Yuval Garini scite author profile

The simultaneous and unequivocal discernment of all human chromosomes in different colors would be of significant clinical and biologic importance. Whole-genome scanning by spectral karyotyping allowed instantaneous visualization of defined emission spectra for each human chromosome after fluorescence in situ hybridization. By means of computer separation (classification) of spectra, spectrally overlapping chromosome-specific DNA probes could be resolved, and all human chromosomes were simultaneously identified.

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Strange kinetics of single molecules in living cells

Barkai¹,

Garini²,

Metzler³

2012

568

710

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Transient Anomalous Diffusion of Telomeres in the Nucleus of Mammalian Cells

et al. 2009

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We measured individual trajectories of fluorescently labeled telomeres in the nucleus of eukaryotic cells in the time range of 10 À2 -10 4 sec by combining a few acquisition methods. At short times the motion is subdiffusive with hr 2 i $ t and it changes to normal diffusion at longer times. The short times diffusion may be explained by the reptation model and the transient diffusion is consistent with a model of telomeres that are subject to a local binding mechanism with a wide but finite distribution of waiting times. These findings have important biological implications with respect to the genome organization in the nucleus. DOI: 10.1103/PhysRevLett.103.018102 PACS numbers: 87.16.Zg, 05.40.Jc, 87.15.Vv The nucleus of the eukaryotic cell contains tens of thousands of genes ($23 000 in human) organized as chromosomal DNA. This crowded environment contains packed genetic material, RNA transcripts, protein factors, and a variety of nuclear bodies. The genetic information (DNA) can be either replicated to form daughter cells, or transcribed to RNA molecules leading to protein translation. These processes depend on the ability of protein factors to locate and interact with specific DNA sequence within this packed nucleus [1], as well as on the organization and structure of chromatin in the nucleus [2]. Telomeres are the end caps of the linear eukaryotic chromosomes. They play an important role in maintaining chromosome organization and integrity throughout the cell cycle. The telomeres are protected by a number of protein factors that are collectively referred to as shelterin and can bind to either the nuclear envelope, nuclear matrix, or heterochromatin, depending on the cell species [3]. Therefore, studying the dynamics of telomeres can shed light on chromosome dynamics, the role of telomeres in genome organization, and the coordination of physical structures and biological processes in the nucleus [4].Chromosomes occupy specific nuclear volumes referred to as chromosome territories [5], and their motion is highly constrained. The diffusion of telomeres was previously studied on a limited time scale of either minutes [6] or 1-200 sec [7] and exhibited mainly normal constrained diffusion with a heterogeneous diffusion coefficient of 2-6 Â 10 À4 m 2 =s. This is significantly lower than the diffusion of small molecules such as dextran in the nucleus (10-100 m 2 =s), which reflects the dense nature of the nucleus. The dynamics of other nuclear bodies as well as messenger RNAs were also measured [8][9][10] and anomalous diffusion was found for specific DNA loci [11].In this study, we examined the diffusion properties of telomeres in the nucleus in a broad time range of almost 6 orders of magnitude (10 À2 -10 4 sec ). Such a broad time range was employed by combining two different imaging setups on the same microscope. We find that the diffusion is anomalous at short times of $10 À2 -10 3 sec . It changes to normal diffusion at longer time intervals and the diffusion constants are found to have a wide distribution...

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Loss of lamin A function increases chromatin dynamics in the nuclear interior

et al. 2015

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Chromatin is organized in a highly ordered yet dynamic manner in the cell nucleus, but the principles governing this organization remain unclear. Similarly, it is unknown whether, and how, various proteins regulate chromatin motion and as a result influence nuclear organization. Here by studying the dynamics of different genomic regions in the nucleus of live cells, we show that the genome has highly constrained dynamics. Interestingly, depletion of lamin A strikingly alters genome dynamics, inducing a dramatic transition from slow anomalous diffusion to fast and normal diffusion. In contrast, depletion of LAP2α, a protein that interacts with lamin A and chromatin, has no such effect on genome dynamics. We speculate that chromosomal inter-chain interactions formed by lamin A throughout the nucleus contribute to chromatin dynamics, and suggest that the molecular regulation of chromatin diffusion by lamin A in the nuclear interior is critical for the maintenance of genome organization.

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Yuval Garini

Multicolor Spectral Karyotyping of Human Chromosomes

Strange kinetics of single molecules in living cells

Transient Anomalous Diffusion of Telomeres in the Nucleus of Mammalian Cells

Loss of lamin A function increases chromatin dynamics in the nuclear interior

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