disulfide isomerase (PDI) family. In this study, the role of disulfide bond isomerization in the entry of NDV was analyzed. Using inhibitors of thiol-disulfide isomerases, we found that blocking the reduction of disulfide bonds in the fusion protein inhibited cell-cell fusion as well as virus entry into the host cell. Also, over-expression of isomerases belonging to the PDI family significantly enhanced cell-cell fusion. Taken together, these results suggest that free thiols play an important role in fusion mediated by NDV glycoproteins. Using a thiol specific, membrane impermeable biotin, MPB, we found that free thiols are produced in cell surface-expressed NDV F protein. The production of free thiols was inhibited by inhibitors of thiol-disulfide isomerases. Over-expression of isomerases belonging to the PDI family enhanced detection of free thiols in F protein. In F protein, present in virions or in virus-like particles, free thiols were detected only after the particles were attached to target cells. Taken together, these results suggest that free thiols are produced in F protein and the production of free thiols is mediated by host cell thiol-disulfide isomerases. Using conformation sensitive antibodies, we also studied the conformation of cell surface-expressed F protein in the presence ofthiol-disulfide isomerase inhibitors or in cells over-expressing thiol-disulfide isomerases. In the presence of thiol-disulfide isomerase inhibitors, the cell surface-expressed F protein was in a prefusion conformation while in cells over-expressing thiol-disulfide isomerases the F protein was in a post-fusion conformation. We also correlated the production of free thiols to the conformational changes in F protein. Using temperature-arrested intermediates or F protein with mutations in heptad repeat domains, which are defective in attaining intermediate conformations, we found that free thiols are produced before any of the proposed conformational changes in F protein. Also, the production of free thiols in F protein was found to be independent of its activation by hemagglutinin-neuraminidase (HN) protein. These results suggest that free thiols are probably required for the activation of F protein during membrane fusion. Viral Fusion Proteins Disulfides Newcastle disease virus Membrane Fusion Protein Disulfide-Isomerase Amino Acids, Peptides, and Proteins Chemical Actions and Uses Inorganic Chemicals Organic Chemicals Viruses
33	Biomimetic Synthetic Tissue Scaffolds for Bone Regeneration: A Dissertation Filion Potts, Tera M. 21 July 2011 (has links) Injury to bone is one of the most prevalent and costly medical conditions. Clinical treatment of volumetric bone loss or hard-to-heal bony lesions often requires the use of proper bone grafting materials, with or without adjuvant anabolic therapeutics. Despite significant problems associated with autografting (donor site morbidity, limited supplies) and allografting (disease transmissions, high graft failure rates) procedures, synthetic bone grafts remain the least utilized clinically. Existing synthetic orthopaedic biomaterials rarely possess a combination of bone-like structural and biochemical properties required for robust osteointegration, scalable and user-friendly characteristics indispensable for successful clinical translations. This thesis tests the hypothesis that by recapitulating key structural elements and biochemical components of bone in 3- and 2-dimensional biomaterials, scalable synthetic bone grafts can be designed to enable expedited healing of hard-to-heal volumetric bone loss. Specifically, FlexBone, a 3-dimensional hydrogel scaffold encapsulating 50 wt% of structurally well integrated nanocrylstalline hydroxyapatite, the main inorganic component of bone, was developed. The large surface area of nanocrystalline hydroxyapatite combined with its intrinsic affinity to proteins and its excellent structural integration with the hydrogel matrix enabled FlexBone to both sequester endogenous protein signals upon press-fitting into an area of skeletal defect and to deliver exogenous protein therapeutics in a localized and sustained manner. We demonstrated that FlexBone enabled the functional healing of critical-size long bone defects in rats in 8 – 12 weeks with the addition of a very low dose of osteogenic growth factor BMP-2/7. This promising synthetic bone graft is now being explored for the delivery of multiple growth factors to expedite the healing of diabetic bony lesions. In addition, a 2-dimensional electrospun cellulose fibrous mesh was chemically modified with sulfate residues to mimic sulfated polysaccharide ECM components of skeletal tissues to enabled progenitor cell attachment and differentiation as well as controlled retention and localized/sustained delivery of protein therapeutics. This sulfated fibrous mesh is currently explored as synthetic periosteum to augment the osteointegration of devitalized structural allografts. Finally, a rat subcutaneous implantation model developed to examine the biocompatibility of newly developed biodegradable shape memory polymer bone substitutes is also presented. Bone Substitutes Hydrogel Hydroxyapatites Bone Transplantation Biology and Biomimetic Materials Biomaterials Cell Biology Inorganic Chemicals Macromolecular Substances Musculoskeletal System Organic Chemicals Pharmaceutical Preparations Tissues
