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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

The Approach to Characterizing Three <i>S</i>-Adenosyl-L-Methionine-Dependent Methyltransferases from <i>Mycobacterium tuberculosis</i>

Loarer, Gwendal January 2018 (has links)
No description available.
2

Genetic analysis of methyltransferases involved in choline synthesis of Arabidopsis thaliana

Zulipihaer, Dilixiati 10 1900 (has links)
<p>In plants, S-adenosyl-L-methionine-dependent phospho-base <em>N</em>-methyl transferases catalyze the three sequential methylations of phosphoethanolamine to phosphocholine, the precursor for choline and the major membrane phospholipid phosphatidylcholine. The enzyme phosphoethanolamine <em>N</em>-methyltransferase (PEAMT) catalyzes the first and committing step in choline synthesis, a step for which no known by-pass has been found. In <em>Arabidopsis thaliana</em> there are two loci annotated as encoding PEAMT and a putative PEAMT, At3g18000 (<em>NMT1</em>) and<em> </em>At1g73600 (<em>NMT3</em>), respectively. A related gene product that catalyzes the last two methylations is encoded by locus At1g48600 (<em>NMT2</em>). The objective of this study was to investigate the role of <em>NMT3 </em>in <em>Arabidopsis</em>. Three SALK lines carrying independent T-DNA insertions in At1g73600 were used: SALK_062703, SALK_016929c and SALK_120703c.</p> <p>Genomic DNA was used for PCR and sequence analysis of the products established the insertion of T-DNA in the protein coding region of At1g73600 for all three lines. Gene expression was analyzed by q-PCR. Primer design was particularly important for <em>NMT3 </em>transcript quantification by q-PCR. In SALK_062703 <em>nmt3 </em>mutants, the T-DNA is in exon 8 and in the SALK_120703c line it is in intron 6. In both cases, no <em>NMT3 </em>transcripts were detected using primers that annealed to sites 3’ to the position of the T-DNA in the gene. However, low levels of transcripts were detected using primers that annealed at positions 5’ to the site of T-DNA insertion. In the SALK_016929c line the position of the T-DNA insertion was in exon 2 and primers annealing near the site of the T-DNA insertion showed no <em>NMT3 </em>expression in this mutant but amplifying the mid portion of the gene showed WT levels of <em>NMT3 </em>transcripts. Thus all the mutants produce truncated <em>NMT3 </em>transcripts and by avoiding areas that overlap truncated transcript regions we could differentiate between <em>NMT3</em> knock-out or knock-down expression.</p> <p>Wild-type (<em>NMT3</em>) and <em>nmt3 </em>seedlings from the three lines grown on defined media plates showed no difference with respect to primary root length, number or density of lateral roots, and total root length. Exposing seedlings to salt (50 or 75 mM NaCl) led to reductions in root growth but again, roots of wild-type plants were indistinguishable from the mutant seedlings. One anomaly relates to the <em>nmt3</em> SALK_120703c<em> </em>line which showed two root phenotypes. On saline media most of the seedlings had longer roots that resembled the wild-type and other mutant lines and about a third had shortened roots. Whether the seedlings had long or short roots on salt, they all lacked <em>NMT3 </em>transcripts. This line is likely carrying another insertion that yields a salt-sensitive root phenotype. Mutant plants at four-weeks looked like wild-type plants and time of flowering was not reproducibly delayed or accelerated in mutant plants relative to wild-type.</p> <p>In wild-type seedlings the relative expression level of the three <em>NMT </em>genes is similar at day or night with transcript abundance ranked in the order <em>NMT3</em> > <em>NMT2 </em>> <em>NMT1. nmt3 </em>seedlings harvested midday showed no detectable <em>NMT3</em> expression but the abundance of <em>NMT1 </em>transcripts was 6.2-fold and 1.7-fold higher relative to wild-type in shoots and roots, respectively. At night, <em>NMT1 </em>expression in shoots of<em> nmt3 </em>seedlings decreased 4.8-fold relative to the level of <em>NMT1 </em>expression at midday while transcripts detected in roots increased slightly (1.3-fold). Using SALK_036291 <em>nmt1 </em>seedlings we found that <em>NMT3 </em>expression in shoots and roots was modestly up-regulated in the absence of <em>NMT1 </em>expression and the expression of <em>NMT3 </em>is lower at night than during the day. Also, regardless of the genotype or time of day, <em>NMT2 </em>expression remained constant even when <em>NMT1 </em>and <em>NMT3 </em>transcripts underwent several-fold changes in abundance. Interestingly, four-week old <em>nmt3 </em>plants of the SALK_062703 line showed that <em>NMT3 </em>expression is knocked-out in leaves but only knocked-down in roots.</p> <p><em> NMT3 </em>was the most highly expressed of the three <em>NMT </em>genes monitored by q-PCR. Nonetheless, three independent T-DNA insertion lines defective for <em>NMT3</em> expression were wild-type by appearance and as such, offer compelling evidence that NMT3 is not required by <em>Arabidopsis. </em>The increased expression of <em>NMT1 </em>in <em>nmt3 </em>plants and <em>NMT3</em> in <em>nmt1 </em>plants strongly suggests that plants compensate for the loss of one gene by up-regulating, to varying extents, the expression of the remaining <em>NMT </em>gene. If this is the case, a reasonable prediction made for a cross between <em>nmt1 </em>and <em>nmt3 </em>plants is that it would be lethal unless plants have yet another way to circumvent the loss of an essential enzyme for this committing metabolic bottleneck in choline synthesis.</p> / Master of Science (MSc)
3

