Developmental changes in messenger RNAs and protein synthesis in Dictyostelium discoideum

The pattern of proteins synthesized at different stages of differentiation of the slime mold Dictyostelium discoideum was studied by two-dimensional polyacrylamide gel electrophoresis. Of the approximately 400 proteins detected during growth and/or development, synthesis of most continued throughout differentiation. Approximately 100 proteins show changes in their relative rates of synthesis. During the transition from growth to interphase, the major change observed is reduction in the relative rate of synthesis of about 8 proteins. Few further changes are noticeable until the stage of late cell aggregation, when production of about 40 new proteins begins and synthesis of about 10 is reduced considerably. Thereafter, there are few changes in the pattern of protein synthesis. Major changes in the relative rates of synthesis of a number of proteins are found during culmination, but few culmination-specific proteins are observed. In an attempt to understand the molecular basis for these changes, mRNA was isolated from different stages of differentiation and translated in an improved wheat germ cell-free system; the products were resolved on two-dimensional gels. The ratio of total translatable mRNA to total cellular RNA is constant throughout growth and differentiation. Messenger RNAs for many, but not all, developmentally regulated proteins can be identified by translation in cell-free systems. Actin is the major protein synthesized by vegetative cells and by early differentiating cells. The threefold increase in the relative rate of synthesis of actin during the first 2 hr of differentiation and the decrease which occurs thereafter can be accounted for by parallel changes in the amount of translatable actin mRNA. Most of the changes in the pattern of protein synthesis which occur during the late aggregation and culmination stages can also be accounted for by parallel increases or decreases in the amounts of translatable mRNAs encoding these proteins. It is concluded that mRNAs do not appear in a translatable form before synthesis of the homologous protein begins, and that regulation of protein synthesis during development is primarily at the levels of production or destruction of mRNA.     

Synthesis and turnover of late H2B histone mRNA in developing embryos of the sea urchin, Strongylocentrotus purpuratus

In sea urchins, "early" histone proteins are synthesized during cleavage and blastula formation, "late" histone proteins in subsequent stages of development. To understand the molecular mechanisms responsible for this ontogenic switch in histone subtype synthesis, we determined the absolute amounts, rates of synthesis, and rates of turnover of late H2b histone mRNAs during development. We showed previously that late H2b mRNA comprises several mRNA isotypes. In this study, we used both a class-specific DNA probe to measure the amounts of the late H2b mRNA isotypes collectively, and a gene-specific probe to measure amounts of a particular late H2b mRNA encoded by a gene known as L1. We found that the amount of late H2b mRNA increased dramatically from 85,000 molecules per embryo in the 16-hr blastula to a peak of 670,000 molecules per embryo in the 24-hr mesenchyme blastula, and fell to 380,000 molecules per embryo in the 72-hr pluteus larva. The L1 late H2b mRNA achieved its maximum abundance earlier than the late H2b mRNA class as a whole, reaching a peak of 34% of total late H2b in the 14-hr blastula and declining to 7% in the pluteus larva. Measurements of the rate of incorporation of [3H]uridine into late class H2b mRNA, performed by a novel in vivo isotope incorporation method, enabled us to calculate both synthesis rates and half-lives of late H2b mRNA during development. These calculations showed (1) that the increase in late H2b mRNA level between 16 and 24 hr postfertilization is regulated primarily if not entirely at the level of mRNA synthesis; and (2) that the half-life of late H2b mRNA is comparatively short, around 20 min, at all stages examined.     