34	M<sub>1</sub> Muscarinic Modulation of N-Type Calcium Channels: A Dissertation Heneghan, John F. 06 November 2006 (has links) The influx of calcium through N-type calcium channels (N-current) affects a myriad of neuronal functions. These include the triggering of synaptic release of neurotransmitter, adjustment of membrane potential and changes in gene transcription. N-channels are highly modulated proteins, so that N-current is attenuated or potentiated in response to environmental changes. In turn, the modulation of N-current has a direct effect on the downstream events, making the N-channel a focal point in neural signaling, and its modulation a mechanism for short term plasticity. The modulation of N-current by M1 muscarinic receptors (M1Rs) is of particular interest for several reasons. The M1R is instrumental in both cognition and memory formation as indicated by studies using either pharmacological agents aimed at M1Rs or knockout animals lacking M1Rs. Clinically, the M1R is an important target in the treatment of Alzheimer’s disease. Thus, like the N-channel, the M1R is an important element of neural signaling. Moreover, the stimulation of M1Rs affects N-current by through signaling pathways which despite being studied for decades, are not completely understood. For my dissertation I have investigated of M1R signaling on N-current using electrophysiological recordings of N-current from freshly dissociated neurons and from HEK cells expressing N-channels and M1Rs. Asking how one receptor affects one type of calcium channel would seem to be a simple question. However, the answer has many facets. Since M1Rs have multiple downstream effects and N-channels are highly modulated proteins, stimulation of M1Rs initiates several different pathways which modulate N-current. This thesis aims to unravel some of the complexities of the interactions of two vital components of neuronal signaling. Here I present the results of studies elucidating three different actions of M1signaling of N-current modulation. The first study I present here examines the effect of N-channel subunit composition on modulation of N-current. The stimulation of M1Rs in superior cervical ganglion (SCG) neurons elicits a distinct pattern of modulation; inhibiting N-current elicited by strong depolarizations and enhancing current elicited by lesser depolarizations. Thus M1Rs cause two simultaneous modulatory effects on N-current; increasing voltage sensitivity and decreasing overall conductance. I found the expression of the N-channel’s β subunit (CaVβ) determines the observed effect. Specifically when the isoform CaVβ2a is expressed M1 stimulation elicits enhancement without inhibition. Conversely, when CaVβ1b, CaVβ3, or CaVβ4 are expressed M1 stimulation elicits inhibition with out enhancement. These results fit a model in which both the enhancing and inhibiting effects of M1stimulation occur in all channels, but typically inhibition dominates. CaVβ2a blocks inhibition unmasking latent enhancement. Moreover, using mutants and chimeras I found palmitoylation of CaVβ2a at the N-terminus plays a key role in blocking inhibition. My findings predict the expression and localization of different CaVβ isoforms would dramatically alter modulation of N-current and thus may represent a previously unrecognized form of plasticity. The inhibition of N-current by M1Rs is controversial. It has been proposed recently that inhibition is directly attributable to the depletion of phosphatidylinositol-4,5-bisphosphate [PtdIns(4,5)P2] during M1 stimulation. However, in our lab, we have found arachidonic acid (AA) release, which occurs subsequent to PtdIns(4,5)P2 hydrolysis, is both necessary and sufficient to elicit inhibition. Therefore, in a second study, I tested the effect of CaVβ expression on N-current during exogenous AA application and found a pattern of modulation identical to M1R stimulation. Furthermore, I took part in a collaborative project identifying the AA producing enzyme, diacylglycerol lipase (DAGL), to be a necessary component of the inhibitory pathway elicited by M1Rs. These findings provide