IDENTIFICATION OF PUTATIVE-S-ADENOSYL-L-METHIONINE: PHOSPHOETHANOLAMINE-N-METHYLTRANSFERASE T-DNA MUTANTS IN ARABIDOPSIS

Gleason, Amber 07 1900 (has links)
<p> Some plants such as spinach, sugar beet, and wheat accumulate the quaternary ammonium compound glycine betaine when exposed to stresses in their environment. Environmental stress can be in the form of an excess or deficiency of water, high salt content, and/or exposure to excessively low or high temperatures and many if not all of these stresses are associated with cell dehydration. </p> <p> Glycine betaine is an organic solute that is believed to help restore the osmotic potential of a cell undergoing dehydration by reducing water loss and preventing damage to the structure and function of macromolecules. However, many plants such as Arabidopsis, tobacco, and rice do not accumulate glycine betaine. Given the perceived benefits of glycine betaine production by plants under stress, studies have been carried out to identify factors regulating its production. </p> <p> Glycine betaine is synthesized by the two-step oxidation of choline. The capacity to synthesize phosphocholine for choline production has been found to limit the production of glycine betaine in non-accumulating plants such as tobacco. As such, genetic engineering has been used to enhance the production of choline to up-regulate the synthesis of glycine betaine. This strategy has required knowledge of the enzyme(s) catalyzing the three N-methylation steps of the phosphocholine biosynthetic pathway. </p> <p> This study focused on a gene product identified as putative-phosphoethanolamine N-methyltransferase (putative PEAMT) based upon its similarity to a spinach Nmethyltransferase known to convert phosphoethanolamine to phosphocholine. This gene is located at the locus Atlg73600 on chromosome I of Arabidopsis and its predicted amino acid sequence has high similarity to two other genes encoding N-methylating enzymes located at At3 g 18000 (a biochemically confirmed PEAMT) and At 1 g48600 (annotated as a putative PEAMT). </p> <p> In this study, publicly available microarray data was examined to identify an expression profile of transcripts associated with the Atlg73600 gene in organs and tissues of Arabidopsis at various developmental stages. A summary of the micro array data shows the highest abundance of transcripts for Atlg73600 to be in the rosette leaves of Arabidopsis at 18.0- 20.9 days of growth. </p> <p> Arabidopsis plants grown from seeds from four SALK lines reported to have a TDNA insert in the Atlg73600 gene were screened for the presence of a T-DNA tag using a three primer PCR design strategy. Individual plants from two of the lines were found to have a T-DNA insert present. RT-PCR was then used to analyze the expression of transcripts associated with the Atlg73600 gene in these mutant lines. Transcripts were not detected among the amplified products from eDNA produced from the SALK line designated 062703 but they were found at reduced levels in eDNA of SALK line 016929c. </p> <p> In future studies the two T -DNA mutant lines identified in this study can be used to assign a biological role for the product of the Atlg73600 gene by examining the phenotype of these mutant plants relative to that of wild-type plants under normal and/or stressed conditions. The line found with no expression associated with the Atlg73600 gene will be useful in crosses with T -DNA knock-out mutants of genes at loci At3g18000 and Atlg48600. Systematic knock-outs for each of the genes in isolation and in combination will help discern whether there is functional redundancy in their biological roles or if their individual expression contributes uniquely towards the development of a plant or its stress response. Given the associated role for PEAMT in phosphatidylcholine metabolism, lipidomics could be used to determine if the composition of the plant membranes is altered relative to wild-type when the Atlg73600 gene is knocked-out. </p> / Thesis / Master of Science (MSc)
4

