ASAR lncRNAs control DNA replication timing through interactions with multiple hnRNP/RNA binding proteins.

ASARs are a family of very-long noncoding RNAs that control replication timing on individual human autosomes, and are essential for chromosome stability. The eight known ASAR lncRNAs remain closely associated with their parent chromosomes. Analysis of RNA-protein interaction data (from ENCODE) revealed numerous RBPs with significant interactions with multiple ASAR lncRNAs, with several hnRNPs as abundant interactors.

Epigenetic control of chromosome-associated lncRNA genes essential for replication and stability.

ASARs are long noncoding RNA genes that control replication timing of entire human chromosomes in cis. The three known ASAR genes are located on human chromosomes 6 and 15, and are essential for chromosome integrity. To identify ASARs on all human chromosomes we utilize a set of distinctive ASAR characteristics that allow for the identification of hundreds of autosomal loci with epigenetically controlled, allele-restricted behavior in expression and replication timing of coding and noncoding genes, and is distinct from genomic imprinting.

Differential Allelic Expression among Long Non-Coding RNAs.

Long non-coding RNAs (lncRNA) comprise a diverse group of non-protein-coding RNAs >200 bp in length that are involved in various normal cellular processes and disease states, and can affect coding gene expression through mechanisms in or in . Since the discovery of the first functional lncRNAs transcribed by RNA Polymerase II, H19 and Xist, many others have been identified and noted for their unusual transcriptional pattern, whereby expression from one chromosome homolog is strongly favored over the other, also known as mono-allelic or differential allelic expression. lncRNAs with differential allelic expression have been observed to play critical roles in developmental gene regulation, chromosome structure, and disease.

Reciprocal monoallelic expression of ASAR lncRNA genes controls replication timing of human chromosome 6.

DNA replication occurs on mammalian chromosomes in a cell-type distinctive temporal order known as the replication timing program. We previously found that disruption of the noncanonical lncRNA genes and results in delayed replication timing and delayed mitotic chromosome condensation of human chromosomes 6 and 15, respectively. and display random monoallelic expression and display asynchronous replication between alleles that is coordinated with other random monoallelic genes on their respective chromosomes.

L1 retrotransposon antisense RNA within ASAR lncRNAs controls chromosome-wide replication timing.

Mammalian cells replicate their chromosomes via a temporal replication program. The and genes were identified as loci that when disrupted result in delayed replication and condensation of entire human chromosomes. ASAR6 and ASAR15 are monoallelically expressed long noncoding RNAs that remain associated with the chromosome from which they are transcribed.

ASAR15, A cis-acting locus that controls chromosome-wide replication timing and stability of human chromosome 15.

DNA replication initiates at multiple sites along each mammalian chromosome at different times during each S phase, following a temporal replication program. We have used a Cre/loxP-based strategy to identify cis-acting elements that control this replication-timing program on individual human chromosomes. In this report, we show that rearrangements at a complex locus at chromosome 15q24.

Asynchronous replication, mono-allelic expression, and long range Cis-effects of ASAR6.

Mammalian chromosomes initiate DNA replication at multiple sites along their length during each S phase following a temporal replication program. The majority of genes on homologous chromosomes replicate synchronously. However, mono-allelically expressed genes such as imprinted genes, allelically excluded genes, and genes on female X chromosomes replicate asynchronously.

DNA replication timing, genome stability and cancer: late and/or delayed DNA replication timing is associated with increased genomic instability.

Normal cellular division requires that the genome be faithfully replicated to ensure that unaltered genomic information is passed from one generation to the next. DNA replication initiates from thousands of origins scattered throughout the genome every cell cycle; however, not all origins initiate replication at the same time. A vast amount of work over the years indicates that different origins along each eukaryotic chromosome are activated in early, middle or late S phase.

Chromosome replicating timing combined with fluorescent in situ hybridization.

Mammalian DNA replication initiates at multiple sites along chromosomes at different times during S phase, following a temporal replication program. The specification of replication timing is thought to be a dynamic process regulated by tissue-specific and developmental cues that are responsive to epigenetic modifications. However, the mechanisms regulating where and when DNA replication initiates along chromosomes remains poorly understood.

Mammalian chromosomes contain cis-acting elements that control replication timing, mitotic condensation, and stability of entire chromosomes.

Recent studies indicate that mammalian chromosomes contain discrete cis-acting loci that control replication timing, mitotic condensation, and stability of entire chromosomes. Disruption of the large non-coding RNA gene ASAR6 results in late replication, an under-condensed appearance during mitosis, and structural instability of human chromosome 6. Similarly, disruption of the mouse Xist gene in adult somatic cells results in a late replication and instability phenotype on the X chromosome.

An autosomal locus that controls chromosome-wide replication timing and mono-allelic expression.

