Project description:This SuperSeries is composed of the SubSeries listed below.

Project description:Progeroid syndromes are rare genetic disorders that phenotypically resemble natural aging. Despite identification of causal mutations, mechanisms that generate their clinical manifestations remain elusive. Here, we identified a DNA replication timing (RT) signature that distinguishes progeroid syndromes from normal aging and identifies TP63 gene as a new disease marker. Abnormal TP63 RT appears early during differentiation of progeroid iPSCs and is associated with altered gene variant expression. Our findings demonstrate the utility of RT signatures to identify novel biomarkers not detected by other methods, reveal abnormal TP63 RT as an early event in progeroid disease progression and offer TP63 gene regulation as a potential therapeutic target.

Project description:Progeroid syndromes are rare genetic disorders that phenotypically resemble natural aging. Despite identification of causal mutations, mechanisms that generate their clinical manifestations remain elusive. Here, we identified a DNA replication timing (RT) signature that distinguishes progeroid syndromes from normal aging and identifies TP63 gene as a new disease marker. Abnormal TP63 RT appears early during differentiation of progeroid iPSCs and is associated with altered gene variant expression. Our findings demonstrate the utility of RT signatures to identify novel biomarkers not detected by other methods, reveal abnormal TP63 RT as an early event in progeroid disease progression and offer TP63 gene regulation as a potential therapeutic target.

Project description:Alterations in DNA replication timing identify TP63 as a novel marker of progeroid diseases

Project description:DNA replication timing alterations in genetic diseases

Project description:DNA replication timing alterations in genetic diseases

Project description:Duplication of the genome in mammalian cells occurs in a defined temporal order referred as its replication-timing program (RT). RT is regulated in units of 400-800 Kb referred as replication domains (RDs) and changes dynamically during development. Changes in RT are generally coordinated with transcriptional competence and changes in sub-nuclear position. We generated genome-wide RT profiles for 29 distinct human cell types including embryonic stem cell (hESC)-derived, primary cells and established cell lines representing intermediate stages of endoderm, mesoderm, ectoderm and neural crest (NC) development. We identified clusters of RDs that replicate at unique times in each stage (RT signatures). Surprisingly, transcriptome data revealed that, despite an overall correlation between early replication and transcriptional activity, most genes that switched RT during differentiation can be expressed when late replicating. Intriguingly, this class of genes was nonetheless induced to high expression levels prior to a late to early RT switch and down-regulated after the switch back to late replication. These results clarify the complex relationship between transcription and RT and identify classes of genes that behave as potential drivers of the RT switch vs. those that may depend upon an RT switch for transcriptional induction. Genome-wide replication timing profiles were constructed from 60 human samples covering 29 distinct cell types including embryonic stem cell (hESC)-derived, primary cells and established cell lines representing intermediate stages of endoderm, mesoderm, ectoderm and neural crest (NC) development.

Project description:Human B-cell precursor acute lymphoid leukemias (BCP-ALLs) comprise a group of genetically and clinically distinct disease entities with features of differentiation arrest at known stages of normal B-lineage differentiation. We previously showed that BCP-ALL cells display unique and clonally heritable, stable DNA replication timing (RT) programs (ie, programs describing the variable order of replication and subnuclear 3D architecture of megabase-scale chromosomal units of DNA in different cell types). To determine the extent to which BCP-ALL RT programs mirror or deviate from specific stages of normal human B-cell differentiation, we transplanted immunodeficient mice with quiescent normal human CD34+ cord blood cells and obtained RT signatures of the regenerating B-lineage populations. We then compared these with RT signatures for leukemic cells from a large cohort of BCP-ALL patients with varied genetic subtypes and outcomes. The results identify BCP-ALL subtype-specific features that resemble specific stages of B-cell differentiation and features that seem to be associated with relapse. These results suggest that the genesis of BCP-ALL involves alterations in RT that reflect biologically significant and potentially clinically relevant leukemia-specific epigenetic changes.

Project description:Genomic DNA replicates in a choreographed temporal order that impacts the distribution of mutations along the genome. We show here that DNA replication timing is shaped by genetic polymorphisms that act in cis upon megabase-scale DNA segments. In genome sequences from proliferating cells, read depth along chromosomes reflected DNA replication activity in those cells. We used this relationship to analyze variation in replication timing among 161 individuals sequenced by the 1000 Genomes Project. Genome-wide association of replication timing with genetic variation identified 16 loci at which inherited alleles associate with replication timing. We call these "replication timing quantitative trait loci" (rtQTLs). rtQTLs involved the differential use of replication origins, exhibited allele-specific effects on replication timing, and associated with gene expression variation at megabase scales. Our results show replication timing to be shaped by genetic polymorphism and identify a means by which inherited polymorphism regulates the mutability of nearby sequences.

Project description:Eukaryotic genomes are replicated in a reproducible temporal order; however, the physiological significance is poorly understood. We compared replication timing in divergent yeast species and identified genomic features with conserved replication times. Histone genes were among the earliest replicating loci in all species. We specifically delayed the replication of HTA1-HTB1 and discovered that this halved the expression of these histone genes. Finally, we showed that histone and cell cycle genes in general are exempt from Rtt109-dependent dosage compensation, suggesting the existence of pathways excluding specific loci from dosage compensation mechanisms. Thus, we have uncovered one of the first physiological requirements for regulated replication time and demonstrated a direct link between replication timing and gene expression.