Substrate-Induced Changes on the Optical Properties of Single-Layer WS2.

Among the most studied semiconducting transition metal dichalcogenides (TMDCs), WS2 showed several advantages in comparison to their counterparts, such as a higher quantum yield, which is an important feature for quantum emission and lasing purposes. We studied transferred monolayers of WS2 on a drilled Si3N4 substrate in order to have insights about on how such heterostructure behaves from the Raman and photoluminescence (PL) measurements point of view. Our experimental findings showed that the Si3N4 substrate influences the optical properties of single-layer WS2. Beyond that, seeking to shed light on the causes of the PL quenching observed experimentally, we developed density functional theory (DFT) based calculations to study the thermodynamic stability of the heterojunction through quantum molecular dynamics (QMD) simulations as well as the electronic alignment of the energy levels in both materials. Our analysis showed that along with strain, a charge transfer mechanism plays an important role for the PL decrease.

In vivo association of Ku with mammalian origins of DNA replication.

Ku is a heterodimeric (Ku70/86-kDa) nuclear protein with known functions in DNA repair, V(D)J recombination, and DNA replication. Here, the in vivo association of Ku with mammalian origins of DNA replication was analyzed by studying its association with ors8 and ors12, as assayed by formaldehyde cross-linking, followed by immunoprecipitation and quantitative polymerase chain reaction analysis. The association of Ku with ors8 and ors12 was also analyzed as a function of the cell cycle. This association was found to be approximately fivefold higher in cells synchronized at the G1/S border, in comparison with cells at G0, and it decreased by approximately twofold upon entry of the cells into S phase, and to near background levels in cells at G2/M phase. In addition, in vitro DNA replication experiments were performed with the use of extracts from Ku80(+/+) and Ku80(-/-) mouse embryonic fibroblasts. A decrease of approximately 70% in in vitro DNA replication was observed when the Ku80(-/-) extracts were used, compared with the Ku80(+/+) extracts. The results indicate a novel function for Ku as an origin binding-protein, which acts at the initiation step of DNA replication and dissociates after origin firing.

Double-strand breaks and tumorigenesis.

The establishment of connections between biochemical defects and clinical disease is a major goal of modern molecular genetics. In this review, we examine the current literature that relates defects in the two major DNA double-strand-break repair pathways--homologous recombination and nonhomologous end-joining--with the development of human tumors. Although definitive proof has yet to be obtained, the current literature is highly suggestive of such a link.

A novel regulatory element in the dnmt1 gene that responds to co-activation by Rb and c-Jun.

Rb, c-Jun and dnmt1 play critical roles in the process of cellular differentiation. We demonstrate that a regulatory region of murine dnmt1 contains an element which is responsible for transactivation by Rb and c-Jun in P19 embryocarcinoma cells which is not observed in Y1 adrenocarcinoma cells. During differentiation of P19 cells, the induction of Rb and c-Jun coincides with an increase of dnmt1 mRNA. Using linker scanning mutagenesis we identify the element that is responsible for this activation to be a non-canonical AP-1 site. Our data is an example of how a proto-oncogene activates its downstream effectors by recruiting a tumor suppressor. This interaction of Rb and a proto-oncogene might play an important role in differentiation. The responsiveness of dnmt1 to this type of signal is consistent with an important role for regulated expression of dnmt1 during cellular differentiation.

The DNMT1 target recognition domain resides in the N terminus.

DNA-cytosine-5-methyltransferase 1 (DNMT1) is the enzyme believed to be responsible for maintaining the epigenetic information encoded by DNA methylation patterns. The target recognition domain of DNMT1, the domain responsible for recognizing hemimethylated CGs, is unknown. However, based on homology with bacterial cytosine DNA methyltransferases it has been postulated that the entire catalytic domain, including the target recognition domain, is localized to 500 amino acids at the C terminus of the protein. The N-terminal domain has been postulated to have a regulatory role, and it has been suggested that the mammalian DNMT1 is a fusion of a prokaryotic methyltransferase and a mammalian DNA-binding protein. Using a combination of in vitro translation of different DNMT1 deletion mutant peptides and a solid-state hemimethylated substrate, we show that the target recognition domain of DNMT1 resides in the N terminus (amino acids 122-417) in proximity to the proliferating cell nuclear antigen binding site. Hemimethylated CGs were not recognized specifically by the postulated catalytic domain. We have previously shown that the hemimethylated substrates utilized here act as DNMT1 antagonists and inhibit DNA replication. Our results now indicate that the DNMT1-PCNA interaction can be disrupted by substrate binding to the DNMT1 N terminus. These results point toward new directions in our understanding of the structure-function of DNMT1.

How does DNA methyltransferase cause oncogenic transformation?

Global hypomethylation of genes and repetitive sequences, as well as hypermethylation of certain genes known to be involved in tumor suppression, are observed concurrently in cancer cells. Aberrant expression of DNA methyltransferase 1 (dnmt1) is a downstream effector of multiple tumorigenic pathways, and several data suggest that dnmt1 plays a causal role in these pathways. These data raise two critical questions: Why does ectopic expression of dnmt1 transform cells? and How can global hypomethylation exist in a cell that bears high levels of DNMT1 activity? It is proposed that DNMT1 induces cellular transformation by a mechanism that does not involve DNA methylation and that the low level of methylation in cancer cells is a result of induction of a DNA demethylase in these cells. Both DNMT1 and the demethylase play a causal role in cellular transformation and are candidate anticancer targets.