Changing rates of histone mRNA synthesis and turnover in Drosophila embryos

The rates of synthesis and turnover of histone mRNA in Drosophila embryos were determined by hybridization of in vivo and in vitro labeled embryonic RNA to Drosophila histone DNA of the recombinant plasmid cDm500. There is a large store of maternal histone mRNA, equivalent to at least 7 X 10(7) copies of each of the five classes of histone mRNA per embryo. Embryonic synthesis of histone mRNA begins at 90 min after oviposition, making the histone genes among the first to be transcribed by embryonic nuclei. Embryonic histone mRNA accumulates rapidly during the blastoderm and gastrula stages. The peak in the rate of histone mRNA synthesis per embryo coincides with the peak in the rate of DNA synthesis per embryo, which occurs at 6 hr after oviposition. After 6 hr, as the rate of DNA synthesis per embryo decreases, the rate of histone mRNA synthesis and the total mass of histone mRNA per embryo both drop sharply. The rate of histone mRNA synthesis per gene falls more than 60 fold in the first 13 hr after oviposition, from 1.3 -2.5 copies per gene-min at 2 hr to 0.02-0.03 copies per gene-min at 13 hr. From measurements of the mass of histone mRNA per embryo and of the rate of accumulation of newly synthesized histone mRNA at a number of stages of early embryogenesis we determined that the cytoplasmic half-life of histone mRNA decreases approximately 7 fold during early Drosophila development, from 2.3 hr at blastoderm to 20 min by the end of gastrulation. Thus the level of expression of histone genes in Drosophila development is controlled not only by the size of the maternal mRNA pool and changes in the rate of histone mRNA synthesis, but also by changes in the rate of histone mRNA turnover.     

Transfer ribonucleic acid synthesis during sporulation and spore outgrowth in Bacillus subtilis studied by two-dimensional polyacrylamide gel electrophoresis.

The synthesis of transfer ribonucleic acid (tRNA) was examined during spore formation and spore outgrowth in Bacillus subtilis by two-dimensional polyacrylamide gel electrophoresis of in vivo 32P-labeled RNA. The two-dimensional gel system separated the B. subtilis tRNA's into 32 well-resolved spots, with the relative abundances ranging from 0.9 to 17% of the total. There were several spots (five to six) resolved which were not quantitated due to their low abundance. All of the tRNA species resolved by this gel system were synthesized at every stage examined, including vegetative growth, different stages of sporulation, and different stages of outgrowth. Quantitation of the separated tRNA's showed that in general the tRNA species were present in approximately the same relative abundances at the different developmental periods. tRNA turnover and compartmentation occurring during sporulation were examined by labeling during vegetative growth followed by the addition of excess phosphate to block further 32P incorporation. The two-dimensional gels of these samples showed the same tRNA's seen during vegetative growth, and they were in approximately the same relative abundances, indicating minimal differences in the rates of turnover of individual tRNA's. Vegetatively labeled samples, chased with excess phosphate into mature spores, also showed all of the tRNA species seen during vegetative growth, but an additional five to six minor spots were also observed. These are hypothesized to arise from the loss of 3'-terminal residues from preexisting tRNA's.     

Sequential Induction of mRNAs for Phenylalanine Ammonia-lyase in Slices of Potato Tuber

Induction of the mRNA that encodes for phenylalanine ammonia-lyase(PAL, EC 4.3.1.5 [EC] ), which catalyzes the first reaction in thebiosynthesis of a wide variety of phenylpropanoid natural productsfrom phenylalanine, was investigated in. wounded tuber tissuesof the potato (Solanum tuberosum L. cv. Irish Cobbler). Northernblot analysis showed that hybridizable RNA was not present inunwounded tissue, but the amount of hybridizable PAL-specificmRNA increased rapidly in the polysomal RNA fraction with asharp, high peak at the early stage (0 h to 6 h) and two broadlower peaks at the later stage (6 h to 48 h) of the wound response.Addition of actinomycin D to the tissue prevented the appearanceof hybridizable mRNA in the total RNA fraction, confirming thatthe increase resulted from synthesis of PAL mRNA de novo. Levelsof translatable PAL mRNA activity in vitro increased in thepolysomal RNA fraction in parallel with the changes in levelsof hybridizable mRNA, with a subsequent increase in levels ofPAL subunit polypeptides and enzymatic activity in wounded tissues.PAL subunits synthesized both in vivo and in vitro had the samemolecular masses, of about 79 kDa, on SDS-polyacrylamide gelelectrophoresis, but isoelectric focusing revealed the presenceof isoforms of the native tetrameric enzyme with different pIvalues and changes in the relative levels of the isoforms afterwounding. Furthermore, two-dimensional gel electrophoresis ofPAL subunits synthesized in vitro showed that at least eightmRNAs that encoded subunit isoforms with different pI valueswere expressed sequentially after wounding. (Received May 24, 1990; Accepted October 24, 1990)     

