Stress mRNA metabolism in canavanine-treated chicken embryo cells.

Four major chicken stress mRNAs with apparent molecular weights of 1.2 X 10(6), 0.88 X 10(6), 0.59 X 10(6), and 0.25 X 10(6) to 0.28 X 10(6) were separated on acidic agarose-urea gels. Using cell-free translation, the coding assignments of these mRNAs were determined to be stress proteins with apparent molecular weights of 88,000, 71,000, 35,000, and 23,000. Despite high levels of translational activity in vivo and in vitro, no newly synthesized mRNA for the 23-kilodalton stress protein was detected on gels under conditions which readily allowed detection of other stress mRNAs, suggesting activation of a stored or incompletely processed mRNA. Cloned Drosophila heat shock genes were used to identify and measure changes in cellular levels of the two largest stress mRNAs. Synthesis of these mRNAs increased rapidly during the first hour of canavanine treatment and continued at a high rate for at least 7 h, with the mRNAs attaining new steady-state levels by ca. 3 h. Both of these inducible stress mRNAs had very short half-lives compared with other animal cell mRNAs. Using an approach-to-steady-state analysis, the half-lives were calculated to be 89 min for the mRNA encoding the 88-kilodalton stress protein and 46 min for the mRNA encoding the 71-kilodalton stress protein. Chicken 18S and 28S rRNA synthesis was inhibited, and actin mRNA levels measured with cloned cDNA encoding chicken beta-actin slowly declined in canavanine-treated cells.     

Role of protein synthesis in decay and accumulation of mRNA during spore germination in the cellular slime mold Dictyostelium discoideum.

Spore germination in Dictyostelium discoideum is a particularly suitable model for studying the regulation of gene expression, since developmentally regulated changes in both protein and mRNA synthesis occur during the transition from dormant spore to amoeba. The previous isolation of three cDNA clones specific for mRNA developmentally regulated during spore germination allowed for the quantitation of the specific mRNAs during this process. The three mRNAs specific to clones pLK109, pLK229, and pRK270 have half-lives much shorter (minutes) than those of constitutive mRNAs (hours). Using spore germination as a model, we studied the roles of ribosome-mRNA interactions and protein synthesis in mRNA degradation by using antibiotics that inhibit specific reactions in protein biosynthesis. Cycloheximide inhibits the elongation step of protein synthesis. Polysomes accumulate in inhibited cells because ribosomes do not terminate normally and new ribosomes enter the polysome, eventually saturating the mRNA. Pactamycin inhibits initiation, and consequently polysomes break down in the presence of this drug. Under this condition, the mRNA is essentially free of ribosomes. pLK109, pLK229, and pRK270 mRNAs were stabilized in the presence of cycloheximide, but pactamycin had no effect on their normal decay. Since it seems likely that stability of mRNA reflects the availability of sites for inactivation by nucleases, it follows that in the presence of cycloheximide, these sites are protected, presumably by occupancy by ribosomes. No ribosomes are bound to mRNA in the presence of pactamycin, and therefore mRNA degrades at about the normal rate. The data further indicate that a labile protein is probably not involved in mRNA decay or stabilization, since protein synthesis is inhibited equally by both antibiotics. We conclude that it may be important to use more than one type of protein synthesis inhibitor to evaluate whether protein synthesis is required for mRNA decay. The effect of protein synthesis inhibition on mRNA synthesis and accumulation was also studied. mRNA synthesis continues in the presence of inhibitors, albeit at a diminished rate relative to that of the uninhibited control.     

Genes expressed in the male gametophyte of flowering plants and their isolation

Recombinant cDNA libraries to poly(A)RNA isolated from mature pollen of Zea mays and Tradescantia paludosa have been constructed. Northern blot analyses indicate that several of the clones are unique to pollen and are not expressed in vegetative tissues. The majority, however, are expressed both in pollen and vegetative tissues. Southern hybridizations show that the pollen specific sequences in corn are present in one or a very few copies in the genome. By using several of the clones as probes, it was found that there are at least two different groups of mRNAs with respect to their synthesis. The mRNAs of the first group represented by the pollen specific clones are synthesized after microspore mitosis and increase in concentration up to maturity. The second group, exemplified by actin mRNA, begins to accumulate soon after meiosis, reaches its maximum by late pollen interphase, and decreases thereafter. Although the actin mRNA and the pollen specific mRNAs studied show very different patterns of initiation of synthesis and accumulation during pollen development, the rates of decline of these mRNAs during the first 60 minutes of germination and pollen tube growth in Tradescantia are similar and reflect the previously observed declines in rates of protein synthesis during this period.     