Regulation of the cardiac isoform of the ryanodine receptor by S-adenosyl-l-methionine

Gaboardi, Angela Kampfer 08 November 2011 (has links)
Activity of the Ryanodine Receptor (RyR2) (aka cardiac Ca2+ release channel) plays a pivotal role in contraction of the heart. S-adenosyl-l-methionine (SAM) is a biological methyl group donor that has close structural similarity to ATP, an important physiological regulator of RyR2. This work provides evidence that SAM can act as a RyR2 regulatory ligand in a manner independent from its recognized role as a biological methyl group donor. RyR2 activation appears to arise from the direct interaction of SAM, via its adenosyl moiety, with the RyR2 adenine nucleotide binding sites. Because uncertainty remains regarding the structural motifs involved in RyR2 modulation by ATP and its metabolites, this finding has important implications for clarifying the structural basis of ATP regulation of RyR2. During the course of this project, direct measurements of single RyR2 activity revealed that SAM has distinct effects on RyR2 conductance. From the cytosolic side of the channel, SAM produced a single clearly resolved subconductance state. The effects of SAM on channel conductance were dependent on SAM concentration and membrane holding potential. A second goal of this work was to distinguish between the two possible mechanisms by which SAM could reduce RyR2 conductance: i) SAM interfering directly with ion permeation via binding within the conduction pathway (pore block), or ii) SAM binding a regulatory (or allosteric) site thereby stabilizing or inducing a reduced conductance conformation of the channel. It was determined that SAM does not directly interact with the RyR2 conduction pathway. To account for these observations an allosteric model for the effect of SAM on RyR2 conductance is proposed. According to this model, SAM binding stabilizes an inherent RyR2 subconductance conformation. The voltage dependence of the SAM related subconductance state is accounted for by direct effects of voltage on channel conformation which indirectly alter the affinity of RyR2 for SAM. Patterns in the transitions between RyR2 conductance states in the presence of SAM may provide insight into the structure-activity relationship of RyR2 which can aid in the development of therapeutic strategies targeting this channel.
5

Development of Novel Methods and their Utilization in the Analysis of the Effect of the N-terminus of Human Protein Arginine Methyltransferase 1 Variant 1 on Enzymatic Activity, Protein-protein Interactions, and Substrate Specificity

