MICRONUCLEAR RNA SYNTHESIS IN PARAMECIUM CAUDATUM

In a generation time of 8 hr in Paramecium caudatum, the bulk of DNA synthesis detected by thymidine-³H incorporation takes place in the latter part of the cell cycle. The micronuclear cycle includes a G₁ of 3 hr followed by an S period of 3–3½ hr. G₂ and division occupies the remaining period of the cycle. Macronuclear RNA synthesis detected by 5'-uridine-³H incorporation is continuous throughout the cell cycle. Micronuclear RNA synthesis is restricted to the S period. Ribonuclease removes 80–90% of the incorporated label. Pulse-chase experiments showed that part of the RNA is conserved and released to the cytoplasm during the succeeding G₁ period.     

Further Evidence for Lack of Gene Expression in the Tetrahymena Micronucleus

Certain galA mutations in the ciliated protozoan Tetrahymena thermophila confer an almost total loss of galactokinase activity in homozygotes. Heterokaryons have been constructed that are homogeneous for the galA1 mutation in the (45n) macronucleus, but which contain a galA⁺ (2n) micronucleus. Soluble cell extracts prepared from these heterokaryons have been assayed for galactokinase activity, using a radiometric assay for the conversion of galactose to galactose-1-phosphate (gal-1-P). No galactokinase activity attributable to the micronuclear genes is observed in such heterokaryons. These results, obtained with the galA1 marker, provide the first direct, quantitative evidence for the lack of micronuclear (germ line) gene expression in Tetrahymena during vegetative growth, and substantiate the predictions of previous phenotypic observations on heterokaryons and autoradiographic studies of micronuclear RNA synthesis. The generality of this conclusion will be established in the future when other enzymically assayable mutations become available for similar studies.     

Micronuclear DNA sequences of Oxytricha fallax homologous to the macronuclear inverted terminal repeat.

The macronucleus of the protozoan Oxytricha fallax is generated from a micronucleus following conjugation. While the micronucleus contains high molecular weight DNA, the macronucleus contains only short linear DNA molecules which all end in the same 20 bp inverted terminal repeat (Ma-ITR). The Ma-ITR was radioactively labeled and purified for use as a probe in hybridizations to micronuclear and macronuclear DNA. Sequences homologous to the Ma-ITR were detected in micronuclear DNA. The copy number of the repeat in the micronuclear genome is approximately that required to encode the macronuclear DNA termini. The micronuclear copies are found embedded in repeated long sequence blocks.     

STUDIES ON NUCLEAR STRUCTURE AND FUNCTION IN TETRAHYMENA PYRIFORMIS : I. RNA Synthesis in Macro- and Micronuclei

Tetrahymena in the log phase of growth were pulse labeled with uridine-³H, fixed in acetic-alcohol, extracted with DNase, and embedded in Epon. 0.5-µ sections were cut, coated with Kodak NTB-2 emulsion, and developed after suitable exposures. Grains were counted above macronuclei, above 1000 micronuclei, and above 1000 micronucleus-sized "blanks" which were situated next to micronuclei in the visual field by means of a camera lucida. An analysis of grain counts showed that micronuclei were less than ½₀₀₀ as active as macronuclei on the basis of grains per nucleus. Since micronuclei contained, on the average, about ½₀ as much DNA as macronuclei, micronuclear DNA had less than 1% of the specific activity of macronuclear DNA in RNA synthesis. However, even this small amount of apparent incorporation was not significantly different from zero. Comparisons of the frequency distributions of labeled micronuclei with those of micronuclear "blanks" showed no evidence of a small population of labeled nuclei such as might be expected if micronuclei synthesized RNA for only a brief portion of the cell cycle. We conclude from these studies that there is no detectable RNA synthesis in Tetrahymena micronuclei during vegetative growth and reproduction.     