increased evidence for AA release being a key factor in the M1R stimulated pathway of inhibition. Moreover, these discoveries identify the expression of CaVβ2a and use of specific DAGL inhibitors as a molecular and pharmacological strategy to block inhibition of N-current, respectively. These tools allow the dissection of downstream effects of M1R stimulation, so that other modulatory effects may be observed. The phosphorylation of N-channels by protein kinase C (PKC) blocks inhibition of current brought on by G-protein β and γ subunits (Gβγ) binding directly to the channel. Relief of Gβγ inhibition by other means has been identified as a mechanism of short term plasticity. M1Rs are known to simulate PKC, but a connection between M1Rs and PKC phosphorylation of Nchannels had not been demonstrated. I hypothesized that PKC stimulation may be occluded by other downstream effects of M1Rs. Therefore in a third study, I used a pharmacological approach on SCG neurons to dissect the PKC activating pathway from the other downstream effects of M1 stimulation. I observed modulation of N-current indicating a loss of Gβγ&#; inhibition, thus consistent with PKC phosphorylation of channels. This conclusion reveals another aspect of M1 modulation, which can function as a means of short term plasticity. Calcium Channels N-Type Receptor Muscarinic M1 Neurotransmitter Agents Signal Transduction Amino Acids, Peptides, and Proteins Biological Factors Cells Enzymes and Coenzymes Inorganic Chemicals Investigative Techniques
35	The Roles of DNA Mismatch Repair and Recombination in Drug Resistance: A Dissertation Calmann, Melissa A. 01 December 2004 (has links) Cells have evolved different pathways in order to tolerate damage produced by different cytotoxic agents. Each agent reacts differently with DNA causing formation of different types of adducts, each eliciting the SOS stress response to induce different cellular repair pathways. One such type of substrate generated by cytotoxic agents is the DNA double strand break (DSB). The main pathway to repair such damage in the cell is through a process of recombination. In this thesis, I specifically examined the anti-cancer therapeutic agent cisplatin, which forms single- and double-strand breaks in DNA, and methylating agents, which are proposed to also be capable of forming such breaks. Neither type of agent can directly form these breaks; however, they leave a signature type of damage lesion which is recognized by different repair processes. The mismatch repair (MMR) status of a mammalian cell or an Escherichia coli dam mutant relates directly to the sensitivity of the cells to the agents mentioned above. As the dam gene product plays an important role in this pathway and in other processes in the cell, when mutated, dam cells are more sensitive to methylating agents and cisplatin than wildtype. A combination of dam and either mutS or mutL restores resistance to the same agents to wild type levels. Therefore, mismatch repair sensitizes dam bacteria to these agents. The rationale for this comes from examining the viability of dam mutants, as dammutants are only viable because they are highly recombinogenic. The presence of MMR-induced nicks or gaps results in the formation of DSBs that require recombination to restore genomic integrity. Mismatch repair proteins inhibit recombination between homeologous DNA. Homeologous recombination (recombination between non-identical, but similar, DNA sequences) is only possible when the MMR proteins, MutS and MutL, are absent. It is postulated that this is because MutS recognizes the homeologous DNA and subsequently slows down or aborts recombination completely. The double mutant, dam mutS/L shows wild type levels of sensitivity to cisplatin because mismatch repair is no longer recognizing the adducts and recombinational repair is allowed to continue. Human cells behave in an analogous fashion to the bacterial dam mutant, showing sensitivity to cisplatin and methylating agents. When an additional mutation in a mismatch repair gene is present, the cells become as resistant as wild type. Therefore, the E. coli dammutant is a useful model system to study this mechanism of drug resistance. DNA containing cisplatin adducts or lesions resulting from methylation are substrates for other types of repair processes such as nucleotide excision repair and base excision repair; however they have also been implicated as substrates for MMR and recombinational repair. The goal of the work in this thesis was two-fold. The first was to identify the gene products and mechanism necessary for repair of cisplatin damage by recombination. The second was to examine the mechanism of cisplatin toxicity, and specifically how MMR proficiency aids in the