Tudor nuclease genes and programmed DNA rearrangements in Tetrahymena thermophila

Proteins containing a Tudor domain and domains homologous to staphylococcal nucleases are found in a number of eukaryotes. These "Tudor nucleases" have been found to be associated with the RNA-induced silencing complex (A. A. Caudy, R. F. Ketting, S. M. Hammond, A. M. Denli, A. M. Bathoorn, B. B. Tops, J. M. Silva, M. M. Myers, G. J. Hannon, and R. H. Plasterk, Nature 425:411-414, 2003). We have identified two Tudor nuclease gene homologs, TTN1 and TTN2, in the ciliate Tetrahymena thermophila, which has two distinct small-RNA pathways. Characterization of single and double KOs of TTN1 and TTN2 shows that neither of these genes is essential for growth or sexual reproduction. Progeny of TTN2 KOs and double knockouts occasionally show minor defects in the small-RNA-guided process of DNA deletion but appear to be normal in hairpin RNA-induced gene silencing, suggesting that Tudor nucleases play only a minor role in RNA interference in Tetrahymena. Previous studies of Tetrahymena have shown that inserted copies of the neo gene from Escherichia coli are often deleted from the developing macronucleus during sexual reproduction (Y. Liu, X. Song, M. A. Gorovsky, and K. M. Karrer, Eukaryot. Cell 4:421-431, 2005; M. C. Yao, P. Fuller, and X. Xi, Science 300:1581-1584, 2003). This transgene deletion phenomenon is hypothesized to be a form of genome defense. Analysis of the Tudor nuclease mutants revealed exceptionally high rates of deletion of the neo transgene at the TTN2 locus but no deletion at the TTN1 locus. When present in the same genome, however, the neo gene is deleted at high rates even at the TTN1 locus, further supporting a role for trans-acting RNA in this process. This deletion is not affected by the presence of the same sequence in the macronucleus, thus providing a counterargument for the role of the macronuclear genome in specifying all sequences for deletion.

Identification of novel chromatin-associated proteins involved in programmed genome rearrangements in Tetrahymena

Extensive DNA rearrangements occur during the differentiation of the developing somatic macronuclear genome from the germ line micronuclear genome of Tetrahymena thermophila. To identify genes encoding proteins likely to be involved in this process, we devised a cytological screen to find proteins that specifically localize in macronuclear anlagen (Lia proteins) at the stage when rearrangements occur. We compared the localization of these with that of the chromodomain protein, Pdd1p, which is the most abundant known participant in this genome reorganization. We show that in live cells, Pdd1p exhibits dynamic localization, apparently shuttling from the parental to the developing nuclei through cytoplasmic bodies called conjusomes. Visualization of GFP-tagged Pdd1p also highlights the substantial three-dimensional nuclear reorganization in the formation of nuclear foci that occur coincident with DNA rearrangements. We found that late in macronuclear differentiation, four of the newly identified proteins are organized into nuclear foci that also contain Pdd1p. These Lia proteins are encoded by primarily novel genes expressed at the beginning of macronuclear differentiation and have properties or recognizable domains that implicate them in chromatin or nucleic acid binding. Three of the Lia proteins also localize to conjusomes, a result that further implicates this structure in the regulation of DNA rearrangement.

Intrastrand annealing leads to the formation of a large DNA palindrome and determines the boundaries of genomic amplification in human cancer

Amplification of large chromosomal regions (gene amplification) is a common somatic alteration in human cancer cells and often is associated with advanced disease. A critical event initiating gene amplification is a DNA double-strand break (DSB), which is immediately followed by the formation of a large DNA palindrome. Large DNA palindromes are frequent and nonrandomly distributed in the genomes of cancer cells and facilitate a further increase in copy number. Although the importance of the formation of large DNA palindromes as a very early event in gene amplification is widely recognized, it is not known how a DSB is resolved to form a large DNA palindrome and whether any local DNA structure determines the location of large DNA palindromes. We show here that intrastrand annealing following a DNA double-strand break leads to the formation of large DNA palindromes and that DNA inverted repeats in the genome determine the efficiency of this event. Furthermore, in human Colo320DM cancer cells, a DNA inverted repeat in the genome marks the border between amplified and nonamplified DNA. Therefore, an early step of gene amplification is a regulated process that is facilitated by DNA inverted repeats in the genome.

