Variable copy number of macronuclear DNA molecules in Tetrahymena

In Tetrahymena, the DNA of the macronucleus exists as very large (100 to 4,000-kb) linear molecules that are randomly partitioned to the daughter cells during cell division. This genetic system leads directly to an assortment of alleles such that all loci become homozygous during vegetative growth. Apparently, there is a copy number control mechanism operative that adjusts the number of each macronuclear DNA molecule so that macronuclear DNA molecules (with their loci) are not lost and aneuploid death is a rare event. In comparing Southern analyses of the DNA from various species of Tetrahymena using histone H4 genes as a probe, we find different band intensities in many species. These differences in band intensities primarily reflect differences in the copy number of macronuclear DNA molecules. The variation in copy number of macronuclear DNA molecules in some species is greater than an order of magnitude. These observations are consistent with a developmental control mechanism that operates by increasing the macronuclear copy number of specific DNA molecules (and the genes located on these molecules) to provide the relatively high gene copy number required for highly expressed proteins. © 1992 Wiley-Liss, Inc.     

Low molecular weight DNA in the heteromeric macronuclei of two cyrtophorid ciliates

Summary— The size range of the native DNA molecules in the heteromeric macronuclei of two cyrtophorid ciliates (Trithigmostoma cucullulus, Chilodonella uncinata) was mainly investigated by using agarose gel electrophoresis. Numerous bands superimposed on a continuous spectrum of molecular sizes between about 0.35 kb and 30 kb were resolved by conventional electrophoresis. Species-specific banding patterns indicate a variation between species in the copy number of individual DNA fragments. A slight intra-specific variability of banding patterns can exist. Electrophoretic distributions for two strains of T cucullulus were indeed found to differ by at least one more intense band (‘overamplified’ sequences?). Fractionation by contour-clamped homogeneous electric field (CHEF) gel electrophoresis revealed that the size continum of macronuclear DNA molecules does not extend beyond 60–70 kb. The average size was estimated to be around 4 kb. Unresolved DNA fraction (> 1000 kb) accounted for less than 10% of the mass of cellular DNA entering CHEF gels. Macronuclear ribosomal DNA of each cyrtophorid species was identified by Southern hybridization with a Tetrahymena rDNA probe. The hybridization signal was observed on a single band of low molecular weight DNA. The corresponding size was close to 14.5 kb in Trithigmostoma and 15.5 kb in Chilodonella, which is about twice the size of monomeric rDNA in hypotrichous ciliates. We showed that S1 nuclease resistant duplexes wit half the length of the native rDNA can be formed by rapid renaturation of heat-denatured molecules and hybridized with native rDNA. This strongly suggests that the nucleotide sequence of this rDNA is a large palindrome. Unlike the hypotrichs, macronuclear rDNA in cyrtophorids should be organized into palindromic dimers as in Tetrahymena species.     

Relationships between species ofLeymus,Psathyrostachys, andHordeum (Poaceae,Triticeae) inferred from Southern hybridization of genomic and cloned DNA probes

We have used total genomic DNA as a probe to size-fractionated restriction enzyme digests of genomic DNA from a range ofTriticeae species from the generaLeymus Hochst.,Psathyrostachys Nevski, andHordeum L., and hybrids betweenHordeum andLeymus to investigate their taxonomic relationships. Genomic Southern hybridization was found to be an effective and simple way to assess the distribution and diversity of essentially species-specific and common, repetitive DNA sequences, and is hence especially useful in evolutionary studies. The DNA sequences ofH. vulgare seem to diverge substantially from those ofH. brachyantherum, H. lechleri, H. procerum, andH. depressum. The genome ofThinopyron bessarabicum shows little homology to those of theLeymus species investigated, confirming thatT. bessarabicum is not an ancestral genome inLeymus. Although the genomes ofLeymus andPsathyrostachys share substantial proportions of DNA sequences, they include divergent repeated sequences as well. Hybridization with a ribosomal DNA probe (pTa 71) showed that the coding regions containing structural genes encoding the 18 S, 5.8 S, and 26 S ribosomal RNA were conserved among the species investigated, whereas the intergenic spacer region was more variable, presenting different sizes of restriction fragments and enabling a classification of the species. The rye heterochromatin probe pSc 119.2 hybridized to DNA fromH. lechleri andT. bessarabicum, but not to DNA from the other species investigated.     

