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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
1

Functional analysis of Ribonuclease III regulation by a viral protein kinase

Gone, Swapna January 2011 (has links)
The bacteriophage T7 protein kinase enhances T7 growth under suboptimal growth conditions, including elevated temperature or limiting carbon source. T7PK phosphorylates numerous E. coli proteins, and it has been proposed that phosphorylation of these proteins is responsible for supporting T7 replication under stressful growth conditions. How the phosphorylation of host proteins supports T7 growth is not understood. Escherichia coli (Ec) RNase III is phosphorylated on serine in bacteriophage T7-infected cells. Phosphorylation of Ec-RNase III induces a ~4-fold increase in catalytic activity in vitro. Ec-RNase III is involved in the maturation of several T7 mRNAs, and it has been shown that RNase III processing controls the translational activity and stability of the T7 mRNAs. Perhaps T7PK phosphorylation of Ec- RNase III ensures optimal processing of T7 mRNAs under suboptimal growth conditions. In this study a biochemical analysis was performed on the N-terminal portion of the 0.7 gene (T7PK), exhibiting only the protein kinase activity. In addition to phosphotransferase activity, T7PK also undergoes self-phosphorylation on serine, which down-regulates catalytic activity by an unknown mechanism. Mass spectral analysis revealed that Ser216 is the autophosphorylation site in T7PK. The serine residue is highly conserved, which in turn suggests that autophosphorylation is a conserved reaction with functional importance. Phosphorylated T7PK exhibits reduced phosphotransferase activity, compared to its dephosphorylated counterpart (dT7PK). The dT7PK exhibits enhanced ability to phosphorylate proteins, as well as undergo autophosphorylation. The mechanism by which autophosphorylation inhibits T7PK activity is unknown. An in vitro phosphorylation assay revealed that T7PK directly phosphorylates RNase III. Ec-RNase III processing activity is stimulated from two to ten-fold upon phosphorylation by the T7PK. The primary site of phosphorylation in RNase III is found to be Ser33, and Ser34 may act as the recognition determinant for T7PK. This was established by Ser →Ala mutations at the concerned site. The enhancement of catalytic activity is primarily due to a larger turnover number (kcat), with some additional contribution from a greater substrate binding affinity, as revealed by lower Km and K‟D values. Substrate cleavage assays under single turn over conditions established that the product release is the rate limiting step. Since there is no significant increase in the kcat as measured under single-turnover (enzyme excess) conditions, the increase in the kcat in the steady-state is due to enhancement of the product release step, and not due to an enhancement of the hydrolysis (chemical) step. / Chemistry
2

Biochemical Analysis of Thermotoga maritima Ribonuclease III and its Ribosomal RNA Substrates

Nathania, Lilian January 2011 (has links)
The site-specific cleavage of double-stranded (ds) RNA is a conserved early step in bacterial ribosomal RNA (rRNA) maturation that is carried out by ribonuclease III. Studies on the RNase III mechanism of dsRNA cleavage have focused mainly on the enzymes from mesophiles such as Escherichia coli. In contrast, little is known of the RNA processing pathways and the functions of associated ribonucleases in the hyperthermophiles. Therefore, structural and biochemical studies of proteins from hyperthermophilic bacteria are providing essential insight on the sources of biomolecular thermostability, and how enzymes function at high temperatures. The biochemical behavior of RNase III of the hyperthermophilic bacterium Thermotoga maritima is analyzed using purified recombinant enzyme and the cognate pre-ribosomal RNAs as substrates. The T. maritima genome encodes a ~5,000 nucleotide (nt) transcript, expressed from the single ribosomal RNA (rRNA) operon. RNase III processing sites are expected to form through base-pairing of complementary sequences that flank the 16S and 23S rRNAs. The Thermotoga pre-16S and pre-23S processing stems are synthesized in the form of small hairpins, and are efficiently and site-specifically cleaved by Tm-RNase III at sites consistent with an in vivo role of the enzyme in producing the immediate precursors to the mature rRNAs. T. maritima (Tm)-RNase III activity is dependent upon divalent metal ion, with Mg^2+ as the preferred species, at concentrations >= 1 mM. Mn^2+, Co^2+ and Ni^2+ also support activity, but with reduced efficiency. The enzyme activity is also supported by salt (Na^+, K^+, or NH4^+) in the 50-80 mM range, with an optimal pH of ~8. Catalytic activity exhibits a broad temperature maximum of ~40-70 deg C, with significant activity retained at 95 deg C. Comparison of the Charged-versus-Polar (C-vP) bias of the protein side chains indicates that Tm-RNase III thermostability is due to large C-vP bias. Analysis of pre-23S substrate variants reveals a dependence of reactivity on the base-pair (bp) sequence in the proximal box (pb), a site of protein contact that functions as a positive determinant of recognition of E. coli (Ec)-RNase III substrates. The pb sequence dependence of reactivity is similar to that observed with the Ec-RNase III pb. Moreover, Tm-RNase III cleaves an Ec-RNase III substrate with identical specificity, and is inhibited by pb antideterminants that also inhibit Ec-Rnase III. These studies reveal the conservation acrosss a broad phylogenetic distance of substrate reactivity epitopes, both the positive and negative determinants, among bacterial RNase III substrates. / Chemistry
3

