PNA interference mapping demonstrates functional domains in the noncoding RNA Xist.

The noncoding RNA Xist has been shown to be essential for X-chromosome inactivation and to coat the inactive X-chromosome (Xi). Thus, an important question in understanding the formation of Xi is whether the binding reaction of Xist is necessary for X-chromosome inactivation. In this article, we demonstrate the failure of X-chromosome silencing if the association of Xist with the X-chromosome is inhibited. The chromatin-binding region was functionally mapped and evaluated by using an approach for studying noncoding RNA function in living cells that we call peptide nucleic acid (PNA) interference mapping. In the reported experiments, a single 19-bp antisense cell-permeating PNA targeted against a particular region of Xist RNA caused the disruption of the Xi. The association of the Xi with macro-histone H2A is also disturbed by PNA interference mapping.

Murine Xist RNA isoforms are different at their 3' ends: a role for differential polyadenylation.

Murine Xist is an essential transcript for X chromosome inactivation (X inactivation). According to recently revised structure, Xist is at least 17.8 kb long. It consists of seven exons and there are two major transcripts in female somatic cells. In this study we further defined the molecular structures of the two isoforms, namely short (S) and long (L) forms by northern blot and RNAse protection assay (RPA). The following lines of evidences suggest that mouse Xist depends on differential polyadenylation, not alternative splicing, to generate the two RNA isoforms: (1) only one band was detectable with the northern probes spanning the 3' end of Xist. (2) RPA showed the 3' termini of both S and L forms, and there are putative polyadenylation signals and hairpin structures close to these ends. (3) Analyses by splice site prediction program did not show any evidence of splice motifs in the sequence of L form. (4) Alignments between Xist 3' end (ESTs) and genomic sequence support the absence of splicing event in the region. The newly revised structure of Xist isoforms may have different stability and roles in the process of X inactivation.

Development of two bacterial artificial chromosome shuttle vectors for a recombination-based cloning and regulated expression of large genes in mammalian cells.

Most conditional expression vectors designed for mammalian cells have been valuable systems for studying genes of interest by regulating their expressions. The available vectors, however, are reliable for the short-length cDNA clones and not optimal for relatively long fragments of genomic DNA or long cDNAs. Here, we report the construction of two bacterial artificial chromosome (BAC) vectors, capable of harboring large inserts and shuttling among Escherichia coli, yeast, and mammalian cells. These two vectors, pEYMT and pEYMI, contain conditional expression systems which are designed to be regulated by tetracycline and mouse interferons, respectively. To test the properties of the vectors, we cloned in both vectors the green fluorescence protein (GFP) through an in vitro ligation reaction and the 17.8-kb-long X-inactive-specific transcript (Xist) cDNA through homologous recombination in yeast. Subsequently, we characterized their regulated expression properties using real-time quantitative RT-PCR (TaqMan) and RNA-fluorescent in situ hybridization (FISH). We demonstrate that these two BAC vectors are good systems for recombination-based cloning and regulated expression of large genes in mammalian cells.

Purification and characterization of YACs containing large inserts.

This unit provides protocols for characterizing DNA segments cloned in YACs and for purifying YACs from yeast chromosomes. The first basic protocol describes Southern blotting and partial-digest restriction analysis of YACs. These methods are useful for determining the size and complexity of the cloned insert DNA, the presence and location of particular restriction sites or sequences, and even the species of origin of the insert DNA (indicated by hybridization to species-specific repetitive elements such as Alu repeats). The second basic protocol describes gel purification of YACs for use in procedures requiring pure YAC DNA, such as mammalian-cell transformation and subcloning into smaller insert vectors. The third basic protocol details characterizing and analyzing YACs: in vivo fragmentation via homologous recombination with specialized fragmentation vectors containing specific probe sequences or repetitive elements, followed by Southern blotting with YAC- and human-derived probes.

Preparation of genomic DNA from mammalian tissue.

There are a number of different procedures for the preparation of genomic DNA. They all start with some form of cell lysis, followed by deproteination and recovery of DNA. The main differences between various approaches lie in the extent of deproteination and in molecular weight of the DNA produced. The isolation procedure described here is relatively brief and relies on the powerful proteolytic activity of proteinase K combined with the denaturing ability of the ionic detergent SDS.

Preparation of genomic DNA from mammalian tissue.

