A G4-DNA/B-DNA junction at codon 12 of c-Ha-ras is actively and asymmetrically methylated by DNA(cytosine-5)methyltransferase

Modulating gene expression in breast cancer via DNA secondary structure and the CRISPR toolbox

Breast cancer is the most commonly diagnosed malignancy in women, and while the survival prognosis of patients with early-stage, non-metastatic disease is ∼75%, recurrence poses a significant risk and advanced and/or metastatic breast cancer is incurable. A distinctive feature of advanced breast cancer is an unstable genome and altered gene expression patterns that result in disease heterogeneity. Transcription factors represent a unique therapeutic opportunity in breast cancer, since they are known regulators of gene expression, including gene expression involved in differentiation and cell death, which are themselves often mutated or dysregulated in cancer. While transcription factors have traditionally been viewed as 'undruggable', progress has been made in the development of small-molecule therapeutics to target relevant protein-protein, protein-DNA and enzymatic active sites, with varying levels of success. However, non-traditional approaches such as epigenetic editing, transcriptional control via CRISPR/dCas9 systems, and gene regulation through non-canonical nucleic acid secondary structures represent new directions yet to be fully explored. Here, we discuss these new approaches and current limitations in light of new therapeutic opportunities for breast cancers.

Age-dependent methylation in epigenetic clock CpGs is associated with G-quadruplex, co-transcriptionally formed RNA structures and tentative splice sites

Horvath's epigenetic clock consists of 353 CpGs whose methylation levels can accurately predict the age of individuals. Using bioinformatics analysis, we investigated the conformation, energy characteristics and presence of tentative splice sites of the sequences surrounding the epigenetic clock CpGs, in relation to the median methylation changes in different ages, the presence of CpG islands and their position in genes. Common characteristics in the 100 nt sequences surrounding the epigenetic clock CpGs are G-quadruplexes and/or tentative splice site motifs. Median methylation increases significantly in sequences which adopt less stable structures during transcription. Methylation is higher when CpGs overlap with G-quadruplexes than when they precede them. Median methylation in epigenetic clock CpGs is higher in sequences expressed as single products rather than in multiple products and those containing single donors and multiple acceptors. Age-related methylation variation is significant in sequences without G-quadruplexes, particularly those producing low stability nascent RNA and those with splice sites. CpGs in sequences close to transcription start sites and those which are possibly never expressed (hypothetical proteins) undergo similar extent of age-related median methylation decrease and increase. Preservation of methylation is observed in CpG islands without G-quadruplexes, contrary to CpGs far from CpG islands (open sea). Sequences containing G-quadruplexes and RNA pseudoknots, determining the recognition by H3K27 histone methyltransferase, are hypomethylated. The presented structural DNA and co-transcriptional RNA analysis of epigenetic clock sequences, foreshadows the association of age-related methylation changes with the principle biological processes of DNA and histone methylation, splicing and chromatin silencing.

Maintaining the unmethylated state

BACKGROUND

A remarkable correspondence exists between the cytogenetic locations of the known fragile sites and frequently reported sites of hypermethylation. The best-known features of fragile sites are sequence motifs that are prone to the spontaneous formation of a non-B DNA structure. These facts, coupled with the known enzymological specificities of DNA methyltransferase 1 (DNMT1), the ATP-dependent and actin-dependent helicases, and the ten-eleven translocation (TET) dioxygenases, suggest that these enzymes are involved in an epigenetic cycle that maintains the unmethylated state at these sites by resolving non-B structure, preventing both the sequestration of DNA methyltransferases (DNMTs) and hypermethylation in normal cells.

PRESENTATION OF THE HYPOTHESIS

The innate tendency of DNA sequences present at fragile sites to form non-B DNA structures results in de novo methylation of DNA at these sites that is held in check in normal cells by the action of ATP-dependent and actin-dependent helicases coupled with the action of TET dioxygenases. This constitutes a previously unrecognized epigenetic repair cycle in which spontaneously forming non-B DNA structures formed at fragile sites are methylated by DNMTs as they are removed by the action of ATP-dependent and actin-dependent helicases, with the resulting nascent methylation rendered non-transmissible by TET dioxygenases.

TESTING THE HYPOTHESIS

A strong prediction of the hypothesis is that knockdown of ATP-dependent and actin-dependent helicases will result in enhanced bisulfite sensitivity and hypermethylation at non-B structures in multiple fragile sites coupled with global hypomethylation.

