Overabundance of rare-cutting restriction endonuclease sites in the human genome

A tandem array of Sp-1 sites and a reverse initiator element are both required for synergistic transcriptional activation of the T-cell-specific MAL gene

We have characterized the three cis elements responsible for promoter strength present in the 5'-flanking proximal region of MAL, a human T-cell-specific gene encoding a proteolipid protein present in detergent-insoluble complexes of high molecular weight. The first element consisted of an initiator sequence that, curiously, was present in reverse orientation compared to that of the standard initiator elements. The other two elements were contained in a region of 126 bp upstream of the mRNA initiation site, and consisted of a tandem array of one GC box and one GA box. The GC box corresponds to a consensus site for the nuclear factor Sp1, whereas the GA box deviates from this consensus, although it was able to compete for the binding of Sp1 in vitro and to respond to trans-activation by Sp1 in vivo. This simple promoter lacks an apparent TATA box and lost more than 99% of its activity when a fragment of 60 bp containing the GC and GA boxes was deleted. A synergistic effect on transcriptional activation was observed in the presence, but not in the absence, of the initiator element when both GC and GA boxes were present.

Structure of the gene encoding pig phosphoglucose isomerase

Genomic clones encoding pig phosphoglucose isomerase (PGI) have been isolated and partially sequenced. The gene (Pgi) contains 18 exons, 17 introns and spans about 32 kb. This structure is partially conserved between plant and animal. A major transcription start point (tsp) has been identified 74 nucleotides (nt) upstream from the AUG. The nt sequence around the tsp is very G+C rich; a 5'-ATAAA sequence, as well as four putative Sp1-binding sites, are present. In the 3'-flanking region, an AATAAA signal has been identified. Extending from the 5'-flanking region to the first intron, a 0.6-kb CpG island has been identified. The Pgi structural gene contains several DNA repetitive elements in its non-coding regions.

Isolation of two contigs of overlapping cosmids derived from human chromosomal band 3p21.1 and identification of 5 new 3p21.1 genes

Consistent loss of DNA sequences from several regions on the short arm of human chromosome 3 has suggested that multiple tumor suppressor genes reside on chromosome 3p in various types of cancer cells. We have focused our efforts on an analysis of chromosomal band 3p21.1 since aminoacylase-1 (ACY1), which is localized to this band, has been shown to have lower levels of expression in several small cell and non-small cell lung cancer cell lines. Starting with two cosmids within 3p21.1, D3S92 and D3S93, we have isolated two separate contigs of overlapping cosmids within 3p21.1, by screening a library of 5700 chromosome 3-specific cosmid clones. Detailed restriction maps for these two contigs show that they contain multiple clusters of rare cutting restriction endonuclease sites. One contig extends for 100 kb and encompassed both ACY1 and D3S92, and the other extends about 80 kb around the D3S93 locus. Many different restriction fragments derived from these two contigs were found to be evolutionarily conserved and hybridized to distinct message transcripts. These fragments were used to identify homologous cDNAs from an adenogastric cDNA library, and several of these cDNAs were partially sequenced. We have identified five new genes from these two contigs and there is evidence to suggest that several additional genes reside within these cosmid contigs. The genes identified from 3p21.1 were then hybridized to DNA, isolated from a series of lung cancer cell lines and matched normal and tumor DNA from lung cancer patients. No alterations were detected with any of these probes, both at the DNA or RNA levels. A similar analysis with DNA fragments derived from these two genomic regions also failed to detect any alterations.