cytotoxicity of this drug by preventing recombination. Using the duplicated inactive lac operon recombination assay, we were able to determine the requirements for spontaneous and cisplatin-induced recombination, the RecBCD and RecFOR pathways. We were also able to further postulate that the cisplatin- induced signature damage recognized by recombination was the double strand break, likely formed from fork stalling and regression or a subsequent collapse during DNA synthesis, thus requiring these pathways for repair. This observation led to the experiments involving examination of the mechanism of cisplatin toxicity and where MMR could inhibit specific steps of recombination with DNA containing cisplatin lesions. Low levels of cisplatin lesions slowed the rate of RecA-mediated strand transfer in vitro, likely due to its ability to form a large bend in the DNA. MutS bound to cisplatin lesions in the DNA during heteroduplex formation in the RecA strand exchange step of recombination, inhibiting branch migration, and aborting the reaction. In order for MutS to inhibit recombination with cisplatin lesions, the results in the work in Chapter IV, show that binding to the lesion requires the C-terminus of MutS to be present, possibly due to a requirement for tetramerization of the protein, a domain contained in the C-terminus of MutS. This antirecombination function is different than the mutation avoidance function of MutS, as binding of mismatches requires only dimers. This differential sensitivity for cisplatin versus a mismatch was further exemplified in Chapter V, the experiments with dna mutants, where the greatest difference in sensitivity was observed for a dnaE mutant (catalytic subunit of polIII), which was as sensitive to cisplatin as a dam mutant, but fairly resistant to treatment with MNNG. This is indicative of the potency of a cisplatin adduct to block polymerase progression, versus a mismatch which poses little problem to synthesis. Recombination is invoked to repair DSBs caused by the cisplatin lesions through the RecBCD and FOR pathways after fork regression or collapse. A main conclusion from these studies is that a cisplatin lesion is processed differently than a mismatch. The mechanism of how a cisplatin lesion is processed, forming the DSB which invokes recombinational repair is still unclear and continues to be investigated. Drug Resistance Cisplatin Bacterial Proteins Escherichia coli Proteins DNA Repair DNA Damage Recombination Genetic Adenosinetriphosphatase DNA-Binding Proteins Amino Acids, Peptides, and Proteins Bacteria Cells Enzymes and Coenzymes Genetic Phenomena Inorganic Chemicals Neoplasms Pharmaceutical Preparations Therapeutics
36	The Coupling Between Folding, Zinc Binding, and Disulfide Bond Status of Human Cu, Zn Superoxide Dismutase: A Dissertation Kayatekin, Can 15 June 2010 (has links) Cu, Zn superoxide dismutase (SOD1) is a dimeric, β-sandwich, metalloenzyme responsible for the dismutation of superoxide. Mutations covering nearly 50% of the amino acid sequence of SOD1 have been found to acquire a toxic gain-of-function leading to amyotrophic lateral sclerosis. A hallmark of this disease is the presence of insoluble aggregates containing SOD1 found in the brain and spinal cord. While it is unclear how these aggregates or smaller, precursor oligomeric species may be the source of the toxicity, mutations leading to increased populations of unstable, partially folded species along the folding pathway of SOD1 may be responsible for seeding and propagating aggregation. In an effort to determine the responsible species, we have systematically characterized the stability and folding kinetics of five well studied ALS variants: A4V, L38V, G93A, L106V and S134N. The effect of the amino acid substitutions was determined on a variety of different constructs characterizing the various post-translational maturation steps of SOD1: folding, disulfide bond formation and Zn binding. Zn was found to bind progressively tighter along the folding pathway of SOD1, minimizing populations of monomeric species. In contrast, ALS variants were found to have the greatest perturbation in the equilibrium populations of the folded and unfolded state for the most immature, disulfide-reduced metal-free SOD1. In this species, at physiological temperature, four out of five ALS variants were >50% unfolded. Finally the energetic barriers in the folding and unfolding reaction were studied to investigate the unusually slow folding of SOD1. These results reveal that both unfolding and refolding are dominated by enthalpic barriers which may be explained by the desolvation of the chain and provide insights into the role of sequence in governing the folding pathway and rate. Superoxide Dismutase Amyotrophic Lateral Sclerosis Zinc Protein Folding Proteostasis Deficiencies Disulfides Amino Acids, Peptides, and Proteins Enzymes and Coenzymes Genetic Phenomena Inorganic Chemicals Nervous System Diseases Nutritional and Metabolic Diseases Organic Chemicals