Large DNA palindromes as a common form of structural chromosome aberrations in human cancers

Breakage-fusion-bridge cycles contribute to chromosome aberrations and generate large DNA palindromes that facilitate oncogene amplification in cancer cells. At the molecular level, large DNA palindrome formation is initiated by chromosome breaks, and genomic architecture such as short inverted repeat sequences facilitates this process in mammalian cells. However, the prevalence of DNA palindromes in cancer cells is currently unknown. To determine the prevalence of DNA palindromes in human cancer cells, we have developed a new microarray-based approach called Genome-wide Analysis of Palindrome Formation (GAPF, Tanaka et al., Nat Genet 2005; 37: 320-7). This approach is based on a relatively simple and efficient method to purify "snap-back DNA" from large DNA palindromes by intramolecular base-pairing, followed by elimination of single-stranded DNA by nuclease S1. Comparison of Genome-wide Analysis of Palindrome Formation profiles between cancer and normal cells using microarray can identify genome-wide distributions of somatic palindromes. Using a human cDNA microarray, we have shown that DNA palindromes occur frequently in human cancer cell lines and primary medulloblastomas. Significant overlap of the loci containing DNA palindromes between Colo320DM and MCF7 cancer cell lines suggests regions in the genome susceptible to chromosome breaks and palindrome formation. A subset of loci containing palindromes is associated with gene amplification in Colo320DM, indicating that the location of palindromes in the cancer genome serves as a structural platform that supports subsequent gene amplification.

Induction of gene silencing by hairpin RNA expression in Tetrahymena thermophila reveals a second small RNA pathway

Unlike in other eukaryotes, in which it causes gene silencing, RNA interference (RNAi) has been linked to programmed DNA deletion in the ciliate Tetrahymena thermophila. Here we have developed an efficient method to inducibly express double-stranded RNA hairpins and demonstrated that they cause gene silencing through targeted mRNA degradation in all phases of the life cycle, including growth, starvation, and mating. This technique offers a new tool for gene silencing in this model organism. Induction of RNA hairpins causes dramatic upregulation of Dicer and Argonaute family genes, revealing a system capable of rapidly responding to double-stranded RNA. These hairpins are processed into 23- to 24-nucleotide (nt) small RNAs, which are distinctly different from the 28- to 30-nt small RNAs known to be associated with DNA deletion. Thus, two different small RNA pathways appear to be responsible for gene silencing and DNA deletion. Surprisingly, expression of the RNA hairpin also causes targeted DNA deletion during conjugation, although at low efficiencies, which suggests a possible crossover of these two molecular paths.

The condensin complex is essential for amitotic segregation of bulk chromosomes, but not nucleoli, in the ciliate Tetrahymena thermophila

The macronucleus of the binucleate ciliate Tetrahymena thermophila contains fragmented and amplified chromosomes that do not have centromeres, eliminating the possibility of mitotic nuclear division. Instead, the macronucleus divides by amitosis with random segregation of these chromosomes without detectable chromatin condensation. This amitotic division provides a special opportunity for studying the roles of mitotic proteins in segregating acentric chromatin. The Smc4 protein is a core component of the condensin complex that plays a role in chromatin condensation and has also been associated with nucleolar segregation, DNA repair, and maintenance of the chromatin scaffold. Mutants of Tetrahymena SMC4 have remarkable characteristics during amitosis. They do not form microtubules inside the macronucleus as normal cells do, and there is little or no bulk DNA segregation during cell division. Nevertheless, segregation of nucleoli to daughter cells still occurs, indicating the independence of this process and bulk DNA segregation in ciliate amitosis.

RNA-guided DNA deletion in Tetrahymena: an RNAi-based mechanism for programmed genome rearrangements

Ciliated protozoan are unicellular eukaryotes. Most species in this diverse group display nuclear dualism, a special feature that supports both somatic and germline nuclei in the same cell. Probably due to this unique life style, they exhibit unusual nuclear characteristics that have intrigued researchers for decades. Among them are large-scale DNA rearrangements, which restructure the somatic genome to become drastically different from its germline origin. They resemble the classical phenomenon of chromatin diminution in some nematodes discovered more than a century ago. The mechanisms of such rearrangements, their biological roles, and their evolutionary origins have been difficult to understand. Recent studies have revealed a clear link to RNA interference, and begin to shed light on these issues. Using the simple ciliate Tetrahymena as a model, this chapter summarizes the physical characterization of these processes, describes recent findings that connect them to RNA interference, and discusses the details of their mechanisms, potential roles in genome defense, and possible occurrences in other organisms.

