Sequence complexity of heterogeneous nuclear RNA in sea urchin embryos

Alterations of RNA metabolism in sea urchin embryos by an inhibitor of protein synthesis initiation

An inhibitor of the initiation of protein synthesis, 2-(4-methyl-2,6 dinitroanilino)-N-methyl propionamide, (MDMP), inhibits incorporation of amino acids by 85--95% without altering the rate of incorporation of uridine into sea-urchin-hatched blastula embryos. Since the inhibition is readily reversible up to at least 90 min after addition, extensive secondary effects are unlikely. Newly synthesized RNA accumulates in polyribosome-like structures in amount and with a size distribution very similar to the control. The polyadenylation of total, cytoplasmic and polyribosomal RNA are only slightly different from the controls. While the size distribution of 9-S of approx. 30-S RNA is about the same, there is relatively less low molecular weight RNA (approx. 4-S). There is also a greater accumulation of greater than 30-S RNA in the cytoplasm of treated embryos due either to leakage and/or improper processing of nuclear RNA. The latter possibility is consistent with the decrease in 4-S RNA which is a presumed degradation product of nuclear HnRNA. While the initial rate of RNA synthesis and much of the accumulation of RNA in polyribosomes are not affected, the inhibition of protein synthesis per se or a secondary effect of MDMP results in altered patterns of RNA transport and processing.

Synthesis of heterogeneous nuclear RNA in full-grown oocytes of Xenopus laevis (Daudin)

At various times following injection of either 3H-GTP or 32PO4 into full-grown (stage 6) Xenopus laevis oocytes, RNA has been extracted and fractionated on polyacrylamide gels. Based on size, base composition and incorporation data, we have defined the kinetics of synthesis and accumulation of ribosomal RNA (40S, 28S, 18S), heterogeneous RNA of high molecular weight (greater than 40S) and heterogeneous RNA migrating with molecular weights of from 4S to 40S. Nuclear isolations have been performed to determine the cellular distribution of these classes of RNA as a function of time. Evidence is presented which shows that stage 6 oocytes synthesize RNA which by virtue of its size, base composition, rapid turnover and nuclear location is equivalent to the heterogeneous nuclear RNA observed in somatic cells. In addition, the data suggest synthesis of a class of nuclear RNA with a half-life of several hours. A small fraction (5%) of the nuclear RNA is stable, enters the cytoplasm and may represent RNA added to the stockpile of maternal transcripts known to be present in stage 6 oocytes.

Frequency distribution of messenger sequences within polysomal mRNA and nuclear RNA from rat liver

DNA complementary to polysomal poly(A)-containing mRNA (cDNA) of male rat liver was used to study the diversity of messenger sequences in the nucleus and in polysomes. 1. Hybridization of cDNA against an excess of its own polysomal mRNA template revealed that about 10,000 different mRNA species are expressed in the liver tissue. They are distributed in a wide frequency range derived from approximately 0.5% of the total genome. 2. Hybridization of the cDNA against total nuclear RNA shows that messenger sequences comprise less than 1% of the mass of total nuclear RNA. Messenger sequences have a different frequency distribution in nucleus and cytoplasm. 3. In hybridizations using cDNA, which had been fractionated into sequences representing abundant and scarce polysomal mRNA molecules, it was found that although abundant cytoplasmic messenger sequences are also abundant in the nucleus, they exist in a significantly lower frequency range in the nuclear compartment.

Relationship between nuclear and polysomal RNA populations of Achlya: a simple eucaryotic system

The relationship between hnRNA and mRNA in the water mold Achlya has been investigated in several ways. Analysis of the nuclear and polysomal poly(A) RNA by sucrose density gradient centrifugation under denaturing and nondenaturing conditions showed that the populations have indistinguishable size distributions. The number average sizes were calculated to be 1150 nucleotides for nuclear and 1140 nucleotides for polysomal poly(A) RNA. Selective inhibition of rRNA synthesis was used to investigate the size distribution of hnRNA without regard to poly(A) content. Very little hnRNA was observed which sedimented more rapidly than polysomal poly(A) RNA. Hybridization experiments in which an excess of nuclear DNA was reacted with 3H-poly(A) hnRNA or 3H-poly(A) mRNA showed that both populations contain repetitive transcripts (9-10%) as well as single-copy transcripts (44%). Analysis of hybrids on hydroxyapatite in the presence of 8 M urea demonstrated that the poly(A) RNA complementary to repetitive DNA sequence components represented a population of molecules distinct from the population complementary to single-copy DNA. The complexity of whole cell, nuclear and polysomal RNA was determined by saturation hypbridization to single-copy 3H-DNA. All three populations were complementary to essentially the same fraction of the DNA. Terminal hybridization values were 3.84, 3.76 and 3.76% for whole cell, nuclear and polysomal RNA, respectively, representing a complexity of 2.1 X 10(6) nucleotides. These data suggest that the composition of the hnRNA and mRNA populations are essentially identical. No evidence for selective turnover of any sequence component or size class within the nucleus was observed.

