A fission yeast chromosome can replicate autonomously in mouse cells

Dispatched uses Na+ flux to power release of lipid-modified Hedgehog

The Dispatched protein, which is related to the NPC1 and PTCH1 cholesterol transporters1,2 and to H+-driven transporters of the RND family3,4, enables tissue-patterning activity of the lipid-modified Hedgehog protein by releasing it from tightly -localized sites of embryonic expression5-10. Here we determine a cryo-electron microscopy structure of the mouse protein Dispatched homologue 1 (DISP1), revealing three Na+ ions coordinated within a channel that traverses its transmembrane domain. We find that the rate of Hedgehog export is dependent on the Na+ gradient across the plasma membrane. The transmembrane channel and Na+ binding are disrupted in DISP1-NNN, a variant with asparagine substitutions for three intramembrane aspartate residues that each coordinate and neutralize the charge of one of the three Na+ ions. DISP1-NNN and variants that disrupt single Na+ sites retain binding to, but are impaired in export of the lipid-modified Hedgehog protein to the SCUBE2 acceptor. Interaction of the amino-terminal signalling domain of the Sonic hedgehog protein (ShhN) with DISP1 occurs via an extensive buried surface area and contacts with an extended furin-cleaved DISP1 arm. Variability analysis reveals that ShhN binding is restricted to one extreme of a continuous series of DISP1 conformations. The bound and unbound DISP1 conformations display distinct Na+-site occupancies, which suggests a mechanism by which transmembrane Na+ flux may power extraction of the lipid-linked Hedgehog signal from the membrane. Na+-coordinating residues in DISP1 are conserved in PTCH1 and other metazoan RND family members, suggesting that Na+ flux powers their conformationally driven activities.

Molecular organization of recombinant human-Arabidopsis chromosomes in hybrid cell lines

Although plants and animals are evolutionarily distant, the structure and function of their chromosomes are largely conserved. This allowed the establishment of a human-Arabidopsis hybrid cell line in which a neo-chromosome was formed by insertion of segments of Arabidopsis chromosomes into human chromosome 15. We used this unique system to investigate how the introgressed part of a plant genome was maintained in human genetic background. The analysis of the neo-chromosome in 60- and 300-day-old cell cultures by next-generation sequencing and molecular cytogenetics suggested its origin by fusion of DNA fragments of different sizes from Arabidopsis chromosomes 2, 3, 4, and 5, which were randomly intermingled rather than joined end-to-end. The neo-chromosome harbored Arabidopsis centromeric repeats and terminal human telomeres. Arabidopsis centromere wasn’t found to be functional. Most of the introgressed Arabidopsis DNA was eliminated during the culture, and the Arabidopsis genome in 300-day-old culture showed significant variation in copy number as compared with the copy number variation in the 60-day-old culture. Amplified Arabidopsis centromere DNA and satellite repeats were localized at particular loci and some fragments were inserted into various positions of human chromosome. Neo-chromosome reorganization and behavior in somatic cell hybrids between the plant and animal kingdoms are discussed.

Large domains of heterochromatin direct the formation of short mitotic chromosome loops

During mitosis chromosomes reorganise into highly compact, rod-shaped forms, thought to consist of consecutive chromatin loops around a central protein scaffold. Condensin complexes are involved in chromatin compaction, but the contribution of other chromatin proteins, DNA sequence and histone modifications is less understood. A large region of fission yeast DNA inserted into a mouse chromosome was previously observed to adopt a mitotic organisation distinct from that of surrounding mouse DNA. Here, we show that a similar distinct structure is common to a large subset of insertion events in both mouse and human cells and is coincident with the presence of high levels of heterochromatic H3 lysine nine trimethylation (H3K9me3). Hi-C and microscopy indicate that the heterochromatinised fission yeast DNA is organised into smaller chromatin loops than flanking euchromatic mouse chromatin. We conclude that heterochromatin alters chromatin loop size, thus contributing to the distinct appearance of heterochromatin on mitotic chromosomes.

Introduction of large insert DNA into mammalian cells and embryos

This unit provides a set of protocols for introducing large insert DNA into cultured mammalian cells and embryos. Two different methods, spheroplast fusion and lipofection, are described for effecting transfer of YACs or gel-purified YAC DNA into cells. Additional protocols discuss preparing and transferring BACs into cells by lipofection and into embryos by microinjection.

Characterization of a Schizosaccharomyces pombe strain deleted for a sequence homologue of the human damaged DNA binding 1 (DDB1) gene

Human damaged DNA-binding protein (DDB) is a heterodimer of p48/DDB2 and p127/DDB1 subunits. Mutations in DDB2 are responsible for Xeroderma Pigmentosum group E, but no mutants of mammalian DDB1 have been described. To study DDB1, the Schizosaccharomyces pombe DDB1 sequence homologue (ddb1(+)) was cloned, and a ddb1 deletion strain was constructed. The gene is not essential; however, mutant cells showed a 37% impairment in colony-forming ability, an elongated phenotype, and abnormal nuclei. The ddb1Delta strain was sensitive to UV irradiation, X-rays, methylmethane sulfonate, and thiabendazole, and these sensitivities were compared with those of the well characterized rad13Delta, rhp51Delta, and cds1Delta mutant strains. Ddb1p showed nuclear and nucleolar localization, and the aberrant nuclear structures observed in the ddb1Delta strain suggest a role for Ddb1p in chromosome segregation.

