Problems and paradigms: Dystrophin as a mechanochemical transducer in skeletal muscle

This review is primarily concerned with two key issues in research on dystrophin: (1) how the protein interacts with the plasma membrane of skeletal muscle fibres and (2) how an absence of dystrophin gives rise to Duchenne muscular dystrophy. In relation to the first point, we suggest that the post-translational acylation of dystrophin may contribute to its interaction with the plasma membrane. Regarding the second point, it is generally considered that an absence of dystrophin makes the plasma membrane susceptible to damage by contraction/relaxation cycles. In this connection, we propose that the progressive nature of Duchenne dystrophy, and the phenotypic characteristics of mdx mice, are more consistent with dystrophin functioning as a mechanical transducer that transmits growth stimuli from the enlarging skeleton to the muscle. On the basis of this hypothesis, dystrophin-deficient muscles would be unable to grow at the same rate as the skeleton.     

Cohesin: a critical chromatin organizer in mammalian gene regulation

Cohesins are evolutionarily conserved essential multi-protein complexes that are important for higher-order chromatin organization. They play pivotal roles in the maintenance of genome integrity through mitotic chromosome regulation, DNA repair and replication, as well as gene regulation critical for proper development and cellular differentiation. In this review, we will discuss the multifaceted functions of mammalian cohesins and their apparent functional hierarchy in the cell, with particular focus on their actions in gene regulation and their relevance to human developmental disorders.     

Prime, repair, restore: the active role of chromatin in the DNA damage response

The view of DNA packaging into chromatin as a mere obstacle to DNA repair is evolving. In this review, we focus on histone variants and heterochromatin proteins as chromatin components involved in distinct levels of chromatin organization to integrate them as real players in the DNA damage response (DDR). Based on recent data, we highlight how some of these chromatin components play active roles in the DDR and contribute to the fine-tuning of damage signaling, DNA and chromatin repair. To take into account this integrated view, we revisit the existing access-repair-restore model and propose a new working model involving priming chromatin for repair and restoration as a concerted process. We discuss how this impacts on both genomic and epigenomic stability and plasticity.     

Assembly of transcriptionally active chromatin in vitro: a possible role for topoisomerase II

Some models of in vitro chromatin assembly suggest a biphasic molecular mechanism. The first phase, nucleosome formation, is comprised of the formation of histone-DNA complexes which mature into a canonical nucleosome structure. The second phase represents the process by which these nucleosomes become properly spaced with a regular periodicity on the DNA. In this report, we examine the role of DNA topoisomerases in the latter phase of chromatin assembly. To study this process, we use a Xenopus laevis cell-free extract, which assembles quantitative amounts of chromatin on circular DNA templates, and the type II topoisomerase-specific antitumor drugs VM-26 and endrofloxicin. Our results suggest that nucleosome formation is unaffected by the presence of VM-26 or endrofloxicin. However, periodic spacing of nucleosomes is inhibited significantly by these drugs. In the absence of proper chromatin assembly, circular DNA molecules are processed into nucleoprotein complexes which are transcribed poorly. Taken together, these results indicate that the antitumor drugs VM-26 and endrofloxicin influence gene expression indirectly by blocking the periodic spacing of nucleosomes.     

Monoazido analog of ethidium as a chromatin probe: Binding to DNA

Two photoaffinity analogs of ethidium, 8-azido-3-amino, and 3-azido-8-amino-5-ethyl-6-phenylphenanthridinium chloride, have been used to probe the structure of mammalian chromatin and its interactions with the ethidium moiety. The monoazido analogs were established as suitable probes by comparing their interactions with chromatin and pure DNA prepared from chromatin to those of the parent ethidium bromide. Scatchard analysis of the binding data determined from spectrophotometric titrations showed that the analogs interacted with both nucleic acids in a manner similar to the parent compound. The effect of chromatin proteins on the interaction of the ethidium moiety with intact chromatin was investigated directly. By exposing the noncovalent complex to visible light, the monoazido analog was attached covalently in its interaction sites within chromatin, and the amount of drug bound covalently to DNA was determined for both protein-free DNA and chromatin. Using saturating concentrations of drug, DNA within intact chromatin was found to be associated with only half as much drug as DNA extracted from its protein prior to drug exposure. The distribution of drug bound within chromatin was determined following the attachment of the monoazido analog (by photoactivation) to chromatin that had undergone limited nuclease digestion. Several distinct populations isolated by size fractionation and quantitative measurements revealed that (1) both the core particles and the spacer-containing particles contained bound drug, reflecting high-affinity binding sites; and (2) chromatin particles containing 150 DNA base pairs (putatively nucleosome core structures) contained less total bound drug at high drug concentrations than those particles having intact spacer DNA.     