LIA4 Encodes a Chromoshadow Domain Protein Required for Genomewide DNA Rearrangements in Tetrahymena thermophila

Extensive DNA elimination occurs as part of macronuclear differentiation during Tetrahymena sexual reproduction. The identification of sequences to excise is guided by a specialized RNA interference (RNAi) machinery that targets the methylation of histone H3 lysine 9 (K9) and K27 on chromatin associated with these internal eliminated sequences (IESs). This modified chromatin is reorganized into heterochromatic subnuclear foci, which is a hallmark of their subsequent elimination. Here, we demonstrate that Lia4, a chromoshadow domain-containing protein, is an essential component in this DNA elimination pathway. LIA4 knockout (ΔLIA4) lines fail to excise IESs from their developing somatic genome and arrest at a late stage of conjugation. Lia4 acts after RNAi-guided heterochromatin formation, as both H3K9 and H3K27 methylation are established. Nevertheless, without LIA4, these cells fail to form the heterochromatic foci associated with DNA rearrangement, and Lia4 accumulates in the foci, indicating that Lia4 plays a key role in their structure. These data indicate a critical role for Lia4 in organizing the nucleus during Tetrahymena macronuclear differentiation.     

Tetrahymena Telomerase RNA levels increase during macronuclear development

Telomeres, the G-rich sequences found at the ends of eukaryotic chromosomes, ensure chromosome stability and prevent sequence loss from chromosome ends during DNA replication. During macronuclear development in Tetrahymena, the chromosomes fragment into pieces ranging from 20 kb to 1,500 kb. Tetrahymena telomerase, a ribonucleoprotein, adds telomeric (TTGGGG)_n repeats onto telomeres and onto the newly generated macronuclear DNA ends. We have investigated whether telomerase RNA levels increase during macronuclear development, since such an increase might be expected during chromosomal fragmentation. The steady-state level of the telomerase RNA component was used to estimate the abundance of telomerase present in mating and nonmating Tetrahymena. Northern blot analysis revealed that in vegetatively growing Tetrahymena, there were 18,000–40,000 copies of telomerase RNA per cell. In mating cultures, the levels of RNA increased 2-to 5-fold at 9–15 h, and 1.5- to 3.5-fold in starved nonmating cultures. This increase in telomerase RNA paralleled telomerase activity, which also increased slightly in mating and starved nonmating cells. © 1992 Wiley-Liss, Inc.     

Histone genes in macronuclear DNA of the ciliate Stylonychia mytilus

DNA in the macronucleus of Stylonychia mytilus exists as discrete gene-sized fragments which are derived from micronuclear DNA through a series of well-defined developmental events. It has been proposed that each of the DNA fragments might represent a gene and its controlling elements. We have investigated this possibility using genes which code for the five histone proteins. Macronuclear DNA fragments were fractionated according to size by agarose gel electrophoresis, the fragments transferred to nitrocellulose filters using the technique of Southern, and the filter-bound DNA hybridized with labeled cloned histone genes of the sea urchin, Psammechinus miliaris. Results indicate, first, that sequences homologous to the five individual histone gene probes are present in discrete macronuclear fragments which appear as bands in the gel hybridization assay. Secondly, for each of the five individual histone gene probes the homologous DNA fragments are several in number, ranging in size from 7.6 Kb (Kilo base pairs) to 0.73 Kb. For example, the largest of six detected fragments hybridizing to the H3 gene probe contains approximately 10 times the amount of DNA required to code for a Stylonychia H3 histone. The smallest detected fragment hybridizing to the H3 probe contains enough DNA to code for approximately two copies of the histone. Finally, in general, no two histone gene probes hybridized to the same macronuclear DNA fragment. This result indicates that genes coding for the five histones in Stylonychia are not located together on the same macronuclear DNA fragments and implies that the five functionally related genes would not be transcribed together as a polycistronic unit.     

Numbers of 5S and tRNA genes in macro- and micronuclei of Tetrahymena pyriformis

Macronuclei of Tetrahymena pyriformis contain approximately 200 copies of the genes for 25S and 17S ribosomal RNA (rRNA) per haploid genome. Micronuclei, however, contain only a few copies of the rRNA genes per haploid complement. Since macronuclei develop from, products of meiosis, fertilization and division of micronuclei, we suggested that the multiple copies of the rRNA genes in macronuclei are generated by amplification of the small number of genes in micronuclei (Yao et al., 1974). This process provides a simple mechanism for maintaining the homogeneity of the repeated rRNA genes. To test if amplification is a general mechanism operating on all repeated genes in Tetrahymena, we have examined the numbers of 5S RNA and tRNA genes in macro- and micronuclei. 5S RNA was purified by polyacrylamide gel electrophoresis and hybridized to saturation against macro- and micronuclear DNA. Approximately 0.013–0.014% of macronuclear DNA and about 0.009% of micronuclear DNA is complementary to 5S RNA. After correcting for the differences in the DNA sequence complexities between the two nuclei, we calculate that there are 300–350 5S genes per haploid macro- or micronuclear genome. From these data we conclude that there is little or no detectable amplification of the 5S genes in macronuclei relative to micronuclei. Similar studies using tRNA indicate that these genes are also highly repeated in both nuclei; about 800 genes are present per haploid genome. Thus, amplification from a small number of genes can be excluded as the mechanism for generating the repeated copies of the 5S and tRNA genes in Tetrahymena and it is likely that another, as yet unidentified, mechanism operates to maintain the homogeneity of these genes.     