Dictyostelium discoideum mRNAs developmentally regulated during spore germination have short half-lives.

mRNA decay was studied during spore germination in Dictyoselium discoideum by the use of three previously isolated cDNA clones, pLK109, pLK229, and pRK270, which are specific for mRNAs developmentally regulated during spore germination. The half-life of a constitutive mRNA, pLK125, which is present throughout germination, growth, and development, as also determined. Nogalamycin, a DNA-intercalating compound, was used to inhibit RNA synthesis. Total RNA was isolated at intervals after addition of the drug, and the decay of mRNAs specific for the cDNA clones was determined by both Northern blot and RNA dot hybridization. If nogalamycin was added immediately after activation of dormant spores, neither pLK229 nor pLK109 mRNA decayed, but pLK125 mRNA did decay. Although pLK109 mRNA did not decay under these conditions, the RNA was smaller 1 h after activation than in dormant spores, indicating that it was processed normally. At 1 h after activation, pLK229-, pLK125-specific mRNAs decayed exponentially, with half-lives of 24, 39, and 165 min, respectively. Under the same conditions, decay of pLK109-specific mRNA was biphasic. Thirty-eight percent of the mRNA decayed with a half-life of 5.5 min, and the remainder decayed with a half-life of 115 min. It seems likely that nogalamycin inhibits the synthesis of an unstable component of the mRNA degradative pathway which is needed continuously for the decay of pLK109 mRNA. By extrapolating the curve representing the rapidly decaying component, a half-life of 18 min was calculated for pLK109-specific mRNA. The mRNAs developmentally regulated during spore germination have half-lives shorter than that of the constitutive messenger and shorter than the average half-life of 3 to 4 h previously determined for total Dicyostelium polyadenylated mRNA.     

Synthesis and turnover of polysomal mRNAs in sea urchin embryos

The synthesis and turnover kinetics of polysomal mRNA have been measured in sea urchin embryos. Polysomes were isolated from stages ranging between mesenchyme blastula and late gastrula Strongylocentrotus purpuratus embryos which had been exposed to exogenous ³H-guanosine. The amount of radioactivity incorporated into messenger and ribosomal RNAs was determined separately as a function of time, and the precursor pool specific activity was measured in the same embryos. Synthesis and decay rate constants were extracted from the data by a leastsquares procedure. Per embryo, the rate of mRNA synthesis was calculated to be about 0.13 pg min^?1, while the rate of rRNA synthesis is about 0.022 pg min^?1. The newly synthesized mRNA turns over with a half-time of 5.7 hr. The data support only a single decay rate for the mRNA, but small fractions of mRNA decaying at different rates cannot be excluded. Previous studies have shown that a minor fraction of the mRNA includes the least abundant, most highly diverse set of messages (“complex class” mRNAs). To determine whether mRNAs of the complex class are synthesized and degraded at similar rates, labeled mRNA was measured in hybrids formed in mRNA excess reactions with single copy DNA. These experiments showed that complex class mRNAs represent an approximately proportional amount of the new mRNA synthesis, and turn over at the same average rate as does the bulk of the mRNA. Most of the mRNAs in the embryo polysomes are newly synthesized, rather than maternal. This statement refers both to complex class mRNAs and to prevalent mRNAs. Considering the sequence homology between embryo and oocyte mRNAs shown earlier, these results indicate that many of the same structural genes active during oogenesis are being transcribed in embryos at these stages.     

mRNA synthesis rates in vivo for androgen-inducible sequences in mouse kidney.

A method was developed for measuring in vivo rates of mRNA synthesis in mice by pulse-labeling with the RNA precursor [3H]orotate and then using hybridization to recover specific mRNAs. The efficiency of recovery is determined with synthetic RNAs as internal hybridization standards. The method is particularly applicable to the kidney since this organ shows a strong preferential uptake of the label. Rates of synthesis, expressed as a fraction of total RNA synthesis, were measured for the androgen-inducible mRNAs coding for beta-glucuronidase (GUS), ornithine decarboxylase (ODC), the protein coded by the RP-2 gene, and the so-called kidney androgen-regulated protein (KAP). Control mRNAs coded for beta-actin, phosphoenolpyruvate carboxykinase, and major urinary protein. Testosterone markedly increased the synthesis of the androgen-inducible mRNAs, but not the control mRNAs. Induction was not seen in mutant mice lacking functional androgen receptor protein. For GUS, ODC, and RP-2 mRNAs, the fold induction of synthesis was less than the fold induction of concentration, suggesting that mRNA stabilization also plays a part in the response to androgen. For GUS, ODC, and RP-2 mRNAs, but not KAP mRNA, induction of synthesis was rapidly reversed after testosterone removal. KAP mRNA was also exceptional in that its concentration was disproportionately high compared with its rate of synthesis, implying that it is a particularly stable mRNA.     