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 least-squares 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 symthesis, 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.

Number and distribution of polyadenylated RNA sequences in yeast

The poly(A)-containing RNA, isolated from the budding yeast Saccharomyces cerevisiae, has been characterized with regard to the number and distribution of sequences by a kinetic analysis of RNA-cDNA hybridization. In agreement with results previously obtained on metazoan eucaryotes (Bishop et al., 1974), discrete complexity classes were observed. There exist low, medium, and high complexity classes which contain approximately 20, 400, and 2400 sequences, respectively. This measurements of the number of sequences has been verified by hybridization with single copy DNA. 20% of the single copy fraction of the yeast genome is rendered double-stranded by poly(A)-containing RNA. Assuming asymmetric transcription, this is equivalent to approximately 4000 poly(A)-containing sequences, verifying the results obtained with RNA-cDNA hybridization. In addition, the first-order kinetics of the hybridization with single copy DNA verified the notion that most of the sequence complexity is present at the same intracellular concentration. The same number and distribution of sequences were found in poly(A)-containing polysomal RNA and in total RNA, suggesting that most or all of the sequence complexity is on polysomes and is adenylated. The results indicate that RNA-cDNA hybridization is an accurate method for determining sequence complexity values and that yeast, grown under vegetative conditions, has 3000-4000 different mRNA sequences.

Gene control in eukaryotes and the c-value paradox "excess" DNA as an impediment to transcription of coding sequences

Ways in which control of gene activity may lead to the observed high DNA content per haploid eukaryote genome are examined. It is proposed that deoxyribonucleoprotein (DNP) acts as a barrier to transcription at two distinct structural levels. At the lower level, melting of the nucleosome supercoil (quaternary structure) and of the nucleosomes (tertiary structure) might be brought about by the process of transcription itself. After unwinding the barrier section, the polymerase would eventually reach the structural gene. The transcripts of noncoding sequences, at least as far as their "unique" sequence components are concerned, may thus have filled their main function through the very process of transcription. The possibility of an inverse relationship between the length of the DNP barrier and the rates of transcription of the coding sequences is to some extent supported by available data. Different modes of coordination between the transcription of mRNA and of hnRNA from a single functional unit of gene action (funga) are considered. An analysis of gene control at high structural levels of DNP is made on the basis of other data, in relation to the concepts of eurygenic and stenogenic control. The concept of a euryon is introduced, namely of a set of linked fugas under common eurygenic control. Structure of order higher than quaternary can be inferred to exist in larger chromomeres of polytene chromosomes and in corresponding sections of ordinary chromosomes. Only moderate amounts of highest order interphase euchromatic structure are likely to be able to be accomodated in average chromomeres and none in very thin chromomeres. Puffs are interpreted as the melting of highest order interphase structure, and the absence of puffs during transcription as the absence of this highest order structure in the resting state of the chromomeres. Genes that are constantly active in all tissues may dispense with highest order interphase structure and with the corresponding control mechanism, and the fugas involved thus may not puff. Puffs, large chromomeres and highest order interphase euchromatic DNP structure seem to be correlated with genes that need to be transcribed only under certain developmental conditions. It is proposed that the function of high order structure is to sequester genetic material, namely mainly controller sequences. Since such high order structure, in most cases, would be built up to house the controller dependencies of just one structural gene, the amount of DNA per structural gene needed for gene control would be considerable, and the concept, if correct, would go a long way towards explaining the c-value paradox ("excess" DNA in eukaryotes). In eurygenic determination, the high order structure is thought to be conditioned for melting or to actually melt to an intermediate level of structure. From there, stenogenic control, leading to transcription, is considered to carry the melting process further to yet lower structural levels...

A model for cytoplasm-governed gene regulation

A model of cytoplasm-governed transcription is presented. The nuclear membrane has a selective permeability towards nuclear pre-mRNA molecules which are provided with group-specific non-translated "passwords". RNA transcription on the chromatin proceeds under a dual control. One of them is gene regulation according to the Britten-Davidson and Georgiev models. The other is cytoplasm-governed regulation mediated through the selective transport of mRNA from nucleus to cytoplasm. Pre-mRNA molecules which are not "in immediate demand" by the cytoplasm and therefore accumulating the nucleus repress their own synthesis by end-product inhibition. The interrelationship of the two types of regulation in the course of cell development is discussed.

Chromosomal subunits in active genes have an altered conformation

Ten percent digestion of isolated nuclei by pancreatic deoxyribonuclease I preferentially removes globin DNA sequences from nuclei obtained from chick red blood cells but not from nuclei obtained from fibroblasts, from brain, or from a population of red blood cell precursors. Moreover, the nontranscribed ovalbumin sequences in nuclei isolated from red blood cells and fibroblasts are retained after mild deoxyribonuclease I digestion. This suggests that active genes are preferentially digested by deoxyribonuclease I. In contrast, treatment of red cell nuclei with staphylococcal nuclease results in no preferential digestion of active globin genes. When the 11S monomers obtained after staphylococcal nuclease digestion of nuclei are then digested with deoxyribonuclease I, the active globin genes are again preferentially digested. The results indicate that active genes are probably associated with histones in a subunit conformation in which the associated DNA is particularly sensitive to digestion by deoxyribonuclease I.