The CNA1 histone of the ciliate Tetrahymena thermophila is essential for chromosome segregation in the germline micronucleus

Ciliated protozoans present several features of chromosome segregation that are unique among eukaryotes, including their maintenance of two nuclei: a germline micronucleus, which undergoes conventional mitosis and meiosis, and a somatic macronucleus that divides by an amitotic process. To study ciliate chromosome segregation, we have identified the centromeric histone gene in the Tetrahymena thermophila genome (CNA1). CNA1p specifically localizes to peripheral centromeres in the micronucleus but is absent in the macronucleus during vegetative growth. During meiotic prophase of the micronucleus, when chromosomes are stretched to twice the length of the cell, CNA1p is found localized in punctate spots throughout the length of the chromosomes. As conjugation proceeds, CNA1p appears initially diffuse, but quickly reverts to discrete dots in those nuclei destined to become micronuclei, whereas it remains diffuse and is gradually lost in developing macronuclei. In progeny of germline CNA1 knockouts, we see no defects in macronuclear division or viability of the progeny cells immediately following the knockout. However, within a few divisions, progeny show abnormal mitotic segregation of their micronucleus, with most cells eventually losing their micronucleus entirely. This study reveals a strong dependence of the germline micronucleus on centromeric histones for proper chromosome segregation.

Class I histone deacetylase Thd1p affects nuclear integrity in Tetrahymena thermophila

Class I histone deacetylases (HDACs) participate in the regulation of DNA-templated processes such as transcription and replication. Members of this class can act locally at specific sites, or they can act more globally, contributing to a baseline acetylation state, both of which actions may be important for genome maintenance and organization. We previously identified a macronuclear-specific class I HDAC in Tetrahymena thermophila called Thd1p, which is expressed early in the development of the macronucleus when it initially becomes transcriptionally active. To test the idea that Thd1p is important for global chromatin integrity in an active macronucleus, Tetrahymena cells reduced in expression of Thd1p were generated. We observed phenotypes that indicated loss of chromatin integrity in the mutant cells, including DNA fragmentation and extrusion of chromatin from the macronucleus, variable macronuclear size and shape, enlarged nucleoli, and reduced phosphorylation of histone H1 from bulk chromatin. Macronuclei in mutant cells also contained more DNA. This observation suggests a role for Thd1p in the control of nuclear DNA content, a previously undescribed role for class I HDACs. Together, these phenotypes implicate Thd1p in the maintenance of macronuclear integrity in multiple ways, probably through site-specific changes in histone acetylation since no change in the acetylation levels of bulk histones was detected in mutant cells.

Widespread and nonrandom distribution of DNA palindromes in cancer cells provides a structural platform for subsequent gene amplification

Breakage-fusion-bridge cycles contribute to chromosome instability and generate large DNA palindromes that facilitate gene amplification in human cancers. The prevalence of large DNA palindromes in cancer is not known. Here, by using a new microarray-based approach called genome-wide analysis of palindrome formation, we show that palindromes occur frequently and are widespread in human cancers. Individual tumors seem to have a nonrandom distribution of palindromes in their genomes, and a subset of palindromic loci is associated with gene amplification. This indicates that the location of palindromes in the cancer genome can serve as a structural platform that supports subsequent gene amplification. Genome-wide analysis of palindrome formation is a new approach to identify structural chromosome aberrations associated with cancer.

Communication between parental and developing genomes during tetrahymena nuclear differentiation is likely mediated by homologous RNAs

Approximately 6000 DNA elements, totaling nearly 15 Mb, are coordinately excised from the developing somatic genome of Tetrahymena thermophila. An RNA interference (RNAi)-related mechanism has been implicated in the targeting of these germline-limited sequences for chromatin modification and subsequent DNA rearrangement. The excision of individual DNA segments can be inhibited if the homologous sequence is placed within the parental somatic nucleus, indicating that communication occurs between the parental and developing genomes. To determine how the DNA content of one nucleus is communicated to the other, we assessed DNA rearrangement occurring in wild-type cells that were mated to cells that contained the normally germline-limited M element within their somatic nuclei. M-element rearrangement was blocked in the wild-type cell even when no genetic exchange occurred between mating partners, a finding that is inconsistent with any genetic imprinting models. This inhibition by the parental somatic nucleus was rapidly established between 5 and 6 hr of conjugation, near or shortly after the time that zygotic nuclei are formed. M-element small RNAs (sRNAs) that are believed to direct its rearrangement were found to rapidly accumulate during the first few hours of conjugation before stabilizing to a low, steady-state level. The period between 5 and 6 hr during which sRNA levels stabilize correlates with the time after which the parental genome can block DNA rearrangement. These data lead us to suggest that homologous sRNAs serve as mediators to communicate sequence-specific information between the parental and developing genomes, thereby regulating genome-wide DNA rearrangement, and that these sRNAs can be effectively compared to the somatic genome of both parents.