IMPLICATIONS OF THE HYPOTHESIS

A key implication of the hypothesis is that helicases, like the lymphoid-specific helicase and alpha thalassemia/mental retardation syndrome X-linked helicase, passively promote accurate maintenance of DNA methylation by preventing the sequestration of DNMTs at sites of unrepaired non-B DNA structure. When helicase action is blocked due to mutation or downregulation of the respective genes, DNMTs stall at unrepaired non-B structures in fragile sites after methylating them and are unable to methylate other sites in the genome, resulting in hypermethylation at non-B DNA-forming sites, along with hypomethylation elsewhere.

DNA quadruplexes and dynamical genetics

In a recent paper, we have put forward the hypothesis that there exist smart purposive mechanisms - tandem repeat length managers - which regulate the length of some tandem repeat, or cause rearrangements, and are almost always driven by some variable number tandem repeat. We have called the framework in which such mechanisms act 'dynamical genetics'. The purpose of this paper is to contribute to lay the foundations of a molecular study of the above mechanisms, by proposing a hypothesis, based on various kinds of supporting evidence and plausibility arguments, about the special importance of DNA quadruplexes for dynamical genetics, and by considering the involved enzymes. This hypothesis states that a tandem repeat length manager acts almost always by monitoring a DNA tract that has the characteristics of being a variable number tandem repeat and/or forming a DNA quadruplex, and that it is almost always driven by at least one of them.

Major versus minor groove DNA binding of a bisarginylporphyrin hybrid molecule: a molecular mechanics investigation

On the basis of theoretical computations, we have recently synthesised [Perrée-Fauvet, M. and Gresh, N., Tetrahedron Lett., 36 (1995) 4227] a bisarginyl conjugate of a tricationic porphyrin (BAP), designed to target, in the major groove of DNA, the d(GGC GCC)2 sequence which is part of the primary binding site of the HIV-1 retrovirus site [Wain-Hobson, S. et al., Cell, 40 (1985) 9]. In the theoretical model, the chromophore intercalates at the central d(CpG)2 step and each of the arginyl arms targets O6/N7 belonging to guanine bases flanking the intercalation site. Recent IR and UV-visible spectroscopic studies have confirmed the essential features of these theoretical predictions [Mohammadi, S. et al., Biochemistry, 37 (1998) 6165]. In the present study, we compare the energies of competing intercalation modes of BAP to several double-stranded oligonucleotides, according to whether one, two or three N-methylpyridinium rings project into the major groove. Correspondingly, three minor groove binding modes were considered, the arginyl arms now targeting N3, O2 sites belonging to the purine or pyrimidine bases flanking the intercalation site. This investigation has shown that: (i) in both the major and minor grooves, the best-bound complexes have the three N-methylpyridinium rings in the groove opposite to that of the phenyl group bearing the arginyl arms; (ii) major groove binding is preferred over minor groove binding by a significant energy (29 kcal/mol); and (iii) the best-bound sequence in the major groove is d(GGC GCC)2 with two successive guanines upstream from the intercalation. On the other hand, due to the flexibility of the arginyl arms, other GC-rich sequences have close binding energies, two of them being less stable than it by less than 8 kcal/mol. These results serve as the basis for the design of derivatives of BAP with enhanced sequence selectivities in the major groove.

The identification and characterization of a G4-DNA resolvase activity

There is increasing evidence that four-stranded Hoogsteen-bonded DNA structures, G4-DNA, play an important role in cellular processes such as meiosis and recombination. The Hoogsteen-bonded G4-DNA is thermodynamically more stable than duplex DNA, and many guanine-rich genomic DNA sequences with the ability to form G4-DNA have been identified. A protein-dependent activity that resolves G4-DNA into single-stranded DNA has been identified in human placental tissue. The resolvase activity was purified from any apparent nuclease activity and is dependent on NTP hydrolysis and MgCl2. Resolvase activity is optimal with 5 mM MgCl2. The Vmax/Km of ATP is 0. 055%/min/microM, higher than the Vmax/Km of the other dNTPs. The products of the resolvase reaction are unmodified single-stranded DNA. The resolvase is not a duplex DNA helicase or a topoisomerase II activity and does not unwind Hoogsteen-bonded triplex DNA. Resolvase is a novel activity that unwinds stable G4-DNA structures using a dNTP-dependent mechanism producing unmodified single-stranded DNA. Potential in vivo roles for this G4-DNA resolvase activity are discussed.