Regulation of ribosomal protein mRNA content and translation in growth-stimulated mouse fibroblasts

When resting (G₀) mouse 3T6 fibroblasts are serum stimulated to reenter the cell cycle, the rates of synthesis of rRNA and ribosomal proteins increase, resulting in an increase in ribosome content beginning about 6 h after stimulation. In this study, we monitored the content, metabolism, and translation of ribosomal protein mRNA (rp mRNA) in resting, exponentially growing, and serum-stimulated 3T6 cells. Cloned cDNAs for seven rp mRNAs were used in DNA-excess filter hybridization studies to assay rp mRNA. We found that about 85% of rp mRNA is polyadenylated under all growth conditions. The rate of labeling of rp mRNA relative to total polyadenylated mRNA changed very little after stimulation. The half-life of rp mRNA was about 11 h in resting cells and about 8 h in exponentially growing cells, values which are similar to the half-lives of total mRNA in resting and growing cells (about 9 h). The content of rp mRNA relative to total mRNA was about the same in resting and growing 3T6 cells. Furthermore, the total amount of rp mRNA did not begin to increase until about 6 h after stimulation. Since an increase in rp mRNA content did not appear to be responsible for the increase in ribosomal protein synthesis, we determined the efficiency of translation of rp mRNA under different conditions. We found that about 85% of pulse-labeled rp mRNA was associated with polysomes in exponentially growing cells. In resting cells, however, only about half was associated with polysomes, and about 30% was found in the monosomal fraction. The distribution shifted to that found in growing cells within 3 h after serum stimulation. Similar results were obtained when cells were labeled for 10.5 h. About 70% of total polyadenylated mRNA was in the polysome fraction in all growth states regardless of labeling time, indicating that the shift in mRNA distribution was species specific. These results indicate that the content and metabolism of rp mRNA do not change significantly after growth stimulation. The rate of ribosomal protein synthesis appears to be controlled during the resting-growing transition by an alteration of the efficiency of translation of rp mRNA, possibly at the level of protein synthesis initiation.     

Quantitative changes in protein synthesis during oogenesis in Xenopus laevis

Protein synthesis rates in Xenopus laevis oocytes from stage 1 through stage 6 were measured. In addition, the translational efficiencies, total RNA contents, and percentages of ribosomes in polysomes in growing oocytes at several stages were determined. Stage 1 oocytes synthesize protein at a mean rate of 0.18 ng hr⁻¹ while stage 6 oocytes make protein at a rate of 22.8 ng hr⁻¹. Polysomes from growing and full-grown oocytes sedimented in a sucrose gradient with a peak value of 300 S, corresponding to a weight-average packing density of 10 ribosomes per mRNA. Ribosome transit times of endogenous mRNAs were essentially unchanged at all stages examined. While the oocyte's total ribosomal RNA content was observed to increase about 115-fold during oogenesis, the percentage of ribosomes in polysomes remained constant at approximately 2%. Taken together, the data suggest that the 127-fold increase in protein synthesis which occurs during Xenopus oogenesis involves the progressive recruitment onto polysomes of mRNA from the maternal stockpile.     

Endonucleolytic activation directs dark-induced chloroplast mRNA degradation

Plastid mRNA stability is tightly regulated by external signals such as light. We have investigated the biochemical mechanism responsible for the dark-induced decrease of relative half-lives for mRNAs encoding photosynthetic proteins. Protein fractions isolated from plastids of light-grown and dark-adapted plants correctly reproduced an RNA degradation pathway in the dark that is downregulated in the light. This dark-dependent pathway is initiated by endonucleolytic cleavages in the petD mRNA precursor substrate proximal to a region that can fold into a stem–loop structure. Polynucleotide phosphorylase (PNPase) polyadenylation activity was strongly increased in the protein fraction isolated from plastids in dark-adapted plants, but interestingly PNPase activity was not required for the initiation of dark-induced mRNA degradation. A protein factor present in the protein fraction from plastids of light-grown plants could inactivate the endonuclease activity and thereby stabilize the RNA substrate in the protein fraction from plastids of dark-adapted plants. The results show that plastid mRNA stability is effectively controlled by the regulation of a specific dark-induced RNA degradation pathway.     

Formation and stability of cytoplasmic mRNAs during myoblast differentiation: Pulse-chase and density labeling analyses

Stabilities and rates of formation of cytoplasmic mRNAs have been measured quantitatively in cultures of embryonic quail breast myoblasts undergoing differentiation to form muscle fibers. Uridine pulse-chase studies show that dividing myoblasts and differentiated fibers form both short- and long-lived mRNAs. Short-lived mRNAs in myoblasts and fibers have similar half-lives of 2–4 hr, however, long-lived mRNAs have a half-life of 60–100 hr in myoblasts and only 20 hr in fibers. When myoblasts fuse, the formation of long-lived cytoplasmic mRNAs increases at least twofold, and this increased formation together with the cessation of myoblast cell division at fusion is sufficient to account for the four- to fivefold accumulation of long-lived mRNA observed in fibers. These long-lived mRNAs were identified by density labeling cultures with ¹⁵N, ¹³C-nucleotides, chasing with light nucleosides, and then translating the density labeled mRNAs in wheat germ extracts. These experiments show that the contractile protein mRNAs, as well as 60–70 other muscle mRNAs are actively synthesized by muscle fibers and that all of the specific mRNAs detected have half-lives clustering around 20 hr.