The specificity of in vitro chromatin transcription

Prolactin induces release of a factor from membranes capable of stimulating beta-casein gene transcription in isolated mammary cell nuclei

Crude microsomes from lactating rabbit mammary gland were incubated with prolactin. The incubation mixture was centrifuged and the supernatant was incubated with isolated mammary cell nuclei from lactating rabbits treated for 4 days by bromocryptin to antagonize prolactin and to deinduce casein gene transcription. Nuclei were incubated with HgCTP, and the newly synthesized mercurated RNA was isolated on SH-Sepharose columns. The content of beta-casein mRNA sequences in the fraction eluted with 2-mercaptoethanol was estimated with a [(3)H]cDNA probe obtained from partially purified beta-casein mRNA. The supernatant markedly stimulated beta-casein gene transcription but not 28S rRNA transcription. The same effect was obtained with other lactogenic hormones such as human growth hormone and ovine placental lactogen but was not observed with bovine growth hormone, insulin, parathyroid hormone, luteotropic hormone, or epidermal growth factor. Prolactin and human growth hormone were totally inactive when added directly to nuclei. The factor stimulating beta-casein gene transcription was also generated by membranes containing prolactin receptors such as those from liver, ovary, adrenals, and brain but not by membranes from heart, lung, and muscle, which do not bind prolactin. The factor stimulated beta-casein transcription when added to mammary nuclei from pseudopregnant or bromocryptin-treated lactating rabbits, in which the transcription rate is submaximal, but was ineffective on mammary nuclei prepared from untreated fully lactating rabbits. The factor was unable to induce beta-casein gene transcription in nuclei isolated from rabbit liver and reticulocytes. The factor did not stimulate the transcription of globin genes in nuclei isolated from reticulocytes or the transcription of mammary "housekeeping" genes evaluated by a cDNA probe prepared from total mRNA isolated from an unstimulated mammary gland. The transcription of beta-casein genes was abolished by adding alpha-amanitin to the medium in the presence or in the absence of the factor, indicating that the generation of mercurated beta-casein mRNA sequences depended upon the transcriptional activity of RNA polymerase II. The addition of the factor to the incubation mixture did not enhance total and alpha-amanitin-sensitive RNA synthesis. These data suggest that the binding of prolactin to its receptor in vitro induces the formation of a second messager, which specifically stimulates the transcription of prolactin-sensitive genes.

Specificity of chromatin transcription in vitro. Asymmetric transcription of the globin gene by Escherichia coli RNA polymerase

The transcription of globin genes in mouse foetal liver chromatin and nuclei by exogenous Escherichia coli RNA polymerase is prone to artifacts due to RNA-dependent transcription of endogenous mRNA sequences. This is particularly evident when Mn2+ is used as divalent cation in the RNA transcription reaction. However, substitution or supplementation with Mg2+ eliminates this artifact and gives essentially asymmetric DNA-dependent transcription by the polymerase. In this paper we discuss a number of general criteria which can be applied to test the validity of specific gene transcription in vitro.

Role of prolactin in the transcription of beta-casein and 28-S ribosomal genes in the rabbit mammary gland

Isolated mammary nuclei were incubated in the presence of HgCTP and the neosynthesized RNA was isolated with a SH-Sepharose column. The concentration of beta-casein mRNA and 28-S ribosomal RNA in the neosynthesized RNA fractions was evaluated using [3H]DNA probes complementary to beta-casein mRNA and 28-S rRNA respectively. In the unstimulated pseudopregnant rabbit, the transcription of both genes was easily detectable. Injections of prolactin progressively enhanced the transcription rate of both genes and preferentially the beta-casein gene. A comparison between the transcription rates and the accumulation of the corresponding gene products in the cell revealed that there is a good correlation between these two parameters for the 28-S rRNA gene. By contrast, the acceleration of beta-casein gene transcription by prolactin is unable to account for the simultaneous accumulation of beta-casein mRNA, indicating that prolactin is a potent stabilizer of casein mRNA. Injections of CB154 into lactating rabbits (a drug which suppresses the secretion of prolactin by hypophysis), induced a rapid drop of beta-casein mRNA concentration and a slow decline of beta-casein gene transcription. Simultaneously the drug was responsible for a marked and rapid decrease of 28-S rRNA gene transcription, while the concentration of the rRNA remained elevated. During weaning the transcription of the beta-casein gene and, to a lower degree, the transcripton of the 28-S rRNA gene proceeded more slowly and this phenomenon was accompanied by a progressive decline of the RNA concentrations.