The isolation of evolutionarily conserved Eag I end-clones from mouse chromosome 17 using cloned DNA

To isolate DNA markers from mouse chromosome 17, a genomic phage library was constructed from the mouse-hamster CMGT cell hybrid RcE-B52. This hybrid contains a chromosomal fragment from the distal end/flanking region of the t complex on mouse chromosome 17. Recombinants of mouse origin were identified by using a panel of mouse-specific repetitive sequences as a probe. A total of 1,500 mouse phage recombinants were isolated. These were found to represent 250-300 individual recombinants, comprising about 4 Mbp of cloned mouse DNA. The pooled mouse recombinant phages were used to construct an Eag I end-library. This was achieved by the specific insertion of a marker plasmid in Eag I recognition sites when present in the mouse inserts of the recombinant phages. The Eag I end-fragments were subsequently subcloned using a simple procedure taking advantage of the inserted plasmid. A total of 56 individual Eag I end-fragments were identified. These were found to contain recognition sites for rare cutting enzymes at high frequency. A large proportion (73%) were found to be evolutionarily conserved in human DNA. Furthermore, a significant fraction of these fragments, two of six tested, appears to detect specific cDNAs in a 8.5-day mouse embryo cDNA library.

Cosmid linking clones localized to the long arm of human chromosome 11

Molecular probes that contain DNA flanking CpG-rich restriction sites are extremely valuable in the construction of physical maps of chromosomes and in the identification of genes associated with hypomethylated HTF (HpaII tiny fragment) islands. We describe a new approach to the isolation and characterization of linking clones in arrayed chromosome-specific cosmid libraries through the large-scale semiautomated restriction mapping of cosmid clones. We utilized a cosmid library representing human chromosome 11q12-11qter and carried out automated restriction enzyme analysis, followed by regional localization to chromosome 11q using high-resolution in situ suppression hybridization. Using this approach, 165 cosmid linking clones containing one or more NotI, BssHII, SfiI, or SacII sites were identified among 960 chromosome-specific cosmids. Furthermore, this analysis allowed clones containing a single site to be distinguished from those containing clusters of two or more rare sites. This analysis demonstrated that more than 75% of cosmids containing a rare restriction site also contained a second rare restriction site, suggesting a high degree of CpG-rich restriction site clustering. Thirty chromosome 11q-specific cosmids containing rare CpG-rich restriction sites were regionally localized by high-resolution fluorescence in situ suppression hybridization, demonstrating that all of the CpG-rich sites detected by this method were located in bands 11q13 and 11q23. In addition, the distribution of (CA)n repetitive sequences was determined by hybridization of the arrayed cosmid library with oligonucleotide probes, confirming a random distribution of microsatellites among CpG-rich cosmid clones. This set of reagent cosmid clones will be useful for physical linking of large restriction fragments detected by pulsed-field gel electrophoresis and will provide a new and highly efficient approach to the construction of a physical map of human chromosome 11q.

Molecular analysis of human chromosome 16 cosmid clones containing NotI sites

To test the feasibility of using cloned NotI sites as markers for physical mapping, we have screened for cosmid clones spanning the NotI sites on human Chromosome (Chr) 16. Fluorescence in situ hybridization analysis of these clones confirms the previously reported cluster of NotI sites on 16p13.3. Methylation status of the cloned NotI sites on genomic DNA was established by hybridization of the cosmids to Southern blots containing EcoRI and EcoRI/NotI digest of genomic DNA. These results indicated that four of six clones included in our study can be used as linking clones for physical mapping. Two clones have NotI sites which are not cleavable in the cell lines tested. In one clone, the NotI site exists as an isolated rare-cutting restriction enzyme site, whereas in the other clone the NotI site appears to be island-related.

Identification of multiple CpG islands and associated conserved sequences in a candidate region for the Huntington disease gene

The HD locus has been assigned to 4p16.3 distal to the DNA segment D4S10. However, the precise location of this gene is still unknown. At least three regions, together encompassing more than 3.5 Mb of DNA, can still be considered as candidate regions for the HD gene. Our efforts are directed toward the cloning and the complete characterization of one of these regions. Thus far we have cloned 460 kb of DNA in contiguously overlapping cosmids distal to D4S111 and have developed a detailed long-range restriction map orienting the contig within the terminal region of 4p16.3. We characterized 15 CpG-rich islands defined by tightly clustered rare cutter restriction sites for the enzymes NotI, BssHII, EagI, NruI, and SacII. In addition, we show that the sequences associated with the CpG-rich islands detect cross-species conservation. The detailed genetic analysis of the 460-kb contig provides a framework for the identification of genes, which can be assessed for the characteristics expected for the HD gene.

