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How the genome is organized in the three-dimensional space of the cell nucleus influences the activity of gene expression. Finn and Misteli review features of genome architecture and cell- and allele-specific variability in spatial genome organization. They also connect stochasticity in gene transcription and variability in genome organization and discuss the functional consequences of genome variability at the cell and population levels in development and disease. Science , this issue p. eaaw9498 The complex three-dimensional organization of genomes in the cell nucleus arises from a wide range of architectural features including DNA loops, chromatin domains, and higher-order compartments. Although these features are universally present in most cell types and tissues, recent single-cell biochemistry and imaging approaches have demonstrated stochasticity in transcription and high variability of chromatin architecture in individual cells. We review the occurrence, mechanistic basis, and functional implications of stochasticity in genome organization. We summarize recent observations on cell- and allele-specific variability of genome architecture, discuss the nature of extrinsic and intrinsic sources of variability in genome organization, and highlight potential implications of structural heterogeneity for genome function.

The eukaryotic cell nucleus provides a home for the genetic material and accessory proteins. As a physical entity, the nucleus also plays an important role in cell dynamics. Bustin and Misteli Review the impacts that the nucleus can have as a nongenetic force. For example, compacted DNA and the nuclear membrane affect nuclear morphology, the cellular response to mechanical force, cell migration, and cell signaling. Chromatin is not only affected by physical forces in cells but participates in a crosstalk of signaling inside cells. Science , this issue p. 10.1126/science.aad6933 The primary function of the genome is to store, propagate, and express the genetic information that gives rise to a cell’s architectural and functional machinery. However, the genome is also a major structural component of the cell. Besides its genetic roles, the genome affects cellular functions by nongenetic means through its physical and structural properties, particularly by exerting mechanical forces and by serving as a scaffold for binding of cellular components. Major cellular processes affected by nongenetic functions of the genome include establishment of nuclear structure, signal transduction, mechanoresponses, cell migration, and vision in nocturnal animals. We discuss the concept, mechanisms, and implications of nongenetic functions of the genome.

Repair of a chromosome break can result in part of a chromosome attaching to a different chromosome, causing gene deregulation and disease. Roukos and Misteli discuss the spatial aspect of chromosome translocation and the role of DNA repair pathways in this process. Chromosome translocations are catastrophic genomic events and often play key roles in tumorigenesis. Yet the biogenesis of chromosome translocations is remarkably poorly understood. Recent work has delineated several distinct mechanistic steps in the formation of translocations, and it has become apparent that non-random spatial genome organization, DNA repair pathways and chromatin features, including histone marks and the dynamic motion of broken chromatin, are critical for determining translocation frequency and partner selection.

Key Points DNA repair occurs in the context of higher-order chromatin structure. The assembly of the DNA-repair machinery on damaged chromatin is a spatially and temporally highly coordinated event. Sites of DNA repair manifest themselves as DNA-repair foci, which form as a consequence of the accumulation of repair factors at sites of damage and serve to amplify the damage signal. Histone modifications, histone exchange and chromatin remodelling are essential steps in DNA repair. In mammalian cells, double-stranded DNA breaks (DSBs) are positionally stable and do not migrate in the nuclear space. In yeast, DSBs can migrate and multiple DSBs coalesce in repair centres. The non-random spatial organization of the genome contributes to the translocation frequency of chromosomes in vivo . DNA repair occurs in the context of nuclear architecture. Assembly of the repair machinery on damaged chromatin and the ensuing signalling events require tight spatial and temporal coordination. Higher-order chromatin structure, chromatin dynamics and non-random global genome organization also influence genome maintenance. DNA repair and maintenance of genome stability are crucial to cellular and organismal function, and defects in these processes have been implicated in cancer and ageing. Detailed molecular, biochemical and genetic analyses have outlined the molecular framework involved in cellular DNA-repair pathways, but recent cell-biological approaches have revealed important roles for the spatial and temporal organization of the DNA-repair machinery during the recognition of DNA lesions and the assembly of repair complexes. It has also become clear that local higher-order chromatin structure, chromatin dynamics and non-random global genome organization are key factors in genome maintenance. These cell-biological features of DNA repair illustrate an emerging role for nuclear architecture in multiple aspects of genome maintenance.

