Article révisé par les pairs
| Résumé : | Our present knowledge of the cell structure, which is largely based on electron microscopy, is compared with what was known a few decades ago, when only light microscopy was available to the cytologist. The importance of cytochemical methods for the detection and localization of macromolecules (nucleic acids, proteins) is stressed. But it is pointed out that further analysis, with biochemical techniques, was required in order to understand the actual mechanisms of macromolecule synthesis in the cell (in particular, the relationships existing between nucleic acids and protein synthesis). The importance of genetical analysis in simple systems such as viruses and bacteria for the development of ‘molecular’ biology is then emphasized: in particular, the work of Avery identifying the ‘transforming principle’ with DNA, of Beadle leading to the ‘one gene, one enzyme’ theory, of the virologists who demonstrated that it is the nucleic acid component of viruses which carries the genetical information, have been of fundamental importance for the development of modern biology. No less important has been the work of the X‐ray crystallographers (Crick and Watson, Perutz, Kendrew, etc.) who established the fine structure of nucleic acids and of proteins. A brief review and a schematic representation of present ideas regarding the control exerted by DNA on the synthesis of specific proteins are then given: the main characteristics of the different kinds of RNA's, their interactions for the formation of polysomes, the role of the latter in protein synthesis, the main principles of the genetic codes, are briefly summarized. But cells are, in many respects, more complicated than bacteria. The concepts of molecular biology cannot be applied to cell differentiation without a recognition of the greater complexity of animal and plant cells. They represent, however, a most useful and powerful guide for research in that area: for instance, many aspects of morphogenesis in the unicellular alga Acetabularia and in amphibian eggs can be explained on the assumption that messenger RNA's are produced by the nucleus and stored, in a stabilized form, in the cytoplasm during days or even weeks. This stability of messenger RNA's in eggs and algae is at variance with their short life in bacteria. The behaviour of non‐nucleate fragments of Acetabularia is surprising in many respects: they are the site, not only of the synthesis of specific proteins, but even of RNA and DNA net synthesis. Such a synthesis of macromolecules, in the absence of the nucleus is probably linked to the presence of the chloroplasts in this alga: they contain DNA, can synthesize RNA and proteins, and can even increase in number in the absence of the nucleus. The presence of large amounts of DNA in the cytoplasm of many animal eggs raises a number of questions and might account for the extremely important role of the cytoplasm in the very early stages of embryonic development. It is concluded that none of the great problems of cell biology will be solved without the help of the techniques and the theoretical ideas which have been so fruitful for the simpler systems used by the molecular biologists. Copyright © 1968, Wiley Blackwell. All rights reserved |