Terbium as a fluorescent probe for DNA and chromatin.

Terbium reacted with DNA and chromatin to form a complex in which terbium acted as a sensitive fluorescent probe. By measuring the narrow-line emission of Tb-3+ when DNA is selectively excited, the relative amount of Tb-3+ bound to the DNA can be calculated. Terbium was bound to DNA until one Tb-3+ was present for each phosphate group. After this point no more terbium was bound. TbCl3 was bound to chromatin in a linear manner until approximately 0.48 TbCl3 was added for each phosphate group in the chromatin-DNA solution. From these data it appears that 52% of the phosphate groups in chromatin were unavailable for binding. The binding of Tb-3+ to DNA can be reversed by prolonged dialysis against 0.5 M NaCl and chelating agents. The terbium ion is ideal in that it binds DNA tight enough so that completion of the reaction can be assumed but loose enough so that it can be removed by gentle means. Low concentrations of salt (up to 2 mM NaCl) enhance the quantum efficiency. Below pH 3 and above pH 7 the DNA-terbium complex will not form. Between pH 3 and pH 7 the quantum efficiency of the DNA terbium complex increases from either pH to a maximum at pH 5.5 to 5.6. Several biochemical uses for Tb-3+ ion are suggested.     

The role of chromatin proteins in DNA damage recognition and repair Mini-review

The structure of chromatin is the major factor determining the rate and efficiency of DNA repair. Chromatin remodeling events such as rearrangement of nucleosomes and higher order chromatin structures are indispensable features of repair processes. During the last decade numerous chromatin proteins have been identified that preferentially bind to different types of DNA damage. The HMGB proteins, which preferentially interact with DNA intrastrand crosslinks induced by cisplatin, are the archetypal example of such proteins. Several hypothetical models have been proposed describing the role of such damage-binding chromatin proteins. The damage shielding model postulates that binding of chromatin proteins to damaged DNA might disturb damage recognition by repair factors and impair its removal. Alternatively, the damage-recognition/signaling model proposes that the binding of specific chromatin proteins to damaged DNA could serve as a hallmark to be recognized by repair proteins. Additionally, the binding of specific chromatin proteins to damaged DNA could induce chromatin remodeling at the damage site and indirectly affect its repair. This paper aims to critically review current experimental data in relation to such possible roles of chromatin proteins.     

The structure and assembly of active chromatin

Much effort has been expended towards understanding the details of how nucleosomes are established on newly replicated DNA. More recently it has begun to be possible to study the binding of both trans-acting factors and histones to DNA. This review is concerned with an assessment of the current status of this work. In addition, we discuss some of the questions that still need to be addressed in order to understand how trans-acting factors can establish extensive interactions with the DNA of active genes while they are excluded from inactive genes.     

A possible role of chromatin and tightly-bound chromatin proteins on enzyme-catalyzed methylation of DNA

Upon extensive digestion with DNAaseI of placenta chromatin matrix, previously "stripped" from its loosely-bound components by high-salt extraction, a fraction is obtained that contains almost no endogenous DNA methylase activity but whose DNA, if still included in this whole fraction--not if it has been purified to a protein-free condition--is a good substrate for externally added enzyme. This chromatin matrix can even cause a significant stimulation of methylation of single-stranded Micrococcus luteus DNA by placental methylase. In vivo, this phenomenon may have possible counterparts in the existence of highly-methylated regions of chromatin loops that appear to be protected by tightly-bound protein components from digestion of the "stripped loops" with DNAaseI.     

Problems and paradigms: Altering sex ratios: The games microbes play

The male gametes of most organisms lack cytoplasm. Consequently, most cytoplasmic genetic elements are maternally inherited: they cannot be transmitted patrilinnearly. The evolutionary interests of cytoplasmic elements therefore lie in transmission through the female. These elements may thus be in evolutionary conflict with nuclear genes which are transmitted by both sexes. This conflict is manifested in observations of cytoplasmically induced biased sex-ratios. Some cytoplasmic genes avoid this fate by biasing the primary sex ratio towards females, or by inducing parthenogenesis. Others kill male hosts, and either achieve transmission via dispersal, or benefit their clonal relatives in the dead male's female siblings. Still others cause the failure of zygotes resulting from pairings between males carrying specific microbes and females lacking them, causing an increase in the microbes through the sterilisation of non-bearing females. Many, but not all, of these ‘ultra-selfish’ microbes are closely related. Investigations of the significance of their phylogenetic affinities, or lack of them, their adaptability in terms of the methods by which they avoid, or ameliorate, the adverse effects of being in male hosts, and their importance as selective agents in the evolution of invertebrate sex determination systems, provide fertile spheres for future research.