Solution structures of unimolecular quadruplexes formed by oligonucleotides containing Oxytricha telomere repeats

BACKGROUND

Oligonucleotides containing the guanine-rich telomeric sequence of Oxytricha chromosomes (dT4G4) have previously been shown to form DNA quadruplexes comprising guanine quartets stabilized by cations. Two different structures have been reported for both d(G4T4G4) (Oxy1.5) and d(G4T4G4T4G4T4G4) (Oxy3.5).

RESULTS

Here we present the solution structure of a uracil- and inosine-containing derivative of Oxy3.5, d(G4TUTUG4T4G4UUTTG3I) (Oxy3.5-U4128), determined using two-dimensional 1H and 31P NMR techniques. This oligonucleotide forms a unimolecular quadruplex that is very similar to the dimeric Oxy1.5 solution structure, in that it contains a loop spanning the diagonal of an end quartet. The groove widths, strand polarities, and positions of the syn bases along the G4 tracts and within the quartets are all as reported for Oxy1.5. The first and third pyrimidine tracts form parallel loops spanning a wide groove and a narrow groove respectively.

CONCLUSIONS

Both Oxy3.5 and Oxy3.5-U(4)128 form unimolecular quadruplexes in solution with a diagonal central T4 loop. These results conflict with those reported for d(G4TUTUG4TTUUG4UUTTG4) in solution, in which the central loop spans a wide groove.

Direct observation of a DNA quadruplex by electrospray ionization mass spectrometry

In 10 mM sodium phosphate, pH 7.6, containing 0.1 mM ethylenediaminetetraacetic acid, ions correspondings to the non-calent, four-stranded oligonucleotide, d(CGCG4GCG)4, were detected by negative ion electrospray ionization (ESI) mass spectrometry at a low nozzle-skimmer (delta NS) bias (-150 V), but not at a higher delta NS bias (> -250 V). In contrast, when the sample was desalted and analyzed by ESI mass spectrometry at a low delta NS bias only ions for the single-stranded d(CGCG4GCG) species were observed. These data agree with spectroscopic evidence which showed that oligonucleotides with the sequence motif 5'd(CGCGnGCG)3', where n = 2-5, formed stable four-stranded complexes in the presence of monatomic cations, like K+, Ca2+, Na+ and Li+, but not in their absence.

Atomic force microscopy of conventional and unconventional nucleic acid structures

Images of conventional (Watson-Crick base paired) and unconventional (G4 RNA) nucleic acid structures have been obtained by atomic force microscopy. The images are reproducibly generated from samples deposited on freshly cleaved mica. Periodic substructural features are evident in fibres observed in both cases. In the case of G4 RNA, tip-induced formation of large fibres is observed.

Formation of novel hairpin structures by telomeric C-strand oligonucleotides

Telomeres are specialized structures at the ends of chromosomes that are required for long term chromosome stability and replication of the chromosomal terminus. Telomeric DNA consists of simple repetitive sequences with one strand G-rich relative to the other, C-rich, strand. Evolutionary conservation of this feature of telomeric repeat sequences suggests that they have specific structural characteristics involved in telomere function. Absorbance thermal denaturation, chemical modification and non-denaturing gel electrophoretic analyses showed that telomeric C-strand oligonucleotides form stable non-Watson-Crick hairpin structures containing C.C+ base pairs. Formation of such hairpins may facilitate previously reported G-strand exclusive interactions.

Telomeres--what's new at the end?

Telomeres are specialized chromatin domains located at the ends of chromosomes. They are involved in chromosome replication, stability and localization in the nucleus. In addition to these functions, recent work suggests that telomeres are involved in such superficially diverse cellular phenomena as ageing, cancer, nuclear architecture and nuclear/cellular division.