Inhibition of DNA methyltransferase inhibits DNA replication.

Ectopic expression of DNA methyltransferase transforms vertebrate cells, and inhibition of DNA methyltransferase reverses the transformed phenotype by an unknown mechanism. We tested the hypothesis that the presence of an active DNA methyltransferase is required for DNA replication in human non-small cell lung carcinoma A549 cells. We show that the inhibition of DNA methyltransferase by two novel mechanisms negatively affects DNA synthesis and progression through the cell cycle. Competitive polymerase chain reaction of newly synthesized DNA shows decreased origin activity at three previously characterized origins of replication following DNA methyltransferase inhibition. We suggest that the requirement of an active DNA methyltransferase for the functioning of the replication machinery has evolved to coordinate DNA replication and inheritance of the DNA methylation pattern.

Transcriptional regulation of the human DNA Methyltransferase (dnmt1) gene.

DNA methylation is an important component of the epigenetic control of genome functions. Understanding the regulation of the DNA Methyltransferase (dnmt1) gene expression is critical for comprehending how DNA methylation is coordinated with other critical biological processes. In this paper, we investigate the transcriptional regulatory region of the human dnmt1 gene using a combination of RACE, RNase protection analysis and CAT assays. We identified one major and three minor transcription initiation sites in vivo (P1-P4), which are regulated by independent enhancers and promoter sequences. The minimal promoter elements of P1, P2 and P4 are mapped within 256 bp upstream of their respective transcription initiation sites. P1 is nested within a CG-rich area, similar to other housekeeping genes, whereas P2-P4 are found in CG-poor areas. Three c-Jun-dependent enhancers are located downstream to P1 and upstream to P2-P4, thus providing a molecular explanation for the responsiveness of dnmt1 to oncogenic signals that are mediated by the Ras-c-Jun oncogenic signaling pathway.

Identification of initiation sites for DNA replication in the human dnmt1 (DNA-methyltransferase) locus.

Vertebrates have developed multiple mechanisms to coordinate the replication of epigenetic and genetic information. Dnmt1 encodes the maintenance enzyme DNA-methyltransferase, which is responsible for propagating the DNA methylation pattern and the epigenetic information that it encodes during replication. Direct sequence analysis and bisulfite mapping of the 5' region of DNA-methyltransferase 1 (dnmt1) have indicated the presence of many sequence elements associated with previously characterized origins of DNA replication. This study tests the hypothesis that the dnmt1 region containing these elements is an origin of replication in human cells. First, we demonstrate that a vector containing this dnmt1 sequence is able to support autonomous replication when transfected into HeLa cells. Second, using a gel retardation assay, we show that it contains a site for binding of origin-rich sequences binding activity, a recently purified replication protein. Finally, using competitive polymerase chain reaction, we show that replication initiates in this region in vivo. Based on these lines of evidence, we propose that initiation sites for DNA replication are located between the first intron and exon 7 of the human dnmt1 locus.

Concurrent replication and methylation at mammalian origins of replication.

Observations made with Escherichia coli have suggested that a lag between replication and methylation regulates initiation of replication. To address the question of whether a similar mechanism operates in mammalian cells, we have determined the temporal relationship between initiation of replication and methylation in mammalian cells both at a comprehensive level and at specific sites. First, newly synthesized DNA containing origins of replication was isolated from primate-transformed and primary cell lines (HeLa cells, primary human fibroblasts, African green monkey kidney fibroblasts [CV-1], and primary African green monkey kidney cells) by the nascent-strand extrusion method followed by sucrose gradient sedimentation. By a modified nearest-neighbor analysis, the levels of cytosine methylation residing in all four possible dinucleotide sequences of both nascent and genomic DNAs were determined. The levels of cytosine methylation observed in the nascent and genomic DNAs were equivalent, suggesting that DNA replication and methylation are concomitant events. Okazaki fragments were also demonstrated to be methylated, suggesting that the rapid kinetics of methylation is a feature of both the leading and the lagging strands of nascent DNA. However, in contrast to previous observations, neither nascent nor genomic DNA contained detectable levels of methylated cytosines at dinucleotide contexts other than CpG (i.e., CpA, CpC, and CpT are not methylated). The nearest-neighbor analysis also shows that cancer cell lines are hypermethylated in both nascent and genomic DNAs relative to the primary cell lines. The extent of methylation in nascent and genomic DNAs at specific sites was determined as well by bisulfite mapping of CpG sites at the lamin B2, c-myc, and beta-globin origins of replication. The methylation patterns of genomic and nascent clones are the same, confirming the hypothesis that methylation occurs concurrently with replication. Interestingly, the c-myc origin was found to be unmethylated in all clones tested. These results show that, like genes, different origins of replication exhibit different patterns of methylation. In summary, our results demonstrate tight coordination of DNA methylation and replication, which is consistent with recent observations showing that DNA methyltransferase is associated with proliferating cell nuclear antigen in the replication fork.