37	Investigating Age-Dependent Arthropathy in a Circadian Mutant Mouse Model: A Dissertation Yu, Elizabeth A. 09 June 2011 (has links) Ectopic calcification can cause pain and limit mobility. Studies suggest that circadian genes may play a role in the calcification process. Core circadian genes Clock, Npas2, and Bmal1 are transcription factors that form CLOCK:BMAL1 or NPAS2:BMAL1 transactivator complexes that drive the rhythmic expression of circadian oscillator genes and output genes. Circadian oscillator genes Period1-3 and Cryptochrome1-2 encode proteins that form transcription repressor complexes that feedback to inhibit CLOCK/NPAS2:BMAL1 activity, thus completing the feedback loop that is the basis of the molecular circadian clockwork. Arrhythmic Bmal1-/- mice exhibit site-specific, age-dependent arthropathy. While studying the circadian phenotype of Clock-/-;Npas2m/m double mutant mice, we discovered that these double mutant mice develop site-specific arthropathy similar to the arthropathy described in Bmal1-/- mice. Based on the circadian clockwork mechanism, we hypothesized that CLOCK/NPAS2:BMAL1 transactivator complexes drive the expression of a gene (or genes) that prevents age-dependent arthropathy. To investigate Clock-/-;Npas2m/m double mutant mouse arthropathy, we evaluated mutant mice using X-ray, micro-computed tomography, and histology, and found that Clock-/-;Npas2m/m double mutant mice exhibit age-dependent, site-specific arthropathy that phenocopies that of Bmal1-/- mice. The costosternal junction and calcaneal tendon are most prominently affected, in that calcification of those tissues is detectable as early as 4-5 weeks and 11-12 weeks, respectively. The arthropathic lesions in these tissues consist of calcium phosphate vii deposits, and in Bmal1-/- costosternal junction calcifications, the deposits contain calcium pyrophosphate dihydrate crystals. Mechanical stress, disregulation of centrally-regulated circadian rhythms, and systemic serum mineral imbalances likely do not contribute to this pathology. In vitro micromass cultures generated from Clock-/-;Npas2m/m double mutant mouse embryonic fibroblasts do not exhibit irregular chondrocyte differentiation compared to wild-type cultures, suggesting that chondrocyte cell-autonomous mechanisms are insufficient to induce this arthropathy. Analysis of Clock-/-;Npas2m/m double mutant intersternebral tissue RNA did not reveal significant changes in chondrocyte or calcification-related gene expression. Histological stains showed an absence of osteoblasts and osteoclasts around costosternal junction calcifications, suggesting that these cell types are not contributing to this pathology. Instead, chondrocytes are localized to the costosternal junction but there were no significant changes in the distribution of chondrocyte markers in this tissue, as evaluated by immunohistochemistry. These findings suggest that Clock or Npas2, and Bmal1, regulate ectopic calcification through a combination of systemic and local factors, and that the cells affected by Clock and Npas2, or Bmal1, disruption are a subset of the cells distributed in specific tissues that develop age-dependent arthropathy. The significance of these findings is that “circadian genes” play a role in the regulation of ectopic calcification in a non-oscillator capacity. Understanding this new mechanism by which ectopic calcification is controlled could lead to novel approaches for the treatment of some human calcification diseases. calcification circadian rhythms mouse model Physiologic Arthropathy Neurogenic Circadian Clocks CLOCK Proteins Cryptochromes ARNTL Transcription Factors Amino Acids, Peptides, and Proteins Biological Factors Genetic Phenomena Inorganic Chemicals Musculoskeletal Diseases Neuroscience and Neurobiology