CpG islands: features and distribution in the genomes of vertebrates

We have investigated the distribution of unmethylated CpG islands in vertebrate genomes fractionated according to their base composition. Genomes from warm-blooded vertebrates (man, mouse and chicken) are characterized by abundant CpG islands, whose frequency increases in DNA fractions of increasing % of guanine + cytosine; % G + C (GC), in parallel with the distribution of genes and CpG doublets. Small, yet significant, differences in the distribution of CpG islands were found in the three genomes. In contrast, genomes from cold-blooded vertebrates (two reptiles, one amphibian, and two fishes) were characterized by an extreme scarcity or absence of CpG islands (detected in these experiments as HpaII tiny fragments or HTF). CpG islands associated with homologous genes from cold- and warm-blooded vertebrates were then compared by analyzing CpG frequencies, GC levels, HpaII sites, rare-cutter sites and G/C boxes (GGGGCGGGGC and closely related motifs) in sequences available in gene banks. Small, yet significant, differences were again detected among the CpG islands associated with homologous genes from warm-blooded vertebrates, in that CpG islands associated with mouse or rat genes often showed low CpG and/or GC levels, as well as low numbers of HpaII sites, rare-cutter sites and G/C boxes, compared to homologous human genes; more rarely, CpG islands were just absent. As far as cold-blooded vertebrates were concerned, a number of genes showed CpG islands, which exhibited a much lower frequency of CpG doublets than that found in CpG islands of warm-blooded vertebrates, but still approached the statistically expected frequency; none of the other features of CpG islands associated with genes from warm-blooded vertebrates were present. Other genes did not show any associated CpG islands, unlike their homologues from warm-blooded vertebrates.

Isolation of large numbers of chromosome 3-specific cosmids containing clusters of rare restriction-endonuclease sites

We tested 519 chromosome 3-specific cosmids for the presence of rare restriction-endonuclease sites in a search for cosmids containing HTF islands. We have identified 49 cosmids (9% of those tested) that contain multiple rare restriction-endonuclease sites. The cosmids were digested with several common cutting restriction endonucleases to liberate small fragments which were tested as unique-sequence chromosome 3-specific hybridization probes and for evolutionary sequence conservation. Unique-sequence hybridization probes isolated from the cosmids were hybridized to a somatic cell hybrid deletion mapping panel to subchromosomally localize the cosmids. Fragments from many of these cosmids demonstrated conservation of sequence through evolution, and these fragments hybridize to distinct transcripts. These cosmids should therefore prove a useful resource for the identification of many chromosome 3-specific genes, in addition to having potential use as linking clones for pulsed-field gel mapping studies.

Localization of 616 human chromosome 3-specific cosmids using a somatic cell hybrid deletion mapping panel

A total of 5700 human chromosome 3-specific cosmid clones was isolated from a series of cosmid libraries constructed from somatic cell hybrids whose only human component was an entire chromosome 3 or a chromosome 3 containing an interstitial deletion removing 50% of long arm sequences. Several unique sequence chromosome 3-specific hybridization probes were isolated from each of 616 of these cosmids. These probes were then used to localize the cosmids by hybridization to a somatic cell hybrid deletion mapping panel capable of resolving chromosome 3 into nine distinct subregions. All 616 of the cosmids were localized to either the long or short arm of chromosome 3 and 63% of the short arm cosmids were more precisely localized. We have identified a total of 87 cosmids that contain fragments that are evolutionarily conserved. Fragments from these cosmids should prove useful in the identification of new chromosome 3-specific genes as well as in comparative mapping studies. The localized cosmids should provide excellent saturation of human chromosome 3 and facilitate the construction of physical and genetic linkage maps to identify various disease loci including Von Hippel Lindau disease and renal and small cell lung carcinoma.