Suh-Lailam, Brenda Bienka 01 May 2010 (has links)
Protein arginine methyltransferases (PRMTs) are enzymes that catalyze the methylation of protein arginine residues, resulting in the formation of monomethylarginine, and/or asymmetric or symmetric dimethylarginines. Although understanding of the PRMTs has grown rapidly over the last few years, several challenges still remain in the PRMT field. Here, we describe the development of two techniques that will be very useful in investigating PRMT regulation, small molecule inhibition, oligomerization, protein-protein interaction, and substrate specificity, which will ultimately lead to the advancement of the PRMT field. Studies have shown that having an N-terminal tag can influence enzyme activity and substrate specificity. The first protocol tackles this problem by developing a way to obtain active untagged recombinant PRMT proteins. The second protocol describes a fast and efficient method for quantitative measurement of AdoMet-dependent methyltranseferase activity with protein substrates. In addition to being very sensitive, this method decreases the processing time for the analysis of PRMT activity to a few minutes compared to weeks by traditional methods, and generates 3000-fold less radioactive waste. We then used these methods to investigate the effect of truncating the NT of human PRMT1 variant 1 (hPRMT1-V1) on enzyme activity, protein-protein interactions, and substrate specificity. Our studies show that the NT of hPRMT1-V1 influences enzymatic activity and protein-protein interactions. In particular, methylation of a variety of protein substrates was more efficient when the first 10 amino acids of hPRMT1v1 were removed, suggesting an autoinhibitory role for this small section of the N-terminus. Likewise, as portions of the NT were removed, the altered hPRMT1v1 constructs were able to interact with more proteins. Overall, my studies suggest the the sequence and length of the NT of hPRMT1v1 is capable of enforcing specific protein interactions.
6

DYNAMICS OF SUBSTRATE INTERACTIONS IN tRNA (m1G37) METHYLTRANSFERASE: IMPLICATIONS FOR DRUG DISCOVERY

Palesis, Maria Kiouppis 14 February 2012 (has links)
The bacterial enzyme t-RNA (m1G37) methyltransferase (TrmD) is an ideal anti-microbial drug target since it is found in all eubacteria, serves an essential role during protein synthesis, and shares very little sequence or structural homology with its eukaryotic counterpart, Trm5. TrmD, a homodimeric protein, methylates the G37 nucleotide of tRNA using S-adenosyl-L-methionine (SAM) as the methyl donor and thus enables proper codon-anticodon alignment during translation. The two deeply buried binding sites for SAM seen in X-ray crystallography suggest that significant conformational changes must occur for substrate binding and catalytic turnover. Results from molecular dynamics simulations implicate a flexible loop region and a halo-like loop which may be gating the entrance to the active site. Analysis of simulation trajectories indicates an alternating pattern of active site accessibility between the two SAM binding sites, suggesting a single site mechanism for enzyme activity. Isothermal titration calorimetry (ITC), demonstrates that binding of SAM to TrmD is an exothermic reaction resulting from sequential binding at two sites. A similar mode of binding at higher affinities was observed for the product, S-adenosyl-L-homocysteine (SAH) suggesting that product inhibition may be important in vivo. ITC reveals that tRNA binding is an endothermic reaction in which one tRNA molecule binds to one TrmD dimer. This further supports the hypothesis of a single site mechanism for enzyme function. However, mutational analysis using hybrid mutant proteins suggests that catalytic integrity must be maintained in both active sites for maximum enzymatic efficiency. Mutations impeding flexibility of the halo loop were particularly detrimental to enzyme activity. Noncompetitive inhibition of TrmD was observed in the presence of bis-ANS, an extrinsic fluorescent dye. In silico ligand docking of bis-ANS to TrmD suggests that dye interferes with mobility of the flexible linker above the active site. Because SAM is a ubiquitous cofactor in methyltransferase reactions, analogs of this ligand may not be suitable for drug development. It is therefore important to investigate allosteric modes of inhibition. These experiments have identified key, mobile structural elements in the TrmD enzyme important for activity, and provide a basis for further research in the development of allosteric inhibitors for this enzyme.
7

