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.     

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.     

A micronucleus-limited sequence family in Tetrahymena thermophila: organization and sequence conservation.

During macronuclear development in the ciliated protozoan Tetrahymena thermophila, sequence reorganization including sequence loss occurs. Addressing questions about the organization and nucleotide sequence of micronucleus limited regions can lead to insights about mechanisms of DNA rearrangements during macronuclear development as well as mechanisms for the maintenance of the stability of micronucleus-limited sequence families. We have previously identified a moderately repetitive micronucleus-limited sequence family called X-H (family members hybridize to an approximately 450 bp Xbal-HindIII restriction fragment), completely absent from macronuclear DNA. The first member of this family which we isolated is associated with terminal sequences characteristic of a Tel-1 element, a putative micronuclear transposable element. Two additional family members have been isolated which are not closely associated with Tel-1 terminal sequences. We have nucleotide sequence data for three cloned members of the X-H family. This analysis has demonstrated that the longest cloned members of the X-H family share a region of homology of approximately 2,400 bp and are highly conserved, differing only by small insertions or deletions of 100 bp or less. The sequences from one of the sequenced family members flanking the region of homology are themselves mostly micronucleus-limited.     

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.     

Nucleotide sequence structure and consistency of a developmentally regulated DNA deletion in Tetrahymena thermophila.

DNA deletion by site-specific chromosome breakage and rejoining occurs extensively during macronuclear development in the ciliate Tetrahymena thermophila. We have sequenced both the micronuclear (germ line) and rearranged macronuclear (somatic) forms of one region from which 1.1 kilobases of micronuclear DNA are reproducibly deleted during macronuclear development. The deletion junctions lie within a pair of 6-base-pair direct repeats. The termini of the deleted sequence are not inverted repeats. The precision of deletion at the nucleotide level was also characterized by hybridization with a synthetic oligonucleotide matching the determined macronuclear (rejoined) junction sequence. This deletion occurs in a remarkably sequence-specific manner. However, a very minor degree of variability in the macronuclear junction sequences was detected and was shown to be inherent in the mechanism of deletion itself. These results suggest that DNA deletion during macronuclear development in T. thermophila may constitute a novel type of DNA recombination and that it can create sequence heterogeneity on the order of a few base pairs at rejoining junctions.     

DNA cloning and hybridization in deer species supporting the chromosome field theory

The Cervidae show the largest variation in chromosome number found within any mammalian family. The eight species of deer which are the subject of this study vary in chromosome number from 2n = 70 to 2n = 6. Three species of Bovidae are also included since they belong to a closely related family. Digestion of nuclear DNAs with the restriction endonucleases Hae III, Hpa II, Msp I, Eco RI, Xba I, Pst I and Bam HI reveals that there is a series of highly repetitive sequences forming similar band patterns in the different species. There are two bands (1100 and 550 base pairs) which are common to all species although the two families separated more than 40 million years ago. To obtain information on the degree of homology among these conserved sequences we isolated a Bam HI restriction fragment of approximately 770 base pairs from red deer DNA. This sequence was 32P labeled and hybridized by the Southern blot technique with DNAs cleaved with Bam HI, Eco RI, Hpa II and Msp I. Moreover, the same sequence was cloned in the plasmid vector pBR322 nick translated with 32P and hybridized with the DNAs of 8 species of Cervidae and 3 of Bovidae. The same cloned probe was labeled with 3H and hybridized in situ with the metaphase chromosomes of red deer (2n = 68) and Muntiacus muntjak (2n = 7 male). Homologies are still present between the highly repetitive sequences of the 8 species of Cervidae despite the drastic reorganization that led to extreme chromosome numbers. Moreover, the cloned DNA sequence was found to occupy the same position, in the proximal regions of the arms, in both red deer (2n = 68) and M. muntjak (2n = 7 male) chromosomes. The ribosomal RNA genes and the centromeres in these species have also maintained their main territory despite the drastic chromosome reorganization. These results are experimental confirmation of the chromosome field theory which predicted that each DNA sequence has an optimal territory within the centromere-telomere field and tends to occupy this same territory following chromosome reorganization.     