Construction and characterization of a NotI linking library of human chromosome 21

Effective procedures have been developed for constructing NotI linking libraries starting from chromosome-specific genomic libraries. Fifteen different single copy and two rDNA NotI linking clones from human chromosome 21 were identified in two libraries. Their chromosomal origin was confirmed, and regional location established using hybrid cell panels. Hybridization experiments with these probes revealed pairs of genomic NotI fragments, each ranging in size from less than 0.05 to 4.0 Mb. Many fragments displayed cell type variation. The total size of the NotI fragments detected in a human fibroblast cell line (GM6167) and mouse hybrid cell containing chromosome 21 as its only human component (WAV17) were approximately 32 and 34 Mb, respectively. If these fragments were all non-overlapping, this would correspond to about 70% of the 50-Mb content estimated for the whole chromosome. The linking clones will be enormously useful in the subsequent construction of a NotI restriction map of this chromosome. Characterization of these clones indicates the presence of numerous additional sites for other enzymes that recognize sequences containing CpG. Thus most NotI linking clones appear to derive from CpG islands and probably identify the 5' end of genes.

Construction and regional localization of clones from a NotI linking library from human chromosome 17q

A NotI linking library was constructed from a somatic cell hybrid containing chromosome 17q as its only human material. A total of 112 human clones were assigned to nine regions of 17q using a somatic cell hybrid mapping panel. The library includes clones that detect the acute promyelocytic leukemia and von Recklinghausen neurofibromatosis translocation breakpoints at 17q11.2-12 and 17q11.2, respectively, on pulsed-field gel electrophoresis. The mapped clones represent over 50% of the estimated number of NotI sites on 17q, and therefore constitute an important resource for long-distance mapping.

Isolation and regional mapping of NotI and EagI clones from human chromosome 21

NotI and EagI boundary libraries were constructed for human chromosome 21. One hundred forty-seven clones were isolated from the somatic cell hybrid 72532X-6 and localized using a hybrid mapping panel. After identification of those clones, which were isolated more than once, as well as those probes derived from a previously unrecognized integrated non-chromosome-21 fragment, 58 individual boundary clones (plus 2 additional NotI-EcoRI clones isolated from a flow-sorted library) were localized to 11 separate regions. The distribution of these probes is highly nonrandom, with 50% of the clones located in the distal band 21q22.3. Two probes, Not50 and Eag101, map to regions in the very proximal long arm which may contain the gene responsible for familial Alzheimer's disease (AD1), and Not50 would appear to be more proximal than D21S16 (E9). Twenty-eight probes map to the region between superoxide dismutase (SOD1) and the ETS2 oncogene, which appears to contain genes responsible for many of the phenotypic features of Down syndrome. Twenty clones contain (GT)n repeats, as determined by hybridization to a CA polymer, and should provide additional highly polymorphic probes. Closure of gaps in the physical linkage map of chromosome 21 should be facilitated by the isolation of these probes, as they identify many of the unmethylated CpG-rich islands that have hindered pulsed-field gel analysis. They will also be useful in identifying a set of genes in proximity to NotI and EagI restriction sites, as well as conserved DNA sequences for comparative mapping studies.

Isolation of a variant family of mouse minor satellite DNA that hybridizes preferentially to chromosome 4

Two cosmids (HRS-1 and HRS-2) containing mouse minor satellite DNA sequences have been isolated from a mouse genomic library. In situ hybridization under moderate stringency conditions to metaphase chromosomes from RCS-5, a tumor cell line derived from the SJL strain, mapped both HRS-1 and HRS-2 to the centromeric region of chromosome 4. Sequence data indicate that these cloned minor satellite DNA sequences have a basic higher order repeat of 180 bp, composed of three diverged 60-bp monomers. Digestion of mouse genomic DNA with several restriction enzymes produces a ladder of minor satellite fragments based on a 120-bp repeat. The restriction enzyme NlaIII (CATG) digests all the minor satellite DNA into three prominent bands of 120, 240, and 360 bp and a weak band of 180 bp. Thus, the majority of minor satellite sequences in the genome are arranged in repeats based on a 120-bp dimer, while the family of minor satellite sequences described here represents a rare variant of these sequences. Our results raise the possibility that there may be other variant families of minor satellites analogous to those of alphoid DNA present in humans.

