Analysis of the chromatin assembled in germinal vesicles of Xenopus oocytes

We have injected circular DNA, labeled with 32P at a single restriction site, into germinal vesicles of Xenopus laevis oocytes in order to study the nucleosome arrangement on the assembled minichromosomes. Two types of genes were used in these studies, the somatic 5 S RNA gene unit of Xenopus borealis and the histone gene unit of Drosophila melanogaster. We find that injections of labeled DNA alone, at 1 ng DNA per oocyte, results in irregularly spaced nucleosomes and partially supercoiled DNA molecules. However, perfectly spaced nucleosomes are assembled and fully supercoiled DNA is recovered if 5 to 20 nanograms of cold vector DNA is coinjected with the labeled DNA. At the optimum chromatin assembly conditions, the nucleosomes are perfectly spaced with a 180 base-pair periodicity, but they are randomly positioned on the DNA. The assembly of a periodic chromatin structure is accompanied by a dramatic enhancement in the expression of the injected 5 S RNA gene.     

Assembly of transcriptionally active chromatin in Xenopus oocytes requires specific DNA binding factors

Active minichromosomes assembled on injected 5S RNA gene clones are stable in Xenopus oocytes; endogenous 5S DNA specific factor(s) are required for their assembly. When somatic-type and oocyte-type 5S RNA gene clones are coinjected, the somatic genes are assembled into active minichromosomes, while most of the oocyte genes are assembled into inactive ones. The differential 5S RNA gene expression, which mimics that in somatic cells, appears to result from titration of 5S DNA specific factor(s) by the competing somatic 5S DNA, followed by histone mediated assembly of inactive chromatin on the oocyte 5S DNA. Stable minichromosomes are also assembled on a cloned histone H4 gene; again, intragenic DNA rearrangements affect the efficiency of assembly of active chromatin and differential gene expression occurs after coinjection of two or more H4 DNA constructs. We suggest that the H4 DNA molecules also compete for limiting quantities of specific DNA binding factor(s) required for the assembly of active H4 gene chromatin.     

Structure of the two distinct types of minichromosomes that are assembled on DNA injected in Xenopus oocytes

DNA injected into germinal vesicles of Xenopus oocytes is assembled into two distinct types of minichromosomes. One type is soluble and behaves like conventional nucleosomal chromatin. The other type is insoluble, is sensitive to DNAase I and to micrococcal nuclease, lacks a canonical nucleosome repeat, and generates a half-nucleosome size limit digest with micrococcal nuclease. We suggest that these peculiar minichromosomes may be the ones that display the unconstrained, "dynamic" DNA supercoils in the living oocyte.     

Mechanism of chromatin assembly in Xenopus oocytes

We have analyzed the chromatin assembly reaction catalyzed by the Xenopus oocyte extract (S-150). A 50 S complex is formed upon mixing the 17 S pUC DNA and the S-150. Mature histones are not detected in this complex, which contains relaxed DNA and protein, and generates subnucleosomal 7 S particles upon digestion with micrococcal nuclease. The relaxed nucleoprotein is gradually supercoiled into nucleosomal chromatin in the S-150, via a pathway that requires ATP and is blocked by novobiocin, and this process is accompanied by the appearance of mature histones H3 and H4. Isolated complexes also supercoil in vitro, which implies the complex is a kit that contains histone precursors, as well as topoisomerases and other enzymes required for assembly. We discuss the biological implications of these findings.     

Minichromosome assembly accompanying repair-type DNA synthesis in Xenopus oocytes.

Minichromosomes were assembled by injection of circular DNA into the nucleus of Xenopus oocytes. We observed that, in the course of DNA supercoiling and chromatin assembly, a small percentage of the injected DNA molecules incorporated a radioactive precursor. This DNA synthesis was carried out by aphidicolin-sensitive DNA polymerase, and generated short repair-like patches covalently linked to the injected DNA. We found that the DNA thus repaired was rapidly supercoiled almost to completion within 15 to 30 min after injection, whereas 60 to 120 min were required to supercoil the intact, bulk DNA molecules. Such differential supercoiling kinetics was also observed when UV-damaged DNA was injected. Chromatin assembly, which was characterized by DNA fragment sizes protected from micrococcal nuclease digestion, was consistent with the rapid DNA supercoiling and proceeded more efficiently on the repaired DNA. These results indicate that there are at least two kinetically distinct ways of assembling minichromosomes in the oocyte nucleus, and that the repaired DNA molecules preferentially follow the faster pathway.     

Assembly of SV40 chromatin in a cell-free system from Xenopus eggs.

A cell-free system is described which assembles chromatin from purified DNA in 1 hr under physiological incubation conditions. It consists of a 145,000 x g (maximum) supernatant fraction from eggs of Xenopus laevis. It converts SV40 DNA to a nucleoprotein which co-sediments with naturally occurring SV40 chromatin and which can be cleaved by micrococcal nuclease to a highly ordered pattern of DNA fragments resembling those from digestion of liver chromatin. It inserts superhelical turns into relaxed, covalently closed DNA. The assembly process is not cooperative. Under limiting conditions, each DNA molecule becomes partially assembled. Assembly does not require replication of the DNA or protein synthesis, but occurs from a stored histone pool of at least 40 ng per egg. Under conditions of DNA excess, assembly becomes dependent upon the amount of exogenous histones added to the incubation. Apart from histones and a nicking-closing activity, chromatin assembly requires an additonal thermolabile factor which is present in the egg supernatant.