Mammalian DNA replication initiates at multiple sites along chromosomes at different times, following a temporal replication program. Homologous alleles typically replicate synchronously; however, mono-allelically expressed genes such as imprinted genes, allelically excluded genes and genes on the female X chromosome replicate asynchronously. We have used a chromosome engineering strategy to identify a human autosomal locus that controls this replication timing program in cis.

Transvection mediated by the translocated cyclin D1 locus in mantle cell lymphoma.

In mantle cell lymphoma (MCL) and some cases of multiple myeloma (MM), cyclin D1 expression is deregulated by chromosome translocations involving the immunoglobulin heavy chain (IgH) locus. To evaluate the mechanisms responsible, gene targeting was used to study long-distance gene regulation. Remarkably, these targeted cell lines lost the translocated chromosome (t(11;14)).

p300/CREB-binding protein interacts with ATR and is required for the DNA replication checkpoint.

The highly related acetyltransferases, p300 and CREB-binding protein (CBP) are coactivators of signal-responsive transcriptional activation. In addition, recent evidence suggests that p300/CBP also interacts directly with complexes that mediate DNA replication and repair. In this report, we show that loss of p300/CBP in mammalian cells results in a defect in the cell cycle arrest induced by stalled DNA replication.

Engineering translocations with delayed replication: evidence for cis control of chromosome replication timing.

Certain chromosome rearrangements, found in cancer cells or in cells exposed to ionizing radiation, exhibit a chromosome-wide delay in replication timing (DRT) that is associated with a delay in mitotic chromosome condensation (DMC). We have developed a chromosome engineering strategy that allows the generation of chromosomes with this DRT/DMC phenotype. We found that approximately 10% of inter-chromosomal translocations induced by two distinct mechanisms, site-specific recombination mediated by Cre or non-homologous end joining of DNA double-strand breaks induced by I-Sce1, result in DRT/DMC.

p300 regulates p63 transcriptional activity.

The transcriptional co-activator p300 has been reported to regulate the tumor suppressor p53 and its ortholog p73. Here we describe a study showing that this coactivator also regulates the transcriptional function of p63. p300 bound to the N-terminal domain of p63gamma, and p63gamma bound to the N terminus of p300 in vitro and in cells.

Gene disruption by regulated short interfering RNA expression, using a two-adenovirus system.

Specific gene ablation by RNA inference (RNAi) involves the binding of short interfering RNA (siRNA), 21 to 22 nucleotides long, to complementary mRNA sequences, leading to sequence-specific posttranslational gene silencing, thus providing a powerful tool for studying gene function with potential therapeutic applications. Here we describe the development of a two-vector adenovirus system for efficient, tightly controlled hairpin siRNA expression (shRNA). Regulated expression of the shRNA is conferred within an adenoviral vector by a modified RNA polymerase III promoter containing a Tet operator element adjacent to the transcription start site.

Ionizing radiation induces frequent translocations with delayed replication and condensation.

Certain chromosome rearrangements display a significant delay in replication timing that is associated with a delay in mitotic chromosome condensation. Chromosomes with delay in replication timing/delay in mitotic chromosome condensation participate in frequent secondary rearrangements, indicating that cells with delay in replication timing/delay in mitotic chromosome condensation display chromosomal instability. In this report, we show that exposing cell lines or primary blood lymphocytes to ionizing radiation results in chromosomes with the delay in replication timing/delay in mitotic chromosome condensation phenotype, and that the delay in replication timing/delay in mitotic chromosome condensation phenotype occurs predominantly on chromosome translocations.

Silencing of mouse Aprt is a gradual process in differentiated cells.

Mouse Aprt constructs that are highly susceptible to DNA methylation-associated inactivation in embryonal carcinoma cells were transfected into differentiated cells, where they were expressed. Construct silencing was induced by either whole-cell fusion of the expressing differentiated cells with embryonal carcinoma cells or by treatment of the differentiated cells with the DNA demethylating agent 5-aza-2'-deoxycytidine. Induction of silencing was enhanced significantly by the presence of a methylation center fragment positioned upstream of a truncated promoter comprised of two functional Sp1 binding sites.

Regulation of MyoD activity and muscle cell differentiation by MDM2, pRb, and Sp1.

Muscle cell differentiation is controlled by a complex set of interactions between tissue restricted transcription factors, ubiquitously expressed transcription factors, and cell cycle regulatory proteins. We previously found that amplification of MDM2 in rhabdomyosarcoma cells interferes with MyoD activity and consequently inhibits overt muscle cell differentiation (1). Recently, we found that MDM2 interacts with Sp1 and inhibits Sp1-dependent transcription and that pRb can restore Sp1 activity by displacing MDM2 from Sp1 (2).