Changes in the polyadenylated messenger RNA population during development of Dictyostelium discoideum

The program of gene expression during the life cycle of Dictyostelium discoideum has been assessed by molecular hybridization of cDNA probes with polysomal RNA extracted at the following different stages of development: vegetative growth, interphase (2.5 hr), aggregation (8 hr), postaggregation (12 hr), and preculmination (18 hr). Several different cDNA probes were used. Two probes were prepared from vegetative stage poly(A⁺) RNA, one representing all species present and the other enriched for abundant species. A third cDNA probe was prepared from preculmination stage polysomal RNA and a fourth probe consisted of the preculmination stage cDNA depleted in those species also present at the vegetative stage. Hybridization of the various probes with the different polysomal RNA preparations has revealed developmental changes in the mRNA populations. These changes were not detected in an aggregation less mutant under similar conditions of starvation. Abundant RNA species of vegetative cells were found to drop to low levels, especially during the aggregation period. Fifty percent by mass of the RNA present in polysomes at 18 hr is not present during vegetative growth. Some of the new RNA species appeared during interphase and the remaining during the postaggregation period. A gradual increase in the number of copies per cell of certain RNA species comprising both new species as well as some shared with vegetative cells was observed throughout development. Other results indicated that the composition of polysomal and cytoplasmic RNA is similar during vegetative growth but differs markedly at 18 hr of development. Also, cytoplasmic RNA at 18 hr contained, in addition to polysomal RNA, a large proportion by mass of nonpolysomal RNA similar to vegetative RNA. The number of polysomal RNA species detected by this analysis during vegetative growth and during the preculmination stage were estimated to be 3000 and 3700, respectively. The number of copies of these RNA species ranged between 30 and 2000 per cell during vegetative growth and 3 to 300 per cell in polysomes at 18 hr. Developmentally induced RNAs which were preferentially distributed among abundant and intermediate classes were estimated to number 700–900 species.     

Frequency distribution of pre-messenger RNA sequences in polyadenylated and non-polyadenylated nuclear RNA from Friend cells.

Hybridisation of cDNA probes for abundant and rare polysomal polyadenylated RNAs with polyadenylated and non-polyadenylated nuclear RNA from Friend cells indicated that the abundant polysomal polyadenylated RNA sequences were present at a higher concentration in the nucleus than rare polysomal sequences, but at a reduced range of concentrations. The ratio of the concentrations of abundant and rare sequences was about 3 in non-polyadenylated nuclear RNA, 9 in polyadenylated nuclear RNA and 13 in polysomal polyadenylated RNA. This suggests that polyadenylation may play a role in the quantitative selection of sequences for transport to the cytoplasm. Polyadenylation cannot be the only signal for transport, since a highly complex population of nucleus-confined polyadenylated molecules exists, each of which is present on average at less than one copy per cell.     

Chloroplast nucleoids are highly dynamic in ploidy,number, and structure during angiosperm leaf development

Chloroplast nucleoids are large, compact nucleoprotein structures containing multiple copies of the plastid genome. Studies on structural and quantitative changes of plastid DNA (ptDNA) during leaf development are scarce and have produced controversial data. We have systematically investigated nucleoid dynamics and ptDNA quantities in the mesophyll of Arabidopsis, tobacco, sugar beet, and maize from the early post‐meristematic stage until necrosis. DNA of individual nucleoids was quantified by DAPI‐based supersensitive epifluorescence microscopy. Nucleoids occurred in scattered, stacked, or ring‐shaped arrangements and in recurring patterns during leaf development that was remarkably similar between the species studied. Nucleoids per organelle varied from a few in meristematic plastids to >30 in mature chloroplasts (corresponding to about 20–750 nucleoids per cell). Nucleoid ploidies ranged from haploid to >20‐fold even within individual organelles, with average values between 2.6‐fold and 6.7‐fold and little changes during leaf development. DNA quantities per organelle increased gradually from about a dozen plastome copies in tiny plastids of apex cells to 70–130 copies in chloroplasts of about 7 μm diameter in mature mesophyll tissue, and from about 80 plastome copies in meristematic cells to 2600–3300 copies in mature diploid mesophyll cells without conspicuous decline during leaf development. Pulsed‐field electrophoresis, restriction of high‐molecular‐weight DNA from chloroplasts and gerontoplasts, and CsCl equilibrium centrifugation of single‐stranded and double‐stranded ptDNA revealed no noticeable fragmentation of the organelle DNA during leaf development, implying that plastid genomes in mesophyll tissues are remarkably stable until senescence.     