A Simple and Rapid PCR-based Method to Isolate Complete Small Macronuclear Minichromosomes from Hypotrich Ciliates: 5S rDNA and S26 Ribosomal Protein Gene of Oxytricha (Sterkiella) nova

Hypotrich ciliates present a macronuclear genome consisting of gene-sized instead of chromosome-sized DNA molecules. Exploiting this unique eukaryotic genome feature, we introduce, for the first time in ciliates, a rapid and easy PCR method using telomeric primers to isolate small complete macronuclear DNA molecules or minichromosomes. Two presumably abundant macronuclear DNA molecules, containing ribosomal genes, were amplified from the Oxytricha (Sterkiella) nova complete genome after using this method, and then were cloned and sequenced. The 5S rDNA sequence of O. (S.) nova is the third one reported among hypotrich ciliates; its primary and secondary structure is compared with other eukaryotic 5S rRNAs. The ribosomal protein S26 gene is the first one reported among ciliates. This “End-End-PCR” method might be useful to obtain similar gene-sized macronuclear molecules from other hypotrich ciliates, and, therefore, to increase our knowledge on ribosomal genes in these eukaryotic microorganisms.     

Adjacent chromosomal regions can evolve at very different rates: Evolution of theDrosophila 68C glue gene cluster

Summary The 68C puff is a highly transcribed region of theDrosophila melanogaster salivary gland polytene chromosomes. Three different classes of messenger RNA originate in a 5000-bp region in the puff; each class is translated to one of the salivary gland glue proteins sgs-3, sgs-7, or sgs-8. These messenger RNA classes are coordinately controlled, with each RNA appearing in the third larval instar and disappearing at the time of puparium formation. Their disappearance is initiated by the action of the steroid hormone ecdysterone. In the work reported here, we studied evolution of this hormone-regulated gene cluster in themelanogaster species subgroup ofDrosophila. Genome blot hybridization experiments showed that five other species of this subgroup have DNA sequences that hybridize toD. melanogaster 68C sequences, and that these sequences are divided into a highly conserved region, which does not contain the glue genes, and an extraordinarily diverged region, which does. Molecular cloning of this DNA fromD. simulans, D. erecta, D. yakuba, andD. teissieri confirmed the division of the region into a slowly and a rapidly evolving protion, and also showed that the rapidly evolving region of each species codes for third instar larval salivary gland RNAs homologous to theD. melanogaster glue mRNAs. The highly conserved region is at least 13,000 bp long, and is not known to code for any RNAs.     

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.     

Variable copy number of macronuclear DNA molecules in Tetrahymena.

In Tetrahymena, the DNA of the macronucleus exists as very large (100 to 4,000-kb) linear molecules that are randomly partitioned to the daughter cells during cell division. This genetic system leads directly to an assortment of alleles such that all loci become homozygous during vegetative growth. Apparently, there is a copy number control mechanism operative that adjusts the number of each macronuclear DNA molecule so that macronuclear DNA molecules (with their loci) are not lost and aneuploid death is a rare event. In comparing Southern analyses of the DNA from various species of Tetrahymena using histone H4 genes as a probe, we find different band intensities in many species. These differences in band intensities primarily reflect differences in the copy number of macronuclear DNA molecules. The variation in copy number of macronuclear DNA molecules in some species is greater than an order of magnitude. These observations are consistent with a developmental control mechanism that operates by increasing the macronuclear copy number of specific DNA molecules (and the genes located on these molecules) to provide the relatively high gene copy number required for highly expressed proteins.     

