The cytoplasmic control of nuclear activity in animal development.

Abstract

Summary1.This article reviews the occurrence, mechanism, and functional significance of the cytoplasmic regulation of nuclear activity during cell differentiation and especially during early animal development.2.Nuclei from brain, and from other kinds of adult cell normally inactive in DNA synthesis, are rapidly induced to commence DNA synthesis by components or properties of intact egg cytoplasm.The components of egg cytoplasm which induce DNA synthesis are not species‐specific and they are likely to include DNA polymerase. It is known that DNA polymerase exists in egg cytoplasm before it becomes associated with nuclei in which it is effective.The induction of DNA synthesis in brain nuclei by living egg cytoplasm is always preceded by a pronounced nuclear swelling, a dispersion of chromosomes or chromatin, and the entry of cytoplasmic protein into the nucleus.3.RNA synthesis can be experimentally induced or repressed by living cytoplasm. The cytoplasm of unfertilized and fertilized eggs appears to contain components which can reversibly and independently repress the synthesis of ribosomal RNA, transfer RNA, and heterogeneous RNA. RNA synthesis can be induced by introducing nuclei inactive in this respect into the cytoplasm of cells very active in RNA synthesis. The induction and repression of RNA synthesis is preceded by a marked swelling of the nucleus and the dispersion of its chromosome material.4.The cytoplasmic control of chromosome condensation before division has been demonstrated by introducing sperm or adult brain nuclei into the cytoplasm of oocytes undergoing meiotic maturation.5.The evidence that regional differences in the composition of eggs and other cells are associated with changes in nuclear and gene activity is reviewed in Section 111. While it is certain that these regional differences are of great importance in cell differentiation, evidence that they have a direct effect on nuclear activity has been obtained in a few instances only.In some species it has been shown that the cytoplasmic components related to germ‐cell differentiation include RNA and, frequently, granules.6.It is concluded that whenever nuclei are introduced experimentally into the cytoplasm of another cell, they very quickly assume, in nearly every respect, the nuclear activity characteristic of the host cell. In many instances, altered function has been demonstrated in nuclei which subsequently support normal development. The induced nuclear changes are therefore regarded as normal and it is believed that they are achieved through the same mechanism as that by which the host cell nucleus originally came to function in its characteristic way.Examples are cited to show that changes in gene activity very frequently arise immediately after mitosis. The changes induced experimentally in transplanted nuclei resemble in very many respects those undergone by nuclei which are naturally reconstituted after mitosis, and it is argued that the two processes are functionally equivalent,It is suggested that during telophase of mitosis, chromosomes are reprogrammed in respect of potential gene activity by association with cytoplasmic proteins. Inter‐phase nuclei seem not to show changes of gene activity except when they undergo a pronounced enlargement after entering a new cytoplasmic environment.