Characterization of a highly repetitive family of DNA sequences in the mouse.

A large proportion (0.5-1%) of total mouse DNA is cleaved by Bam HI into fragments whose size is about 500 base pairs. A cloned member of this repetitive family of DNA sequences (BAM5 family) was sequenced by the dideoxy chain termination procedure and shown to contain 507 base pairs. The sequence exhibited no unusual or remarkable features. Repetitive sequences complementary to the cloned BAM5 fragment were found in rat DNA, but not in feline or human DNA. Restriction mapping suggested that many BAM5 sequences were components of much larger repetitive DNAs which were scattered throughout the mouse genome. The BAM5 sequences within the larger repetitive DNAs did not appear to be arranged tandemly or as members of scrambled tandem repeats. RNA homologous to the cloned BAM5 sequence was detected in cultured mouse cells, but not in cultured rat cells.     

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.     

The effects of substituted pyrimidines in DNAs on cleavage by sequence-specific endonucleases.

The rates of cleavage of DNAs containing substituents at position 5 of thymine or cytosine have been measured for a variety of sequence-specific endonucleases, so as to determine which features in the DNA sequence are being probed. Phage phi e DNA fully substituted with 5-hydroxymethyluracil is cleaved more slowly by enzymes whose recognition sequences contain A-T base pairs than are DNAs containing thymine, but both types of DNA are cleaved at similar rates by enzymes recognizing sequences composed only of G-C base pairs. Phage PBS2 DNA with uracil completely substituted for thymine is cleaved slowly by several enzymes which recognize sequences containing A-T base pairs (endonucleases Hpa I, HindII, and HindIII), while the rates of cleavage by other enzymes (endonucleases EcoRI and BamHI) are not affected. Phage lambda- and P22 DNAs containing 5-bromouracil are cleaved more slowly by several enzymes (endonucleases HindIII, Hpa I, BamHI) than are thymine-containing DNAs. Enzymes that recognize sequence isomers with the composition G:C:2A:2T (endonucleases EcoRI, Hpa I, HindIII) are not equally affected by substitution at position 5 of thymine, suggesting that they differ in their contacts with A-T base pairs. DNA containing glucosylated 5-hydroxymethylcytosine in place of cytosine is resistant to cleavage by all the endonucleases examined.     

A micronucleus-limited sequence family in Tetrahymena thermophila: Organization and sequence conservation

During mocronuclear development in the ciliated protozoan Tetrahymena thermophila, sequence reorganization including sequence loss occurs. Addressing questions about the organization and nucleotide sequence of micronucleus limited regions can lead to insights about mechanisms of DNA rearrangements during macronuclear development as well as mechanisms for the maintenance of the stability of micronucleus-limited sequence families. We have previously identified a moderately repetitive micronu-cleus-limited sequence family called X-H (family members hybridize to an approximately 450 bp Xbal-HindIII restriction fragment), completely absent from macronuclear DNA. The first member of this family which we isolated is associated with terminal sequences characteristic of a Tel-1 element, a putative micronuclear transposable element. Two additional family members have been isolated which are not closely associated with Tel-1 terminal sequences. We have nucleotide sequence data for three cloned members of the X-H family. This analysis has demonstrated that the longest cloned members of the X-H family share a region of homology of approximately 2,400 bp and are highly conserved, differing only by small insertions or deletions of 100 bp or less. The sequences from one of the sequenced family members flanking the region of homology are themselves mostly micronucleus-limited. © 1992 Wiley-Liss, Inc.     

Characterization and genetic variations of satellite DNAs in Acrossocheilus paradoxus (Günther, 1868) (Cyprinidae) indicate population expansion

A Hin dIII repetitive DNA family from Acrossocheilus paradoxus , a cyprinid fish endemic to Taiwan, was isolated and identified as a tandem arrangement of satellites in the genomic DNA. Cross-hybridization revealed similar patterns across fish genera and two families and suggested that this repetitive DNA is a conserved satellite sequence in fish. Forty-five monomeric repeat units of the repetitive DNA were cloned and sequenced, and found to be approximately 210 base pairs long and to have an average base composition of 52·8% A+T. Alignment analysis by examining 45 cloned repeat DNA strands from 22 individuals from nine different streams suggested that this repetitive DNA is highly polymorphic. The variability of sequences was mainly attributable to point mutations within the sequences. Genetic distances in all repeated DNAs ranged from 0 to 0·129 (average, 0·06). The high levels of genotype diversity and low levels of nucleotide diversity in satellites suggest population expansion of A. paradoxus .     