What makes a stem cell is still poorly understood. Recent studies have uncovered that chromatin might hold some of the keys to how embryonic stem cells maintain their pluripotency, their ability to self-renew and induce lineage specification. Embryonic stem (ES) cells are unique in that they are pluripotent and have the ability to self-renew. The molecular mechanisms that underlie these two fundamental properties are largely unknown. We discuss how unique properties of chromatin in ES cells contribute to the maintenance of pluripotency and the determination of differentiation properties.

Mutations in the nuclear structural protein lamin A cause the premature aging syndrome Hutchinson-Gilford progeria (HGPS). Whether lamin A plays any role in normal aging is unknown. We show that the same molecular mechanism responsible for HGPS is active in healthy cells. Cell nuclei from old individuals acquire defects similar to those of HGPS patient cells, including changes in histone modifications and increased DNA damage. Age-related nuclear defects are caused by sporadic use, in healthy individuals, of the same cryptic splice site in lamin A whose constitutive activation causes HGPS. Inhibition of this splice site reverses the nuclear defects associated with aging. These observations implicate lamin A in physiological aging.

The cellular DNA damage response (DDR) is initiated by the rapid recruitment of repair factors to the site of DNA damage to form a multiprotein repair complex. How the repair complex senses damaged DNA and then activates the DDR is not well understood. We show that prolonged binding of DNA repair factors to chromatin can elicit the DDR in an ATM (ataxia telangiectasia mutated)- and DNAPK (DNA-dependent protein kinase)-dependent manner in the absence of DNA damage. Targeting of single repair factors to chromatin revealed a hierarchy of protein interactions within the repair complex and suggests amplification of the damage signal. We conclude that activation of the DDR does not require DNA damage and stable association of repair factors with chromatin is likely a critical step in triggering, amplifying, and maintaining the DDR signal.

The human genome is non-randomly organized within the cell nucleus. Spatial mapping of genome folding by biochemical methods and imaging has revealed extensive variation in locus interaction frequencies between cells in a population and between homologs within an individual cell. Commonly used mapping approaches typically examine either the relative position of genomic sites to each other or the position of individual loci relative to nuclear landmarks. Whether the frequency of specific chromatin-chromatin interactions is affected by where in the nuclear space a locus is located is unknown. Here, we have simultaneously mapped at the single cell level the interaction frequencies and radial position of more than a hundred locus pairs using high-throughput imaging to ask whether the location within the nucleus affects interaction frequency. We find strong enrichment of many interactions at specific radial positions. Position-dependency of interactions was cell-type specific, correlated with local chromatin type, and cell-type-specific enriched associations were marked by increased variability, sometimes without a significant decrease in mean spatial distance. These observations demonstrate that the folding of the chromatin fiber, which brings genomically distant loci into proximity, and the position of that chromatin fiber relative to nuclear landmarks, are closely linked.

Hutchinson-Gilford progeria syndrome (HGPS) is a childhood premature aging disease caused by a spontaneous point mutation in lamin A (encoded by LMNA ), one of the major architectural elements of the mammalian cell nucleus 1 , 2 , 3 , 4 . The HGPS mutation activates an aberrant cryptic splice site in LMNA pre-mRNA, leading to synthesis of a truncated lamin A protein and concomitant reduction in wild-type lamin A 3 , 4 . Fibroblasts from individuals with HGPS have severe morphological abnormalities in nuclear envelope structure. Here we show that the cellular disease phenotype is reversible in cells from individuals with HGPS. Introduction of wild-type lamin A protein does not rescue the cellular disease symptoms. The mutant LMNA mRNA and lamin A protein can be efficiently eliminated by correction of the aberrant splicing event using a modified oligonucleotide targeted to the activated cryptic splice site. Upon splicing correction, HGPS fibroblasts assume normal nuclear morphology, the aberrant nuclear distribution and cellular levels of lamina-associated proteins are rescued, defects in heterochromatin-specific histone modifications are corrected and proper expression of several misregulated genes is reestablished. Our results establish proof of principle for the correction of the premature aging phenotype in individuals with HGPS.