38	Co– and Post–Translational N–Linked Glycosylation of Cardiac Potassium Channel Subunits: A Dissertation Bas, Tuba 03 June 2010 (has links) KCNE1 (E1) peptide is the founding member of the KCNE family (1-5), which is a class of type I transmembrane ß-subunits. KCNE1 peptides assemble with and modulate the gating, ion conducting properties and pharmacology of a variety of voltage-gated K+ channel a-subunits, including KCNQ1 (Q1). Mutations that interfere with the function of either E1 and/or Q1 and disrupt the assembly and trafficking of KCNE1- KCNQ1 channel complexes give rise to diseases such as Romano-Ward (RW) and Jervell Lange Nielsen Syndrome (JLNS), two different forms of Long QT Syndrome (LQTS). Using enzymatic deglycosylation assays, immunofluorescence techniques and quantitative cell surface labeling, we showed that KCNE1 peptides are retained in the early stages of the secretory pathway as immaturely N-linked glycosylated proteins. KCNE1 co-assembly with KCNQ1 leads to E1 progression through the secretory pathway and glycan maturation, resulting in cell surface expression. N-linked glycosylation of some membrane proteins is critical for proper folding, co-assembly and subsequent trafficking through the biosynthetic pathway. Previous studies have shown that genetic mutations that disrupt one of the two N-linked glycosylation sites on KCNE family members lead to LQTS (T7I, KCNE1 and T8A, KCNE2) (Schulze-Bahr et al., 1997; Sesti et al., 2000a; Park et al., 2003). Having confirmed that KCNE1 proteins acquire N-linked glycans, we examined the kinetics and efficiency of N-linked glycan addition to KCNE1. We showed that KCNE1 has two distinct N-linked glycosylation sites. The N-terminal sequon is a traditional co-translational site. The internal sequon (which is only ~ 20 residues away from the N-terminal sequon) acquires N-linked glycans primarily after protein synthesis (post-translationally). Surprisingly, mutations that prevent N-glycosylation at the cotranslational site also reduce the glycosylation efficiency of post-translational glycosylation at the internal sequon, resulting in a large population of unglycosylated KCNE1 peptides that are retained in the early stages of the secretory pathway and do not reach the cell surface with their cognate K+ channel. We showed that KCNE1 post-translational N-glycosylation in the endoplasmic reticulum is a cellular mechanism that ensures E1 proteins acquire the maximal number of glycans needed for proper channel assembly and trafficking. Our findings provide a new biogenic mechanism for human disease by showing that the JLNS mutation, T7I, not only inhibits glycosylation of the N-terminal sequon, but also indirectly prevents the glycosylation of the internal sequon, giving rise to a large population of assembly incompetent hypoglycosylated KCNE1 peptides. To further investigate the two N-linked glycosylation sites on KCNE1, we generated structure-function deletion scans of KCNE1 and performed positional glycosylation scanning mutagenesis. We examined the glycosylation pattern of glycosylation mutants in an effort to define the glycosylation window important for proper KCNE1 assembly and trafficking. Our findings suggested a nine amino acid periodicity to serve as a desirable glycosylation site and a better substrate for N-glycosylation. Appendix II shows work on the characterization of the C-terminally HA-tagged KCNE1 protein, which was used throughout the experiments presented in Chapter II, Chapter III and Chapter IV. Analysis of the C-terminally HA-tagged KCNE1 protein revealed that in heterologous expression systems KCNE1 had an internal translational start site, a methionine at position 27. A proteolytic cleavage site was also identified at the arginine cluster spanning residues 32 through 38 bearing the two known Long QT mutations (R32H and R36H) (Splawski et al., 2000; Napolitano et al., 2005). My work in Professor Craig C. Mello’s lab during the first four years of my graduate study is presented in Appendix I. The highly conserved Wnt/Wingless glycoproteins regulate many aspects of animal development. Wnt signaling specifies endoderm fate by controlling the fate of EMS blastomere daughters in 4-cell stage Caenorhabditis elegans embryos. A suppressor genetic screen was performed using two temperature sensitive alleles of mom-2/Wnt to identify additional regulators of the Wnt/Wingless signaling pathway during C. elegans endoderm specification. Five intragenic suppressors and three extragenic suppressors of mom-2/Wnt embryonic lethality were identified. We cloned ifg-1, eIF4G homologue, as one of the extragenic suppressors suggesting an intriguing connection between the Wnt signaling pathway and the translational machinery. Potassium Channels Potassium Channels Voltage-Gated Glycosylation N-Glycosyl Hydrolases Amino Acids, Peptides, and Proteins Cardiovascular Diseases Enzymes and Coenzymes Genetic Phenomena Inorganic Chemicals
