Ineke van der Kraan
University of Amsterdam
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Featured researches published by Ineke van der Kraan.
Molecular and Cellular Biology | 2005
Pernette J. Verschure; Ineke van der Kraan; Wim C. de Leeuw; Johan van der Vlag; Anne E. Carpenter; Andrew S. Belmont; Roel van Driel
ABSTRACT Changes in chromatin structure are a key aspect in the epigenetic regulation of gene expression. We have used a lac operator array system to visualize by light microscopy the effect of heterochromatin protein 1 (HP1) α (HP1α) and HP1β on large-scale chromatin structure in living mammalian cells. The structure of HP1, containing a chromodomain, a chromoshadow domain, and a hinge domain, allows it to bind to a variety of proteins. In vivo targeting of an enhanced green fluorescent protein-tagged HP1-lac repressor fusion to a lac operator-containing, gene-amplified chromosome region causes local condensation of the higher-order chromatin structure, recruitment of the histone methyltransferase SETDB1, and enhanced trimethylation of histone H3 lysine 9. Polycomb group proteins of both the HPC/HPH and the EED/EZH2 complexes, which are involved in the heritable repression of gene activity, are not recruited to the amplified chromosome region by HP1α and HP1β in vivo targeting. HP1α targeting causes the recruitment of endogenous HP1β to the chromatin region and vice versa, indicating a direct interaction between the two HP1 homologous proteins. Our findings indicate that HP1α and HP1β targeting is sufficient to induce heterochromatin formation.
EMBO Reports | 2003
Pernette J. Verschure; Ineke van der Kraan; Erik M. M. Manders; Deborah Hoogstraten; Adriaan B. Houtsmuller; Roel van Driel
Most chromatin in interphase nuclei is part of condensed chromatin domains. Previous work has indicated that transcription takes place predominantly at the surface of chromatin domains, that is, in the perichromatin region. It is possible that genes inside chromatin domains are silenced due to inaccessibility to macromolecular components of the transcription machinery. We have tested the accessibility of chromatin domains in nuclei of living cells with proteins and dextrans of different molecular sizes. Our results show that chromatin domains are readily accessible to large macromolecules, including proteins with a molecular weight of several hundred kilodaltons. Therefore, the silencing of genes that are incorporated into such domains is not due to the physical inaccessibility of condensed chromatin domains to transcription factors.
Journal of Cellular Biochemistry | 1996
Marjolein A. Grande; Ineke van der Kraan; Bas van Steensel; Wouter Schul; Hans T M van der Voort; Luitzen de Jong; Roel van Driel
The PML protein is a human growth suppressor concentrated in 10 to 20 nuclear bodies per nucleus (PML bodies). Disruption of the PML gene has been shown to be related to acute promyelocytic leukaemia (APL). To obtain information about the function of PML bodies we have investigated the 3D‐distribution of PML bodies in the nucleus of T24 cells and compared it with the spatial distribution of a variety of other nuclear components, using fluorescence dual‐labeling immunocytochemistry and confocal microscopy. Results show that PML bodies are not enriched in nascent RNA, the splicing component U2‐snRNP, or transcription factors (glucocorticoid receptor, TFIIH, and E2F). These results show that PML bodies are not prominent sites of RNA synthesis or RNA splicing. We found that a large fraction of PML bodies (50 to 80%) is closely associated with DNA replication domains during exclusively middle‐late S‐phase. Furthermore, in most cells that we analysed we found at least one PML body was tightly associated with a coiled body. In the APL cell line NB4, the PML gene is fused with the RARα gene due to a chromosomal rearrangement. PML bodies have disappeared and the PML antigen, i.e., PML and the PML‐RAR fusion protein, is dispersed in a punctated pattern throughout the nucleoplasm. We showed that in NB4 cells the sites that are rich in PML antigen significantly colocalize with sites at which nascent RNA accumulates. This suggests that, in contrast to non‐APL cells, in NB4 cells the PML antigen is associated with sites of transcription. The implications of these findings for the function of PML bodies are consistent with the idea that PML bodies are associated with specific genomic loci.
Journal of Histochemistry and Cytochemistry | 2002
Pernette J. Verschure; Ineke van der Kraan; Jorrit M. Enserink; Martijn J. Moné; Erik M. M. Manders; Roel van Driel
Compartmentalization of the interphase nucleus is an important element in the regulation of gene expression. Here we investigated the functional organization of the interphase nucleus of HeLa cells and primary human fibroblasts. The spatial distribution of proteins involved in transcription (TFIIH and RNA polymerase II) and RNA processing and packaging (hnRNP-U) were analyzed in relation to chromosome territories and large-scale chromatin organization. We present evidence that these proteins are present predominantly in the interchromatin space, inside and between chromosome territories, and are largely excluded by domains of condensed chromatin. We show that they are present throughout the active and inactive X-chromosome territories in primary female fibroblasts, indicating that these proteins can freely diffuse throughout the interchromatin compartment in the interphase nucleus. Furthermore, we established that the in vivo spatial distribution of condensed chromatin in the interphase nucleus does not depend on ongoing transcription. Our data support a conceptually simple model for the functional organization of interphase nuclei.
Biochimica et Biophysica Acta | 1991
Luitzen de Jong; Ineke van der Kraan; Anthony de Waal
Abstract Prolyl 4-hydroxylase modifies only approx. 5% of the hydroxylatable prolyl residues in procollagen at a relatively high rate, after which the rate of further hydroxylation rapidly decreases. This suggests that the probability to exist in a defined hydroxylation-committed conformation differs between the numerous -X-Pro-Gly- sequences in the substrate. The enzyme reaction is characterized by the unusually high k cat /K m ratio of 3 · 10 9 M −1 s −1 . To explain these kinetic features, an extremely high second-order rate constant for the association of enzyme and the subset of rapidly hydroxylated prolyl residues has to be assumed. A two-step mechanism is proposed in which diffusional constraints on the rate of association of prolyl 4-hydroxylase with hydroxylatable prolyl residues can be overcome. Upon encountering a random coil pro-α chain, the dimeric enzyme is first ‘aspecifically’ bound, followed by rapid transfers between different segments of the flexible peptide substrate via fast transitions between ‘aspecific’ single and double bound intermediate states. The rate of the second step, the productive (specific) binding of hydroxylation-committed -X-Pro-Gly- sequences to the active site, can be enhanced significantly by such an, in essence, ‘one-dimensional’ search. This processive mechanism of binding does not necessarily imply many hydroxylation reactions during one encounter between enzyme and a peptide with several substrate sites as suggested previously in a slightly different model (De Waal, A. and De Jong, L. (1988) Biochemistry 27, 150–155).
Journal of Cell Biology | 1999
Pernette J. Verschure; Ineke van der Kraan; Erik M. M. Manders; Roel van Driel
Genes & Development | 2003
Frauke Greil; Ineke van der Kraan; Jeffrey J. Delrow; James F. Smothers; Elzo de Wit; Harmen J. Bussemaker; Roel van Driel; Steven Henikoff; Bas van Steensel
Molecular Biology of the Cell | 1999
Wouter Schul; Ineke van der Kraan; A. Gregory Matera; Roel van Driel; Luitzen de Jong
Experimental Cell Research | 1999
Karin A. Mattern; Ineke van der Kraan; Wouter Schul; Luitzen de Jong; Roel van Driel
Molecular Biology of the Cell | 2007
Julio Mateos-Langerak; Maartje C. Brink; Martijn S. Luijsterburg; Ineke van der Kraan; Roel van Driel; Pernette J. Verschure