The 3'-end of turnip yellow mosaic virus RNA : application of novel sequencing techniques.

Silberklang, Melvin.

January 1977

Thesis: Ph. D., Massachusetts Institute of Technology, Department of Biology, 1977 / Vita. / Includes bibliographical references. / Ph. D. / Ph. D. Massachusetts Institute of Technology, Department of Biology

Biology

RNA Synthesis.

Turnip mosaic virus.

Genetic transcription.

Genetic transcription. fast

Turnip mosaic virus. fast

RNA fast

An Investigation Into the Fate of a C5'-Uridinyl Radical

Ellis, Matthew

January 2017

No description available.

Chemistry

Organic Chemistry

Pharmacy Sciences

Novel Methods for Synthesis of High Quality Oligonucleotides

Semenyuk, Andrey

January 2006

<p>The first part of the work describes a procedure of oligonucleotide purification using a reversed-phase cartridge. The developed method employs a very efficient yet mild oligonucleotide detritylation on the cartridge support allowing fast purification of oligonucleotides regardless of their 5´-modification. Thiol- and amino-modified oligonuc-leotides were detritylated and purified with the same high efficiency as non-modified oligonucleotides. The method enables fast, parallel and automated purification of many oligonucleotide probes that was not possible before. In combination with the method of removal of tritylated failure fragments oligonucleotides were produced with purity superior to that of oligonucleotides purified using RP HPLC.</p><p>In the second part of the present study a method of solid-phase RNA synthesis using 2´-tert-butyldithiomethyl (2´-O-DTM) is discussed. The stability of the DTM group during oligonucleotide assembly and deprotection in ammonia, together with its ability for rapid deprotection under mild conditions, allowed the synthesis of RNA with the quality similar to that of synthetic DNA oligonucleotides. The advantage of the 2´-O-DTM group is that it is completely orthogonal to all protecting groups used for the traditional solid-phase DNA synthesis. Therefore, the synthesis can be performed using a standard DNA synthesis procedure – no changes are needed for the product assembly. RNA oligonucleotides synthesized with retained 5´-terminal trityl group can be subjected to a cartridge-based purification using the procedure described in the first part of the study. The phosphoramidite synthesis was optimized for a large scale preparation and gives versatility for introduction of other alkyldithiomethyl groups according to the preference to their certain properties.</p><p>The third part of the thesis describes the synthesis of a dithiomethyl linker and its utility for reversible conjugation of oligonucleotides. A dithiomethyl group, cleavable under mild conditions, was introduced onto 3´-OH of tritylated nucleosides via 3´-O-methylthiomethyl derivatives. The influence of different alkyl substituents on the disulfide bond stability was investigated, and stable analogues were employed in oligosyntheses. Two applications were developed using the present linker: 1) purification of oligonucleotides linked to the solid support; and 2) cartridge-based purification of tritylated oligonucleotides having an additional hydrophobic group on their 3´- terminus.</p>

Organic chemistry

oligonucleotide

solid-phase synthesis

RNA synthesis

phosphoramidite

abasic sites

depurination

2'-O-DTM

protecting group

cartridge

conjugate

dithiomethyl linker

base-stable linker

oligonucleotide purification

nucleoside

Organisk kemi

Novel Methods for Synthesis of High Quality Oligonucleotides

Semenyuk, Andrey

January 2006

The first part of the work describes a procedure of oligonucleotide purification using a reversed-phase cartridge. The developed method employs a very efficient yet mild oligonucleotide detritylation on the cartridge support allowing fast purification of oligonucleotides regardless of their 5´-modification. Thiol- and amino-modified oligonuc-leotides were detritylated and purified with the same high efficiency as non-modified oligonucleotides. The method enables fast, parallel and automated purification of many oligonucleotide probes that was not possible before. In combination with the method of removal of tritylated failure fragments oligonucleotides were produced with purity superior to that of oligonucleotides purified using RP HPLC. In the second part of the present study a method of solid-phase RNA synthesis using 2´-tert-butyldithiomethyl (2´-O-DTM) is discussed. The stability of the DTM group during oligonucleotide assembly and deprotection in ammonia, together with its ability for rapid deprotection under mild conditions, allowed the synthesis of RNA with the quality similar to that of synthetic DNA oligonucleotides. The advantage of the 2´-O-DTM group is that it is completely orthogonal to all protecting groups used for the traditional solid-phase DNA synthesis. Therefore, the synthesis can be performed using a standard DNA synthesis procedure – no changes are needed for the product assembly. RNA oligonucleotides synthesized with retained 5´-terminal trityl group can be subjected to a cartridge-based purification using the procedure described in the first part of the study. The phosphoramidite synthesis was optimized for a large scale preparation and gives versatility for introduction of other alkyldithiomethyl groups according to the preference to their certain properties. The third part of the thesis describes the synthesis of a dithiomethyl linker and its utility for reversible conjugation of oligonucleotides. A dithiomethyl group, cleavable under mild conditions, was introduced onto 3´-OH of tritylated nucleosides via 3´-O-methylthiomethyl derivatives. The influence of different alkyl substituents on the disulfide bond stability was investigated, and stable analogues were employed in oligosyntheses. Two applications were developed using the present linker: 1) purification of oligonucleotides linked to the solid support; and 2) cartridge-based purification of tritylated oligonucleotides having an additional hydrophobic group on their 3´- terminus.