Programmed DNA deletion as an RNA-guided system of genome defense

Genomewide DNA rearrangements occur in many eukaryotes during development, but their functions and mechanisms are poorly understood. Previous studies have implicated a sequence-recognition mechanism based on RNA-mediated interactions between nuclei in ciliated protozoa. In this study, we found that the process recognized and deleted a foreign gene integrated in a Tetrahymena chromosome, suggesting an unusual mechanism of genome surveillance. We further found that injection of double-stranded RNA into the cell at specific developmental stages triggers efficient deletion of the targeted genomic regions. Together the results indicate an RNA-based mechanism that directs genomewide DNA rearrangements and serves to disable invading genetic agents.

Short inverted repeats initiate gene amplification through the formation of a large DNA palindrome in mammalian cells

Gene amplification is a common form of genomic instability in a wide variety of organisms and is often associated with tumor progression in mammals. One striking feature of many amplified genes is their organization as large inverted duplications (palindromes). Here, we describe a molecular mechanism for palindrome formation in mammalian cells that is also conserved in protists. We introduced a short (79 or 229 bp) inverted repeat into the genome of Chinese hamster ovary cells and showed that it promoted the formation of a large DNA palindrome after an adjacent DNA double-strand break. This finding suggests that short inverted repeats in the mammalian genome can have a critical role in the initiation of gene amplification. This specific mechanism may provide a novel target for cancer therapies.

Role of histone deacetylation in developmentally programmed DNA rearrangements in Tetrahymena thermophila

In Tetrahymena, as in other ciliates, development of the somatic macronucleus during conjugation involves extensive and reproducible rearrangements of the germ line genome, including chromosome fragmentation and excision of internal eliminated sequences (IESs). The molecular mechanisms controlling these events are poorly understood. To investigate the role that histone acetylation may play in the regulation of these processes, we treated Tetrahymena cells during conjugation with the histone deacetylase inhibitor trichostatin A (TSA). We show that TSA treatment induces developmental arrests in the early stages of conjugation but does not significantly affect the progression of conjugation once the mitotic divisions of the zygotic nucleus have occurred. Progeny produced from TSA-treated cells were examined for effects on IES excision and chromosome breakage. We found that TSA treatment caused partial inhibition of excision of five out of the six IESs analyzed but did not affect chromosome breakage at four different sites. TSA treatment greatly delayed in some cells and inhibited in most the excision events in the developing macronucleus. It also led to loss of the specialized subnuclear localization of the chromodomain protein Pdd1p that is normally associated with DNA elimination. We propose a model in which underacetylated nucleosomes mark germ line-limited sequences for excision.

Nongenic, bidirectional transcription precedes and may promote developmental DNA deletion in Tetrahymena thermophila

A large number of DNA segments are excised from the chromosomes of the somatic nucleus during development of Tetrahymena thermophila. How these germline-limited sequences are recognized and excised is still poorly understood. We have found that many of these noncoding DNAs are transcribed during nuclear development. Transcription of the germline-limited M element occurs from both DNA strands and results in heterogeneous transcripts of < 200 b to > 1 kb. Transcripts are most abundant when developing micro- and macronuclei begin their differentiation. Transcription is normally restricted to unrearranged DNA of micronuclei and/or developing nuclei, but germline-limited DNAs can induce their own transcription when placed into somatic macronuclei. Brief actinomycin D treatment of conjugating cells blocked M-element excision, providing evidence that transcription is important for efficient DNA rearrangement. We propose that transcription targets these germline-limited sequences for elimination by altering chromatin to ensure their accessibility to the excision machinery.