Deletion of the Tetrahymena thermophila rDNA replication fork barrier region disrupts macronuclear rDNA excision and creates a fragile site in the micronuclear genome

During macronuclear development the Tetrahymena thermophila ribosomal RNA gene is excised from micronuclear chromosome 1 by site-specific cleavage at chromosome breakage sequence (Cbs) elements, rearranged into a ‘palindromic’ 21 kb minichromosome and extensively amplified. Gene amplification initiates from origins in the 5′ non-transcribed spacer, and forks moving toward the center of the palindrome arrest at a developmentally regulated replication fork barrier (RFB). The RFB is inactive during vegetative cell divisions, suggesting a role in the formation or amplification of macronuclear rDNA. Using micronuclear (germline) transformation, we show that the RFB region facilitates Cbs-mediated excision. Deletion of the RFB inhibits chromosome breakage in a sub-population of developing macronuclei and promotes alternative processing by a Cbs-independent mechanism. Remarkably, the RFB region prevents spontaneous breakage of chromosome 1 in the diploid micronucleus. Strains heterozygous for ΔRFB and wild-type rDNA lose the ΔRFB allele and distal left arm of chromosome 1 during vegetative propagation. The wild-type chromosome is subsequently fragmented near the rDNA locus, and both homologs are progressively eroded, suggesting that broken micronuclear chromosomes are not ‘healed’ by telomerase. Deletion of this 363 bp segment effectively creates a fragile site in the micronuclear genome, providing the first evidence for a non-telomere cis-acting determinant that functions to maintain the structural integrity of a mitotic eukaryotic chromosome.     

Replication of Western Equine Encephalomyelitis Virus II. Cytoplasmic Structure Involved in the Synthesis and Development of the Virions

Analysis of the cytoplasmic fraction of chick embryo cells during the exponential phase of Western equine encephalomyelitis (WEE) virus growth showed that the viral ribonucleic acid (RNA) labeled by a short pulse with ³H-uridine was associated with a structure which sedimented in sucrose density gradients with a coefficient of 65S. The RNA extracted from this structure sedimented in sucrose density gradients at 26S. After a longer period of exposure to ³H-uridine, the radio-active viral RNA was associated with a structure which sedimented in sucrose density gradients as would materials with coefficients of about 140S. The 140S structure contained viral RNA and viral protein. It was shown that the 140S structures are not virus-induced polysomes. The 140S structure contained predominantly the 40S type of viral RNA and some 26S type. Electrophoretic analysis of the disrupted virion revealed that at least two proteins (types I and II) were present in the purified virion. Only type II protein was present in the 140S structure. Unlike the virion, the 140S structure did not contain any lipid which could be detected by the incorporation of ¹⁴C-choline. These data suggest that the 140S structure represents the internal nucleoprotein part of the virion. The rate of appearance of labeled virus lags behind that of the formation of the 140S structure in infected cells. Pulse-chase experiments with ³H-leucine suggest that the 140S structure may represent a precursor to the virus particle. The results are discussed in terms of the maturation of WEE virus in the infected cells.     

Allele-specific,selective amplification of a ribosomal RNA gene in tetrahymena thermophila

The amplification of ribosomal DNA during development of the somatic macronucleus In Tetrahymens thermophila was analyzed by genetic and molecular biological techniques. We have Identified an alternate form of the rDNA, structurally distinguishable from the wild-type by an extra cutting site for Bam HI in its nontranscribed spacer. The altered rDNA was Inherited in crosses in a simple Mendelian fashion, consistent with the presence of only one rRNA gene copy per haploid genome in the micronucleus. We therefore define a locus for the rRNA structural gene, the rdnA locus, with the allele determining the alternate form designated rdnA1. In over 95% of T. thermophila clones heterozygous for the rdnA locus in the micronucleus (rdnA1/rdn⁺), the macronucleus, which develops from a division product of this micronucleus, contained almost exclusively rdnA1-type amplified palindromic rDNA molecules. The rdnA1 allele is thus almost always dominant over the rdn⁺ allele with respect to amplification. This genetic variant of the rdnA locus was used to show that the single, free, nonpalindromic rRNA genes, which are synthesized during rDNA amplification, are derived from micronuclear gene copies from both chromosomal homologs. We therefore conclude that in these heterozygotes, selective amplification of the rdnA1 allele is not caused by the production of only one type of free, single rRNA gene during amplification.     