In vitro synthesis of RNA by Xenopus spermatogenic cells I. Evidence for polyadenylated and non-polyadenylated RNA synthesis in different cell populations.

Premeiotic and postmeiotic (haploid) gene expression during spermatogenesis in the anuran, Xenopus laevis, was studied by analyzing the accumulation of radioactively labelled cytoplasmic polyadenylated [poly (A +)] and non-polyadenylated [poly (A -)] RNAs. Dissociated spermatogenic cells were labelled and maintained in an in vitro system capable of supporting cell differentiation. Labelled cells were separated by density gradient centrifugation into subpopulations enriched for individual spermatogenic stages. RNA was extracted and purified from each cell fraction, and separated into poly (A +) and poly (A -) species. Comparison of poly (A +) to non-poly (A) radioactivity in cells labelled with tritiated uridine or adenosine demonstrated that (1) all cell fractions produced significant quantities of polyadenylated RNA relative to total RNA synthesis; and (2) that a cell fraction enriched for pachytene spermatocyte RNA contained up to 15% of total cytoplasmic and 35% of total polysomal RNA labelled as poly (A +) containing species. RNA was also characterized by sucrose density gradient centrifugation and polyacrylamide gel electrophoresis. All cell types showed typical poly (A -) peaks of 4S, 18S and 28S, corresponding to tRNA (4S) and rRNAs (18, 28S) respectively. Spermatids and spermatozoa had additional absorbance peaks at 13 and 21S which cosedimented with Xenopus oocyte mitochondrial rRNA. Patterns of incorporation of uridine and adenosine into poly (A +) RNA in all germ cell fractions tested were complex. In all cases, major areas of radioactivity were found in a broad band sedimenting between 6-17S. Spermatid fractions showed a prominent peak of incorporation at 6-8S, while pachytene cells also showed heavier poly (A +) peaks in the 17-25S region. A non-polyadenylated RNA species sedimenting at 6-8S with a relatively rapid rate of turnover was also observed in spermatids. From these results it is concluded that synthesis of transfer, ribosomal, and putative messenger RNA species continues in spermatogenic cells throughout all but the very last stages of spermatogenesis in Xenopus.     

Growth-related fluctuation in messenger RNA utilization in animal cells

Monkey fibroblasts maintained in culture regulate their levels of intracellular protein throughout the growth cycle by means of variations in the rate of protein biosynthesis. Cytoplasmic mRNA in stationary phase cells was compared to that in exponential phase cells. In stationary phase cells 56% of the cytoplasmic polyadenylated RNA was found in the 40--90S postpolysomal region of sucrose sedimentation gradients, while only 23% was found in this region in exponential phase cells. Analysis of electron micrographs of sectioned exponential and stationary phase cells revealed that this shift in polyadenylated RNA location is accompanied by a loss of polysome-like aggregates of ribosomes. Most if not all of this species of postpolysomal polyadenylated RNA is not being translated by single ribosomes since no detectable amounts of nascent peptide were present in this region. This nonpolysomal polyadenylated RNA is comparable in size to polysomal polyadenylated RNA. The length of the 3'-poly(A) tract was also comparable for these two species. The extent of capping of poly(A)- containing molecules was also comparable for these two species. The template activity of nonpolysomal RNA in a wheat germ extract was comparable to that of polysomal RNA. The peptides produced by these two preparations were of a similar large size. Furthermore, most of the nonpolysomal polyadenylated RNA of stationary phase cells was driven into polysomes in the presence of a low dose of cycloheximide. Therefore, we conclude that the untranslated mRNA that accumulates in stationary phase cells is structurally intact, is fully capable of being translated, and is not being translated due to the operation of a translational initiation block.     