Phylogenetic relationships amongTetrahymena species determined using the polymerase chain reaction

Summary The species of theTetrahymena pyriformis complex present a conundrum with regard to their highly conservative morphology and widely divergent molecular characteristics. We have investigated the phylogenetic relationships among these species using the nucleotide sequences from the histone H3II/H4II region of the genome. This region includes portions of the two histone coding sequences, as well as the intergenic region. The DNA sequences of these regions were amplified by the polymerase chain reaction (PCR) and the sequence of each was determined. Nucleotide substitutions and insertions/deletions within this set of sequences were compared to determine the phylogenetic relationships among the species of the complex. These data yield phylogenetic trees with identical topologies when different tree-building routines are used, indicating that the data are very robust.Glaucoma chattoni was used as an outgroup to root the trees for this analysis. The genome organization ofG. chattoni and the divergence of its histone H3II/H4II region sequence relative to those of the complex clearly indicate that this species has diverged considerably from the complex. These results show that PCR amplification analysis is feasible over considerable evolutionary distances. However, DNA-DNA hybridization may be more useful than sequence analysis in resolving the relationships among the closely related species in the complex.     

Drosophila virilis histone gene clusters lacking H1 coding segments

Summary Approximately 30–40% ofDrosophila virilis DNA complementary to clonedDrosophila histone genes is reduced to 3.4-kilobase-pair (kbp) segments by Bgl I or Bgl II digestion. The core histone genes of a 3.4-kbp Bgl II segment cloned in the plasmid pDv3/3.4 have the same order as theD. melanogaster core histone genes in the plasmid cDm500: . Nonetheless, pDv3/3.4 and cDm500 have different histone gene configurations: In pDv3/3.4, the region between the H2B and H3 genes contains 0.35 kbp and cannot encode histone H1; in cDm500, the region contains 2.0 kbp and encodes histone H1. The lack of an H1 gene between the H2B and H3 genes in 30–40% ofD. virilis histone gene clusters suggests that changes in histone gene arrays have occurred during the evolution ofDrosophila. The ancestors of modernDrosophila may have possessed multiple varieties of histone gene clusters, which were subsequently lost differentially in thevirilis andmelanogaster lineages. Alternatively, they may have possessed a single variety, which was rearranged during evolution. The H1 genes ofD. virilis andD. melanogaster did not cross-hybridize in vitro under conditions that maintain stable duplexes between DNAs that are 75% homologous. Consequently,D. virilis H1 genes could not be visualized by hybridization to an H1-specific probe and thus remain unidentified. Our observations suggest that the coding segments in the H1 genes ofD. virilis andD. melanogaster are >25% divergent. Our estimate of sequence divergence in the H1 genes ofD. virilis andD. melanogaster seems high until one considers that the coding sequences of cloned H1 genes from the closely related speciesD. melanogaster andD. simulans are 5% divergent.     

snRNA and heterochromatin formation are involved in DNA excision during macronuclear development in stichotrichous ciliates

Several models for specific excision of micronucleus-specific DNA sequences during macronuclear development in ciliates exist. While the template-guided recombination model suggests recombination events resulting in specific DNA excision and reordering of macronucleus-destined sequences (MDS) guided by a template, there is evidence that an RNA interference-related mechanism is involved in DNA elimination in holotrichous ciliates. We describe that in the stichotrichous ciliate Stylonychia, snRNAs homologous to micronucleus-specific sequences are synthesized during macronuclear differentiation. Western and in situ analyses demonstrate that histone H3 becomes methylated at K9 de novo during macronuclear differentiation, and chromatin immunoprecipitation revealed that micronucleus-specific sequences are associated with methylated H3. To link both observations, expression of a PIWI homolog, member of the RNA-induced silencing complex, was silenced. In these cells, the methylated micronucleus-specific histone H3 variant "X" is still present in macronuclear anlagen and no K9 methylation of histone H3 is observed. We suggest that snRNA recruits chromatin-modifying enzymes to sequences to be excised. Based on our and earlier observations, we believe that this mechanism is not sufficient for specific excision of sequences and reordering of MDS in the developing macronucleus and propose a model for internal eliminated sequence excision and MDS reordering in stichotrichous ciliates.     

Generation and characterization of novel antibodies highly selective for phosphorylated linked histone H1 in Tetrahymena and HeLa cells

Phosphorylated forms of Tetrahymena macronuclear histone H1 were separated from each other and from dephosphorylated H1 by cation-exchange HPLC. A homogeneous fraction of hyperphosphorylated macronuclear H1 was then used to generate novel polyclonal antibodies highly selective for phosphorylated H1 in Tetrahymena and in human cells. These antibodies fail to recognize dephosphorylated forms of H1 in both organisms and are not reactive with most other nuclear or cytoplasmic phosphoproteins including those induced during mitosis. The selectivity of these antibodies for phosphorylated forms of H1 in Tetrahymena and in HeLa argues strongly that these antibodies recognize highly conserved phosphorylated epitopes found in most H1s and from this standpoint Tetrahymena H1 is not atypical. Using these antibodies in indirect immunofluorescence analyses, we find that a significant fraction of interphase mammalian cells display a strikingly punctate pattern of nuclear fluorescence. As cells enter S-phase, nuclear staining becomes more diffuse, increases significantly, and continues to increase as cells enter mitosis. As cells exit from mitosis, staining with the anti-phosphorylated H1 antibodies is rapidly lost presumably owing to the dephosphorylation of H1. These immunofluorescent data document precisely the cell cycle changes in the level of H1 phosphorylation determined by earlier biochemical studies and suggest that these antibodies represent a powerful new tool to probe the function(s) of H1 phosphorylation in a wide variety of eukaryotic systems. Received: 3 August 1993; in revised form: 9 November 1993 / Accepted: 23 November 1993     