39	Surface of <em>Yersinia pestis</em>: LCRV, F1 Production, Invasion and Oxygen: A Dissertation Pouliot, Kimberly Lea 20 December 2007 (has links) Of the eleven species of bacteria that comprise the genus Yersinia of the family Enterobacteriaceae, three species are pathogenic for humans. Yersinia pseudotuberculosis and Yersinia enterocolitica usually cause a mild, self-limiting mesenteric lymphadenitis or ileitis. Yersinia pestis causes a highly invasive often fatal disease known as plague. All three elaborate a type three secretion system that is essential for virulence and encoded on closely related plasmids. In Y. pestis, all the effectors, structural components and chaperones are encoded on the 70kb plasmid, pCD1. Of these, LcrV from Y. enterocolitica has been implicated in playing an immunosuppressive role through its interaction with host Toll-like receptor 2 (TLR2) and induction of IL-10. Through expression and purification of recombinant LcrV from Escherichia coliwe show that only high molecular weight species of rLcrV are able to stimulate TLR2. In a highly sensitive subcutaneous mouse infection model we demonstrate no difference in the time to death between TLR2-sufficient or deficient mice. Analysis of cytokine levels between these two genotypes also shows no significant difference between splenic IL-10 and IL-6 or levels of bacteria. We conclusively show that this interaction, if it does occur, plays no significant role in vivo. In a separate set of experiments, we also determined that the expression of F1, a peptide shown to be responsible for 37°C-dependent inhibition of invasion by Y. pestis in vitro, was significantly decreased under high oxygen conditions. This led us to re-examine the invasion phenotype both in vitro and in vivo. These results give new insights into virulence gene expression in Y. pestis by environmental cues other than temperature. Yersinia pestis Plague Antigens Bacterial Pore Forming Cytotoxic Proteins Toll-Like Receptor 2 Signal Transduction Virulence Factors Oxygen Amino Acids, Peptides, and Proteins Bacteria Bacterial Infections and Mycoses Biological Factors Inorganic Chemicals
40	Arsenic Contamination in Groundwater in Vietnam: An Overview and Analysis of the Historical, Cultural, Economic, and Political Parameters in the Success of Various Mitigation Options Ly, Thuy M 01 May 2012 (has links) Although arsenic is naturally present in the environment, 99% of human exposure to arsenic is through ingestion. Throughout history, arsenic is known as “the king of poisons”; it is mutagenic, carcinogenic, and teratogenic. Even in smaller concentrations, it accumulates in the body and takes decades before any physical symptoms of arsenic poisoning shows. According to the World Health Organization (WHO), the safe concentration of arsenic in drinking water is 10 µg/L. However, this limit is often times ignored until it is decades too late and people begin showing symptoms of having been poisoned. This is the current situation for Vietnam, whose legal arsenic concentration limit is 50 µg/L, five times higher than the WHO guidelines. Groundwater in Vietnam was already naturally high in arsenic due to arsenic-rich soils releasing arsenic into groundwater. Then, in the past half century, with the use of arsenic-laden herbicides dispersed during the Vietnam War and subsequent industrial developments, the levels of bio-available arsenicals has dangerously spiked. With the proliferation of government-subsidized shallow tube-wells in the past two decades, shallow groundwater has become the primary source for drinking and irrigation water in Vietnam. This is a frightening trend, because this groundwater has arsenic concentrations up to 3050 µg/L, primarily in the +3 and +5 oxidation states, the most readily available oxidation states for bioaccumulation. This thesis argues that measures must be taken immediately to remedy the high concentration of arsenic in groundwater, which in Vietnam is the primary and, in some cases, the sole source of water for domestic consumption and agricultural production. Although there are numerous technologies available for treating arsenic in groundwater, not all of them are suited for Vietnam. By analyzing the historical, cultural, economic, and political parameters of Vietnam, several optimal treatments of groundwater for drinking water emerged as most recommended, a classification that is based on their local suitability, social acceptability, financial feasibility, and governmental support. Further research on irrigation water treatment is proposed due to the need for sustainable crop production, the safe ingestion of rice and vegetables, and the continued growth of Vietnam’s economy, which is heavily dependent on agriculture. Arsenic Vietnam Vietnam War Treatment Agricultural and Resource Economics Environmental Chemistry Environmental Health Environmental Health and Protection Environmental Monitoring Environmental Public Health Health Economics Inorganic Chemicals International Public Health Natural Resources Management and Policy Physical and Environmental Geography Science and Technology Studies Sustainability Toxicology Water Resource Management

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