Synthesis of histone mRNA sequences in isolated nuclei of cleavage stage sea urchin embryos

A qualitative assay for detection of histone mRNA sequences in nuclear RNA was developed using actinomycin D-CsCl gradients to separate histone DNA from bulk DNA by differences in buoyant density. A significant amount of RNA synthesized in vitro in isolated nuclei from early blastula stage sea urchin embryos hybridized coincident with the histone DNA satellite, and this hybridization was competed out by unlabeled “9S” polysomal RNA purified from embryos at the same stage of development. The biogenesis of these histone mRNA sequences appeared similar as observed during in vivo and in vitro synthesis. Nuclear RNA from embryos pulse labeled in vivo was found to lack histone sequences, suggesting a rapid exit time for these sequences from the nucleus. Attempts to study the exit of histone sequences from isolated nuclei labeled in vitro also suggested a rapid exit time for histone sequences. The histone sequences were synthesized to a much lesser extent in isolated nuclei from late blastula stage embryos, as anticipated from the much reduced amount of histone mRNA labeled on polysomes at this stage.     

Translational control of the circadian rhythm of liver sterol carrier protein. Analysis of mRNA sequences with a specific cDNA probe

The striking changes in amount of rat liver SCP (sterol carrier protein) during a 24-h dark-light cycle are due to alterations in the relative synthetic rate of SCP. However, functional SCP mRNA, measured by a cell-free translational assay, does not fluctuate in the dark-light cycle. Since cell-free translational assays do not always reflect the actual abundance of an mRNA molecule, a specific cDNA hybridization assay was used to directly quantitate SCP mRNA sequences. The cDNA probe was selected from a rat liver library by hybridization to a mixture of synthetic oligonucleotides containing a portion of the sequence of SCP mRNA. The relative amount and size distribution of the SCP mRNA species (approximately 700-800 nucleotides) does not change during the diurnal cycle. To explore possible mechanisms of this translational control, the polysomal distribution of SCP mRNA was compared at the maximum and minimum points of SCP synthesis. No significant amounts of SCP mRNA were present in nonpolysomal ribonucleoprotein particles. Furthermore, no alteration in the relative level of SCP mRNA associated with polysomes or in polysome size occurs at the maximum and minimum points of SCP synthesis. Thus, changes in total SCP mRNA levels or its polysomal distribution cannot account for the diurnal variation in SCP synthesis.     

Individual regulation of the accumulation of H1 mRNA and core histone mRNAs in sea urchin embryos.

The relative cytoplasmic accumulation of the individual histone mRNAs in sea urchins was determined by gel analysis of 3H-labeled cytoplasmic RNA isolated from embryos of the early cleavage through the mesenchyme blastula stages. A number of separate determinations showed that H1 mRNA accumulates at a molar ratio of 0.5 or less compared with each of the H2 or H3 core histone mRNAs through approximately the first 12 h of embryonic development. After this time, the accumulation of H1 mRNA increases relative to the core histone mRNAs, and approximately equimolar amounts of the histone mRNAs are produced by about the 14-h stage. The equimolar synthesis of H1 mRNA appears to be transient, returning to 0.5-molar levels several hours later. The increase in H1 mRNA accumulation, relative to the core histone RNAs, is coincident with the transition from expression of the early (alpha) sea urchin histone gene set to the late histone genes. Since all five of the early histone genes occur in a 1:1 ratio within repeating units, the data suggest that the genes within a single repeat, or their immediate products, are individually regulated. Gel analysis of the proteins synthesized in vivo by embryos demonstrates that the pattern of synthesis of the histone proteins reflects the changing ratios of the histone mRNAs.     