Four chromo-domain proteins of Schizosaccharomyces pombe differentially repress transcription at various chromosomal locations

Transcription is repressed in regions of the fission yeast genome close to centromeres, telomeres, or the silent mating-type cassettes mat2-P and mat3-M. The repression involves the chromo-domain proteins Swi6 and Clr4. We report that two other chromo-domain proteins, Chp1 and Chp2, are also important for these position effects. Chp1 showed a specificity for centromeric regions. Its essentiality for the transcriptional repression of centromeric markers correlates with its importance for chromosome stability. Chp2 appeared more pleiotropic. Its effects on centromeric silencing were less pronounced than those of Chp1, and it participated in telomeric position effects and transcriptional silencing in the mating-type region. We also found that PolII-transcribed genes were repressed when placed in one of the Schizosaccharomyces pombe rDNA clusters, a situation analogous to that in the budding yeast Saccharomyces cerevisiae. Chp2, Swi6, Clr4, and, to a lesser extent, Chp1 participated in that repression.

Investigation of Schizosaccharomyces pombe as a cloning host for human telomere and alphoid DNA

The fission yeast Schizosaccharomyces pombe (Sch. pombe) has been proposed as a possible cloning host for both mammalian artificial chromosomes (MACs) and mammalian genomic libraries, due to the large size of its chromosomes and its similarity to higher eukaryotic cells. Here, it was investigated for its ability to form telomeres from human telomere sequence and to stably maintain long stretches of alphoid DNA. Using linear constructs terminating in the telomere repeat, T2AG3, human telomere DNA was shown to efficiently seed telomere formation in Sch. pombe. Much of the human telomeric sequence was removed on addition of Sch. pombe telomeric sequence, a process similar to that described in S. cerevisiae. To investigate the stability of alphoid DNA in fission yeast, bacterial artificial chromosomes (BACs) containing 130 and 173 kb of alphoid DNA were retrofitted with the Sch. pombe ars1 element and ura4+ marker using Cre-lox recombination. These alphoid BACs were found to be highly unstable in Sch. pombe deleting down to less than 40 kb, whilst control BACs of 96 and 202 kb, containing non-repetitive DNA, were unrearranged. Alphoid DNA has been shown to be sufficient for human centromere function, and this marked instability excludes Sch. pombe as a useful cloning host for mammalian artificial chromosomes. In addition, regions containing repetitive DNA from mammalian genomes may not be truly represented in libraries constructed in Sch. pombe.

A Schizosaccharomyces pombe artificial chromosome large DNA cloning system

The feasibility of using the fission yeast, Schizosaccharomyces pombe , as a host for the propagation of cloned large fragments of human DNA has been investigated. Two acentric vector arms were utilized; these carry autonomously replicating sequences ( ars elements), selectable markers ( ura4(+) or LEU2 ) and 250 bp of S. pombe terminal telomeric repeats. All cloning was performed between the unique sites in both vector arms for the restriction endonuclease Not I. Initially the system was tested by converting six previously characterized cosmids from human chromosome 11p13 into a form that could be propagated in S.pombe as linear episomal elements of 50-60 kb in length. In all transformants analysed these cosmids were maintained intact. To test if larger fragments of human DNA could also be propagated total human DNA was digested with Not I and size fractionated by pulsed field gel electrophoresis (PFGE). Fractions of 100-1000 kb were ligated to Not I-digested vector arms and transformed into S.pombe protoplasts in the presence of lipofectin. Prototrophic ura+leu+transformants were obtained which upon examination by PFGE were found to contain additional linear chromosomes migrating at between 100 and 500 kb with a copy number of 5-10 copies/cell. Hybridization analyses revealed that these additional bands contained human DNA. Fluorescent in situ hybridization (FISH) analyses of several independent clones indicated that the inserts were derived from single loci within the human genome. These analyses clearly demonstrate that it is possible to clone large fragments of heterologous DNA in fission yeast using this S.p ombe artificial chromosome system which we have called SPARC. This vector-host system will complement the various other systems for cloning large DNA fragments.

Analysis of extrachromosomal structures containing human centromeric alphoid satellite DNA sequences in mouse cells

Yeast artificial chromosomes (YACs) spanning the centromeric region of the human Y chromosome were introduced into mouse LA-9 cells by spheroplast fusion in order to determine whether they would form mammalian artificial chromosomes. In about 50% of the cell lines generated, the YAC DNA was associated with circular extrachromosomal structures. These episomes were only present in a proportion of the cells, usually at high copy number, and were lost rapidly in the absence of selection. These observations suggest that, despite the presence of centromeric sequences, the structures were not segregating efficiently and thus were not forming artificial chromosomes. However, extrachromosomal structures containing alphoid DNA appeared cytogenetically smaller than those lacking it, as long as yeast DNA was also absent. This suggests that alphoid DNA can generate the condensed chromatin structure at the centromere.

