Organization of the Euplotes crassus Micronuclear Genome1

Euplotes crassus, like other hypotrichous ciliated protozoa, eliminates most of its micronuclear chromosomal DNA in the process of forming the small linear DNA molecules that comprise the macronuclear genome. By characterizing randomly selected lambda phage clones of E. crassus micronuclear DNA, we have determined the distribution of repetitive and unique sequences and the arrangement of macronuclear genes relative to eliminated DNA. This allows us to compare the E. crassus micronuclear genome organization to that of another distantly related hypotrichous ciliate, Oxytricha nova. The clones from E. crassus segregate into three prevalent classes: those containing primarily eliminated repetitive DNA (Class I); those containing macronuclear genes in addition to repetitive sequences (Class II); and those containing only eliminated unique sequence DNA (Class III). All of the repetitive sequences in these clones belong to the same highly abundant repetitive element family. Our results demonstrate that the sequence organization of the E. crassus and O. nova micronuclear genomes is related in that the macronuclear genes are clustered together in the micronuclear genome and the eliminated unique sequences occur in long stretches that are uninterrupted by repetitive sequences. In both organisms a single repetitive element family comprises the majority of the eliminated interspersed middle repetitive DNA and appears to be preferentially associated with the macronuclear sequence clusters. The similarities in the sequence organization in these two organisms suggest that clustering of macronuclear genes plays a role in the chromosome fragmentation process.     

Organization of gene and non-gene sequences in micronuclear DNA of Oxytricha nova.

In order to study the derivation of the macronuclear genome from the micronuclear genome in Oxytricha nova micronuclear DNA was partially digested with EcoRI, size fractionated, and then cloned in the lambda phage Charon 8. Clones were selected a) at random b) by hybridization with macronuclear DNA or c) by hybridization with clones of macronuclear DNA. One group of these clones contains only unique sequence DNA, and all of these had sequences that were homologous to macronuclear sequences. The number of macronuclear genes with sequences homologous to these micronuclear clones indicates that macronuclear sequences are clustered in the micronuclear genome. Many micronuclear clones contain repetitive DNA sequences and hybridize to numerous EcoRI fragments of total micronuclear DNA, yielding similar but non-identical patterns. Some micronuclear clones containing these repetitive sequences also contained unique sequence DNA that hybridized to a macronuclear sequence. These clones define a major interspersed repetitive sequence family in the micronuclear genome that is eliminated during formation of the macronuclear genome.     

Organization of the micronuclear genome of oxytricha nova

In the hypotrichous ciliated protozoan Oxytricha nova, approximately 95% of the micronuclear genome, including all of the repetitive DNA and most of the unique sequence DNA, is eliminated during the formation of the macronuclear genome. We have examined the interspersion patterns of repetitive and unique and eliminated and retained sequences in the micronuclear genome by characterizing randomly selected clones of micronuclear DNA. Three major classes of clones have been defined: (1) those containing primarily unique, retained sequences; (2) those containing only unique, eliminated sequences; and (3) those containing only repetitive, eliminated sequences. Clones of type one and three document two aspects of organization observed previously: clustering of macronuclear destined sequences and the presence of a prevalent repetitive element. Clones of the second type demonstrate for the first time that eliminated unique sequence DNA occurs in long stretches uninterrupted by repetitive sequences. To further examine repetitive sequence interspersion, we characterized the repetitive sequence family that is present in 50% of the clones (class three above). A consensus map of this element was obtained by mapping approximately 80 phage clones and by hybridization to digests of micronuclear DNA. The repeat element is extremely large (approximately 24 kb) and is interspersed with both macronuclear destined sequences and eliminated unique sequences.     

Characterization of a family of repetitive sequences that is eliminated late during macronuclear development of the hypotrichous ciliate Stylonychia lemnae

A repetitive element from the hypotrichous ciliate Stylonychia lemnae was characterized by restriction and hybridization analysis. This repetitive element is present in about 5,000–7,000 copies per haploid genome in the micronucleus and the macronuclear anlagen. Its DNA sequence is very conserved, but the length of the repetitive sequence blocs is variable. In some cases, it is associated with telomeric sequences and macronucleus–homologous sequences. Restriction analysis of genomic micronuclear and macronuclear anlagen DNA and in situ hybridization showed that the repetitive sequences are amplified during the formation of polytene chromosomes. They are localized in many bands of the polytene chromosomes and are eliminated during the degradation of the polytene chromosomes. Possible functions of the repetitive sequences during macronuclear differentiation are discussed. Dev. Genet. 21:201–211, 1997.© 1997 Wiley-Liss, Inc.     