NUCLEOLAR-DERIVED RIBONUCLEIC ACID IN CHROMOSOMES, NUCLEAR SAP, AND CYTOPLASM OF CHIRONOMUS TENTANS SALIVARY GLAND CELLS

The distribution of monodisperse high molecular weight RNA (38, 30, 28, 23, and 18S RNA) was studied in the salivary gland cells of Chironomus tentans. RNA labeled in vitro and in vivo with tritiated cytidine and uridine was isolated from microdissected nucleoli, chromosomes, nuclear sap, and cytoplasm and analyzed by electrophoresis on agarose-acrylamide composite gels. As shown earlier, the nucleoli contain labeled 38, 30, and 23S RNA. In the chromosomes, labeled 18S RNA was found in addition to the 30 and 23S RNA previously reported. The nuclear sap contains labeled 30 and 18S RNA, and the cytoplasm labeled 28 and 18S RNA. On the basis of the present and earlier analyses, it was concluded that the chromosomal monodisperse high molecular weight RNA fractions (a) show a genuine chromosomal localization and are not due to unspecific contamination, (b) are not artefacts caused by in vitro conditions, but are present also in vivo, and (c) are very likely related to nucleolar and cytoplasmic (pre)ribosomal RNA. The 30 and 23S RNA components are likely to be precursors to 28 and 18S ribosomal RNA. The order of appearance of the monodisperse high molecular weight RNA fractions in the nucleus is in turn and order: (a) nucleolus, (b) chromosomes, and (c) nuclear sap. Since both 23 and 18S RNA are present in the chromosomes, the conversion to 18S RNA may take place there. On the other hand, 30S RNA is only found in the nucleus while 28S RNA can only be detected in the cytoplasm, suggesting that this conversion takes place in connection with the exit of the molecule from the nucleus.     

Elimination of germ-line tandemly repeated sequences from the somatic genome of the ciliate Oxytricha fallax

The ciliated protozoa exhibit nuclear dimorphism. The genome of the somatic macronucleus arises from the germ-line genome of the micronucleus following conjugation. We have studied the fates of highly repetitious sequences in this process. Two cloned, tandemly repeated sequences from the micronucleus of Oxytricha fallax were used as probes in hybridizations to micronuclear and macronuclear DNA. The results of these experiments show: (1) the cloned repeats are members of two apparently unrelated repetitious sequence families, which each appear to comprise a few percent of the micronuclear genome, and (2) the amount of either family in the macronuclei from which our DNA was prepared is about 1/15 that found in an equal number of diploid micronuclei. Most, if not all, of the apparent macronuclear copies of these repeats can be accounted for by micronuclear contamination, which strongly suggests that these sequences are eliminated from the macronuclei and have no vegetiative function.     

Localization of genes for ribosomal RNA in the nuclei of Oxytricha fallax

The location of ribosomal RNA (rRNA) genes in the nuclei of the ciliated protozoan, Oxytricha fallax, was analysed by in situ hybridization. The micronuclear genome of O. fallax has typical chromosomal DNA organization. Macronuclei, although derived from micronuclei, lack chromosomes and instead contain short pieces of DNA ranging from 500 to 20 000 base pairs in length. In situ hybridization was carried out to determine if specific DNA sequences are limited to certain locations within the macronucleus, or if sequences are randomly arranged. Cells were fixed, squashed and then hybridized with ³H-labelled RNA synthesized in vitro using cloned O. fallax rDNA as a template. After autoradiography, silver grains were found to be distributed uniformly over the entire macronucleus without any detectable localization to specific regions. The uniformity of hybridization indicates that rDNA molecules are randomly dispersed throughout the macronucleus and suggests that the macronuclear genetic apparatus lacks any substantial multimolecular organization. S phase macronuclei also showed a uniform distribution of rDNA molecules, irrespective of the position of the replication band at which DNA synthesis takes place. The micronuclei, in contrast, did not show any hybridization, even in cells in which macronuclei were heavily labelled. Macronuclear anlagen, in which the micronuclear chromosomes are polytenized, also do not hybridize. This absence of hybridization indicates a much lower concentration of rDNA in the micronucleus than in the macronucleus. The change in rDNA concentration of rRNA genes presumably occurs during the complicated process of development of a macronucleus from a micronucleus.     

Role of micronucleus-limited DNA in programmed deletion of mse2.9 during macronuclear development of Tetrahymena thermophila

Extensive programmed DNA rearrangements occur during the development of the somatic macronucleus from the germ line micronucleus in the sexual cycle of the ciliated protozoan Tetrahymena thermophila. Using an in vivo processing assay, we analyzed the role of micronucleus-limited DNA during the programmed deletion of mse2.9, an internal eliminated sequence (IES). We identified a 200-bp region within mse2.9 that contains an important cis-acting element which is required for the targeting of efficient programmed deletion. Our results, obtained with a series of mse2.9-based chimeric IESs, led us to suggest that the cis-acting elements in both micronucleus-limited and macronucleus-retained flanking DNAs stimulate programmed deletion to different degrees depending on the particular eliminated sequence. The mse2.9 IES is situated within the second intron of the micronuclear locus of the ARP1 gene. We show that the expression of ARP1 is not essential for the growth of Tetrahymena. Our results also suggest that mse2.9 is not subject to epigenetic regulation of DNA deletion, placing possible constraints on the scan RNA model of IES excision.     