Investigations of the Natural Product Antibiotic Thiostrepton from Streptomyces azureus and Associated Mechanisms of Resistance

Myers, Cullen Lucan January 2013 (has links)
The persistence and propagation of bacterial antibiotic resistance presents significant challenges to the treatment of drug resistant bacteria with current antimicrobial chemotherapies, while a dearth in replacements for these drugs persists. The thiopeptide family of antibiotics may represent a potential source for new drugs and thiostrepton, the prototypical member of this antibiotic class, is the primary subject under study in this thesis. Using a facile semi-synthetic approach novel, regioselectively-modified thiostrepton derivatives with improved aqueous solubility were prepared. In vivo assessments found these derivatives to retain significant antibacterial ability which was determined by cell free assays to be due to the inhibition of protein synthesis. Moreover, structure-function studies for these derivatives highlighted structural elements of the thiostrepton molecule that are important for antibacterial activity. Organisms that produce thiostrepton become insensitive to the antibiotic by producing a resistance enzyme that transfers a methyl group from the co-factor S-adenosyl-L-methionine (AdoMet) to an adenosine residue at the thiostrepton binding site on 23S rRNA, thus preventing binding of the antibiotic. Extensive site-directed mutagenesis was performed on this enzyme to generate point mutations at key active site residues. Ensuing biochemical assays and co-factor binding studies on these variants identified amino acid residues in the active site that are essential to the formation of the AdoMet binding pocket and provided direct evidence for the involvement of an active site arginine in the catalytic mechanism of the enzyme. Certain bacteria that produce neither thiostrepton nor the resistance methyltransferase express the thiostrepton binding proteins TIP-AL and TIP-AS, that irreversibly bind to the antibiotic, thereby conferring resistance by sequestration. Here, it was found that the point mutation of the previously identified reactive amino acid in TIP-AS did not affect covalent binding to the antibiotic, which was immediately suggestive of a specific, high affinity non-covalent interaction. This was confirmed in binding studies using chemically synthesized thiostrepton derivatives. These studies further revealed structural features from thiostrepton important in this non-covalent interaction. Together, these results indicate that thiostrepton binding by TIP-AS begins with a specific non-covalent interaction, which is necessary to properly orient the thiostrepton molecule for covalent binding to the protein. Finally, the synthesis of a novel AdoMet analogue is reported. The methyl group of AdoMet was successfully replaced with a trifluoromethyl ketone moiety, however, the hydrated form (germinal diol) of this compound was found to predominate in solution. Nevertheless, the transfer of this trifluoroketone/ trifluoropropane diol group was demonstrated with the thiopurine methyltransferase.
8

Investigations into Streptomyces azureus Thiostrepton-resistance rRNA Methyltransferase and its Cognate Antibiotic