There are a number of different procedures for the preparation of genomic DNA. They all start with some form of cell lysis, followed by deproteinization and recovery of DNA. The main differences between various approaches lie in the extent of deproteinization and in molecular weight of the DNA produced. The isolation procedure described here is relatively brief and relies on the powerful proteolytic activity of proteinase K combined with the denaturing ability of the ionic detergent SDS.

Preparation of genomic DNA from mammalian tissue.

There are a number of different procedures for the preparation of genomic DNA. They all start with some form of cell lysis, followed by deproteination and recovery of DNA. The main differences between various approaches lie in the extent of deproteination and in molecular weight of the DNA produced. The isolation procedure described here is relatively brief and relies on the powerful proteolytic activity of proteinase K combined with the denaturing ability of the ionic detergent SDS.

Using DNA fragments as probes.

All hybridization methods depend upon the ability of denatured DNA to reanneal when complementary strands are present in an environment near but below their Tm (melting temperature). A detailed procedure is described in which bacteriophage plaques or bacterial colonies bound to a filter membrane are detected by hybridization with a radioactive probe. Hybridization proceeds on prewet filters placed in a sealable plastic bag. After hybridization the filters are removed from the sealed bag, excess probe is washed off, and the filters are autoradiographed to identify the clones that have hybridized with the probe. An Alternate Protocol differs mainly in that formamide is not used in the hybridization solution.

Unique chromosome identification and sequence-specific structural analysis with short PNA oligomers.

We have extended our earlier work to show that individual 14-20mer peptide nucleic acid probes directed against interspersed alpha-satellite sequences can specifically identify chromosomes. Peptide nucleic acid (PNA) probes were used to detect chromosomal abnormalities and repeat structure in the human genome by fluorescence in situ hybridization (FISH). The hybridization of a single PNA probe species directed against a highly abundant alpha-satellite DNA repeat sequence was sufficient to absolutely identify a chromosome. Selection of highly repetitive or region-specific DNA repeats involved DNA database analysis. Distribution of a specific repeat sequence in human genome was estimated through two means: a computer program "whole genome" approach based on approximately 400 Mb (12%) human genomic sequence. The other method involved directed search for alpha satellite sequences. In total, approximately 240 unique DNA repeat candidates were found. Forty-two PNA probes were designed for screening chromosome-specific probes. Ten chromosome-specific PNA probes for human Chromosomes (Chrs) 1, 2, 7, 9, 11, 17, 18, X, and Y have been identified. Interphase and metaphase results demonstrate that chromosome-specific PNA probes are capable of detecting simple aneuploidies (trisomies) in human. Another set of PNA probes showed distinct banding-like patterns and could be used as sequence-specific stains for chromosome "bar coding". Potential application of PNA probes for investigating repeat structure and function is also discussed.

A revision of the human XIST gene organization and structural comparison with mouse Xist.

The XIST gene plays an essential role in X Chromosome (Chr) inactivation during the early development of female humans. It is believed that the XIST gene, not encoding a protein, functions as an RNA. The XIST cDNA is unusually long, as its full length is reported to be 16.5 kilobase pairs (kb). Here, comparison of sequences from the genomic interval downstream to the 3' end of the human XIST gene against the human EST database brought to light a number of human EST sequences that are mapped to the region. Furthermore, PCR amplification of human cDNA libraries and RNA fluorescence in situ hybridization (RNA-FISH) demonstrate that the human XIST gene has additional 2.8 kb downstream sequences which have not been documented as a part of the gene. These data show that the full-length XIST cDNA is, in fact, 19.3 kb, not 16.5 kb as previously reported. The newly defined region contains an intron that may be alternatively spliced and seven polyadenylation signal sequences. Sequences in the newly defined region show overall sequence similarity with the 3' terminal region of mouse Xist, and three subregions exhibit quite high sequence conservation. Interestingly, the new intron spans the first two sub-regions that are absent in one of the two isoforms of mouse Xist. Taken together, we revise the structure of human XIST cDNA and compare cDNA structures between human and mouse XIST/Xist. al. 1992). This gene, called XIST/Xist (X inactive specific transcript), shows several interesting features. First, both human and mouse XIST/Xist cDNA are unusually long, reportedly 16.5 kb and 17.8 kb, respectively (Brown et al. 1992; Hong et al. 1999). Second, the transcript does not seem to encode a protein, on the basis of the lack of a significant open reading frame, absence of the Xist RNA from polysomes, and localization of the transcript in the nucleus (Brockdorff et al. 1992; Brown et al. 1992). Third, the XIST/Xist RNA physically associates with, or 'coats,' the inactive X Chr (Brown et al. 1992; Clemson et al. 1996). Fourth, XIST/Xist transcripts can be observed as early as the four-cell stage, and upon the initiation of X-inactivation, the steady-state level of the transcript rises dramatically, apparently by stabilization of the RNA (Panning et al. 1997; Sheardown et al. 1997). Although the function of XIST/Xist is not known, deletion of the gene leads to failure of X-inactivation, and knock-out mice die around the gastrulation stage (Marahrens et al. 1997; Penny et al. 1996). In this report, we revise the structure of the human XIST cDNA and discuss structural features of the newly defined region.