Telomerase activation in mouse mammary tumors: lack of detectable telomere shortening and evidence for regulation of telomerase RNA with cell proliferation

Activation of telomerase in human cancers is thought to be necessary to overcome the progressive loss of telomeric DNA that accompanies proliferation of normal somatic cells. According to this model, telomerase provides a growth advantage to cells in which extensive terminal sequence loss threatens viability. To test these ideas, we have examined telomere dynamics and telomerase activation during mammary tumorigenesis in mice carrying a mouse mammary tumor virus long terminal repeat-driven Wnt-1 transgene. We also analyzed Wnt-1-induced mammary tumors in mice lacking p53 function. Normal mammary glands, hyperplastic mammary glands, and mammary carcinomas all had the long telomeres (20 to 50 kb) typical of Mus musculus and did not show telomere shortening during tumor development. Nevertheless, telomerase activity and the RNA component of the enzyme were consistently upregulated in Wnt-1-induced mammary tumors compared with normal and hyperplastic tissues. The upregulation of telomerase activity and RNA also occurred during tumorigenesis in p53-deficient mice. The expression of telomerase RNA correlated strongly with histone H4 mRNA in all normal tissues and tumors, indicating that the RNA component of telomerase is regulated with cell proliferation. Telomerase activity in the tumors was elevated to a greater extent than telomerase RNA, implying that the enzymatic activity of telomerase is regulated at additional levels. Our data suggest that the mechanism of telomerase activation in mouse mammary tumors is not linked to global loss of telomere function but involves multiple regulatory events including upregulation of telomerase RNA in proliferating cells.

Replication of yeast DNA and novel chromosome formation in mouse cells

To determine whether yeast DNA can replicate or segregate in mammalian cells, we have transferred genomic DNA from the yeast Saccharomyces cerevisiae into mouse cells. Most of the lines contained stably integrated yeast DNA. However, in two of the lines, the yeast DNA was maintained as numerous small extrachromosomal elements which were still present after 26 cell divisions in selection but which were lost rapidly out of selection. This indicates that, although yeast DNA can replicate in mouse cells, the yeast centromere does not function to give segregation. In one cell line we observed a large novel chromosome consisting almost entirely of yeast DNA. This chromosome segregates well and contains mouse centromeric minor satellite DNA and variable amounts of major satellite DNA which probably comprise the functional centromere. The yeast DNA in the novel chromosome has a compacted chromatin structure which may be responsible for the efficient formation of anaphase bridges. Furthermore, yeast DNA integrated into mouse chromosomes forms constrictions at the point of integration. These features have previously been presumed to be hallmarks of centromeric function in transfection assays aimed at identifying putative centromeric DNA. Hence our results suggest caution be exercised in the interpretation of such assays.

Localization of centromere function in a Drosophila minichromosome

The DNA elements responsible for centromere activity in a metazoan have been localized using the Drosophila minichromosome Dp1187. Deleted minichromosomes were generated by irradiation mutagenesis, and their molecular structures were determined by pulsed-field Southern blot analysis. Analyses of the transmission behavior of Dp1187 derivatives localized sequences necessary for chromosome inheritance within the centric heterochromatin. The essential core of the centromere is contained within a 220 kb region that includes significant amounts of complex DNA. Completely normal inheritance also requires approximately 200 kb on either side of the essential core. This flanking DNA predominantly contains highly repeated sequences, and the amount required for normal transmission differs among division types and between the sexes. We propose that the essential core is the site of kinetochore formation and that flanking DNA provides two functions: sister chromatid cohesion and indirect assistance in kinetochore formation or function.

CENP-B binds a novel centromeric sequence in the Asian mouse Mus caroli

Minor satellite DNA, found at Mus musculus centromeres, is not present in the genome of the Asian mouse Mus caroli. This repetitive sequence family is speculated to have a role in centromere function by providing an array of binding sites for the centromere-associated protein CENP-B. The apparent absence of CENP-B binding sites in the M. caroli genome poses a major challenge to this hypothesis. Here we describe two abundant satellite DNA sequences present at M. caroli centromeres. These satellites are organized as tandem repeat arrays, over 1 Mb in size, of either 60- or 79-bp monomers. All autosomes carry both satellites and small amounts of a sequence related to the M. musculus major satellite. The Y chromosome contains small amounts of both major satellite and the 60-bp satellite, whereas the X chromosome carries only major satellite sequences. M. caroli chromosomes segregate in M. caroli x M. musculus interspecific hybrid cell lines, indicating that the two sets of chromosomes can interact with the same mitotic spindle. Using a polyclonal CENP-B antiserum, we demonstrate that M. caroli centromeres can bind murine CENP-B in such an interspecific cell line, despite the absence of canonical 17-bp CENP-B binding sites in the M. caroli genome. Sequence analysis of the 79-bp M. caroli satellite reveals a 17-bp motif that contains all nine bases previously shown to be necessary for in vitro binding of CENP-B. This M. caroli motif binds CENP-B from HeLa cell nuclear extract in vitro, as indicated by gel mobility shift analysis. We therefore suggest that this motif also causes CENP-B to associate with M. caroli centromeres in vivo. Despite the sequence differences, M. caroli presents a third, novel mammalian centromeric sequence producing an array of binding sites for CENP-B.