Quadruplex DNA formation in a region of the tRNA gene supF associated with hydrogen peroxide mediated mutations

A hot spot for H2O2/Fe-mediated mutation has been observed between bases 154 and 170 of the supF gene in the mutation reporter plasmid pZ189 [Moraes et al. (1990) Carcinogenesis 11, 283; Akman et al. (1991) Mutat. Res. (in press)]. To further characterize this hot spot, we synthesized the 33mer d(pAAAGTGATGGTGGTGGGGGAAGGATTCGAACCT) (pZ33), which is complementary to bases 159-191 of the supF gene. pZ33 annealed spontaneously in 10 mM Tris-HCl (pH 8.0)-1 mM EDTA-100 mM NaCl at 50 degrees C into two major forms, one of which migrates more slowly than does d(pT)33 on nondenaturing 12% polyacrylamide gels. We propose that this form is a four-stranded structure stabilized by Hoogsteen-type deoxyguanosine quartets involving all deoxyguanosines of the sequence d-(pGGTGGTGGGGG) because of the following. (1) pZ33 migrates as a single form that comigrates with d(pT)33 on denaturing 20% acrylamide-8 M urea gels. (2) Annealing an equimolar mixture of 5'-32P-labeled pZ33 and the oligodeoxynucleotide d(pTTTTTTTTpZ33TTTTTTTT) (pZ49), as well as 5'-32P-labeled pZ49 and pZ33, caused the formation of four, discreet slowly migrating bands on nondenaturing 12% polyacrylamide gels. Mixing 5'-32P-labeled pZ33 with 5'-32P-labeled pZ49 resulted in five slowly migrating bands. (3) An oligodeoxynucleotide identical with pZ33 except that every deoxyguanosine has been replaced with deoxyinosine did not anneal into a slowly migrating form. (4) Dimethyl sulfate protection studies demonstrated that all deoxyguanosines of the sequence d(pGGTGGTGGGGG) were protected at N-7 in the slowly migrating form but not in single-stranded pZ33. These data suggest that a hot spot for H2O2/Fe-mediated base substitutions is located adjacent to a sequence that can spontaneously adopt a quadruplex structure in which deoxyguanosine quartets are Hoogsteen bonded.

Theoretical design of a bistetrapeptide derivative of mitoxantrone targeted towards the double-stranded hexanucleotide sequence d(GGCGCC)2

The hexanucleotide d(GGCGCC)2 is encountered in recurrent fashion within transcriptional activating sequences in retroviruses and protooncogenes. Our first theoretical design of novel oligopeptide derivatives of mitoxantrone, MTX (1), had enabled us to predict derivatives depsiGly-Lys(L) and depsiGly-Gly-Orn(D) to preferentially target the tetrameric core d(CCGG)2. Owing to the crucial importance of hexamer d(GGCGCC)2, we have attempted to extend the realm of our approach by now targeting this specific hexanucleotide. For that purpose, we undertook the design of further oligopeptide derivatives of MTX, in which each arm was identically amidated (rather than esterified as in (1)) by tri- or tetrapeptides of varying sequences and individual residue configurations. The binding affinities of these derivatives to the palindromic sequences d(GGCGCC)2, d(CGCGCG)2, d(GCCGGC)2 and d(CCCGGG)2, were compared by energy-minimization. We report here the results obtained with the most promising derivative, having the sequence Arg(L)-Gly-Val(L)-Glu(L), and displaying a considerable energy preference for d(GGCGCC)2 over the other candidate hexameric sites (referred to as I). In the corresponding complexes, the two arms are in two mutually antiparallel directions in the major groove, and adopt a beta-sheet like arrangement stabilized by two H-bonds involving the carbonyl and amide groups of the Gly residues. Each Arg side chain on a given arm chelates O6 and N7 atoms of G1, G2/G1', G2' with its imino and cis amino hydrogen, and is simultaneously bound through two amino hydrogens in a bidentate interaction with the Glu residue.