A new structure for the murine Xist gene and its relationship to chromosome choice/counting during X-chromosome inactivation.

In this report, we present structural data for the murine Xist gene. The data presented in this paper demonstrate that the murine Xist transcript is at least 17.4 kb, not 14.3 kb as previously reported. The new structure of the murine Xist gene described herein has seven exons, not six. Exon VII encodes an additional 3.1 kb of information at the 3' end. Exon VII contains seven possible sites for polyadenylation; four of these sites are located in the newly discovered 3' end. Consequently, it is possible that several distinct transcripts may be produced through differential polyadenylation of a primary transcript. Alternative use of polyadenylation signals could result in size changes for exon VII. Two major species of Xist are detectable by Northern analysis, consistent with differential polyadenylation. In this paper, we propose a model for the role of the Xist 3' end in the process of X-chromosome counting and choice during embryonic development.

Single base discrimination of CENP-B repeats on mouse and human Chromosomes with PNA-FISH.

The satellite repeat structure of the mammalian centromere contains the CENP-B protein binding site. Using the peptide nucleic acid-fluorescence in situ hybridization (PNA-FISH), we show by direct PNA-DNA binding that all detectable CENP-B sites in a mammalian genome might have the same sequence. Two species-specific PNA 17-mers, pMm and pMc, were identified from CENP-B binding sites of Mus musculus and M. caroli, respectively. Fluorescence in situ hybridization confirmed that pMc hybridized to M. caroli centromeres only; however, pMm cross-hybridized to M. musculus and human centromeres. By using a series of CENP-B PNA 17-mers containing 1, 2, 3, 5, and 7 base-pair mismatches to their DNA counterparts, we further demonstrate that PNA-FISH can discriminate between two CENP-B DNA sequences that differ by a single base-pair in mouse and human centromeres, suggesting the degree of conservation of CENP-B sequences throughout the genome. In comparison with DNA oligonucleotides, PNA oligomers demonstrate the higher sequence specificity, improved stability, reproducibility, and lower background. Therefore, PNA oligomers have significant advantages over DNA oligonucleotide probes in analyzing microsatellites in a genome.

A far upstream cis-element is required for Wilms' tumor-1 (WT1) gene expression in renal cell culture.

To identify novel cis-regulatory elements responsible for the tissue-restricted expression pattern of the Wilms' tumor-1 (WT1) gene, we mapped a total of 11 DNase I-hypersensitive sites in the 5'-flanking region and first intron of the human gene, six of which were specific for WT1 expressing cell lines. A 1.4-kilobase (kb) fragment from the mouse wt1 5'-flanking region contained cross-hybridizing sequence with significant homology to a region of DNase I hypersensitivity in the human WT1 gene which bound to nuclear matrix in human fetal kidney 293 cells. None of the DNase I-hypersensitive sites/matrix attachment regions, either alone or in combination, were sufficient for tissue-specific WT1 expression in transient and stably transfected cell lines. However, stable transfection of an approximately 620-kb yeast artificial chromosome (YAC) that carried the entire mouse wt1 locus into 293 cells resulted in wt1 (trans)gene expression at a level of approximately 30% of the endogenous human gene. Deletion of the 1.4-kb cross-hybridizing mouse fragment, located approximately 15 kb upstream of the transcription start site, caused complete loss of wt1 gene expression in the YAC-transfected 293 cells. In summary, we have identified a far upstream element that contains a region of DNase I hypersensitivity and that binds to nuclear matrix. This element includes phylogenetically conserved sequence and is required, although not sufficient, for mouse wt1 gene expression in human fetal kidney cells in culture.

A 450 kb transgene displays properties of the mammalian X-inactivation center.