Gene-sized macronuclear DNA molecules are clustered in micronuclear chromosomes of the ciliate Oxytricha nova.

Following the sexual phase of its life cycle, the hypotrichous ciliate Oxytricha nova transforms a copy of its chromosomal micronucleus into a macronucleus containing short, linear DNA molecules with an average size of 2.2 kilobase pairs. In addition, more than 90% of the DNA sequences in the micronuclear genome are eliminated during this process. We have examined the organization of macronuclear DNA molecules in the micronuclear chromosomes. Macronuclear DNA molecules were found to be clustered and separated by less than 550 base pairs in two cloned segments of micronuclear DNA. Recombinant clones of two macronuclear DNA molecules that are adjacent in the micronucleus were also isolated and examined by DNA sequencing. The two macronuclear DNA molecules were found to be separated by only 90 base pairs in the micronuclear genome.     

A chicken middle-repetitive DNA sequence which shares homology with mammalian ubiquitous repeats.

We have identified and sequenced two members of a chicken middle repetitive DNA sequence family. By reassociation kinetics, members of this family (termed CRl) are estimated to be present in 1500-7000 copies per chicken haploid genome. The first family member sequenced (CRlUla) is located approximately 2 kb upstream from the previously cloned chicken Ul RNA gene. The second CRl sequence (CRl)Va) is located approximately 12 kb downstream from the 3' end of the chicken ovalbumin gene. The region of homology between these two sequences extends over a region of approximately 160 base pairs. In each case, the 160 base pair region is flanked by imperfect, but homologous, short direct repeats 10-15 base pairs in length. When the CRl sequences are compared with mammalian ubiquitous interspersed repetitive DNA sequences (human Alu and Mouse Bl families), several regions of extensive homology are evident. In addition, the short nucleotide sequence CAGCCTGG which is completely conserved in ubiquitous repetitive sequence families from several mammalian species is also conserved at a homologous position in the chicken sequences. These data imply that at least certain aspects of the sequence and structure of these interspersed repeats must predate the avian-mammalian divergence. It seems that the CRl family may possibly represent an avian counterpart of the mammalian ubiquitous repeats.     

Genomic Organization and Developmental Fate of Adjacent Repeated Sequences in a Foldback DNA Clone of Tetrahymena thermophila

DNA sequence elimination and rearrangement occurs during the development of somatic cell lineages of eukaryotes and was first discovered over a century ago. However, the significance and mechanism of chromatin elimination are not understood. DNA elimination also occurs during the development of the somatic macronucleus from the germinal micronucleus in unicellular ciliated protozoa such as Tetrahymena thermophila. In this study foldback DNA from the micronucleus was used as a probe to isolate ten clones. All of those tested (4/4) contained sequences that were repetitive in the micronucleus and rearranged in the macronucleus. The presence of inverted repeated sequences was clearly demonstrated in one of them by electron microscopy. DNA sequence analysis showed that the left portion of this clone contains three tandem, directly repeated copies of a 340-bp sequence, a 120-bp portion of which appears in inverted orientation at a 1.6-kb distance. This clone, pTtFB1, was subjected to a detailed analysis of its developmental fate. Subregions were subcloned and used as probes against Southern blots of micronuclear and macronuclear DNA. We found that all subregions defined repeated sequence families in the micronuclear genome. A minimum of four different families was defined, two of which are retained in the macronucleus and two of which are completely eliminated. The inverted repeat family is retained with little rearrangement. Two of the families, defined by subregions that do not contain parts of the inverted repeat, one in the "loop" and one in the "right flanking region," are totally eliminated during macronuclear development--and contain open reading frames. A fourth family occurs in the "loop" region and is rearranged extensively during development. The two gene families that are eliminated are stable in the micronuclear genome but are not clustered together as evidenced by experiments in which DNAs from nullisomic strains are used to map family members to specific micronuclear chromosomes. The inverted repeat family is also stable in the micronuclear genome and is dispersed among several chromosomes. The significance of retained inverted repeats to the process of elimination is discussed.     