Biochemical properties and substrate reactivities of Aquifex Aeolicus Ribonuclease III

Shi, Zhongjie January 2012 (has links)
Ribonuclease III is a highly-conserved bacterial enzyme that cleaves double-stranded (ds) RNA structures, and participates in diverse RNA maturation and decay pathways. Essential insight on the RNase III mechanism of dsRNA cleavage has been provided by crystallographic studies of the enzyme from the hyperthermophilic bacterium, Aquifex aeolicus. However, those crystals involved complexes containing either cleaved RNA, or a mutant RNase III that is catalytically inactive. In addition, neither the biochemical properties of A. aeolicus (Aa)-RNase III, nor the reactivity epitopes of its cognate substrates are known. The goal of this project is to use Aa-RNase III, for which there is atomic-level structural information, to determine how RNase III recognizes its substrates and selects the target site. I first purified recombinant Aa-RNase III and defined the conditions that support its optimal in vitro catalytic activity. The catalytic activity of purified recombinant Aa-RNase III exhibits a temperature optimum of 70-85°C, a pH optimum of 8.0, and with either Mg2+ or Mn2+ supports efficient catalysis. Cognate substrates for Aa-RNase III were identified and their reactivity epitopes were characterized, including the specific bp sequence elements that determine processing reactivity and selectivity. Small RNA hairpins, based on the double-stranded structures associated with the Aquifex 16S and 23S rRNA precursors, are cleaved in vitro at sites that are consistent with production of the immediate precursors to the mature rRNAs. Third, the role of the dsRBD in scissile bond selection was examined by a mutational analysis of the conserved interactions of RNA binding motif 1 (RBM1) with the substrate proximal box (pb). The individual contributions towards substrate recognition were determined for conserved amino acid side chains in the RBM1. It also was shown that the dsRBD plays key dual roles in both binding energy and selectivity, through RBM1 responsiveness to proximal box bp sequence. The dsRBD is specifically responsive to an antideterminant (AD) bp in pb position 2. The relative structural rigidity of both dsRNA and dsRBD rationalizes the strong effect of an inhibitory bp at pb position 2: disruption of one RBM1 side chain interaction can effectively disrupt the other RBM1 side chain interactions. Finally, a cis-acting model was developed for subunit involvement in substrate recognition by RNase III. Structurally asymmetric mutant heterodimers of Escherichia coli (Ec)-RNase III were constructed, and asymmetric substrates were employed to reveal how RNase III can bind and deliver hairpin substrates to the active site cleft in a pathway that requires specific binding configurations of both enzyme and substrate. / Chemistry
4

Small RNA Regulation of the Innate Immune Response: A Role for Dicer in the Control of Viral Production and Sensing of Nucleic Acids: A Dissertation

Nistler, Ryan J. 09 December 2015 (has links)
All organisms exist in some sort of symbiosis with their environment. The food we eat, air we breathe, and things we touch all have their own microbiota and we interact with these microbiota on a daily basis. As such, we employ a method of compartmentalization in order to keep foreign entities outside of the protected internal environments of the body. However, as other organisms seek to replicate themselves, they may invade our sterile compartments in order to do so. To protect ourselves from unfettered replication of pathogens or from cellular damage, we have developed a series of receptors and signaling pathways that detect foreign bodies as well as abnormal signals from our own perturbed cells. The downstream effector molecules that these signaling pathways initiate can be toxic and damaging to both pathogen and host, so special care is given to the regulation of these systems. One method of regulation is the production of endogenous small ribonucleic acids that can regulate the expression of various receptors and adaptors in the immune signaling pathways. In this dissertation, I present work that establishes an important protein in small ribonucleic acid regulation, Dicer, as an essential protein for regulating the innate immune response to immuno-stimulatory nucleic acids as well as regulating the productive infection of encephalomyocarditis virus. Depleting Dicer from murine embryonic fibroblasts renders a disparate type I interferon response where nucleic acid stimulation in the Dicer null cells fails to produce an appreciable interferon response while infection with the paramyxovirus, Sendai, induces a more robust interferon response than the wild-type control. Additionally, I show that Dicer plays a vital role in controlling infection by the picornavirus, encephalomyocarditis virus. Encephalomyocarditis virus fails to grow efficiently in Dicer null cells due to the inability for the virus to bind to the outside of the cell, suggesting that Dicer has a role in modulating viral infection by affecting host cellular protein levels. Together, this work identifies Dicer as a key protein in viral innate immunology by regulating both the growth of virus and also the immune response generated by exposure to pathogen associated molecular patterns. Understanding this regulation will be vital for future development of small molecule therapeutics that can either modulate the innate immune response or directly affect viral growth.
5

