5. The contrast between interphase chromatin and mitotic chromosomes

18.5 The contrast between interphase chromatin and mitotic chromosomes

Key terms defined in this section
Chromocenter is an aggregate of heterochromatin from different chromosomes.
Euchromatin comprises all of the genome in the interphase nucleus except for the heterochromatin.
Heterochromatin describes regions of the genome that are permanently in a highly condensed condition, are not transcribed, and are late-replicating. May be constitutive or facultative.

Each chromosome contains a single, very long duplex of DNA. This explains why chromosome replication is semiconservative like the individual DNA molecule. (This would not necessarily be the case if a chromosome carried many independent molecules of DNA.) The single duplex of DNA is folded into a fiber that runs continuously throughout the chromosome. So in accounting for interphase chromatin and mitotic chromosome structure, we have to explain the packaging of a single, exceedingly long molecule of DNA into a form in which it can be transcribed and replicated, and can become cyclically more and less compressed.




Figure 18.9 The sister chromatids of a mitotic pair each consist of a fiber (~30 nm in diameter) compactly folded into the chromosome. Photograph kindly provided by E. J. DuPraw.

Individual eukaryotic chromosomes come into the limelight for a brief period, during the act of cell division. Only then can each be seen as a compact unit. Figure 18.9 is an electron micrograph of a sister chromatid pair, captured at metaphase. (The sister chromatids are daughter chromosomes produced by the previous replication event, still joined together at this stage of mitosis.) Each consists of a fiber with a diameter of ~30 nm and a nubbly appearance. The DNA is 5 V10 more condensed in chromosomes than in interphase chromatin.


During most of the life cycle of the eukaryotic cell, however, its genetic material occupies an area of the nucleus in which individual chromosomes cannot be distinguished. The structure of the interphase chromatin does not change visibly between divisions. No disruption is evident during the period of replication, when the amount of chromatin doubles. Chromatin is fibrillar, although the overall configuration of the fiber in space is hard to discern in detail. The fiber itself, however, is similar or identical to that of the mitotic chromosomes.




Figure 18.10 A thin section through a nucleus stained with Feulgen shows heterochromatin as compact regions clustered near the nucleolus and nuclear membrane. Photograph kindly provided by Edmund Puvion.

Chromatin can be divided into two types of material, which can be seen in the nuclear section of Figure 18.10:



  • In most regions, the fibers are much less densely packed than in the mitotic chromosome. This material is called euchromatin. It has a relatively dispersed appearance in the nucleus, and occupies most of the nuclear region in Figure 18.10.
  • Some regions of chromatin are very densely packed with fibers, displaying a condition comparable to that of the chromosome at mitosis. This material is called heterochromatin. It is typically found at centromeres, but occurs at other locations also. It passes through the cell cycle with relatively little change in its degree of condensation. It forms a series of discrete clumps in Figure 18.10, but often the various heterochromatic regions aggregate into a densely staining chromocenter.

The same fibers run continuously between euchromatin and heterochromatin, which implies that these states represent different degrees of condensation of the genetic material. In the same way, euchromatic regions exist in different states of condensation during interphase and during mitosis. So the genetic material is organized in a manner that permits alternative states to be maintained side by side in chromatin, and allows cyclical changes to occur in the packaging of euchromatin between interphase and division.


The structural condition of the genetic material is correlated with its activity. Heterochromatin is not transcribed; also, it replicates late in S phase. This suggests that condensation of the genetic material is associated with (perhaps is responsible for) its inactivity. Note, however, that the reverse is not true. Active genes are contained within euchromatin; but only a small minority of the sequences in euchromatin are transcribed at any time. So location in euchromatin is necessary for gene expression, but is not sufficient for it.


Because of the diffuse state of chromatin, we cannot directly determine the specificity of its organization. But we can ask whether the structure of the chromosome is ordered. Do particular sequences always lie at particular sites, or is the folding of the fiber into the overall structure a more random event?




Figure 18.11 G-banding generates a characteristic lateral series of bands in each member of the chromosome set. Photograph kindly provided by Lisa Shaffer.

At the level of the chromosome, each member of the complement has a different and reproducible ultrastructure. When subjected to certain treatments and then stained with the chemical dye Giemsa, chromosomes generate a series of G-bands. An example of the human set is presented in Figure 18.11.




Figure 18.12 The human X chromosome can be divided into distinct regions by its banding pattern. The short arm is p and the long arm is q; each arm is divided into larger regions that are further subdivided. This map shows a low resolution structure; at higher resolution, some bands are further subdivided into smaller bands and interbands, e.g. p21 is divided into p21.1, p21.2, and p21.3.

Until the development of this technique, chromosomes could be distinguished only by their overall size and the relative location of the centromere (see later). Now each chromosome can be identified by its characteristic banding pattern. This pattern is reproducible enough to allow translocations from one chromosome to another to be identified by comparison with the original diploid set. Figure 18.12 shows a diagram of the bands of the human X chromosome. The bands are large structures, each ~107 bp of DNA, which could include many hundreds of genes.


The banding technique is of enormous practical use, but the mechanism of banding remains a mystery. All that is certain is that the dye stains untreated chromosomes more or less uniformly. So the generation of bands depends on a variety of treatments that change the response of the chromosome (presumably by extracting the component that binds the stain from the nonbanded regions). But the variety of effective treatments is so great that no common cause yet has been discerned. These results imply the existence of a definite long-range structure, but its basis is unknown.




Genes VII
Genes VII
ISBN: B000R0CSVM
EAN: N/A
Year: 2005
Pages: 382

flylib.com © 2008-2017.
If you may any questions please contact us: flylib@qtcs.net