Organization of the Euplotes crassus micronuclear genome

Euplotes crassus, like other hypotrichous ciliated protozoa, eliminates most of its micronuclear chromosomal DNA in the process of forming the small linear DNA molecules that comprise the macronuclear genome. By characterizing randomly selected lambda phage clones of E. crassus micronuclear DNA, we have determined the distribution of repetitive and unique sequences and the arrangement of macronuclear genes relative to eliminated DNA. This allows us to compare the E. crassus micronuclear genome organization to that of another distantly related hypotrichous ciliate, Oxytricha nova. The clones from E. crassus segregate into three prevalent classes: those containing primarily eliminated repetitive DNA (Class I); those containing macronuclear genes in addition to repetitive sequences (Class II); and those containing only eliminated unique sequence DNA (Class III). All of the repetitive sequences in these clones belong to the same highly abundant repetitive element family. Our results demonstrate that the sequence organization of the E. crassus and O. nova micronuclear genomes is related in that the macronuclear genes are clustered together in the micronuclear genome and the eliminated unique sequences occur in long stretches that are uninterrupted by repetitive sequences. In both organisms a single repetitive element family comprises the majority of the eliminated interspersed middle repetitive DNA and appears to be preferentially associated with the macronuclear sequence clusters. The similarities in the sequence organization in these two organisms suggest that clustering of macronuclear genes plays a role in the chromosome fragmentation process.     

Rearrangement of repeated DNA sequences during development of macronucleus in Tetrahymena thermophila.

Three clones of non-repetitive sequences and six clones containing repetitive sequences were obtained from micronuclear DNA of Tetrahymena thermophila. All the non-repetitive and three repetitive sequences had the same organization in micro- and macronuclear DNAs as revealed by blot hybridization. On the other hand, the remaining three clones with repetitive sequences had apparently different organization in the two nuclear DNAs. All these repetitive sequences showed a smear on the blot in addition to a number of discrete bands when micronuclear DNA was digested with EcoR I. In macronuclear DNAs, these sequences invariably became one or two bands and the smear disappeared. We conclude that, when a macronucleus develops from a micronucleus, the non-repetitive sequences amplify by more than 20 times with relatively few rearrangement, whereas some selected portions of repeated and/or repeat-contiguous sequences are amplified with rather extensive reorganization.     

Micronuclear genome organization in Euplotes crassus: a transposonlike element is removed during macronuclear development.

After mating, hypotrichous ciliated protozoa transform a set of their micronuclear chromosomes into thousands of short, linear DNA molecules that form the macronuclear genome. To examine micronuclear genome organization in the hypotrich Euplotes crassus, we have analyzed two cloned segments of micronuclear DNA as well as the macronuclear DNA molecules that are derived from them. E. crassus was found to display a number of features characteristic of other hypotrich genomes, including (i) clustering and close spacing of the precursors of macronuclear DNA molecules, (ii) the frequent occurrence of internal eliminated sequences within macronuclear precursors, (iii) overlapping macronuclear precursors, (iv) lack of telomeric repeats at the ends of macronuclear precursors, and (v) alternative processing of the micronuclear chromosome to yield multiple macronuclear DNA molecules. In addition, a moderately repetitive, transposonlike element that interrupts the precursors of two macronuclear DNA molecules has been identified and characterized. This transposonlike element, designated Tec1, is shown to be reproducibly removed from one of the macronuclear precursors during independent episodes of macronuclear development.     

Micronuclear and Macronuclear Sequences of a Euplotes crassus Gene Encoding a Putative Nuclear Protein Kinase

The sequences of a 1.8-kbp macronuclear DNA molecule (V3), and the majority of its micronuclear counterpart, are reported. The macronuclear V3 DNA molecule contains an open reading frame that is interrupted by a single intron, while the micronuclear copy is interrupted by four internal eliminated sequences, one of which is located within the intron. The predicted protein product of the macronuclear V3 gene is a 471-amino acid polypeptide that is very similar to a group of protein-serine/threonine kinases from both plant and animal species, some of whose members appear to be involved in cell cycle or growth control.     