Related base sequences in the DNA of simple and complex organisms. III. Variability in the base sequence of the reduplicated genes for ribosomal RNA in the rabbit

A comparative study has been made of the arrangement of base sequences in the ribosomal RNA cistrons of Escherichia coliand rabbit DNA. This was accomplished by examination of the thermal stability profiles of DNA/RNA hybrids formed by the two types of ribosomal RNA under various conditions. The thermal stabilities of ribosomal RNA hybrids of rabbit origin are more dependent on the conditions of reaction during the formation and are always lower than those of E. coli RNA. It is concluded that the rabbit ribosomal RNA hybrids are formed mainly from mismatching between RNA molecules and DNA sites other than those from which they were transcribed. Thus, the cluster of ribosomal RNA cistrons in a mammalian DNA, representing a historical series of tandem duplications, exhibits intercistronic base sequence divergence. This research was supported by a research grant from the National Science Foundation (GB 6099) and a predoctoral traineeship (to R.L.M.) from the U.S. Public Health Service.     

Recent developments inRhizobium taxonomy

Recent developments inRhizobium taxonomy are presented from a molecular and evolutionary point of view. Analyses of ribosomal RNA gene sequences provide a solid basis to infer phylogenies in the Rhizobiaceae family. These studies confirmed thatRhizobium andBradyrhizobium are only distantly related and showed thatRhizobium andBradyrhizobium are related to other groups of bacteria that are not plant symbionts.Rhizobium andAgrobacterium species are intermixed. Differences in plasmid content may explain to a good extent the different behavior ofRhizobium andAgrobacterium as symbionts or pathogens. Other approaches to identify and classify bacteria such as DNA-DNA hybridization, fatty acid analysis, RFLP and RPD-PCR techniques and phylogenies derived from other genes are in general agreement to the groupings derived by ribosomal sequences. Only a small proportion of nodulated legumes have been sampled for their symbionts and more knowledge is required on the systematics and taxonomy ofRhizobium andBradyrhizobium species.     

Genome structure of Tetrahymena pyriformiis

Reassociation kinetics of DNA from the macronucleus of the ciliate, Tetrahymena pyriformis GL, has been studied. The genome size determined by the kinetic complexity of DNA was found to be 2.0×10⁸ base pairs (or 1.2×10¹¹ daltons). About 90% of the macronuclear DNA fragments 200–300 nucleotides in length reassociate at a rate corresponding to single-copy nucleotide sequences, and 7–9% at a rate corresponding to moderate repetitive sequences; 3–4% of such DNA fragments reassociate at C₀t practically equal to zero. To investigate the linear distribution of repetitive sequences, DNA fragments of high molecular weight were reassociated and reassociation products were treated with Sl-nuclease. DNA double-stranded fragments were then fractionated by size. It has been established that in the Tetrahymena genome long regions containing more than 2000 nucleotides make up about half of the DNA repetitive sequences. Another half of the DNA repetitive sequences (short DNA regions about 200–300 nucleotides long) intersperse with single-copy sequences about 1,000 nucleotides long. Thus, no more than 15% of the Tetrahymena genome is patterned on the principle of interspersing single-copy and short repetitive sequences. Most of the so called zero time binding or foldback DNA seem to be represented by inverted self-complementary (palindromic) nucleotide sequences. The conclusion has been drawn from the analysis of this fraction isolated preparatively by chromatography. About 75% of the foldback DNA is resistant to Sl-nuclease treatment. The Sl-nuclease resistance is independent of the original DNA concentration. Heat denaturation and renaturation are reversible and show both hyper and hypochromic effects. The majority of the inverted sequences are unique and about 20% are repeated tens of times. According to the equilibrium distribution in CsCl density gradients the average nucleotide content of the palindromic fraction does not differ significantly from that of total macronuclear DNA. It was shown that the largest part of this fraction of the Tetrahymena genome are not fragments of ribosomal genes.