The thermal stability of DNA fragments with tandem mismatches at a d(CXYG).d(CY'X'G) site.

Temperature-Gradient Gel Electrophoresis (TGGE) was employed to determine the thermal stabilities of 28 DNA fragments, 373 bp long, with two adjacent mismatched base pairs, and eight DNAs with Watson-Crick base pairs at the same positions. Heteroduplex DNAs containing two adjacent mismatches were formed by melting and reannealing pairs of homologous 373 bp DNA fragments differing by two adjacent base pairs. Product DNAs were separated based on their thermal stability by parallel and perpendicular TGGE. The polyacrylamide gel contained 3.36 M urea and 19.2 % formamide to lower the DNA melting temperatures. The order of stability was determined in the sequence context d(CXYG).d(CY'X'G) where X.X' and Y.Y" represent the mismatched or Watson-Crick base pairs. The identity of the mismatched bases and their stacking interactions influence DNA stability. Mobility transition melting temperatures (T u) of the DNAs with adjacent mismatches were 1.0-3.6 degrees C (+/-0.2 degree C) lower than the homoduplex DNA with the d(CCAG).d(CTGG) sequence. Two adjacent G.A pairs, d(CGAG).d(CGAG), created a more stable DNA than DNAs with Watson-Crick A.T pairs at the same sites. The d(GA).d(GA) sequence is estimated to be 0.4 (+/-30%) kcal/mol more stable in free energy than d(AA).d(TT) base pairs. This result confirms the unusual stability of the d(GA).d(GA) sequence previously observed in DNA oligomers. All other DNAs with adjacent mismatched base pairs were less stable than Watson-Crick homoduplex DNAs. Their relative stabilities followed an order expected from previous results on single mismatches. Two homoduplex DNAs with identical nearest neighbor sequences but different next-nearest neighbor sequences had a small but reproducible difference in T u value. This result indicates that sequence dependent next neighbor stacking interactions influence DNA stability.     

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 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.     

A novel retroviruslike family in mouse DNA.

In the course of structural analysis of VL30 DNA elements, a recombinant retroviruslike element was encountered that contained non-VL30 long terminal repeats (LTRs) flanking internal VL30 sequences. With the aid of this novel LTR sequence probe, we cloned several DNA elements that were apparently members of a new retroviruslike family. A particular DNA element representative of this family (designated GLN) was characterized. It was approximately 8 kilobase pairs long and contained LTRs that are 430 base pairs long. It possessed an unusual primer-binding site sequence that corresponds to tRNAGln and a polypurine tract primer that is adjacent to the 3' LTR. The nucleotide sequences of the LTRs and their adjacent regions (which together housed all cis-acting retroviral functions) were different from those of known retroviruses and retroviruslike families. The comparison of three different GLN LTR sequences revealed a marked heterogeneity of U3 sequences relative to the homogeneity of R and U5 sequences. We estimate that approximately 20 to 50 copies of GLN elements are dispersed in all species of mice. GLN-related LTRs, however, are present in a much higher copy number (1,000 to 1,500 per genome). Nucleotide sequences that are more distantly related to GLN DNA are present in multiple copies in DNAs of other rodents but not in nonrodent genomes.     

A family of DNA sequences is reproducibly rearranged in the somatic nucleus of Tetrahymena.

A small family of DNA sequences is rearranged during the development of the somatic nucleus in Tetrahymena. The family is defined by 266 bp of highly conserved sequence which restriction mapping, hybridization and sequence analysis have shown is shared by a cloned micronuclear fragment and three sequences which constitute the macronuclear family. Genomic Southern hybridization experiments indicate there are five members of the family in micronuclear DNA. All of the family members are present in whole genome homozygotes and are therefore nonallelic. The three macronuclear sequences are all present in clonal cell lines and are reproducibly generated in every developing macronucleus. The rearrangement event begins 14 hours after conjugation is initiated and is nearly completed by 16 hours.