Developmentally regulated rpd3p homolog specific to the transcriptionally active macronucleus of vegetative Tetrahymena thermophila

A clear relationship exists between histone acetylation and transcriptional output, the balance of which is conferred by opposing histone acetyltransferases (HATs) and histone deacetylases (HDACs). To explore the role of HDAC activity in determining the transcriptional competency of chromatin, we have exploited the biological features of Tetrahymena as a model. Each vegetative cell contains two nuclei: a somatic, transcriptionally active macronucleus containing hyperacetylated chromatin and a transcriptionally silent, germ line micronucleus containing hypoacetylated histones. Using a PCR-based strategy, a deacetylase gene (named THD1) encoding a homolog of the yeast HDAC Rpd3p was cloned. Thd1p deacetylates all four core histones in vitro. It resides exclusively in the macronucleus during vegetative growth and is asymmetrically distributed to developing new macronuclei early in their differentiation during the sexual pathway. Together, these data are most consistent with a potential role for Thd1p in transcriptional regulation and suggest that histone deacetylation may be important for the differentiation of micronuclei into macronuclei during development.

A long stringent sequence signal for programmed chromosome breakage in Tetrahymena thermophila

Programmed chromosome breakage occurs at 50-200 specific sites in the genome of Tetrahymena thermo-phila during somatic nuclear (macronuclear) differentiation. Previous studies have identified a 15 bp sequence, the Cbs (for chromosome breakage sequence), that is necessary and sufficient to specify these sites. In this study we determined the effects of mutations in the Cbs on its ability to specify the chromosome breakage site and promote new telomere formation in conjugating cells. Twenty-one constructs with single nucleotide substitutions covering all 15 positions of the Cbs were made and tested. Fourteen of them (covering 11 positions) abolished breakage entirely, six (covering six positions, including the remaining four) caused partial loss of breakage function and one showed no detectable effect. This result indicates that the Cbs has an exceptionally long and stringent sequence requirement. It offers no evidence that the Cbs contains a separate domain for promoting new telomere formation. In addition, we found that a partially functional Cbs retained in the macronucleus does not induce chromosome breakage during vegetative growth and that excess copies of this germline-specific sequence in the somatic nucleus have little deleterious effect on cell growth.

Parental expression of the chromodomain protein Pdd1p is required for completion of programmed DNA elimination and nuclear differentiation

Thousands of DNA elimination events occur during somatic differentiation of many ciliated protozoa. In Tetrahymena, the eliminated DNA aggregates into submacronuclear structures containing the protein Pdd1p, a member of the chromodomain family. We disrupted somatic copies of PDD1, eliminating parental expression of the gene early in the sexual phase of the life cycle. Even though zygotic expression, from the undisrupted germline PDD1 copy, is activated before DNA elimination normally occurs, the somatic knockout cells suffer defects in DNA elimination, genome endoduplication, and nuclear resorption, and eventually die, demonstrating that PDD1 is essential and suggesting Pdd1p is directly involved in establishing a chromatin structure required for DNA elimination.

Flanking regulatory sequences of the Tetrahymena R deletion element determine the boundaries of DNA rearrangement

In the ciliate Tetrahymena thermophila, thousands of DNA segments of variable size are eliminated from the developing somatic macronucleus by specific DNA rearrangements. It is unclear whether rearrangement of the many different DNA elements occurs via a single mechanism or via multiple rearrangement systems. In this study, we characterized in vivo cis-acting sequences required for the rearrangement of the 1.1-kbp R deletion element. We found that rearrangement requires specific sequences flanking each side of the deletion element. The required sequences on the left side appear to span roughly a 70-bp region that is located at least 30 bp from the rearrangement boundary. When we moved the location of the left cis-acting sequences closer to the eliminated region, we observed a rightward shift of the rearrangement boundary such that the newly formed deletion junction retained its original distance from this flanking region. Likewise, when we moved the flanking region as much as 500 bp away from the deletion element, the rearrangement boundary shifted to remain in relative juxtaposition. Clusters of base substitutions made throughout this critical flanking region did not affect rearrangement efficiency or accuracy, which suggests a complex nature for this regulatory sequence. We also found that the right flanking region effectively replaced the essential sequences identified on the left side, and thus, the two flanking regions contain sequences of analogous function despite the lack of obvious sequence identity. These data taken together indicate that the R-element flanking regions contain sequences that position the rearrangement boundaries from a short distance away. Previously, a 10-bp polypurine tract flanking the M-deletion element was demonstrated to act from a distance to determine its rearrangement boundaries. No apparent sequence similarity exists between the M and R elements. The functional similarity between these different cis-acting sequences of the two elements is firm support for a common mechanism controlling Tetrahymena rearrangement.