Hang, Pei Chun January 2008 (has links)
Thiostrepton (TS: TS; C72H85N19O18S5) is a thiazoline antibiotic that is effective against Gram-positive bacteria and the malarial parasite, Plasmodium falciparum. Tight binding of TS to the bacterial L11-23S ribosomal RNA (rRNA) complex of the large 50S ribosomal unit inhibits protein biosynthesis. The TS producing organism, Streptomyces azureus, biosynthesizes thiostrepton-resistance methyltransferase (TSR), an enzyme that uses S-adenosyl-L-methionine (AdoMet) as a methyl donor, to modify the TS target site. Methylation of A1067 (Escherichia coli ribosome numbering) by TSR circumvents TS binding. The S. azureus tsr gene was overexpressed in E. coli and the protein purified for biochemical characterization. Although the recombinant protein was produced in a soluble form, its tendency to aggregate made handling a challenge during the initial stages of establishing a purification protocol. Different purification conditions were screened to generate an isolation protocol that yields milligram quantities of protein with little aggregation and sufficient purity for crystallographic studies. Enzymological characterization of TSR was carried out using an assay to monitor AdoMet-dependent ([methyl-3H]-AdoMet) methylation of the rRNA substrate by liquid scintillation counting. During the optimization of assay, it was found that, although this method is frequently employed, it is very time and labour intensive. A scintillation proximity assay was investigated to evaluate whether it could be a method for collecting kinetic data, and was found that further optimization is required. Comparative sequence analysis of TSR has shown it to be a member of the novel Class IV SpoUT family of AdoMet-dependent MTases. Members of this class possess a non-canonical AdoMet binding site containing a deep trefoil knot. Selected SpoUT family proteins were used as templates to develop a TSR homology model for monomeric and dimeric forms. Validation of the homology models was performed with structural validation servers and the model was then used as the basis of ongoing mutagenesis experiments. The X-ray crystal structure of TSR bound with AdoMet (2.45 Å) was elucidated by our collaborators, Drs. Mark Dunstan and Graeme Conn (University of Manchester). This structure confirms TSR MTase’s membership in the SpoUT MTase family with a deep trefoil knot in the catalytic domain. The AdoMet bound in the crystal structure is in an extended conformation not previously observed in SpoUT MTases. RNA docking simulations revealed some features that may be relevant to binding and recognition of TSR to the L11 binding domain of the RNA substrate. Two structure-activity studies were conducted to investigate the TS-rRNA interaction and TS solubility. Computational analyses of TS conformations, molecular orbitals and dynamics provided insight into the possible modes of TS binding to rRNA. Single-site modification of TS was attempted, targeting the dehydroalanine and dehydrobutyrine residues of the antibiotic. These moieties were modified using the polar thiol, 2-mercaptoethanesulfonic acid (2-MESNA). Similar modifications had been previously used to improve solubility and bioavailability of antibiotics. The resulting analogue was structurally characterized (NMR and mass spectrometry) and showed antimicrobial activity against Bacillus subtilis and Staphylococcus aureus.
9

Investigations into Streptomyces azureus Thiostrepton-resistance rRNA Methyltransferase and its Cognate Antibiotic

Hang, Pei Chun January 2008 (has links)
Thiostrepton (TS: TS; C72H85N19O18S5) is a thiazoline antibiotic that is effective against Gram-positive bacteria and the malarial parasite, Plasmodium falciparum. Tight binding of TS to the bacterial L11-23S ribosomal RNA (rRNA) complex of the large 50S ribosomal unit inhibits protein biosynthesis. The TS producing organism, Streptomyces azureus, biosynthesizes thiostrepton-resistance methyltransferase (TSR), an enzyme that uses S-adenosyl-L-methionine (AdoMet) as a methyl donor, to modify the TS target site. Methylation of A1067 (Escherichia coli ribosome numbering) by TSR circumvents TS binding. The S. azureus tsr gene was overexpressed in E. coli and the protein purified for biochemical characterization. Although the recombinant protein was produced in a soluble form, its tendency to aggregate made handling a challenge during the initial stages of establishing a purification protocol. Different purification conditions were screened to generate an isolation protocol that yields milligram quantities of protein with little aggregation and sufficient purity for crystallographic studies. Enzymological characterization of TSR was carried out using an assay to monitor AdoMet-dependent ([methyl-3H]-AdoMet) methylation of the rRNA substrate by liquid scintillation counting. During the optimization of assay, it was found that, although this method is frequently employed, it is very time and labour intensive. A scintillation proximity assay was investigated to evaluate whether it could be a method for collecting kinetic data, and was found that further optimization is required. Comparative sequence analysis of TSR has shown it to be a member of the novel Class IV SpoUT family of AdoMet-dependent MTases. Members of this class possess a non-canonical AdoMet binding site containing a deep trefoil knot. Selected SpoUT family proteins were used as templates to develop a TSR homology model for monomeric and dimeric forms. Validation of the homology models was performed with structural validation servers and the model was then used as the basis of ongoing mutagenesis experiments. The X-ray crystal structure of TSR bound with AdoMet (2.45 Å) was elucidated by our collaborators, Drs. Mark Dunstan and Graeme Conn (University of Manchester). This structure confirms TSR MTase’s membership in the SpoUT MTase family with a deep trefoil knot in the catalytic domain. The AdoMet bound in the crystal structure is in an extended conformation not previously observed in SpoUT MTases. RNA docking simulations revealed some features that may be relevant to binding and recognition of TSR to the L11 binding domain of the RNA substrate. Two structure-activity studies were conducted to investigate the TS-rRNA interaction and TS solubility. Computational analyses of TS conformations, molecular orbitals and dynamics provided insight into the possible modes of TS binding to rRNA. Single-site modification of TS was attempted, targeting the dehydroalanine and dehydrobutyrine residues of the antibiotic. These moieties were modified using the polar thiol, 2-mercaptoethanesulfonic acid (2-MESNA). Similar modifications had been previously used to improve solubility and bioavailability of antibiotics. The resulting analogue was structurally characterized (NMR and mass spectrometry) and showed antimicrobial activity against Bacillus subtilis and Staphylococcus aureus.
10