Evolution of the Germline Actin Gene in Hypotrichous Ciliates: Multiple Nonscrambled IESs at Extremely Conserved Locations in Two Urostylids

In hypotrichous ciliates, macronuclear chromosomes are gene‐sized, and micronuclear genes contain short, noncoding internal eliminated segments (IESs) as well as macronuclear‐destined segments (MDSs). In the present study, we characterized the complete macronuclear gene and two to three types of micronuclear actin genes of two urostylid species, i.e. Pseudokeronopsis rubra and Uroleptopsis citrina. Our results show that (1) the gain/loss of IES happens frequently in the subclass Hypotrichia (formerly Stichotrichia), and high fragmentation of germline genes does not imply for gene scrambling; and (2) the micronuclear actin gene is scrambled in the order Sporadotrichida but nonscrambled in the orders Urostylida and Stichotrichida, indicating the independent evolution of MIC‐actin gene patterns in different orders of hypotrichs; (3) locations of MDS–IES junctions of micronuclear actin gene in coding regions are conserved among closely related species.     

Multiple Sequence Versions of the Oxytricha fallax 81-MAC Alternate Processing Family1

The 81-MAC family consists of three sizes of macronuclear chromosomes in Oxytricha fallax. Clones of these and of micronuclcar homologs have been classified according to DNA sequence into three highly homologous (95.9–97.9%), but distinct versions. Version A is represented by a micronuclear clone and by clones of two different-sized macronuclear chromosomes, showing that alternate processing of micronuclear DNA is responsible for the variety of sizes of macronuclcar chromosomes. Three Internal Eliminated Sequences (IES's) are demonstrated in Version A micronuclcar DNA. Two have been sequenced and show short, flanking direct repeats but no inverted terminal repeats. Version C micronuclear DNA has interruptions in the macronuclear homology which correspond closely to the Version A IES's. Whether they are true IES's is unknown because no Version C macronuclear DNA has been demonstrated. Version C micronuclear DNA may be “macronuclear-homologous” but “micronucleus-limited” and not “macronucleusdestined.” Version B is represented by macronuclear DNA clones, but no micronuclear clones. Vegetative micronuclear aneuploidy is suggested. The possible role of micronuclear defects in somatic karyonidai senescence is discussed in light of the precise macronuclear chromosome copy controls demonstrated within the 81-MAC family. These controls apparently operate throughout karyonidai life to mairitain 1) a constant absolute amount of 81-MAC sequences in the macronuclcus and 2) a constant sioichiometry within the family, both according to version and chromosome size.     

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.     

The Micronuclear Gene Encoding β-Telomere Binding Protein in Oxytricha nova

ABSTRACT The micronuclear version of the gene encoding β-telomere binding protein (β-TBP) in Oxytricha nova has been sequenced and compared to the macronuclear β-TBP gene, previously described. The micronuclear gene contains three AT-rich internal eliminated sequences (IES) of 37, 40, and 43 bp and four macronuclear destined sequences (MDS). The IES interrupt the gene once near the 5′ end of the coding region and twice in the 3′ trailer downstream from the TGA stop codon. The sequences of the micronuclear and macronuclear genes are colinear. Thus, the micronuclear β-TBP gene is not scrambled, which contrasts with the highly scrambled state among the 14 MDS in the micronuclear α;-TBP gene.     

Analysis of the micronuclear B type surface protein gene in Paramecium tetraurelia.

The micronuclear DNA of Paramecium contains sequences that are precisely excised during the formation of the macronuclear (somatic) genome. In this paper we show that four eliminated sequences ranging in size from 28 to 416 base pairs, are present in or near the micronuclear copy of the B surface protein gene. Each excised sequence is bounded by the dinucleotide 5'-TdA-3'. Comparison of the micronuclear B gene with the previously determined micronuclear sequence of the A surface protein gene shows that although the positions of at least three of the eliminated sequences are conserved in both genes, the sequences are highly divergent. Transformation of vegetative macronuclei with fragments of the micronuclear B gene results in replication and maintenance of the DNA, but the micronuclear specific sequences are not removed. Previous studies have shown that the correct incorporation of the B gene into the new macronucleus requires copies of the macronuclear B gene in the old macronucleus. Using macronuclear transformation, we show that the micronuclear B gene can substitute for the macronuclear B gene with regard to its role in DNA processing. This suggests that the macronuclear DNA is not acting as a guide for the excision of the micronuclear specific sequences.     