A physical map around the retinoblastoma gene

The gene predisposing to retinoblastoma, RB1, has been mapped to 13q14 and a cDNA clone has been isolated. Alterations of this chromosomal region are found not only in retinoblastoma, but in other tumor types including bone and soft tissue sarcomas, gastric tumors, small cell lung cancer, hematologic malignancies, rhabdomyosarcoma, and breast cancer. Genetic alterations implicating RB1 in some of these cancers have been observed. A long-range, overlapping restriction map around RB1 has been derived to provide a basis for study of rearrangements in tumors. Putative CpG islands closely linked to RB1 were identified, the effect of methylation was investigated, and RB1 transcriptional direction was determined. Using data in the literature, the map was oriented with respect to the centromere and it was determined that the distance between esterase D, a nearby gene, and RB1 was greater than 200 kb.

A human alphoid DNA clone from the EcoRI dimeric family: genomic and internal organization and chromosomal assignment

We isolated an alpha satellite DNA clone (pC1.8), 17 kb long, which is composed exclusively of tandemly repeated 340-bp EcoRI fragments. Hybridization studies using 37 random EcoRI dimers subcloned from pC1.8 showed that they are heterogeneous. The sequence of 5 dimers, 3 of them adjacent, confirmed this observation and showed that the heterogeneity is more accentuated among the second monomers. The chromosomal assignment under high stringency conditions showed that this alphoid subset is located on chromosomes 1, 5, and 19. No conditions that eliminate the hybridization on any one of those chromosomes were found. This suggests that, in contrast to many other chromosome-specific alpha satellite subsets, the single chromosome subsets of this family are virtually indistinguishable by hybridization techniques.

Identification of two cosmids derived from within chromosomal band 3p21.1 that contain clusters of rare restriction sites and evolutionarily conserved sequences

We have isolated large numbers of human recombinants from a cosmid library constructed from an interspecific (hamster/human) somatic cell hybrid whose only human component is an intact chromosome 3. Unique sequence probes were isolated from these recombinants and were used to localize them along the length of chromosome 3 by hybridization to a somatic cell hybrid deletion panel. We identified two cosmids, cA84 (D3S92) and cA199 (D3S93), derived from within chromosomal band 3p21.1. Both cosmids contained multiple rare restriction sites that were tightly clustered within the cosmids. We have therefore identified, in a region consistently deleted in a variety of lung cancers, two cosmids that may contain genes that are candidates for involvement in lung cancer.

Saturation of human chromosome 3 with unique sequence hybridization probes

We have generated chromosome 3-specific recombinant libraries in both lambda and cosmid cloning vectors starting with somatic cell hybrids (hamster/human) containing either an intact chromosome 3 or a chromosome 3 with an interstitial deletion removing 75% of long-arm sequences. The libraries contained between 2 X 10(5) and 5 X 10(6) independent recombinants. Approximately 2% of the recombinants in these libraries contain inserts of human DNA. These were identified by hybridizing the recombinants to radioactively labeled total human DNA. Over 2500 recombinants containing human DNA were isolated from these various libraries and DNA was prepared from each of them. This represents 80,000 kb of cloned chromosome 3 sequences. One-third of the DNAs were digested with EcoRI or HindIII, and fragments free of repetitive sequences were radioactively labeled using random hexanucleotide primers and tested as unique sequence hybridization probes. Over 6500 of the fragments were tested and of these 758 were unique sequence probes with minimal or no background hybridization. Their hybridization only to chromosome 3 was verified. These probes, which were derived from 452 independent recombinants, should provide an effective saturation of human chromosome 3.

Linguistics of nucleotide sequences. I: The significance of deviations from mean statistical characteristics and prediction of the frequencies of occurrence of words

Mathematical models of the generation of genetic texts appeared simultaneously with the first sequencing DNA. They are used to establish functional and evolutionary relations between genetic texts, to predict the number and distribution of specific sites in a sequence and to identify "meaningful" words. The present paper deals with two problems: 1) The significance of deviations from the mean statistical characteristics in a genetic text. Anyone who has addressed himself to the statistical analysis of sequenced DNA is familiar with the question: what deviations from the expected frequencies of occurrence of particular words testify to the "biological" significance of those words? We propose a formula for the variance of the number of word's occurrences in the text, with allowance for word overlaps, making it possible to assess the significance of the deviations from the expected statistical characteristics. 2) A new method for predicting the frequencies of occurrence of particular words in a genetic text using the statistical characteristics of "spaced" L-grams. The method can be used for predicting the number of restriction sites in human DNA and in planning experiments on the physical mapping and sequencing of the human genome.