Recognition of unusual DNA structures by human DNA (cytosine-5)methyltransferase

The symmetry of the responses of the human DNA (cytosine-5)methyltransferase to alternative placements of 5-methylcytosine in model oligodeoxynucleotide duplexes containing unusual structures has been examined. The results of these experiments more clearly define the DNA recognition specificity of the enzyme. A simple three-nucleotide recognition motif within the CG dinucleotide pair can be identified in each enzymatically methylated duplex. The data can be summarized by numbering the four nucleotides in the dinucleotide pair thus: 1 4/2 3. With reference to this numbering scheme, position 1 can be occupied by cytosine or 5-methylcytosine; position 2 can be occupied by guanosine or inosine; position 3, the site of enzymatic methylation, can be occupied only by cytosine; and position 4 can be occupied by guanosine, inosine, O6-methylguanosine, cytosine, adenosine, an abasic site, or the 3' hydroxyl group at the end of a gapped molecule. Replacing the guanosine normally found at position 4 with any of the moieties introduces unusual (non-Watson-Crick) pairing at position 3 and generally enhances methylation of the cytosine at that site. The exceptional facility of the enzyme in actively methylating unusual DNA structures suggests that the evolution of the DNA methyltransferase, and perhaps DNA methylation itself, may be linked to the biological occurrence of unusual DNA structures.

Tetraplex formation of a guanine-containing nonameric DNA fragment

A combination of spectroscopic and calorimetric techniques has been used to characterize the structures formed by a family of short, guanine-containing DNA single strands of the form d[GGTTXTTGG], X = A, C, G, T. In 1 molar NaCl at low temperatures, these molecules do not behave like single strands, but rather exhibit properties consistent with tetraplex formation. The standard state enthalpies, entropies, and free energies for formation of each tetraplex have been measured, as have preliminary nuclear magnetic resonance (NMR) spectra. In 1 molar KCl, the melting behavior of the structure or structures is more complex than in 1 molar NaCl. This observation may be related to the recently proposed "sodium-potassium switch."

Interaction of oligonucleotides containing 6-O-methylguanine with human DNA (cytosine-5-)-methyltransferase [published erratumm appears in Biochemistry 1992 Aug 4;31(30):7008]

Thirty-base-pair synthetic oligonucleotide duplexes containing a single meG.C (meG = 6-O-methylguanine) or A.C base pair at the 16th position (i.e., 5'-CCCGTTTAAATATACXTATACCCGGGTACC-3', where X = A or meG) were used to study de novo methylation by the purified human DNA (cytosine-5)-methyltransferase isolated from CEM cells. Both duplexes containing meG.C and A.C base pairs show enhanced methyl group acceptor properties. Subsequent introduction of hemimethylated sites at the 15th position of the top strand (the C residue next to the abnormal base pair) and the 7th, 15th (which represents the C residue in the 6meG.C and A.C base pairs), and 27th positions of the bottom strand were used to study the maintenance methylation of the hemimethylated duplexes by the methylase. This revealed striking differences in the rate, amount, and sites of methylation, which are dependent on the position of the hemimethylated site in the duplex. The possible mechanism of action of the methylase is discussed. The data show that 6-O-methylguanine residues in DNA can have other genetic effects apart from their miscoding behavior and that meG.C and A.C base pairs exert different effects in terms of methylation.

In vivo footprint and methylation analysis by PCR-aided genomic sequencing: comparison of active and inactive X chromosomal DNA at the CpG island and promoter of human PGK-1

The promoter region of the X-linked human phosphoglycerate kinase-1 (PGK-1) gene is a CpG island, similar to those often found near autosomal genes. We used ligation-mediated polymerase chain reaction (PCR) for a genomic sequencing study in which 450 bp of the human PGK-1 promoter region was analyzed for the presence of in vivo protein footprints and cytosine methylation at all CpG sites. A technique was devised to selectively visualize the DNA of the inactive X chromosome (Xi), even in the presence of the active X chromosome (Xa). We found that the human Xa in both normal male lymphocytes and hamster-human hybrids is completely unmethylated at all 120 CpG sites. In contrast, 118 of the CpG sites are methylated on the human Xi in hamster-human hybrids. The Xi in normal female lymphocytes is also highly methylated, but some GCG or CGC trinucleotides partially escape methylation; all other CpGs are fully methylated. In vivo footprinting studies with dimethylsulfate (DMS) revealed eight regions of apparent protein-DNA contacts on the Xa. Four of the footprints contained the consensus sequence of the binding site for transcription factor Sp1. The other regions include potential binding sites for transcription factors ATF, NF1, and a CCAAT-binding protein. The Xi did not show any specifically protected sequences, and with the exception of four hyperreactive sites, the in vivo DMS reactivity profile of Xi DNA was very similar to that of purified, linear Xi DNA. The implications of these findings with regard to the maintenance of methylation-free islands, X chromosome inactivation, and the chromatin structure of facultative heterochromatin are discussed.