尖毛虫属Actin Ⅰ、α-TBP和DNA pol α乱序基因的模式研究

研究旨在对尖毛虫属内现有物种的3种乱序小核基因结构进行比较,探讨其乱序模式。于湛江湖光红树林水域中采集到一个尖毛虫属物种Oxytricha sp.（ZJ）,成功扩增了其肌动蛋白Ⅰ（ActinⅠ）、端粒结合蛋白（α-TBP）、DNA聚合酶α（DNA pol α）3个乱序基因的完整大核基因序列和完整/部分小核基因序列,并结合已有资料对比研究了尖毛虫属这3个乱序基因的进化。结果表明:（1）Oxytricha sp.（ZJ）与O.nova的小核Actin Ⅰ基因具有相同的乱序模式,区别于其余的尖毛虫属物种;在增加尖毛虫属物种的基础上,对前人推测提出了质疑,我们认为MDS-IES接合处移动现象在乱序MDSs之间并非比非乱序MDSs之间更保守。（2）Oxytricha sp.（ZJ）与O.nova的小核α-TBP基因具有相同乱序模式和相似长度的IESs。（3）Oxytricha sp.（ZJ）的小核DNA pol α基因乱序模式,区别于任一已报道物种,与属内O. trifallax最为相近。基于序列分析,在DNA pol α基因中发现了一例IES转换为MDS的痕迹,以及由此导致原先MDS的丢失。研究发现在编码区内IES向MDS的转变,使得本应删除的序列成为基因组永久保留的一部分。     

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.     

Rare internal C4A4 repeats in the micronuclear genome of Oxytricha fallax.

Approximately 20,000 different short, linear, macronuclear DNA molecules are derived from micronuclear sequences of Oxytricha fallax after conjugation. These macronuclear DNAs are terminated at both ends by 20 base pairs of the sequence 5'-dC4A4-3'. Sequences homologous to this repeat (C4A4+) are also abundant in the micronuclear chromosomes, but most reside at their telomeres. Here we show that nontelomeric C4A4 clusters of 20 base pairs or longer exist in only a few hundred copies per micronuclear genome. This demonstrates that nearly none of the 20,000 sequence blocks of micronuclear DNA destined to be macronuclear DNA molecules can be flanked by full-length (20-base pair) C4A4 clusters, and therefore C4A4 repeats must be added to most, if not all, macronuclear telomeres during macronuclear development. Six internal micronuclear C4A4+ loci were cloned, and their structural relationships with macronuclear and micronuclear sequences were examined. The possible origins and functions of these rare, micronuclear internal C4A4 loci are discussed.     

Common terminal repeats of the macronuclear DNA are absent from the micronuclear DNA in hypotrichous ciliate, Stylonychia pustulata.

Comparison of nucleotide sequences of a macronuclear DNA and its micronuclear counterpart of a hypotrichous ciliate, Stylonychia pustulata, demonstrates that common terminal repeats (C4A4) of the macronuclear DNA are not present at the corresponding region in the micronuclear genome. The results indicate that the common terminal C4A4 repeat is added or translocated during or after the rearrangement of the micronuclear DNA to the macronuclear DNA.     

Multiple sequence versions of the Oxytricha fallax 81-MAC alternate processing family

The 81-MAC family consists of three sizes of macronuclear chromosomes in Oxytricha fallax. Clones of these and of micronuclear homologs have been classified according to DNA sequence into three highly homologous (95.9-97.9%), but distinct versions. Version A is represented by a micronuclear clone and by clones of two different-sized macronuclear chromosomes, showing that alternate processing of micronuclear DNA is responsible for the variety of sizes of macronuclear chromosomes. Three Internal Eliminated Sequences (IES's) are demonstrated in Version A micronuclear DNA. Two have been sequenced and show short, flanking direct repeats but no inverted terminal repeats. Version C micronuclear DNA has interruptions in the macronuclear homology which correspond closely to the Version A IES's. Whether they are true IES's is unknown because no Version C macronuclear DNA has been demonstrated. Version C micronuclear DNA may be "macronuclear-homologous" but "micronucleus-limited" and not "macronucleus-destined." Version B is represented by macronuclear DNA clones, but no micronuclear clones. Vegetative micronuclear aneuploidy is suggested. The possible role of micronuclear defects in somatic karyonidal senescence is discussed in light of the precise macronuclear chromosome copy controls demonstrated within the 81-MAC family. These controls apparently operate throughout karyonidal life to maintain 1) a constant absolute amount of 81-MAC sequences in the macronucleus and 2) a constant stoichiometry within the family, both according to version and chromosome size.