Unusual features of CpG-rich (HTF) islands in the human alpha globin complex: association with non-functional pseudogenes and presence within the 3' portion of the zeta gene

We have characterised a cluster of CpG rich (HTF) islands in the alpha-globin complex and report here two unusual features: The human embryonic zeta 2-globin gene is associated with an HTF island within its 3' portion rather than at the 5' end. Furthermore at least two non-functional pseudogenes within the cluster (psi zeta 1 and psi alpha 2) are associated with CpG rich islands.

Construction of long-range restriction maps in human DNA using pulsed field gel electrophoresis

Pulsed field gel electrophoresis (PFGE) is a powerful new tool for genetic analysis that can be applied to a variety of problems concerning genome structure and organization. This technique uses an agarose gel matrix to separate DNA molecules in a size range from 40 kb to 2,000 kb, molecules far larger than the maximum separable using standard agarose gel electrophoresis. The PFGE method can be used to separate the intact chromosomes from lower eukaryotes or to separate very large DNA fragments from higher eukaryotes generated by digestion with restriction endonucleases whose cleavage sites are rare. This paper describes the use of PFGE for construction of long-range restriction maps in the human genome and includes detailed methods for all steps. A pulsed field gel device that utilizes a rotating platform for altering the applied electric field is also described. Map construction is illustrated using a cloned DNA fragment (D3S2) from human chromosome 3. Several technical problems specific for mammalian genomes are discussed.

Molecular mapping of the human major histocompatibility complex by pulsed-field gel electrophoresis

Pulsed-field gel electrophoresis and "cosmid walking" have been used to establish a molecular map of the human major histocompatibility complex (MHC). We have isolated approximately equal to 230 kilobases (kb) of genomic DNA in overlapping cosmid clones covering the genes for the second and fourth components of complement (C2 and C4, respectively), factor B, and steroid 21-hydroxylase, and approximately equal to 82 kb of genomic DNA surrounding the genes for the tumor necrosis factors alpha and beta. Single-copy hybridization probes isolated from these cosmid clusters and probes for the known MHC gene loci were hybridized to Southern blots of genomic DNA that had been digested with infrequently cutting restriction endonucleases and separated on pulsed-field gels. The data obtained allowed the construction of a long-range genomic restriction map and indicated that the MHC spans 3800 kb. This map orients the MHC class III gene cluster with respect to the DR subregion; the C2 gene is on the telomeric side of the 21-hydroxylase B gene. In addition we have defined the positions of the genes for the tumor necrosis factors alpha and beta in the human MHC. Genes for the alpha chain of DR and 21-hydroxylase B are separated by at least 300 kb, while the distance between the genes for C2 and tumor necrosis factor alpha is 390 kb. The HLA-B locus lies approximately equal to 250 kb on the telomeric side of the tumor necrosis factor genes.

Measuring the human T cell receptor gamma-chain locus

The human T cell receptor gamma locus, including eleven variable-region, five joining-region, and two constant-region segments, is contained in 160 kilobases. During T cell somatic development these genes undergo rearrangement by deletion of the sequences separating the variable and joining regions. The molecular map of this locus was completely defined by deletion mapping and restriction mapping. Restriction fragments were resolved by standard agarose electrophoresis and field inversion electrophoresis. These studies demonstrate that the deletions in this locus, which occur during the formation of a functional T cell receptor gamma-chain gene, range from 50 to 145 kilobases in length. These studies also provide a structural basis for understanding the development of the gamma-chain peptide repertoire, and extends the potential of the emerging pulsed-field electrophoretic technology.