Saulius Klimašauskas

5-hmC in the brain is abundant in synaptic genes and shows differences at the exon-intron boundary

The 5-methylcytosine (5-mC) derivative 5-hydroxymethylcytosine (5-hmC) is abundant in the brain for unknown reasons. Here we characterize the genomic distribution of 5-hmC and 5-mC in human and mouse tissues. We assayed 5-hmC by using glucosylation coupled with restriction-enzyme digestion and microarray analysis. We detected 5-hmC enrichment in genes with synapse-related functions in both human and mouse brain. We also identified substantial tissue-specific differential distributions of these DNA modifications at the exon-intron boundary in human and mouse. This boundary change was mainly due to 5-hmC in the brain but due to 5-mC in non-neural contexts. This pattern was replicated in multiple independent data sets and with single-molecule sequencing. Moreover, in human frontal cortex, constitutive exons contained higher levels of 5-hmC relative to alternatively spliced exons. Our study suggests a new role for 5-hmC in RNA splicing and synaptic function in the brain.

Cytosine-5-methyltransferases add aldehydes to DNA

Targeted methylation of cytosine residues by S-adenosylmethionine-dependent DNA methyltransferases modulates gene expression in vertebrates. Here we show that cytosine-5-methyltransferases catalyze reversible covalent addition of exogenous aliphatic aldehydes to their target residues in DNA, thus yielding corresponding 5-hydroxyalkylcytosines. Such atypical enzymatic reactions with non-cofactor-like substrates open new ways for sequence-specific derivatization of DNA and demonstrate enzymatic exchange of 5-hydroxymethyl groups on cytosine in support of an oxidative mechanism of DNA demethylation.

Dynamic modes of the flipped-out cytosine during HhaI methyltransferase-DNA interactions in solution.

Flipping of a nucleotide out of a B‐DNA helix into the active site of an enzyme has been observed for the HhaI and HaeIII cytosine‐5 methyltransferases (M.HhaI and M.HaeIII) and for numerous DNA repair enzymes. Here we studied the base flipping motions in the binary M.HhaI–DNA and the ternary M.HhaI–DNA–cofactor systems in solution. Two 5‐fluorocytosines were introduced into the DNA in the places of the target cytosine and, as an internal control, a cytosine positioned two nucleotides upstream of the recognition sequence 5′‐GCGC‐3′. The 19F NMR spectra combined with gel mobility data show that interaction with the enzyme induces partition of the target base among three states, i.e. stacked in the B‐DNA, an ensemble of flipped‐out forms and the flipped‐out form locked in the enzyme active site. Addition of the cofactor analogue S–adenosyl‐L‐homocysteine greatly enhances the trapping of the target cytosine in the catalytic site. Distinct dynamic modes of the target cytosine have thus been identified along the reaction pathway, which includes novel base‐flipping intermediates that were not observed in previous X‐ray structures. The new data indicate that flipping of the target base out of the DNA helix is not dependent on binding of the cytosine in the catalytic pocket of M.HhaI, and suggest an active role of the enzyme in the opening of the DNA duplex.

Time-resolved fluorescence of 2-aminopurine as a probe of base flipping in M.HhaI–DNA complexes

DNA base flipping is an important mechanism in molecular enzymology, but its study is limited by the lack of an accessible and reliable diagnostic technique. A series of crystalline complexes of a DNA methyltransferase, M.HhaI, and its cognate DNA, in which a fluorescent nucleobase analogue, 2-aminopurine (AP), occupies defined positions with respect the target flipped base, have been prepared and their structures determined at higher than 2 Å resolution. From time-resolved fluorescence measurements of these single crystals, we have established that the fluorescence decay function of AP shows a pronounced, characteristic response to base flipping: the loss of the very short (∼100 ps) decay component and the large increase in the amplitude of the long (∼10 ns) component. When AP is positioned at sites other than the target site, this response is not seen. Most significantly, we have shown that the same clear response is apparent when M.HhaI complexes with DNA in solution, giving an unambiguous signal of base flipping. Analysis of the AP fluorescence decay function reveals conformational heterogeneity in the DNA–enzyme complexes that cannot be discerned from the present X-ray structures.

Synthesis of S-adenosyl-L-methionine analogs and their use for sequence-specific transalkylation of DNA by methyltransferases

Here we describe a one-step synthetic procedure for the preparation of S-adenosyl-L-methionine (AdoMet) analogs with extended carbon chains replacing the methyl group. These AdoMet analogs function as efficient cofactors for DNA methyltransferases (MTases), and we provide a protocol for sequence-specific transfer of extended side chains from these AdoMet analogs to DNA by DNA MTases. Direct chemoselective allylation or propargylation of S-adenosyl-L-homocysteine (AdoHcy) at sulfur is achieved under the acidic conditions needed to protect other nucleophilic positions in AdoHcy. The unsaturated bonds in β position to the sulfonium center of the resulting AdoMet analogs are designed to stabilize the transition state formed upon DNA MTase-catalyzed nucleophilic attack at the carbon next to the sulfonium center and lead to efficient transfer of the extended side chains to DNA. Using these protocols, sequence-specific functionalized DNA can be obtained within one to two weeks.