X inactivation results in inactivation of one X chromosome to compensate for gene dosage differences between mammalian females and males. It requires the X-inactivation center (Xic) and Xist in cis. We report that introducing 450 kb of murine Xic/Xist sequences onto autosomes activates female dosage compensation in male ES cells. Xist is induced upon differentiation and can be expressed from both endogenous and ectopic loci, suggesting that elements for counting and choosing Xs are present in the transgene. Differentiating transgenic ES cells undergo excessive cell death. Postnatally, Xist is expressed only from the transgene. Ectopic Xist RNA structurally associates with the autosome and may inactivate a marker gene in cis. These results argue that the Xic is contained within 450 kb and that these sequences are sufficient for chromosome counting, choosing, and initiation of X inactivation.

Germ line transmission of a yeast artificial chromosome spanning the murine alpha 1(I) collagen locus.

Molecular complementation of mutant phenotypes by transgenic technology is a potentially important tool for gene identification. A technology was developed that allows the transfer of a physically intact yeast artificial chromosome (YAC) into the germ line of the mouse. A purified 150-kilobase YAC encompassing the murine gene Col1a1 was efficiently introduced into embryonic stem (ES) cells via lipofection. Chimeric founder mice were derived from two transfected ES cell clones. These chimeras transmitted the full length transgene through the germ line, generating two transgenic mouse strains. Transgene expression was visualized as nascent transcripts in interphase nuclei and quantitated by ribonuclease protection analysis. Both assays indicated that the transgene was expressed at levels comparable to the endogenous collagen gene.

Incorporation of copy-number control elements into yeast artificial chromosomes by targeted homologous recombination.

We have developed a pair of vectors for exchanging yeast artificial chromosome (YAC) arms by targeted homologous recombination. These conversion vectors allow the introduction of copy-number control elements into YACs constructed with pYAC4 or related vectors. YACs modified in this way provide an enriched source of DNA for genetic or biochemical studies. A LYS2 gene on the conversion vector provides a genetic selection for the modified YACs after transformation with appropriately prepared vector. A background of Lys+ clones that do not contain modified YACs is also present. However, clones with converted YACs can be distinguished from this background by counter-screening for loss of the original p YAC4 TRP1 arm (Trp- phenotype). The elimination of yeast replication origins (ARS elements) from the conversion vectors increased the frequency of Lys+ Trp- clones, but resulted in weaker amplification. Several YACs have been converted with these vectors, and the fate of the transformed DNA and of the resident YAC DNA has been systematically investigated.

Molecular complementation of a collagen mutation in mammalian cells using yeast artificial chromosomes.

The cloning of large contiguous segments of mammalian DNA in Saccharomyces cerevisiae has become possible with the advent of Yeast Artificial Chromosomes (YACs). We are interested in extending the technique of genetic complementation analysis to the molecular level through the introduction of YACs into mammalian cells and the mammalian germline. We report the successful introduction of homogeneous DNA derived from a 150 kbp YAC spanning the murine Col1a1 locus into murine fibroblasts carrying a mutation at this locus. The YAC DNA was fractionated by pulse field electrophoresis, condensed with polyamines, and introduced into mutant fibroblasts via DNA-lipid micelles. The DNA was integrated as a stable intact unit in 10% of the transfected clones conferring collagen RNA expression to the mutant cells.

A strategy for rapid production and screening of yeast artificial chromosome libraries.

We describe methods for rapid production and screening of yeast artificial chromosome (YAC) libraries. Utilizing complete restriction digests of mouse genomic DNA for ligations in agarose, a 32,000-clone library was produced and screened in seven weeks. Screening was accomplished by subdividing primary transformation plates into pools of approximately 100 clones which were transferred into a master glycerol stock. These master stocks were used to inoculate liquid cultures to produce culture "pools," and ten pools of 100 clones were then combined to yield superpools of 1,000 clones. Both pool and superpool DNA was screened by polymerase chain reaction (PCR) and positive pools representing 100 clones were then plated on selective medium and screened by in situ hybridization. Screening by the two tiered PCR assay and by in situ hybridization was completed in 4-5 days. Utilizing this methodology we have isolated a 150 kb clone spanning the alpha 1(I) collagen (Col1a1) gene as well as 40 kb clones from the Hox-2 locus. To characterize the representation of the YAC library, the size distribution of genomic Sal I fragments was compared to that of clones picked at random from the library. The results demonstrate significant biasing of the cloned fragment distribution, resulting in a loss of representation for larger fragments.