Robertsonian metacentrics of the house mouse lose telomeric sequences but retain some minor satellite DNA in the pericentromeric area

A combination of cytogenetic and molecular biology techniques were used to study the molecular composition and organisation of the pericentromeric regions of house mouse metacentric chromosomes, the products of Robertsonian (Rb) translocations between telocentrics. Regardless of whether mitotic or meiotic preparations were used, in situ hybridisation failed to reveal pericentromeric telomeric sequences on any of the Rb chromosomes, while all metacentrics retained detectable, although reduced (average 50 kb), amounts of minor satellite DNA in the vicinity of their centromeres. These results were supported by slot blot hybridisation which indicated that mice with 2n=22 Rb chromosomes have 65% of telomeric sequences (which are allocated to the distal telomeres of both Rb and telocentric chromosomes and to the proximal telomeres of telocentrics) and 15% the amount of minor satellite, compared with mice with 2n=40 all-telocentric chromosomes. Pulsed field gel electrophoresis and Southern analysis of DNA from Rb mice showed that the size of the telomeric arrays is similar to that of mice with all-telocentric chromosomes and that the minor satellite sequences were hybridising to larger fragments incorporating major satellite DNA. Since the telomeric sequences are closer to the physical end of the chromosome than the minor satellite sequences, the absence of telomeric sequences and the reduced amount of minor satellite sequences at the pericentromeric region of the Rb metacentrics suggest that the breakpoints for the Rb translocation occur very close to the minor satellite-major satellite border. Moreover, it is likely that the minor satellite is required for centromeric function, 50-67 kb being enough DNA to organise one centromere with a functionally active kinetochore.

Unusual chromosome structure of fission yeast DNA in mouse cells

Chromosomes from the fission yeast Schizosaccharomyces pombe have been introduced into mouse cells by protoplast fusion. In most cell lines the yeast DNA integrates into a single site within a mouse chromosome and results in striking chromosome morphology at metaphase. Both light and electron microscopy show that the yeast chromosome region is narrower than the flanking mouse DNA. Regions of the yeast insert stain less intensely with propidium iodide than surrounding DNA and bear a morphological resemblance to fragile sites. We investigate the composition of the yeast transgenomes and the modification and chromatin structure of this yeast DNA in mouse cells. We suggest that the underlying basis for the structure we see lies above the level of DNA modification and nucleosome assembly, and may reflect the attachment of the yeast DNA to the rodent cell nucleoskeleton. The yeast integrant replicates late in S phase at a time when G bands of the mouse chromosomes are being replicated, and participates in sister chromatid exchanges at a high frequency. We discuss the implications of these studies to the understanding of how chromatin folding relates to metaphase chromosome morphology and how large stretches of foreign DNA behave when introduced into mammalian cells.

Generation of random internal deletion derivatives of YACs by homologous targeting to Alu sequences

To facilitate the manipulation of human genomic DNA in yeast artificial chromosome (YAC) clones, a plasmid to integrate the selective marker for antibiotic G418 resistance into YACs and to delete some of the human DNA fragments from YACs was constructed. The linearized integration/deletion plasmid, which contains Alu family sequences at both ends, can recombine with YACs containing human repetitive sequences via homologous recombination. The homologous recombination results in a random integration of the antibiotic G418-resistant gene into a human genomic Alu sequence, and in most cases, an internal deletion within the YAC. The YACs with internal deletions can be useful to identify the location of the genes if they produce functional knockouts. In those cases when the integration/deletion event disrupts the integrity of the gene so it no longer can produce a viable and functional mRNA in fused eukaryotic cells, the site of integration in the YAC thus serves as a marker for the inactivated gene. In this report we describe a model system to locate specific genes in YACs.

Mouse centromere mapping using oligonucleotide probes that detect variants of the minor satellite

Cytologically, the centromere is found at the very end of most Mus musculus chromosomes, co-localizing with an array of minor satellite sequences. It is separated from the euchromatin of the long arm by a large domain of heterochromatin, composed in part of arrays of major satellite sequences. We used oligonucleotide probes that specifically detect regions of sequence variation found in certain cloned minor satellite sequences. They detect a limited subset of the minor satellite arrays in the mouse genome, based on both pulsed-field gel electrophoresis and in situ hybridization data, and provide direct molecular genetic markers for individual centromeres in some inbred mouse strains. Array size polymorphisms detected by these probes map to positions consistent with the centromeres of chromosomes 1 and 14 in the BXD recombinant inbred (RI) strains. The genetic distances between these minor satellite arrays and loci on the long arms of chromosomes 1 and 14 are consistent with repression of meiotic recombination in the heterochromatic domains separating them. The existence of chromosome-specific minor satellite sequences implies that the rate of sequence exchange between non-homologous chromosomes relative to the rate between homologous chromosomes is much lower than has previously been postulated. We suggest that the high degree of sequence homogeneity of mouse satellite sequences may instead reflect recent common ancestry.