Understanding Small RNA Formation in Drosophila Melanogaster: A Dissertation

Cenik, Elif Sarinay 09 July 2012 (has links)
Drosophila Dicer-2 generates small interfering RNAs (siRNAs) from long double-stranded RNA (dsRNA), whereas Dicer-1 produces microRNAs from premicroRNA. My thesis focuses on the functional characteristics of two Drosophila Dicers that makes them specific for their biological substrates. We found that RNA binding protein partners of Dicers and two small molecules, ATP and phosphate are key in regulating Drosophila Dicers’ specificity. Without any additional factor, recombinant Dicer-2 cleaves pre-miRNA, but its product is shorter than the authentic miRNA. However, the protein R2D2 and inorganic phosphate block pre-miRNA processing by Dicer-2. In contrast, Dicer-1 is inherently capable of processing the substrates of Dicer, long dsRNAs. Yet, partner protein of Dicer-1, Loqs-PB and ATP increase the efficiency of miRNA production from pre-miRNAs by Dicer-1, therefore enhance substrate specificity of Dicer-1. Our data highlight the role of ATP and regulatory dsRNA-binding partner proteins to achieve substrate specificity in Drosophila RNA silencing. Our study also sheds light onto the function of the helicase domain in Drosophila Dicers. Although Dicer-1 doesn’t hydrolyze ATP, ATP enhances miRNA production by increasing Dicer-1’s substrate specificity through lowering its KM. On the other hand, Dicer-2 is a dsRNA-stimulated ATPase that hydrolyzes ATP to ADP, and ATP hydrolysis is required for Dicer-2 to process long dsRNA. Wild-type Dicer-2, but not a mutant defective in ATP hydrolysis, is processive; generating siRNAs faster than it can dissociate from a long dsRNA substrate. We propose that the Dicer-2 helicase domain uses ATP to generate many siRNAs from a single molecule of dsRNA before dissociating from its substrate. Piwi-dependent small RNAs, namely piRNAs, are a third class of small RNAs that are distinct from miRNAs and siRNAs. Their primary function is to repress transposons in the animal germline. piRNAs are Dicer-independent, and require Piwi family proteins for their biogenesis and function. Recently in addition to their presence in animal germlines, the presence and function of piRNA-like RNAs in the somatic tissues have been suggested (Yan et al. 2011; Morazzani et al. 2012; Rajasethupathy et al. 2012). We have investigated whether the piRNA-like reads in our many Drosophila head libraries come from the germline as a contaminant or are soma-specific. Most of the piRNA reads in our published head libraries show high similarity to germline piRNAs. However, piRNA-like reads from manually dissected heads are distinct from germline piRNAs, proving the presence of somatic piRNA-like small RNAs. We are currently asking the question whether these distinct piRNA-like reads in the heads are dependent on the Piwi family proteins, like the germline piRNAs.
6

Using Experimental and Computational Strategies to Understand the Biogenesis of microRNAs and piRNAs: A Dissertation

Han, Bo W. 24 July 2015 (has links)
Small RNAs are single-stranded, 18–36 nucleotide RNAs that can be categorized as miRNA, siRNA, and piRNA. miRNA are expressed ubiquitously in tissues and at particular developmental stages. They fine-tune gene expression by regulating the stability and translation of mRNAs. piRNAs are mainly expressed in the animal gonads and their major function is repressing transposable elements to ensure the faithful transfer of genetic information from generation to generation. My thesis research focused on the biogenesis of miRNAs and piRNAs using both experimental and computational strategies. The biogenesis of miRNAs involves sequential processing of their precursors by the RNase III enzymes Drosha and Dicer to generate miRNA/miRNA* duplexes, which are subsequently loaded into Argonaute proteins to form the RNA-induced silencing complex (RISC). We discovered that, after assembled into Ago1, more than a quarter of Drosophila miRNAs undergo 3′ end trimming by the 3′-to-5′ exoribonuclease Nibbler. Such trimming occurs after removal of the miRNA* strand from pre-RISC and may be the final step in RISC assembly, ultimately enhancing target messenger RNA repression. Moreover, by developing a specialized Burrow-Wheeler Transform based short reads aligner, we discovered that in the absence of Nibbler a subgroup of miRNAs undergoes increased tailing—non-templated nucleotide addition to their 3′ ends, which are usually associated with miRNA degradation. Therefore, the 3′ trimming by Nibbler might increase miRNA stability by protecting them from degradation. In Drosophila germ line, piRNAs associate with three PIWI-clade Argonaute proteins, Piwi, Aub, and Ago3. piRNAs bound by Aub and Ago3 are generated by reciprocal cleavages of sense and antisense transposon transcripts (a.k.a., the “Ping-Pong” cycle), which amplifies piRNA abundance and degrades transposon transcripts in the cytoplasm. On the other hand, Piwi and its associated piRNA repress the transcription of transposons in the nucleus. We discovered that Aub- and Ago3-mediated transposon RNA cleavage not only generates piRNAs bound to each other, but also produces substrates for the endonuclease Zucchini, which processively cleaves those substrates in a periodicity of ~26 nt and generates piRNAs that predominantly load into Piwi. Without Aub or Ago3, the abundance of Piwi-bound piRNAs drops and transcriptional silencing is compromised. Our discovery revises the current model of piRNA biogenesis.

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