DNA of ciliated protozoa: DNA sequence diminution during macronuclear development of oxytricha

We have measured the reassociation kinetics of DNA from the micronucleus and from the macronucleus of the hypotrichous cillate Oxytricha. The micronuclear DNA reassociates with at least a two-component reaction, indicating the presence of both repeated and non-repeated sequences. The kinetic complexity of micronuclear non-repeated DNA is in the range of 2 to 15 × 10¹¹ daltons; the haploid DNA content of the micronucleus is 4 × 10¹¹ daltons (0.66 pg), measured microspectrophotometrically. The DNA of the macronucleus reassociates as a single second-order reaction, with a kinetic complexity of 3.6 × 10¹⁰ daltons. A comparison of the kinetic complexities of micronuclear and macronuclear DNAs suggest a 5 to 30 fold reduction in DNA sequence complexity during the formation of a macronucleus from a micronucleus. Macronuclear DNA is in pleces with an average molecular weight of 2.1 × 10⁶ daltons. Since the kinetic complexity of macronuclear DNA is 3.6 × 10¹⁰ daltons, the macronucleus must contain about 17,000 different kinds of DNA pieces.Each macronucleus contains 3.5 × 10¹³ daltons (58 pg) of DNA, indicating that each sequence must be present about 1000 times per macronucleus or 2000 times per cell.     

Analysis of the coding activity and stability of messenger RNA in Drosophila oocytes.

The coding activity of the messenger RNA in the ooplasm of late stage 14 (S14) oocytes of Drosophila melanogaster was analyzed by labeling the oocytes in vitro with [³⁵S]methionine and examining the labeled products by two-dimensional gel electrophoresis and fluorography. This analysis was done both with newly formed S14 oocytes from rapidly laying females and with S14 oocytes stored for about 10 days in females that were prevented from laying. Comparison of the fluorographs showed that the proteins labeled in the newly formed oocytes were also labeled in the stored oocytes. Thus, the coding activity of S14 oocyte messenger RNA appears to remain stable during prolonged storage in utero. The oocyte proteins synthesized during oogenesis and incorporated into S14 oocytes were labeled in vivo by injecting [³⁵S]methionine into newly eclosed females, and the S14 oocytes were removed 2 days later for gel electrophoresis and fluorography. Comparison of the fluorographs produced by the in vivo and in vitro labeling procedures showed that most of the oocyte proteins labeled in vivo were also labeled in vitro. The S14 oocytes, therefore, appear to contain messenger RNA for most of the oocyte proteins synthesized during oogenesis. There were also several additional proteins detected only in the fluorographs of the in vivo labeled oocytes; the most prominent of these were identified by immunoprecipitation tests as vitellogenin proteins of yolk granules, which are known to be synthesized outside the oocyte, in fat bodies. The occurrence of stable S14 oocyte messenger RNA for most of the oocyte proteins suggests that the synthesis of those proteins during oogenesis occurs in the developing oocytes, specified by a stable population of oocyte messenger RNA.     

Germ line specific DNA and chromosomes of the ciliate Stylonychia lemnae

The variation in DNA content of the micronucleus (germinal nucleus) of Stylonychia lemnae and its relation to the number of chromosomes was examined. Different populations possess similar amounts of micronuclear DNA but there are differences of ±30% between clones of the same population. However, the DNA content varies by about 100% in the micronuclei during the lifetime of a clone. The haploid micronucleus contains 35 or 36 chromosomes which persist in the developing macronucleus anlagen and grow to giant chromosomes. Besides this remaining subset, the micronucleus contains a variable number of germ line restricted chromosomes (mean about 140; range between 100 and 180). The somatic macronucleus eliminates these elements early in its development. The varying number of the germ line restricted chromosomes is responsible for the variation in the micronuclear DNA content.     

Messenger RNA synthesis during early ascidian development.