Differences in abundance of individual RNAs in normal and animalized sea urchin embryos

A library of cDNA clones was constructed representing polysomal polyadenylated RNA of mesenchyme blastulae of Strongylocentrotus purpuratus. Using this library, we determined whether or not individual RNA species are associated with animalization of embryos by zinc ions. Clones corresponding to the most actively synthesized RNAs during the period just prior to the mesenchyme blastula stage were selected by screening colonies with in vivo-labeled RNA. The most abundant of these were chosen for further study. Individual RNA abundance was measured as percent of mass of total polyadenylated RNA by hybridizing cDNA exhaustively with cloned DNA on filters. The RNAs in the selected, cloned sequences were present in abundances of 0.01 to 1% of the mass of polyadenylated RNA. Changes in abundance of individual RNA species occurred during normal development and departures from these developmental changes occurred in the zinc-animalized embryos. Two RNA species, which normally increase 10-fold in abundance, are drastically repressed and at least one RNA species increases in abundance dramatically in the animalized embryos. These departures from the normal program of presumptive gene expression may furnish insights into changes in the normal processes of development.     

Changes in nuclear and polysomal polyadenylated RNA sequences during rat-liver regeneration.

Nuclear and polysomal polyadenylated RNA populations of normal and 16 hour regenerating rat liver have been compared by mRNA-cDNA hybridisations and by unique DNA saturation experiments. It was found that nuclear polyadenylated RNA hybridises to 6.8% of unique DNA in both normal and 16 hour regenerating rat liver. However, cross-hybridisation experiments using cDNA have shown that 10-15% by weight of nuclear polyadenylated RNA sequences are specific to 16 hour regenerating rat-liver. Since both unique DNA and cDNA hybridisation have shown that normal and 16 hour regenerating rat-liver polysomal polyadenylated RNA populations are qualitatively very similar sequences specific to 16 hour regenerating rat-liver nuclear polyadenylated RNA are nucleus confined. Polysomal RNA sequences which were abundant in normal rat-liver have become less abundant in regenerating rat liver.     

Cytogenetic analysis of oocytes and early preimplantation embryos from XO mice.

The cytoplasm of early sea urchin embryos contains nonribosomal, high molecular weight RNA both associated with ribosomes in polysomes and free of ribosomes in particles termed free RNP. In a 1-hr labeling period, 50% of the newly synthesized RNA enters the pool of ribosome-free RNP particles during the cleavage stages, and this percentage decreases until less than 20% of the new RNA in the mesenchyme blastula stage is found in the free RNP. mRNA from both polysomes and free RNP contain poly(A)(+) and poly(A)(?) species. During the cleavage stages only 8–10% of the RNA from each fraction is polyadenylated; however, in the blastula, 40–50% of the nonhistone polysomal RNA is polyadenylated while only 22–30% of the free RNP RNA is polyadenylated. At any developmental stage, the poly(A)(+)RNA from the free RNA and polysomes have identical sedimentation profiles; this is also the case for the poly(A)(?)RNA except for the absence of the 9 S histone mRNA from the free RNP. Changes in poly(A)(+)RNA content and sedimentation profiles during development occur simultaneously in the free RNP and the polysomes. Kinetic studies of these two RNP populations as well as nuclear RNP show that the bulk of the free RNP are not unusually stable cytoplasmic components. The free RNP decay with a half-life of about 40 min while nuclear RNA and polysomal RNA display half-lives of about 12 and 65 min, respectively. Further, the rate of synthesis of the free RNP is not consistent with their being the only precursors for polysomes. Our estimates of the rates of synthesis for nuclear RNA, polysomes, and free RNP are, respectively, 1.1 × 10^?15, 2.2 × 10^?16, and 5.0 × 15^?17 g/min/nucleus. The data on free RNP is discussed in terms of translational regulation of protein synthesis in the developing sea urchin.