Organic chemistry

oligonucleotide

solid-phase synthesis

RNA synthesis

phosphoramidite

abasic sites

depurination

2'-O-DTM

protecting group

cartridge

conjugate

dithiomethyl linker

base-stable linker

oligonucleotide purification

nucleoside

Organisk kemi

Identification of the Minimal Domain of RNA Trihosphastase Activity in the L Protien of Rinderpest Virus and Charecterization of its Enzymatic Activities

Singh, Piyush Kumar

January 2013

Morbilliviruses belong to the family Paramyxoviridae of the Mononegavirale order of viruses. The Mononegavirale order contains viruses which contain negatively-polar, non-segmented and single stranded RNA genomes. This order contains some of most lethal pathogens known to the humankind. Ebola virus and Marburg virus are perhaps the most lethal human pathogens. Rinderpest virus, declared eradicated in 2011, was known to be the most significant cattle killer. Similarly the Canine distemper virus and Rabies virus, two topmost canine pathogens belong to this order. The L protein in the viruses of Morbillivirus genus harbours the viral RNA-dependent RNA polymerase that replicates and transcribes the viral genome and also all the mRNA capping enzymes, viz. RNA 5’ triphosphatase, guanylyltransferase, RNA (guanine-7-)methyltransferase and RNA 5’ cap-dependent (2’-oxo-)methyltransferase. Moreover this protein can act as a protein kinase that can regulate the function of P protein which serves as a switch between transcription and replication. mRNA capping is necessary for the virus for the purpose of exploiting host cellular machinery towards viral protein synthesis. The Rinderpest virus L protein serves as a model to study the capping enzymes of Morbillivirus. RNA triphosphatase (RTPase), the first enzyme of the capping cascade had earlier been located on the L protein. The RTPase minimal domain on the L protein was identified earlier by sequence homology studies done with RTPase proteins of Baculovirus and Vaccinia virus and cloned. The bacterially expressed recombinant domain was shown to possess RTPase activity. The enzymatic activity was characterized and the RTPase was found to be a metal-dependent enzyme which is highly specific to capping viral mRNA. Further characterization of the domain revealed that the domain also possesses nucleotide triphosphatase (NTPase), tripolyphosphatase and pyrophosphatase activities. Two site-directed mutants in motif-A of the domain: E1645A and E1647A were also tested and were found to be essential for the RTPase and NTPase activity. It was also recognized through these mutant studies that the active sites of RTPase and NTPase activities are partially overlapping. Earlier work done with Vesicular stomatitis virus capping enzymes showed that the Rhabdoviridae family of viruses follow unconventional capping pathway utilizing an enzyme polyribonucleotidyltransferase (PRNTase) which transfers GDP to 5’-monophosphated RNA. Characterization of the RTPase activity which converts 5’-triphosphated RNA into 5’-diphosphated RNA is an evidence for the morbilliviruses utilizing the conventional eukaryotic capping cascade. The results show that Paramyxoviridae do not follow unconventional capping pathway for the mRNA capping as has been the paradigm in the past decade.

Rinderpest Virus (RPV)

Viral Replication

Viral Transcription

Viral Structure

Viral RNA Synthesis

Morbilliviruses

Rinderpest Virus L Protein

Viral Proteins - Synthesis

Viruses - Reproduction

Viral Proteins

Viruses - RNA Capping

Viral Genome Organization

Viral RNA

L Protein

Virology