4D Visualization of replication foci in mammalian cells corresponding to individual replicons.

Since the pioneering proposal of the replicon model of DNA replication 50 years ago, the predicted replicons have not been identified and quantified at the cellular level. Here, we combine conventional and super-resolution microscopy of replication sites in live and fixed cells with computational image analysis. We complement these data with genome size measurements, comprehensive analysis of S-phase dynamics and quantification of replication fork speed and replicon size in human and mouse cells. These multidimensional analyses demonstrate that replication foci (RFi) in three-dimensional (3D) preserved somatic mammalian cells can be optically resolved down to single replicons throughout S-phase. This challenges the conventional interpretation of nuclear RFi as replication factories, that is, the complex entities that process multiple clustered replicons. Accordingly, 3D genome organization and duplication can be now followed within the chromatin context at the level of individual replicons.

3D replicon distributions arise from stochastic initiation and domino-like DNA replication progression.

DNA replication dynamics in cells from higher eukaryotes follows very complex but highly efficient mechanisms. However, the principles behind initiation of potential replication origins and emergence of typical patterns of nuclear replication sites remain unclear. Here, we propose a comprehensive model of DNA replication in human cells that is based on stochastic, proximity-induced replication initiation. Critical model features are: spontaneous stochastic firing of individual origins in euchromatin and facultative heterochromatin, inhibition of firing at distances below the size of chromatin loops and a domino-like effect by which replication forks induce firing of nearby origins. The model reproduces the empirical temporal and chromatin-related properties of DNA replication in human cells. We advance the one-dimensional DNA replication model to a spatial model by taking into account chromatin folding in the nucleus, and we are able to reproduce the spatial and temporal characteristics of the replication foci distribution throughout S-phase.

Measurement of replication structures at the nanometer scale using super-resolution light microscopy.

DNA replication, similar to other cellular processes, occurs within dynamic macromolecular structures. Any comprehensive understanding ultimately requires quantitative data to establish and test models of genome duplication. We used two different super-resolution light microscopy techniques to directly measure and compare the size and numbers of replication foci in mammalian cells. This analysis showed that replication foci vary in size from 210 nm down to 40 nm. Remarkably, spatially modulated illumination (SMI) and 3D-structured illumination microscopy (3D-SIM) both showed an average size of 125 nm that was conserved throughout S-phase and independent of the labeling method, suggesting a basic unit of genome duplication. Interestingly, the improved optical 3D resolution identified 3- to 5-fold more distinct replication foci than previously reported. These results show that optical nanoscopy techniques enable accurate measurements of cellular structures at a level previously achieved only by electron microscopy and highlight the possibility of high-throughput, multispectral 3D analyses.

[High resolution analysis of replication foci by conventional fluorescent microscopy. I. A study of complexity and DNA content of the foci]. / Issledovanie fokusov replikatsii pri vysokom razreshenii metodom shirokopol'noi fluoreschentnoi mikroskopii. I. Analyz kompleksnosti i soderzhaniia DNK v fokusakh.

Newly replicated DNA segments (RDS) have been shown to form discrete foci in the mammalian nucleus. Comparison of the number of such foci in formaldehyde-fixed cell nucleus with estimated number of simultaneously active replication forks (RF) suggests that each replication focus contains a cluster of about 10 to 20 closely associated RF. That implied the cluster of synchronously activated replicons as the primary unit of mammalian DNA replication. It still remains unclear whether such clustering of RF does mean adjacency of the replicons in a genomic location (structural clustering, model 1), or it arises from transient clustering of the replicons from different DNA domains at the functioning replication machinery (functional clustering, model 2). In this study we used conventional fluorescence microscopy of the hypotonically treated nuclei preparations to investigate replication foci at the optical resolution limit. Human K562 cells were labeled with 5'-iododeoxyuridine for different time periods. We synchronized the cell culture with hydroxyurea to be able to measure an average increase in DNA content during labeling period using DNA cytometry. Under these conditions, RDS appear as multiple small foci (mini-foci, MF). Further studies revealed that most of such mini-foci of replication represent optical diffraction spots, which are standard in size and different in brightness. The number of the "spots" and variation of their brightness mostly depend on the extent of hypotonic treatment. Flow cytometry control of the synchronized cells peak movement allowed us to measure mean DNA content of the MF. In case of most effective hypotonic treatment, a MF contains about 40 Kbp of labeled DNA, and the general number of the MF approaches the number of replicons that are simultaneously active in a given moment of S-phase. Influence of the effect of hypotonic treatment on overall number of observed MF suggests that replication foci in early and mid S-phase cells do not represent stable structures, but rather arise from functional clustering of comparatively distant replicating regions, thus supporting model 2.

[Organization of DNA replication domains in S-phase nuclei of human cells]. / Organizatsiia replikativnykh domenov DNK v S-faznykh iadrakh kletok cheloveka.

Each chromosome of eukaryotic cells contains multiple units of DNA replication that are activated during S-phase of cell cycle according to a definite program. It is considered at present that the main independent units of replication in mammalian cells represent groups of 20-25 adjacent synchronously activated small (with the average size 100 kbp) replicons. After labelling of nascent DNA with nonradioactive DNA precursors and immunofluorescent staining of incorporated label, discrete replication domains (RDs) are detected in S-phase nuclei. It is assumed that each RD is formed by a single group of synchronously activated small replicons. Since the average rate of replication fork movement is 2 kbp/min, a group of small replicons should finish DNA synthesis within 25 min, and only during this time one RD should incorporate the replicative label. We have studied the duration of DNA synthesis in individual RDs in S-phase human cells using double replicative labelling that can be detected in the nucleus by specific reagents. Our results indicate that in the main fraction of RDs DNA synthesis lasts more than 90 min, that contradicts the generally accepted model of organization of replication units in mammalian cells (Hand, 1978), but is in agreement with an alternative model, according to which the main replication units are single or clustered big replicons more than 300 kbp in size (Liapunova, 1994).