Introduction of YACs containing a putative mammalian replication origin into mammalian cells can generate structures that replicate autonomously

Yeast artificial chromosomes (YACs) containing or lacking a biochemically defined DNA replication origin were transferred from yeast to mammalian cells in order to determine whether origin-dependent autonomous replication would occur. A specialized YAC vector was designed to enable selection for YACs in mammalian cells and for monitoring YAC abundance in individual mammalian cells. All of eight clones made with linear and circularized YACs lacking the origin and seven of nine clones made with linear and circularized YACs containing the origin region contained single copies of the transfected YAC, along with various amounts of yeast DNA, integrated into single but different chromosomal sites. By contrast, two transformants derived from circularized YACs containing the putative replication origin showed very heterogeneous YAC copy number and numerous integration sites when analyzed after many generations of in vitro propagation. Analysis of both clones at an early time after fusion revealed variously sized extrachromosomal YAC/yeast structures reminiscent of the extrachromosomal elements found in some cells harboring amplified genes. The data are consistent with the interpretation that YACs containing a biochemically defined origin of replication can initially replicate autonomously, followed by integration into multiple chromosomal locations, as has been reported to occur in many examples of gene amplification in mammalian cells.

Identification and characterization of a complex chromosomal replication origin in Schizosaccharomyces pombe

In the budding yeast, S. cerevisiae, two-dimensional (2D) gel electrophoresis techniques permit mapping of DNA replication origins to short stretches of DNA (+/- 300 bp). In contrast, in mammalian cells and Drosophila, 2D gel techniques do not permit precise origin localization; the results have been interpreted to suggest that replication initiates in broad zones (several kbp or more). However, alternative techniques (replication timing, nascent strand polarity analysis, nascent strand size analysis) suggest that mammalian origins can be mapped to short DNA stretches, just like S. cerevisiae origins. Because the fission yeast, Schizosaccharomyces pombe, resembles higher organisms in several ways to a greater extent than does S. cerevisiae, we thought that S. pombe replication origins might prove to resemble--and thus be helpful models for--animal cell origins. An attempt to test this possibility using 2D gel techniques resulted in identification of a replication origin near the ura4 gene on chromosome III of S. pombe. The 2D gel patterns produced by this S. pombe origin indeed resemble the patterns produced by animal cell origins and show that the S. pombe origin cannot be precisely located. The data suggest an initiation zone of 3-5 kbp. Some aspects of the 2D gel patterns detected at the S. pombe origin cannot be explained by the rationale of initiation in broad zones, suggesting that future biochemical and genetic studies of this complex origin are likely to provide information useful in helping to understand the apparent conflict between the 2D gel mapping techniques and other mapping techniques at animal cell origins.

Complete coverage of the Schizosaccharomyces pombe genome in yeast artificial chromosomes

The genome of the fission yeast, Schizosaccharomyces pombe, consists of some 14 million base pairs of DNA contained in three chromosomes. On account of its excellent genetics we used it as a test system for a strategy designed to map mammalian chromosomes and genomes. Data obtained from hybridization fingerprinting established an ordered library of 1,248 yeast artificial chromosome clones with an average size of 535 kilobases. The clones fall into three contigs completely representing the three chromosomes of the organism. This work provides a high resolution physical and clone map of the genome, which has been related to available genetic and physical map information.

Transgenic mice generated by pronuclear injection of a yeast artificial chromosome

Transgenic mice have become invaluable for analysing gene function and regulation in vivo. However, the size of constructs injected has been limited by the cloning capacity of conventional vectors, a constraint that could be overcome with yeast artificial chromosomes (YACs). We investigated the feasibility of making transgenic mice with YACs by pronuclear injection of a small YAC carrying a gene encoding tyrosinase. Use of a vector with a conditional centromere allowed fifteenfold amplification of the YAC in yeast and its recovery in high yield. The albino phenotype of the recipient mice was rescued demonstrating the correct expression of the tyrosine gene from the construct. Furthermore, the telomeric sequences added by the yeast integrated into the mouse genome and did not reduce efficiency of integration. Using this technique future experiments with longer YACs will allow the expression of gene complexes such as Hox and the globin gene clusters to be analysed in transgenic animals.

Molecular cloning and analysis of Schizosaccharomyces pombe rad9, a gene involved in DNA repair and mutagenesis

The mutant allele rad9-192 renders Schizosaccharomyces pombe cells sensitive to ionizing radiation and UV light. We have isolated from a S. pombe genomic DNA library a unique recombinant plasmid that is capable of restoring wild-type levels of radioresistance to a rad9-192-containing cell population. Plasmid integration studies using the cloned DNA, coupled with mating and tetrad analyses, indicate that this isolated DNA contains the wild-type rad9 gene. We inactivated the repair function of the cloned fragment by a single insertion of the S. pombe ura4 gene. This nonfunctional fragment was used to create a viable disruption mutant, thus demonstrating that the rad9 gene does not encode an essential cellular function. In addition, the rad9-192 mutant population is as radiosensitive as the disruption mutant, indicating that rad9 gene function is severely if not totally inhibited by the molecular defect responsible for the rad9-192 phenotype. DNA sequence analysis of rad9 reveals an open reading frame of 1,278 bp, interrupted by three introns 53 bp, 57 bp, and 56 bp long, respectively, and ending in the termination codon TAG. This gene is capable of encoding a protein of 426 amino acids, with a corresponding calculated molecular weight of 47,464 daltons. No significant homology was detected between the rad9 gene or its deduced protein sequence and sequences previously entered into DNA and protein sequence data banks.

