5-Formylcytosine is an activating epigenetic mark for RNA Pol III during zygotic reprogramming.

5-Methylcytosine (5mC) is an established epigenetic mark in vertebrate genomic DNA, but whether its oxidation intermediates formed during TET-mediated DNA demethylation possess an instructive role of their own that is also physiologically relevant remains unresolved. Here, we reveal a 5-formylcytosine (5fC) nuclear chromocenter, which transiently forms during zygotic genome activation (ZGA) in Xenopus and mouse embryos. We identify this chromocenter as the perinucleolar compartment, a structure associated with RNA Pol III transcription.

Mammalian N1-adenosine PARylation is a reversible DNA modification.

Poly-ADP-ribosylation (PARylation) is regarded as a protein-specific modification. However, some PARPs were recently shown to modify DNA termini in vitro. Here, we use ultrasensitive mass spectrometry (LC-MS/MS), anti-PAR antibodies, and anti-PAR reagents to show that mammalian DNA is physiologically PARylated and to different levels in primary tissues.

The origin of genomic N-methyl-deoxyadenosine in mammalian cells.

The proposal that N-methyl-deoxyadenosine (mdA) acts as an epigenetic mark in mammals remains controversial. Using isotopic labeling coupled to ultrasensitive mass spectrometry, we confirm the presence of low-level mdA in mammalian DNA. However, the bulk of genomic mdA originates from ribo-N-methyladenosine, which is processed via the nucleotide-salvage pathway and misincorporated by DNA polymerases.

NEIL1 and NEIL2 DNA glycosylases protect neural crest development against mitochondrial oxidative stress.

Base excision repair (BER) functions not only in the maintenance of genomic integrity but also in active DNA demethylation and epigenetic gene regulation. This dual role raises the question if phenotypic abnormalities resulting from deficiency of BER factors are due to DNA damage or impaired DNA demethylation. Here we investigate the bifunctional DNA glycosylases/lyases NEIL1 and NEIL2, which act in repair of oxidative lesions and in epigenetic demethylation.

GADD45 promotes locus-specific DNA demethylation and 2C cycling in embryonic stem cells.

Mouse embryonic stem cell (ESC) cultures contain a rare cell population of "2C-like" cells resembling two-cell embryos, the key stage of zygotic genome activation (ZGA). Little is known about positive regulators of the 2C-like state and two-cell stage embryos. Here we show that GADD45 (growth arrest and DNA damage 45) proteins, regulators of TET (TET methylcytosine dioxygenase)-mediated DNA demethylation, promote both states.

Neil DNA glycosylases promote substrate turnover by Tdg during DNA demethylation.

DNA 5-methylcytosine is a dynamic epigenetic mark with important roles in development and disease. In the Tet-Tdg demethylation pathway, methylated cytosine is iteratively oxidized by Tet dioxygenases, and unmodified cytosine is restored via thymine DNA glycosylase (Tdg). Here we show that human NEIL1 and NEIL2 DNA glycosylases coordinate abasic-site processing during TET-TDG DNA demethylation.

GADD45a physically and functionally interacts with TET1.

DNA demethylation plays a central role during development and in adult physiology. Different mechanisms of active DNA demethylation have been established. For example, Growth Arrest and DNA Damage 45-(GADD45) and Ten-Eleven-Translocation (TET) proteins act in active DNA demethylation but their functional relationship is unresolved.

DAZL regulates Tet1 translation in murine embryonic stem cells.

Embryonic stem cell (ESC) cultures display a heterogeneous gene expression profile, ranging from a pristine naïve pluripotent state to a primed epiblast state. Addition of inhibitors of GSK3β and MEK (so-called 2i conditions) pushes ESC cultures toward a more homogeneous naïve pluripotent state, but the molecular underpinnings of this naïve transition are not completely understood. Here, we demonstrate that DAZL, an RNA-binding protein known to play a key role in germ-cell development, marks a subpopulation of ESCs that is actively transitioning toward naïve pluripotency.

Stable DNA aggregation by removal of counterions.

Negatively charged DNA can form extremely stable complexes with positively charged ions. These counterions are very difficult to remove from DNA; therefore, little is known about DNA behavior in their deficiency. We investigated whether removal of counterions from the strongly bound counterion layer would elicit any novel DNA properties or behaviors.

Non-uniform velocity of homogeneous DNA in a uniform electric field: consequence of electric-field-induced slow dissociation of highly stable DNA-counterion complexes.

Identical molecules move with identical velocities when placed in a uniform electric field within a uniform electrolyte. Here we report that homogeneous DNA does not obey this fundamental rule. While most DNA moves with similar velocities, a fraction of DNA moves with velocities that vary within a multiple-fold range.

DNA aptamers for as analytical tools for the quantitative analysis of DNA-dealkylating enzymes.

The AlkB family of oxygenases catalyze the removal of alkyl groups from nucleic acid substrates in an iron and 2-oxoglutarate-dependent manner and have roles including in DNA repair. To understand the biological functions of these DNA-dealkylating enzymes it is desirable to measure their expression levels in vitro and in vivo in complex biological matrixes. Quantitative analyses of the enzymes require affinity probes capable of binding AlkB family members selectively and with high affinity.

Universal method for determining electrolyte temperatures in capillary electrophoresis.