Characterization of the Euplotes crassus macronuclear rDNA and its potential as a DNA transformation vehicle

We have cloned the macronuclear linear DNA molecule carrying the ribosomal RNA genes from the ciliated protozoan Euplotes crassus. DNA sequence analysis was carried out to locate coding regions and to determine whether sequences that have been mutated to confer antibiotic resistance are conserved in the E. crassus genes. The beginning and end of the primary transcript were mapped. In order to determine whether conserved sequences that might serve as replication origins were present, the 5' and 3' non-coding sequences from E. crassus were compared to the corresponding sequences from the macronuclear linear rDNA molecules from the following euplotid species: Euplotes vannus, Euplotes minuta, Euplotes raikovii and Euplotes rariseta. A DNA transformation construct was made by generating a putative anisomycin resistant mutation along with a mutation generating a restriction site polymorphism. Microinjection of the construct into the developing macronucleus of mated cells resulted in exconjugant cell lines with increased resistance to anisomycin. The injected rDNA with the restriction site polymorphism is detectable in the anisomycin resistant cells and appears to represent a minor fraction of the rDNA.

Antisense in abundance: the ribosome as a vehicle for antisense RNA

Insertions at some sites within rRNA variable regions can be tolerated without affecting rRNA function. Antisense RNAs inserted at such sites in the T. thermophila rRNA can eliminate phenotypically or immunologically detectable gene expression of three genes tested. This unusually effective antisense activity is probably due to the abundance, stability and favourable intracellular localization of these antisense rRNAs with respect to mRNAs. Since antisense RNAs function very well as a part of the rRNA, rRNA might also be useful as a vehicle for other RNAs that might affect cell function such as protein binding sites or trans-acting ribozymes. The robust function of the antisense ribosome system in T. thermophila should allow the use of this system to specifically suppress gene expression and to clone genes by their null or hypomorphic phenotypes. The use of the antisense ribosome in other eukaryotes has yet to be explored, but the realization of this goal is well within the realm of possibility.

An intragenic suppressor of cold sensitivity identifies potentially interacting bases in the peptidyl transferase center of Tetrahymena rRNA

Peptidyl transfer of a growing peptide on a ribosome-bound transfer RNA (tRNA) to an incoming amino acyl tRNA is the central step in translation, and it may be catalyzed primarily by the large subunit (LSU) ribosomal RNA (rRNA). Genetic and biochemical evidence suggests that the central loop of domain V of the LSU rRNA plays a direct role in peptidyl transfer. It was previously found that a single base change at a universally conserved site in this region of the Tetrahymena thermophila LSU rRNA confers anisomycin resistance (an-r) as well as extremely slow growth, cold sensitivity, and aberrant cell morphology. Because anisomycin specifically inhibits peptidyl transfer, possibly by interfering with tRNA binding, it is likely that this mutant rRNA is defective in efficiently completing one of these steps. In the present study, we have isolated an intragenic suppressor mutation located only three bases away from the original mutation that partially reverses the slow growth and cold-sensitive phenotypes. These data imply that the functional interaction of these two bases is necessary for normal rRNA function, perhaps for peptidyl transfer or tRNA binding. These data provide the first demonstration of a functional interaction between bases within this rRNA region.

Regulatory sequences for the amplification and replication of the ribosomal DNA minichromosome in Tetrahymena thermophila

We have analyzed the cis-acting sequences that regulate rRNA gene (rDNA) replication in Tetrahymena thermophila. The macronucleus of this ciliated protozoan contains 9,000 copies of a 21-kbp minichromosome in the form of a palindrome comprising two copies of the rDNA. These are derived from a single chromosomally integrated copy during conjugation through selective amplification and are maintained by replicating once per cell cycle during vegetative growth. We have developed a transformation vector and carried out a deletion analysis to determine the minimal sequences required for replication, amplification, and/or stable maintenance of the rDNA molecule. Using constructs containing progressively longer deletions, we show that only a small portion (approximately 900 bp) of the rDNA is needed for extrachromosomal replication and stable maintenance of this molecule. This core region is very near but does not include the rRNA transcription initiation site or its putative promoter, indicating that replication is not dependent on normal rRNA transcription. It includes two nearly identical nuclease-sensitive domains (D1 and D2), one of which (D1) corresponds to the physical origin of replication determined previously. Deletion of both domains abolishes replication, whereas deletion of either domain allows the molecules to replicate, indicating that only one domain is required. In addition to this core region, we have found several DNA segments, including a tandem array of a 21-nucleotide repeat (type II repeats) and sequences within the rRNA coding region, that play distinctive and important roles in maintaining the rDNA at a high copy number.