The appearance of polygalacturonase mRNA in tomatoes: one of a series of changes in gene expression during development and ripening

Tomato mRNA was extracted from individual fruits at different stages of development and ripening, translated in a rabbit reticulocyte lysate and the protein products analysed by sodium dodecyl sulphate-polyacrylamide gel electrophoresis. The results indicate that there are at least two classes of mRNA under separate developmental control. One group of approximately six mRNAs is present during fruit growth and then declines at the mature-green stage. Another group of between four and eight mRNAs increases substantially in amount at the onset of ripening, after the start of enhanced ethylene synthesis by the fruit, and continues to accumulate as ripening progresses. Studies of protein synthesis in vivo show that several new proteins are synthesised by ripening fruits including the fruit-softening enzyme polygalacturonase. One of the ripening-related mRNAs is shown to code for polygalacturonase, by immunoprecipitation with serum from rabbits immunised against the purified tomato enzyme. Polygalacturonase mRNA is not detectable in green fruit but accumulates during ripening. It is proposed that the ripening-related mRNAs are the products of a group of genes that code for enzymes important in the ripening process.Abbreviation SDS sodium dodecyl sulfate     

Involvement of the 24-kDa cap-binding protein in regulation of protein synthesis in mitosis

The rate of protein synthesis in metaphase-arrested cells is reduced as compared to interphase cells. The reduction occurs at the translation initiation step. Here, we show that, whereas poliovirus RNA translation is not affected by the mitotic translational block, the translation of vesicular stomatitis virus mRNAs is. In an attempt to elucidate the mechanism by which initiation of protein synthesis is reduced in mitotic cells, we found that the interaction of the mRNA 24-kDa cap-binding protein (CBP) with the mRNA 5' cap structure is reduced in mitotic cell extracts, consistent with their lower translational efficiency. Addition of cap-binding protein complex stimulated the translation of endogenous mRNA in extracts from mitotic but not interphase cells. In addition, we found that the 24-kDa CBP from mitotic cells was metabolically labeled with 32P to a lesser extent than the protein purified from interphase cells. These results are consistent with a hypothesis that the 24-kDa CBP is implicated in the inhibition of protein synthesis in metaphase-arrested cells. Possible mechanisms for this inhibition are offered.     

Gene-specific expression of the actin multigene family of Dictyostelium discoideum

We have investigated the expression of 14 cloned genes of the 20-member actin multigene family of Dictyostelium discoideum using gene-specific mRNA complementary probes and an RNase protection assay. Actin gene expression was studied in vegetative cells and in cells at a number of developmental stages chosen to represent the known major shifts in actin mRNA and protein synthesis. At least 13 of these genes are expressed. A few genes are expressed very abundantly at 10% or more of total actin mRNA; however, the majority are maximally expressed at 1 to 5% of actin message. Although all of the genes are transcribed in vegetative cells, most genes appear to be independently regulated. Actin 8 appears to be transcribed at constant, high levels throughout growth and development. Actin 12 mRNA is maximally expressed in vegetative cells but the level is reduced appreciably by the earliest stage of development examined, while Actin 7 mRNA is specifically induced approximately sevenfold at this time. The rest of the genes appear to be induced 1.5 to 2-fold early in development, coincident with the increase in total actin mRNA. Since 12 of the genes code for extremely homologous proteins, it is possible that the large number of actin genes in Dictyostelium is utilized for precise regulation of the amount of actin produced at any stage of development, even though individual gene expression appears in some cases to be very stage-specific. In addition to these 13 actin genes, at least two and possibly four more genes are known to be expressed, because they are represented by complementary DNA clones, and an additional one or two expressed genes are indicated by primer extension experiments. Only one known gene, Actin 2-sub 2, is almost certainly a pseudogene. Thus the vast majority of Dictyostelium actin genes are expressed.     

RNA synthesis during spore germination in Bacillus subtilis.

Summary We have analyzed the RNA synthesized during spore germination in Bacillus subtilis. Early in germination there is little incorporation of [³H]uridine into RNA. A large increase in incorporation into RNA was found at 45–60 min into germination which was in part due to increases in the specific activity of the UTP pool. When corrected for specific activity changes, the instantaneous rate of RNA synthesis showed a seven to tenfold increase between 30 and 45 min of germination. Polyacrylamide gel electrophoresis studies showed that the RNA synthesized during germination appeared very similar to the RNA made during vegetative growth. DNA-RNA hybridization studies indicated that mRNA and rRNA were synthesized throughout germination. Their relative proportions remained constant and were very similar to the composition of RNA synthesized during vegetative growth.In partial fulfillment of the requirements for the doctoral degree by A.S. in the Department of Microbiology at the New York University School of Medicine