Alignment of Sfi I sites with the Not I restriction map of Schizosaccharomyces pombe genome

A Sfi I restriction map of the fission yeast Schizosaccharomyces pombe genome was aligned with the Not I restriction map. There are 16 Sfi I sites in the S. pombe genome. Three Sfi I sites are on chromosome III which is devoid of Not I sites. The sizes of the entire genome and individual chromosomes, calculated from the Sfi I fragment sizes, are consistent with that calculated from the Not I fragment sizes. The Sfi I map provides greater physical characterization of the S. pombe genome and further validates the use of S. pombe chromosomal DNA as size standard. These maps have allowed detection of polymorphism on all three chromosomes.

Characterization of the POL3 gene product from Schizosaccharomyces pombe indicates inter-species conservation of the catalytic subunit of DNA polymerase delta

The Schizosaccharomyces pombe POL3 gene was isolated by sequence homology with a region of the Saccharomyces cerevisiae POL3 gene, the only gene sequenced to date encoding the catalytic subunit of eukaryotic DNA polymerase delta. The fission yeast POL3 gene contains a 52 base-pair (bp) intron and encodes a 3600 bp transcript the 5'-end of which is located 32 bp upstream from the initiation codon. The polypeptides predicted from budding and fission yeast POL3 genes share 52% of conserved amino acid residues and have a 60% identical central region. This structural conservation of the catalytic subunit of DNA polymerases delta is probably related to functional constraints. A portion of the most conserved region was used to raise antibodies against an S. pombe polymerase delta/beta-galactosidase fusion protein expressed in Escherichia coli. The purified antibodies recognized a 123,000 Da protein in S. pombe wild-type cell extracts and inhibited an aphidicolin-sensitive DNA polymerase activity that was distinct from DNA polymerase alpha. The antibodies also detected a 140,000 Da protein in extracts from different proliferating mammalian cells, indicating that the catalytic subunits of DNA polymerase delta are highly conserved between yeast and higher eukaryotes.

Transfer of yeast artificial chromosomes from yeast to mammalian cells

Human DNA can be cloned as yeast artificial chromosomes (YACs), each of which contains several hundred kilobases of human DNA. This DNA can be manipulated in the yeast host using homologous recombination and yeast selectable markers. In relatively few steps it is possible to make virtually any change in the cloned human DNA from single base pair changes to deletions and insertions. In order to study the function of the cloned DNA and the effects of the changes made in the yeast, the human DNA must be transferred back into mammalian cells. Recent experiments indicate that large genes can be transferred from the yeast host to mammalian cells in tissue culture and that the genes are transferred intact and are expressed. Using the same methods it may soon be possible to transfer YAC DNA into the mouse germ line so that the expression and function of genes cloned in YACs can be studied in developing and adult mammalian animals.

Mouse minor satellite DNA genetically maps to the centromere and is physically linked to the proximal telomere

As an adjunct to attempts to define functionally important sequences at human centromeres, we have undertaken a long-range physical analysis of these regions in the mouse. Mouse centromeres are usually situated very close to the chromosome ends and are closely associated with minor satellite sequences on the basis of cytological observations. Using pulsed-field gel electrophoresis we find that this satellite DNA is arranged as tandem arrays, predominantly uninterrupted by nonsatellite sequences. These arrays can be released largely intact by digestion with a range of enzymes that generally cleave frequently in non-satellite DNA. The restriction fragments carrying these arrays are polymorphic in size between inbred strains and provide direct markers for mouse centromeres. To illustrate the possible use of these polymorphic markers we have mapped a 1.3-Mb PvuII variant in a set of RI strains to the centromere of Chromosome 7. The minor satellite arrays are very close to the centromeric telomere and physical linkage with terminal repeat sequences can readily be detected, placing many minor satellite arrays on terminal restriction fragments smaller than 1 Mb. The apparent lack of any sizable amount of nonsatellite DNA between the minor satellite and the terminal repeat arrays indicates that many mouse chromosomes are truly telocentric.

Scanning electron microscopy of mammalian chromosomes from prophase to telophase

Changes in the morphology of human and murine chromosomes during the different stages of mitosis have been examined by scanning electron microscopy. Two important findings have emerged from this study. The first is that prophase chromosomes do not become split into pairs of chromatids until late prophase or early metaphase. This entails two distinct processes of condensation, the earlier one starting as condensations of chromosomes into chromomeres which then fuse to form a cylindrical body. After this cylindrical body has split in two longitudinally, further condensation occurs by mechanisms that probably include coiling of the chromatids as well as other processes. The second finding is that the centromeric heterochromatin does not split in two at the same time as the rest of the chromosome, but remains undivided until anaphase. It is proposed that the function of centromeric heterochromatin is to hold the chromatids together until anaphase, when they are separated by the concerted action of topoisomerase II acting on numerous similar sites provided by the repetitive nature of the satellite DNA in the heterochromatin. A lower limit to the size of blocks of centromeric heterochromatin is placed by the need for adequate mechanical strength to hold the chromatids together, and a higher limit by the necessity for rapid splitting of the heterochromatin at anaphase. Beyond these limits malsegregation will occur, leading to aneuploidy. Because the centromere remains undivided until anaphase, it cannot undergo the later stage of condensation found in the chromosome arms after separation into chromatids, and therefore the centromere remains as a constriction.