RNA synthesis during early embryogenesis of the ascidian Ciona intestinalis was studied. Embryonic polyribosomes labeled with uridine from 5 to 7 hr after fertilization were isolated and the labeled RNA species were characterized by oligo(dT)-cellulose chromatography and sucrose gradient sedimentation analysis. Since at least 50% of the labeled RNA was polyadenylated and all of it sedimented heterogeneously, it was concluded that mRNA was synthesized during the labeling period. Further, the synthesis of heterogeneously sedimenting, polyadenylated RNA at various stages of development from midcleavage to metamorphosis indicated that gene activity and perhaps mRNA synthesis occurred at earlier and later stages of development as well. Autoradiographic studies showed that the embryonic genome was the site of this activity, since uridine incorporation was localized in embryonic cells and not in accessory cells. Finally, under the labeling conditions employed (2-hr pulses), rRNA synthesis was not detected until larvae hatched.     

Behavior of germinal micronuclei under control of the somatic macronucleus during conjugation in Paramecium caudatum.

In conjugating pairs of Paramecium caudatum, the micronuclear events occur synchronously in both members of the pair. To find out whether micronuclear behavior is controlled by the somatic macronucleus or by the germinal micronucleus, and whether or not synchronization of micronuclear behavior is due to intercellular communication between conjugating cells, the behavior of the micronucleus was examined after removal of the macronuclei from either or both cells of a mating pair at various stages of conjugation. When macronuclei were removed from both cells of a pair, micronuclear development was arrested 1 to 1.5 hr after macronuclear removal. When the macronucleus of a micronucleate cell mating with an amicronucleate cell was removed later than 3 to 3.5 hr of conjugation, that is, an early stage of meiotic prophase of the micronucleus, micronuclear events occurred normally in the operated cell. These results suggest that most micronuclear events are under the control of the macronucleus and that the gene products provided by the macronucleus are transferable between mating cells. One such product is required for induction of micronuclear division and is provided just before metaphase of the first meiotic division of the micronucleus. This factor is effective at a lower concentration in the cytoplasm and/or is more transferable between mating cells than the factors required for other stages. This factor, which seems to be present at least until the stage of micronuclear disintegration, is able to induce repeated micronuclear division as long as it remains active. The factor can act on a micronucleus which has not passed through a meiotic prophase. Moreover, the results suggest the existence of a second factor which is provided by the macronucleus after the first meiotic division that inhibits further micronuclear division.     

Cellular distribution of RNA populations in 16-cell stage embryos of the sand dollar, Dendraster excentricus

RNA was extracted from pure preparations of micromeres and meso-plus macromeres isolated from 16-cell stage embryos of Dendraster excentricus. Molecular hybridization-competition experiments disclosed that the binding of 16-cell stage labeled RNA to denatured sperm DNA was competed equally well by micromere RNA, meso-plus macromere RNA, total 16-cell RNA and unfertilized egg RNA, indicating the egg-type populations were distributed almost equally in the different blastomeres. In contrast, experiments with ³H-RNA extracted from micromeres obtained from pulse-labeled 16-cell stage embryos showed qualitative differences when unfertilized egg RNA and total 16-cell stage RNA were used as competitors. Such differences in RNA populations could not be detected in ³H-RNA isolated from the meso-plus macromere fraction.     

Micronuclear DNA of Oxytricha nova contains sequences with autonomously replicating activity in Saccharomyces cerevisiae.

Oxytricha nova is a hypotrichous ciliate with micronuclei and macronuclei. Micronuclei, which contain large, chromosomal-sized DNA, are genetically inert but undergo meiosis and exchange during cell mating. Macronuclei, which contain only small, gene-sized DNA molecules, provide all of the nuclear RNA needed to run the cell. After cell mating the macronucleus is derived from a micronucleus, a derivation that includes excision of the genes from chromosomes and elimination of the remaining DNA. The eliminated DNA includes all of the repetitious sequences and approximately 95% of the unique sequences. We cloned large restriction fragments from the micronucleus that confer replication ability on a replication-deficient plasmid in Saccharomyces cerevisiae. Sequences that confer replication ability are called autonomously replicating sequences. The frequency and effectiveness of autonomously replicating sequences in micronuclear DNA are similar to those reported for DNAs of other organisms introduced into yeast cells. Of the 12 micronuclear fragments with autonomously replicating sequence activity, 9 also showed homology to macronuclear DNA, indicating that they contain a macronuclear gene sequence. We conclude from this that autonomously replicating sequence activity is nonrandomly distributed throughout micronuclear DNA and is preferentially associated with those regions of micronuclear DNA that contain genes.