Chromatin replication.

Just as the faithful replication of DNA is an essential process for the cell, chromatin structures of active and inactive genes have to be copied accurately. Under certain circumstances, however, the activity pattern has to be changed in specific ways. Although analysis of specific aspects of these complex processes, by means of model systems, has led to their further elucidation, the mechanisms of chromatin replication in vivo are still controversial and far from being understood completely. Progress has been achieved in understanding: 1. The initiation of chromatin replication, indicating that a nucleosome-free origin is necessary for the initiation of replication; 2. The segregation of the parental nucleosomes, where convincing data support the model of random distribution of the parental nucleosomes to the daughter strands; and 3. The assembly of histones on the newly synthesized strands, where growing evidence is emerging for a two-step mechanism of nucleosome assembly, starting with the deposition of H3/H4 tetramers onto the DNA, followed by H2A/H2B dimers.     

Chromatin goes global.

The latest findings on the structure of chromatin, its organization in the nucleus, and its involvement in regulating gene expression were presented at a recent meeting at the Juan March Foundation in Madrid, Spain.     

Chromatin,Chromosomen, Gene

Ohne Zusammenfassung     

Chromatin fibers,one-at-a-time

Eukaryotic DNA is presented to the enzymatic machineries that use DNA as a template in the form of chromatin fibers. At the first level of organization, DNA is wrapped around histone octamers to form nucleosomal particles that are connected with stretches of linker DNA; this beads-on-a-string structure folds further to reach a very compact state in the nucleus. Chromatin structure is in constant flux, changing dynamically to accommodate the needs of the cell to replicate, transcribe, and repair the DNA, and to regulate all these processes in time and space. The more conventional biochemical and biophysical techniques used to study chromatin structure and dynamics have been recently complemented by an array of single-molecule approaches, in which chromatin fibers are investigated one-at-a-time. Here we describe single-molecule efforts to see nucleosomes, touch them, put them together, and then take them apart, one-at-a-time. The beginning is exciting and promising, but much more effort will be needed to take advantage of the huge potential that the new physics-based techniques offer.     

Chromatin and nucleosome structure.

Chromatin nucleosomes (mononucleosomes through pentanucleosomes) have been isolated by staphylococcal nuclease digestion of calf thymus nuclei. The peak value ellipticity is the same for all oligomers, 1900 deg cm2, mol-1 at 280-nm, 23 degrees C. The dh280/dT vs T show a progressive increase in Tm of the main thermal band (73.5 degrees C, monomer; 79 degrees C, pentamer). Very small amounts of free DNA can be observed in the melting profiles, and shoulders at 60 degrees C and 93 degrees C appear and increase in magnitude as the particle size increases. The magnitude of the change, delta[theta]280, increases with oligomer size. This pattern could result from an initial unfolding of an asymmetric assembly of nucleosomes (polynucleosome superhelix) in addition to the denaturation of the internal nucleosome structure, and a subsequent or simultaneous denaturation of the double strand DNA. The extent of this unfolding appears to depend upon the size of the oligomer and therefore implies interactions between asymmetrically assembled neighboring nucleosomes.     

Chromatin structure in Down's syndrome.

In the chromatin of patients with Down's syndrome, changes are shown to occur in a short-term lymphocyte culture of the human peripheral blood. Some of them are induced by the patient's blood serum and are reversible when this is replaced by normal serum. A 100-fold dilution of the blood serum taken in subjects with Down's syndrome does not produce any changes in the structure of the lymphocyte chromatin of the patients. A similar procedure with the blood serum of healthy donors resulted in a drastic activation of their lymphocyte chromatin. These experiments, and investigations on the effect produced by the blood serum on the model desoxyribonucleoprotein systems, support the suggestion that the changed state of the chromatin in subjects with Down's syndrome is caused by a complex set of components contained in the blood serum, whose degree of dissociation deviates from the normal.     

Chromatin nu bodies: isolation, subfractionation and physical characterization.

Monomer chromatin subunit particles (nu1) have been isolated in gram quantities by large-scale zonal centrifugation of micrococcal nuclease digests of chicken erythrocyte nuclei. nu1 can be stored, apparently indefinitely, frozen in 0.2 mM EDTA (pH 7.0) at less than or equal to 25 degrees C. Aliquots of the stored monomers have been subfractionated by dialysis against 0.1 M KCl buffers into a soluble fraction containing equimolar amounts of H4, H3, H2A, H2B associated with a DNA fragment of approximately 130-140 nucleotide pairs, and a precipitated fraction containing all of the histones including H5 and H1 associated with DNA fragments. The total nu1 and the KCl-soluble fraction of nu1 have been examined by sedimentation, diffusion, sedimentation equilibrium ultracentrifugation, low-angle X-ray diffraction, and electron microscopy. Physical parameters from all of these techniques are presented and correlated in this study.     

Chromatin remodeling in mammalian zygotes.

With sperm-egg fusion at the time of fertilization the gamete nuclei are remodeled from genetically quiescent structures into pronuclei capable of DNA synthesis. Features of this process that are critical to insure the genetic integrity of the zygote and the success of subsequent embryonic development include: oocyte responses that prevent polyspermy; completion of the 2nd meiotic division by the oocyte; exchange of proteins in the sperm nucleus; and, remodelling of the oocyte chromosomes and sperm nucleus into functional pronuclei. Elucidation of the biological and molecular mechanisms underlying zygote formation and chromatin remodeling should enhance our understanding of the potential vulnerability of the zygote to toxicant-induced damage.     

Chromatin, epigenetics and stem cells

Epigenetics is a term that has changed its meaning with the increasing biological knowledge on developmental processes. However, its current application to stem cell biology is often imprecise and is conceptually problematic. This article addresses two different subjects, the definition of epigenetics and chromatin states of stem and differentiated cells. We describe mechanisms that regulate chromatin changes and provide an overview of chromatin states of stem and differentiated cells. Moreover, a modification of the current epigenetics definition is proposed that is not restricted by the heritability of gene expression throughout cell divisions and excludes translational gene expression control.