The POL1 gene from the fission yeast, Schizosaccharomyces pombe, shows conserved amino acid blocks specific for eukaryotic DNA polymerases alpha

The POL1 gene of the fission yeast, Schizosaccharomyces pombe, was isolated using a POL1 gene probe from the budding yeast Saccharomyces cerevisiae, cloned and sequenced. This gene is unique and located on chromosome II. It includes a single 91 bp intron and is transcribed into a mRNA of about 4500 nucleotides. The predicted protein coded for by the S. pombe POL1 gene is 1405 amino acid long and its calculated molecular weight is about 160,000 daltons. This peptide contains seven amino acid blocks conserved among several DNA polymerases from different organisms and shares overall 37% and 34% identity with DNA polymerases alpha from S. cerevisiae and human cells, respectively. These results indicate that this gene codes for the S. pombe catalytic subunit of DNA polymerase alpha. The comparisons with human DNA polymerase alpha and with the budding yeast DNA polymerases alpha, delta and epsilon reveal conserved blocks of amino acids which are structurally and/or functionally specific only for eukaryotic alpha-type DNA polymerases.

Hypervariable ultra-long telomeres in mice

Telomere structure and behaviour is less well understood in vertebrates than it is in ciliates and yeasts (reviewed in ref. 1). Like all other eukaryotic chromosomes, those of vertebrates terminate in an array of a short repeated sequence. In vertebrates this sequence is (TTAGGG)n, as shown by in situ hybridization. In humans, these terminal repeats are heterogeneous in length, averaging about 10 kilobases in blood cells. Here we report the structure and inheritance of the terminal repeats present at mouse telomeres. The (TTAGGG)n tracts are many times larger than those present at human telomeres. Because of their constancy in length through somatic cell divisions, they are resolved as multiple discrete restriction fragments of up to 150 kilobases. Strikingly, this banding pattern is highly polymorphic within populations of inbred mice, suggesting an unusually high mutation rate. Indeed, although the banding pattern is inherited in a largely mendelian fashion, (TTAGGG)n tracts of new size appear frequently in family studies.

Modification and transfer into an embryonal carcinoma cell line of a 360-kilobase human-derived yeast artificial chromosome

A neomycin resistance cassette was integrated into the human-derived insert of a 360-kilobase yeast artificial chromosome (YAC) by targeting homologous recombination to Alu repeat sequences. The modified YAC was transferred into an embryonal carcinoma cell line by using polyethylene glycol-mediated spheroplast fusion. A single copy of the human sequence was introduced intact and stably maintained in the absence of selection for over 40 generations. A substantial portion of the yeast genome was retained in hybrids in addition to the YAC. Hybrid cells containing the YAC retained the ability to differentiate when treated with retinoic acid. This approach provides a powerful tool for in vitro analysis because it can be used to modify any human DNA cloned as a YAC and to transfer large fragments of DNA intact into cultured mammalian cells, thereby facilitating functional studies of genes in the context of extensive flanking DNA sequences.

Modification and transfer into an embryonal carcinoma cell line of a 360-kilobase human-derived yeast artificial chromosome

A neomycin resistance cassette was integrated into the human-derived insert of a 360-kilobase yeast artificial chromosome (YAC) by targeting homologous recombination to Alu repeat sequences. The modified YAC was transferred into an embryonal carcinoma cell line by using polyethylene glycol-mediated spheroplast fusion. A single copy of the human sequence was introduced intact and stably maintained in the absence of selection for over 40 generations. A substantial portion of the yeast genome was retained in hybrids in addition to the YAC. Hybrid cells containing the YAC retained the ability to differentiate when treated with retinoic acid. This approach provides a powerful tool for in vitro analysis because it can be used to modify any human DNA cloned as a YAC and to transfer large fragments of DNA intact into cultured mammalian cells, thereby facilitating functional studies of genes in the context of extensive flanking DNA sequences.

Transfer of a yeast artificial chromosome carrying human DNA from Saccharomyces cerevisiae into mammalian cells

To test the feasibility of transferring yeast artificial chromosomes (YACs) into mammalian cells, we modified a YAC that carries approximately 450 kilobases (kb) of human DNA, by inserting a neomycin-resistance gene. Saccharomyces cerevisiae cells carrying this YAC were fused by polyethylene glycol to mouse L cells and G418-resistant colonies were obtained. A high percentage of these clones contained virtually intact YAC sequences as revealed by "Alu fingerprint" analysis and restriction enzyme analysis using pulsed-field gel electrophoresis. Furthermore, the YAC sequences were stably integrated into the mouse chromosomes, as shown by in situ hybridization and by the stability of the G418 resistance. These results establish that large segments of the mammalian genome, cloned in yeast, can be efficiently transferred into cultured mammalian cells.

Introduction of large linear minichromosomes into Schizosaccharomyces pombe by an improved transformation procedure

The efficiency of transformation of Schizosaccharomyces pombe has been increased 10- to 50-fold over previously reported methods. By using 1 microgram of plasmid, 7.0 x 10(5) transformants are regularly obtained. This increased transformation efficiency is mainly due to the inclusion of the cationic liposome-forming reagent Lipofectin in the protocol. Various parameters affecting transformation of Sc. pombe in the presence of Lipofectin have been examined. Lipofectin can also be used to increase transformation efficiency in Saccharomyces cerevisiae. It is also demonstrated that by using this improved transformation procedure, linear minichromosomes of greater than 500 kilobases can be introduced into Sc. pombe with relative ease. These minichromosomes can replicate as stable linear molecules upon reintroduction into Sc. pombe, demonstrating that Sc. pombe telomeres retain function when reintroduced as naked DNA. The ability of Sc. pombe to admit large DNA molecules indicates that it should be feasible to clone large DNA from other organisms in Sc. pombe.