5-Hydroxymethylcytosine – the elusive epigenetic mark in mammalian DNA

Over the past decade, epigenetic phenomena claimed a central role in cell regulatory processes and proved to be important factors for understanding complex human diseases. One of the best understood epigenetic mechanisms is DNA methylation. In the mammalian genome, cytosines (C) were long known to exist in two functional states: unmethylated or methylated at the 5-position of the pyrimidine ring (5mC). Recent studies of genomic DNA from the human and mouse brain, neurons and from mouse embryonic stem cells found that a substantial fraction of 5mC in CpG dinucleotides is converted to 5-hydroxymethyl-cytosine (hmC) by the action of 2-oxoglutarate- and Fe(ii)-dependent oxygenases of the TET family. These findings provided important clues in a long elusive mechanism of active DNA demethylation and bolstered a fresh wave of studies in the area of epigenetic regulation in mammals. This review is dedicated to critical assessment of the most popular techniques with respect to their suitability for analysis of hmC in mammalian genomes. It also discusses the most recent data on biochemical and chemical aspects of the formation and further conversion of this nucleobase in DNA and its possible biological roles in cell differentiation, embryogenesis and brain function.

DNA fluorocode: A single molecule, optical map of DNA with nanometre resolution

We present a new method for single-molecule optical DNA mapping using an exceptionally dense, yet sequence-specific coverage of DNA with a fluorescent probe. The method employs a DNA methyltransferase enzyme to direct the DNA labelling, followed by molecular combing of the DNA onto a polymer-coated surface and subsequent sub-diffraction limit localization of the fluorophores. The result is a ‘DNA fluorocode’; a simple description of the DNA sequence, with a maximum achievable resolution of less than 20 bases, which can be read and analyzed like a barcode. We demonstrate the generation of a fluorocode for genomic DNA from the lambda bacteriophage using a DNA methyltransferase, M.HhaI, to direct fluorescent labels to four-base sequences reading 5′-GCGC-3′. A consensus fluorocode that allows the study of the DNA sequence at the level of an individual labelling site can be generated from a handful of molecules.

Programmable sequence-specific click-labeling of RNA using archaeal box C/D RNP methyltransferases

Biophysical and mechanistic investigation of RNA function requires site-specific incorporation of spectroscopic and chemical probes, which is difficult to achieve using current technologies. We have in vitro reconstituted a functional box C/D small ribonucleoprotein RNA 2′-O-methyltransferase (C/D RNP) from the thermophilic archaeon Pyrococcus abyssi and demonstrated its ability to transfer a prop-2-ynyl group from a synthetic cofactor analog to a series of preselected target sites in model tRNA and pre-mRNA molecules. Target selection of the RNP was programmed by changing a dodecanucleotide guide sequence in a 64-nt C/D guide RNA leading to efficient derivatization of three out of four new targets in each RNA substrate. We also show that the transferred terminal alkyne can be further appended with a fluorophore using a bioorthogonal azide-alkyne 1,3-cycloaddition (click) reaction. The described approach for the first time permits synthetically tunable sequence-specific labeling of RNA with single-nucleotide precision.

Methyltransferase-Directed Derivatization of 5-Hydroxymethylcytosine in DNA†

Cytosine modification by AdoMet–dependent DNA methyltransferases is part of an epigenetic regulatory network in vertebrates. Here we show that, in the absence of AdoMet, bacterial cytosine-5 methyltransferases can catalyze condensation of aliphatic thiols and selenols to 5-hydroxymethylcytosine in DNA yielding 5-chalcogenomethyl derivatives. These new atypical reactions open new ways for sequence-specific derivatization and analysis of 5-hydroxymethylcytosine, a recently discovered nucleobase in mammalian DNA

Allosteric control of catalysis by the F loop of RNA polymerase

Bacterial RNA polymerases (RNAPs) undergo coordinated conformational changes during catalysis. In particular, concerted folding of the trigger loop and rearrangements of the bridge helix at the RNAP active center have been implicated in nucleotide addition and RNAP translocation. At moderate temperatures, the rate of catalysis by RNAP from thermophilic Thermus aquaticus is dramatically reduced compared with its closest mesophilic relative, Deinococcus radiodurans. Here, we show that a part of this difference is conferred by a third element, the F loop, which is adjacent to the N terminus of the bridge helix and directly contacts the folded trigger loop. Substitutions of amino acid residues in the F loop and in an adjacent segment of the bridge helix in T. aquaticus RNAP for their D. radiodurans counterparts significantly increased the rate of catalysis (up to 40-fold at 20 °C). A deletion in the F loop dramatically impaired the rate of nucleotide addition and pyrophosphorolysis, but it had only a moderate effect on intrinsic RNA cleavage. Streptolydigin, an antibiotic that blocks folding of the trigger loop, did not inhibit nucleotide addition by the mutant enzyme. The resistance to streptolydigin likely results from the loss of its functional target, the folding of the trigger loop, which is already impaired by the F-loop deletion. Our results demonstrate that the F loop is essential for proper folding of the trigger loop during nucleotide addition and governs the temperature adaptivity of RNAPs in different bacteria.