Investigations of the Natural Product Antibiotic Thiostrepton from Streptomyces azureus and Associated Mechanisms of Resistance

Myers, Cullen Lucan January 2013 (has links)
The persistence and propagation of bacterial antibiotic resistance presents significant challenges to the treatment of drug resistant bacteria with current antimicrobial chemotherapies, while a dearth in replacements for these drugs persists. The thiopeptide family of antibiotics may represent a potential source for new drugs and thiostrepton, the prototypical member of this antibiotic class, is the primary subject under study in this thesis. Using a facile semi-synthetic approach novel, regioselectively-modified thiostrepton derivatives with improved aqueous solubility were prepared. In vivo assessments found these derivatives to retain significant antibacterial ability which was determined by cell free assays to be due to the inhibition of protein synthesis. Moreover, structure-function studies for these derivatives highlighted structural elements of the thiostrepton molecule that are important for antibacterial activity. Organisms that produce thiostrepton become insensitive to the antibiotic by producing a resistance enzyme that transfers a methyl group from the co-factor S-adenosyl-L-methionine (AdoMet) to an adenosine residue at the thiostrepton binding site on 23S rRNA, thus preventing binding of the antibiotic. Extensive site-directed mutagenesis was performed on this enzyme to generate point mutations at key active site residues. Ensuing biochemical assays and co-factor binding studies on these variants identified amino acid residues in the active site that are essential to the formation of the AdoMet binding pocket and provided direct evidence for the involvement of an active site arginine in the catalytic mechanism of the enzyme. Certain bacteria that produce neither thiostrepton nor the resistance methyltransferase express the thiostrepton binding proteins TIP-AL and TIP-AS, that irreversibly bind to the antibiotic, thereby conferring resistance by sequestration. Here, it was found that the point mutation of the previously identified reactive amino acid in TIP-AS did not affect covalent binding to the antibiotic, which was immediately suggestive of a specific, high affinity non-covalent interaction. This was confirmed in binding studies using chemically synthesized thiostrepton derivatives. These studies further revealed structural features from thiostrepton important in this non-covalent interaction. Together, these results indicate that thiostrepton binding by TIP-AS begins with a specific non-covalent interaction, which is necessary to properly orient the thiostrepton molecule for covalent binding to the protein. Finally, the synthesis of a novel AdoMet analogue is reported. The methyl group of AdoMet was successfully replaced with a trifluoromethyl ketone moiety, however, the hydrated form (germinal diol) of this compound was found to predominate in solution. Nevertheless, the transfer of this trifluoroketone/ trifluoropropane diol group was demonstrated with the thiopurine methyltransferase.

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