Adenylyl cyclase activity of the fission yeast Schizosaccharomyces pombe is not regulated by guanyl nucleotides

The adenylyl cyclase activity of the fission yeast Schizosaccharomyces pombe is localized to the plasma membrane of the cell. The enzyme utilizes Mn2+/ATP as substrate and free Mn2+ ions as an effector. Unlike the baker yeast Saccharomyces cerevisiae, S. pombe adenylyl cyclase does not utilize Mg2+/ATP as substrate and the activity is not stimulated by guanyl nucleotides. The optimal pH for the S. pombe adenylyl cyclase activity is 6.0. The activity dependence on ATP is cooperative with a Hill coefficient of 1.68 +/- 0.14.

A review of mitosis in the fission yeast Schizosaccharomyces pombe

Mitosis and cell division are the final events of the cell cycle, resulting in the precise segregation of chromosomes into two daughter cells. A highly controlled and accurate segregation of the chromosomes is required to ensure that each daughter cell receives a complete genome and remains viable. The fission yeast, Schizosaccharomyces pombe, is a unicellular eukaryotic organism which is particularly convenient for investigating these problems. It is very amenable to genetic analysis and its predominantly haploid life cycle has allowed the isolation of recessive temperature-sensitive mutants unable to complete the cell cycle. Classical genetic analysis of these mutants has been used to identify over 40 gene functions that are required for cell cycle progress in S. pombe. Many of these genes have now been cloned and sequenced and in some cases the encoded gene product has been identified. This approach, coupling classical and molecular genetics, allows identification of the molecules important in the mitotic processes and provides a means for establishing what functional roles they may play.

Mammalian chromosome banding--an expression of genome organization

Banding of metaphase chromosomes is an invaluable aid to analysing the complex genomes of vertebrates, but the biochemical basis for this phenomenon is poorly understood. Advances in molecular biology are beginning to point to features of genome organization that may play roles in chromosome banding.

Construction of a Not I restriction map of the fission yeast Schizosaccharomyces pombe genome

Pulsed field gel electrophoresis and large DNA technology were used to construct a Not I restriction map of the entire genome of the fission yeast Schizosaccharomyces pombe. There are 14 detectable Not I sites in S. pombe 972h: 9 sites on chromosome I and 5 sites on chromosome II, while no Not I sites were found on chromosome III. The 17 fragments (including intact chromosome III) generated by Not I digestion were resolved by PFG electrophoresis. These fragments ranged in size from 4.5 kb to approximately 3.5 Mb. Various strategies were applied in determining, efficiently, the order of the fragments on the chromosomes. The genomic size measured by adding all the fragments together is about 14 Mb and the sizes of the three chromosomes are I, 5.7 Mb, II, 4.6 to 4.7 Mb, and III, 3.5 Mb. These are generally somewhat smaller than estimated previously.

Development of large DNA methods for plants: molecular cloning of large segments of Arabidopsis and carrot DNA into yeast

Procedures for the preparation, analysis and cloning of large DNA molecules from two different plant species are described. Arabidopsis and carrot protoplasts were used for the preparation of large DNA molecules in agarose "plugs" or in solution. Pulsed-field gel electrophoresis (PFGE) analysis of large plant DNA preparations using a contour-clamped homogeneous field (CHEF) apparatus indicated that the size of the DNA was at least 12 Mb. Large DNA preparations were shown to be useful for restriction enzyme analysis of the Arabidopsis genome using both frequent and infrequent cutting enzymes and for the molecular cloning of large segments of DNA into yeast using artificial chromosome (YAC) vectors. PFGE and blot hybridization analysis of Arabidopsis and carrot DNA-containing YACs indicated that both unique and highly repeated DNA sequences were represented in these libraries.

Telomeric repeat from T. thermophila cross hybridizes with human telomeres

The ends (telomeres) of eukaryotic chromosomes must have special features to ensure their stability and complete replication. Studies in yeast, protozoa, slime moulds and flagellates show that telomeres are tandem repeats of simple sequences that have a G-rich and a C-rich strand. Mammalian telomeres have yet to be isolated and characterized, although a DNA fragment within 20 kilobases of the telomeres of the short arms of the human sex chromosomes has been isolated. Recently we showed that a chromosome from the fission yeast Schizosaccharomyces pombe could, in some cases, replicate as an autonomous mini-chromosome in mouse cells. By extrapolation from other systems, we reasoned that mouse telomeres could be added to the S. pombe chromosome ends in the mouse cells. On setting out to test this hypothesis we found to our surprise that the telomeric probe used (containing both the S. pombe and Tetrahymena thermophila repeats) hybridized to a series of discrete fragments in normal mouse DNA and DNA from a wide range of eukaryotes. We show here that the sequences hybridizing to this probe are located at the telomeres of most, if not all, human chromosomes and are similar to the Tetrahymena telomeric-repeat component of the probe.