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Methyltransferase Domain (methyltransferase + domain)

Distribution by Scientific Domains

Chemistry	100%

Selected Abstracts

Functional Characterization of the Recombinant N -Methyltransferase Domain from the Multienzyme Enniatin Synthetase

CHEMBIOCHEM, Issue 9 2007
Till Hornbogen Dr.
Abstract A 51 kDa fusion protein incorporating the N -methyltransferase domain of the multienzyme enniatin synthetase from Fusarium scirpi was expressed in Saccharomyces cerevisiae. The protein was purified and found to bind S -adenosyl methionine (AdoMet) as demonstrated by cross-linking experiments with 14C-methyl-AdoMet under UV irradiation. Cofactor binding at equilibrium conditions was followed by saturation transfer difference (STD) NMR spectroscopy, and the native conformation of the methyltransferase was assigned. STD NMR spectroscopy yielded significant signals for H2 and H8 of the adenine moiety, H1' of D -ribose, and SCH3 group of AdoMet. Methyl group transfer catalyzed by the enzyme was demonstrated by using aminoacyl- N -acetylcysteamine thioesters (aminoacyl-SNACs) of L -Val, L -Ile, and L -Leu, which mimic the natural substrate amino acids of enniatin synthetase presented by the enzyme bound 4,-phosphopantetheine arm. In these experiments the enzyme was incubated in the presence of the corresponding aminoacyl-SNAC and 14C-methyl-AdoMet for various lengths of time, for up to 30 min. N -[14C-Methyl]-aminoacyl-SNAC products were extracted with EtOAc and separated by TLC. Acid hydrolysis of the isolated labeled compounds yielded the corresponding N -[14C-methyl] amino acids. Further proof for the formation of N - 14C-methyl-aminoacyl-SNACs came from MALDI-TOF mass spectrometry which yielded 23,212 Da for N -methyl-valyl-SNAC, accompanied by the expected postsource decay (PSD) pattern. Interestingly, L -Phe, which is not a substrate amino acid of enniatin synthetase, also proved to be a methyl group acceptor. D -Val was not accepted as a substrate; this indicates selectivity for the L isomer. [source]

Structure of the methyltransferase domain from the Modoc virus, a flavivirus with no known vector

ACTA CRYSTALLOGRAPHICA SECTION D, Issue 8 2009
Anna M. Jansson
The Modoc virus (MODV) is a flavivirus with no known vector (NKV). Evolutionary studies have shown that the viruses in the MODV group have evolved in association with mammals (bats, rodents) without transmission by an arthropod vector. MODV methyltransferase is the first enzyme from this evolutionary branch to be structurally characterized. The high-resolution structure of the methyltransferase domain of the MODV NS5 protein (MTaseMODV) was determined. The protein structure was solved in the apo form and in complex with its cofactor S -adenosyl- l -methionine (SAM). Although it belongs to a separate evolutionary branch, MTaseMODV shares structural characteristics with flaviviral MTases from the other branches. Its capping machinery is a relatively new target in flaviviral drug development and the observed structural conservation between the three flaviviral branches indicates that it may be possible to identify a drug that targets a range of flaviviruses. The structural conservation also supports the choice of MODV as a possible model for flavivirus studies. [source]

Structure analysis of the conserved methyltransferase domain of human trimethylguanosine synthase TGS1

ACTA CRYSTALLOGRAPHICA SECTION D, Issue 4 2009
Thomas Monecke
Methyltransferases play an important role in the post-transcriptional maturation of most ribonucleic acids. The modification of spliceosomal UsnRNAs includes N2-dimethylation of the m7G cap catalyzed by trimethylguanosine synthase 1 (TGS1). This 5,-cap hypermethylation occurs during the biogenesis of UsnRNPs as it initiates the m3G cap-dependent nuclear import of UsnRNPs. The conserved methyltransferase domain of human TGS1 has been purified, crystallized and the crystal structure of this domain with bound substrate m7GpppA was solved by means of multiple-wavelength anomalous dispersion. Crystal structure analysis revealed that m7GpppA binds via its adenosine moiety to the structurally conserved adenosylmethionine-binding pocket, while the m7 guanosine remains unbound. This unexpected binding only occurs in the absence of AdoMet and suggests an incomplete binding pocket for the m7G cap which is caused by the N-terminal truncation of the protein. These structural data are consistent with the finding that the crystallized fragment of human TGS1 is catalytically inactive, while a fragment that is 17 amino acids longer exhibits activity. [source]