Temperature increase in capillary electrophoresis (CE) due to Joule heating is an inherent limitation of this powerful separation technique. Active cooling systems can decrease the temperature of a large part of the capillary but they leave "hot spots" at the capillary ends which can completely ruin some CE analyses despite their short lengths. Here, we introduce a "universal method for determining electrolyte temperatures" (UMET) that can determine temperatures in both efficiently- and inefficiently-cooled parts of the capillary.

Heat-associated field distortion in electro-migration techniques.

Electro-migration techniques, such as electrophoresis, are widely utilized in analytical sciences. If a single electrolyte is used, the field strength is typically assumed to be well-defined. Heat-associated field distortion (HAFD) has been suggested as a result of the nonuniform heat dissipation throughout the electrolyte; however, it has never been experimentally studied.

Temperature difference between the cooled and the noncooled parts of an electrolyte in capillary electrophoresis.

Joule heating always accompanies electrophoresis and unavoidably leads to a temperature increase of the electrolyte. The elevated temperatures are known to adversely affect the quality of separation and detection. To minimize the temperature increase in capillary electrophoresis (CE), Joule heat is removed by actively cooling the capillary.

Noncooled capillary inlet: a source of systematic errors in capillary-electrophoresis-based affinity analyses.

Capillary electrophoresis (CE) serves as a platform for a large family of temperature-sensitive affinity methods. To control the electrolyte temperature, the heat generated during electrophoresis is removed by actively cooling the capillary. Short parts of the capillary, particularly at its inlet, are not actively cooled, however, and the electrolyte in this part is likely to be at an elevated temperature.

Electric field destabilizes noncovalent protein-DNA complexes.

Noncovalent protein-DNA interactions are involved in many vital biological processes. In cells, these interactions may take place in the environment of an electric field which originates from the plasma and organelle membranes and reaches strengths of 1 MV/cm. Moreover, protein-DNA interactions are often studied in vitro using an electric field as strong as 1 kV/cm, for example by electrophoresis.

Direct analysis of enzyme-catalyzed DNA demethylation.

N/O-methylation of DNA can be cytotoxic and mutagenic; therefore, enzymes that reverse DNA methylation are essential for organism survival. Several 2-oxoglutarate-dependent oxygenases and methyltransferases that remove a methyl group from a methylated DNA base have been identified. Studies of their kinetics and search for their inhibitors have been retarded by the lack of an approach to directly quantitate DNA substrates and products that differ by a single methyl group.

Selection of aptamers for a protein target in cell lysate and their application to protein purification.

Functional genomics requires structural and functional studies of a large number of proteins. While the production of proteins through over-expression in cultured cells is a relatively routine procedure, the subsequent protein purification from the cell lysate often represents a significant challenge. The most direct way of protein purification from a cell lysate is affinity purification using an affinity probe to the target protein.

Selection of smart small-molecule ligands: the proof of principle.

The development of drugs and diagnostics with desirable characteristics requires smart small-molecule ligandsligands with predefined binding parameters of interaction with the target. Here, we propose a general approach for selection of such ligands from highly diverse combinatorial libraries of small molecules by methods of kinetic capillary electrophoresis (KCE). We deduct three fundamental requirements for the combinatorial library to suit the KCE-based selection of smart ligands and suggest a universal design of the library for selecting smart small-molecule ligands: every small molecule in the library is tagged with DNA that encodes the structure of the molecule.

Kinetic capillary electrophoresis-based affinity screening of aptamer clones.

DNA aptamers are single stranded DNA (ssDNA) molecules artificially selected from random-sequence DNA libraries for their specific binding to a certain target. DNA aptamers have a number of advantages over antibodies and promise to replace them in both diagnostic and therapeutic applications. The development of DNA aptamers involves three major stages: library enrichment, obtaining individual DNA clones, and the affinity screening of the clones.

Diffusion as a tool of measuring temperature inside a capillary.

Application of capillary electrophoresis (CE) to temperature-sensitive biomolecular interactions requires knowledge of the temperature inside the capillary. The simplest approach to finding temperature in CE employs a molecular probe with a temperature-dependent parameter. Up until now only spectral parameters of molecular probes were utilized for temperature measurements in CE.

Aptamer-facilitated biomarker discovery (AptaBiD).

Here we introduce a technology for biomarker discovery in which (i) DNA aptamers to biomarkers differentially expressed on the surfaces of cells being in different states are selected; (ii) aptamers are used to isolate biomarkers from the cells; and (iii) the isolated biomarkers are identified by means of mass spectrometry. The technology is termed aptamer-facilitated biomarker discovery (AptaBiD). AptaBiD was used to discover surface biomarkers that distinguish live mature and immature dendritic cells.

Selection of aptamers by systematic evolution of ligands by exponential enrichment: addressing the polymerase chain reaction issue.

Aptamers are DNA oligonucleotides capable of binding different classes of targets with high affinity and selectivity. They are particularly attractive as affinity probes in multiplexed quantitative analysis of proteins. Aptamers are typically selected from large libraries of random DNA sequences in a general approach termed systematic evolution of ligands by exponential enrichment (SELEX).

Non-SELEX: selection of aptamers without intermediate amplification of candidate oligonucleotides.

Aptamers are typically selected from libraries of random DNA (or RNA) sequences through systematic evolution of ligands by exponential enrichment (SELEX), which involves several rounds of alternating steps of partitioning of candidate oligonucleotides and their PCR amplification. Here we describe a protocol for non-SELEX selection of aptamers--a process that involves repetitive steps of partitioning with no amplification between them. Non-equilibrium capillary electrophoresis of equilibrium mixtures (NECEEM), which is a highly efficient affinity method, is used for partitioning.