Globin mRNA sequences in polyadenylated and nonpolyadenylated nuclear precursor-messenger RNA from avian erythroblasts

Nuclear RNA from immature duck erythrocytes was fractionated into polyadenylated and nonpolyadenylated fractions, and globin mRNA sequences were determined by hybridization to DNA complementary to globin mRNA. 80--90% of labeled nuclear RNA is found to be nonpolyadenylated, and 70--80% of the globin mRNA sequences present in the nucleus are found in nonpolyadenylated molecules. These data suggest that polyadenylation does not specifically select for globin mRNA sequences. The nonpolyadenylated globin mRNA sequences present in the nucleus are found mostly in molecules of small size, close to the size of polyribosomal globin mRNA, suggesting that polyadenylation is a later event in globin mRNA formation.

Diversity of sequences in total and polyadenylated nuclear RNA from Drosophila cells

Complementary DNA was synthesized using polyadenylated nuclear RNA of cultured Drosophila cells as template. The kinetics of hybridization of this cDNA with nuclear RNA indicated that the complexity of this RNA population is five to ten times greater than that of cytoplasmic mRNA. The same difference in the fraction of DNA represented was obtained when nuclear and cytoplasmic RNA were hybridized with labeled unique sequence DNA. The fraction of the DNA sequences represented in total number of polyadenylated nuclear RNA is much higher than that represented in cytoplasmic RNA.

Relationship between nuclear and cytoplasmic RNA in Drosophilia cells

Polyadenylated RNA was isolated from nuclei of cultured Drosophila cells, Schneider's line 2, and used as a template to synthesize a complementary DNA probe. Hybridization experiments were performed to study the relationship between nuclear and cytoplasmic RNA. About two-thirds of the nuclear polyadenylated RNA sequences exist in the cytoplasm. Experiments with fractionated cDNA probes demonstrated that RNA sequences that are frequent in the nucleus are also abundant in the cytoplasm. These findings are consistent with a precursor-product relationship in which some polyadenylated molecules in the nucleus are destined for the cytoplasm while other sequences are polyadenylated but not transferred.

Sequence composition of the template-active fraction of rat liver chromatin

Rat liver chromatin has been separated into nuclease-sensitive and -resistant fractions after mild digestion with DNAase II. The nuclease-sensitive material is further fractionated into Mg2+ -soluble and -insoluble chromatin fractions. The kinetics of production of these chromatin fractions have been investigated. After a brief enzyme treatment (5 min at 10 enzyme units/A260 unit of chromatin at pH 6.6), 11% of the input chromatin DNA is found in the Mg2+ -soluble fraction. This DNA has a weight-average single-strand length of about 400 nucleotides and, as determined by renaturation kinetics, comprises a subset of nonrepetitive DNA sequences and a subset of families of middle repetitive sequences. This demonstrates the nonrandom distribution of repetitive and single copy sequences in the Mg2+ -soluble fraction of chromatin. Previous studies have shown that the Mg2+ -soluble fraction is enriched in nonrepeated sequences which are transcribed in vivo (Gottesfeld, J.M., Garrard, W.T., Bagi, G., Wilson, R.F., and Bonner, J. (1974), Proc. Natl. Acad. Sci. U.S.A. 71, 2193-2197). We now report that the Mg2+ -soluble fraction of liver chromatin contains a low proportion of sequences in common with the Mg2+ -soluble fraction of brain chromatin. Thus, fractionation does not depend on some general property of chromatin but is specific with regard to the template activity of the tissue from which the chromatin was obtained.

Comparison of cytoplasmic and nuclear poly(A)-containing RNA sequences in Xenopus liver cells

Poly(A)-containing RNAs from cytoplasm and nuclei of adult Xenopus liver cells are compared. After denaturation of the RNA by dimethysulfoxide the average molecule of nuclear poly(A)-containing RNA has a sedimentation value of 28 S whereas the cytoplasmic poly(A)-containing RNA sediments slightly ahead of 18 S. To compare the complexity of cytoplasmic and nuclear poly(A)-containing RNA, complementary DNA (cDNA) transcribed on either cytoplasmic or nuclear RNA is hybridized to the RNA used as a template. The hybridization kinetics suggest a higher complexity of the nuclear RNA compared to the cytoplasmic fraction. Direct evidence of a higher complexity of nuclear poly(A)-containing RNA is shown by the fact that 30% of the nuclear cDNA fails to hybridize with cytoplasmic poly(A)-containing RNA. An attempt to isolate a specific probe for this nucleus-restricted poly(A)-containing RNA reveals that more than 10(4) different nuclear RNA sequences adjacent to the poly(A) do not get into the cytoplasm. We conclude that a poly(A) on a nuclear RNA does not ensure the transport of the adjacent sequence to the cytoplasm.