Nucleotide Sequence Surrounding the Locus Marker D21S246 on Human Chromosome 21

Most ofthe human Not I linking clones identified to date areconsidered to be derived from CpG islands because ofthe recognitionsequence of this enzyme, and CpG islands have been reportedto be located around the 5' regions of genes. As a pilot study,we determined the complete nucleotide sequence (41,924 bp) ofa human cosmid clone (LL21NC02Q7A10) containing the marker D21S246originating from a Not I linking clone. As a result of sequenceanalysis, we successfully mapped and revealed the genomic genestructure for KIAA0002 previously reported as a cDNA clone.This gene consists of 15 exons and was shown to exist at theD21S246 locus on human chromosome 21q21.3–q22.1. Theseresults demonstrated that genomic marker-anchored DNA sequencingis a useful approach for the human genome project.     

Direct Determination of NotI Cleavage Sites in the Genomic DNA of Adult Mouse Kidney and Human Trophoblast Using Whole-Range Restriction Landmark Genomic Scanning

Restriction landmark genomic scanning (RLGS) is a method forvisualizing restriction landmarks, employing direct labelingof restriction sites of genomic DNA and high-resolution two-dimensionalelectrophoresis. We determined the conditions for both the firstand second dimensions of RLGS that define all of the restrictionfragments which carry the NotI landmark. Using this system,we determined the number of cleavable NotI sites of genomicDNA from the mouse kidney (C57BL/6) and from the human placenta.The mouse and human genomes were cleaved at 2,380±80sites (4,760±160 spots) and 3,240±110 sites (6,480±220spots), respectively with NotI.     

Alu-PCR Approach to Isolating NotI-Linking Clones from the 3p14-p21 Region Frequently Deleted in Renal Cell Carcinoma

In the mammalian genome CpG islands are associated with functional genes and cloning of these islands could be an alternative approach for cloning functional genes. Recently we have developed a new approach for cloning CpG islands and constructing NotI linking libraries. We have initiated the construction of a NotI restriction map for chromosome 3, especially focusing on the rearrangements in the 3p14-p21 region, which are associated with different malignancies. CpG islands from this region are useful for isolation of candidate tumor suppressor genes that map to this region and for isolating NotI-linking clones from 3p14-p21 for mapping purposes. Here we suggest a modification of Alu-PCR as an approach to isolating Not I sites (e.g., CpG islands) from defined regions of the chromosome. Instead of using whole chromosomal DNA for Alu-PCR, we have used representative NotI-linking libraries from hybrid cell lines containing either whole or deleted human chromosome 3 (MCH903.1 and MCH924.4, respectively). This decreases the complexity of the Alu-PCR products 10-100 times compared to the whole human genome. Using this modification, we can isolate NotI-linking clones, which are natural markers on the chromosome, rather than random genomic fragments. Among eight clones selected by this method, seven were from the region deleted in MCH924.4. The results clearly demonstrate the feasibility of Alu-PCR for isolating CpG islands from defined regions of the genome.     

NotI clones in the analysis of the human genome

NotI linking clones contain sequences flanking NotI recognition sites and were previously shown to be tightly associated with CpG islands and genes. To directly assess the value of NotI clones in genome research, high density grids with 50 000 NotI linking clones originating from six representative NotI linking libraries were constructed. Altogether, these libraries contained nearly 100 times the total number of NotI sites in the human genome. A total of 3437 sequences flanking NotI sites were generated. Analysis of 3265 unique sequences demonstrated that 51% of the clones displayed significant protein similarity to SWISSPROT and TREMBL database proteins based on MSPcrunch filtering with stringent parameters. Of the 3265 sequences, 1868 (57.2%) were new sequences, not present in the EMBL and EST databases (similarity ≤ 90%). Among these new sequences, 795 (24.3%) showed similarity to known proteins and 712 (21.8%) displayed an identity of >75% at the nucleotide level to sequences from EMBL or EST databases. The remaining 361 (11.1%) sequences were completely new, i.e. <75% identical. The work also showed tight, specific association of NotI sites with the first exon and suggest that the so-called 3′ ESTs can actually be generated from 5′-ends of genes that contain NotI sites in their first exon.     

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.     

NotI flanking sequences: a tool for gene discovery and verification of the human genome

A set of 22 551 unique human NotI flanking sequences (16.2 Mb) was generated. More than 40% of the set had regions with significant similarity to known proteins and expressed sequences. The data demonstrate that regions flanking NotI sites are less likely to form nucleosomes efficiently and resemble promoter regions. The draft human genome sequence contained 55.7% of the NotI flanking sequences, Celera’s database contained matches to 57.2% of the clones and all public databases (including non-human and previously sequenced NotI flanks) matched 89.2% of the NotI flanking sequences (identity ≥90% over at least 50 bp, data from December 2001). The data suggest that the shotgun sequencing approach used to generate the draft human genome sequence resulted in a bias against cloning and sequencing of NotI flanks. A rough estimation (based primarily on chromosomes 21 and 22) is that the human genome contains 15 000–20 000 NotI sites, of which 6000–9000 are unmethylated in any particular cell. The results of the study suggest that the existing tools for computational determination of CpG islands fail to identify a significant fraction of functional CpG islands, and unmethylated DNA stretches with a high frequency of CpG dinucleotides can be found even in regions with low CG content.     

EagI andNotI linking clones from human chromosomes 11 and Xp

EagI and NotI linking libraries were prepared in the lambda vector, EMBL5, from the mouse-human somatic cell hybrid 1W1LA4.9, which contains human chromosomes 11 and Xp as the only human component. Individual clones containing human DNA were isolated by their ability to hybridise with total human DNA and digested with SalI and EcoRI to identify the human insert size and single-copy fragments. The mean (± SD) insert sizes of the EagI and NotI clones were 18.3 ± 3.2 kb and 16.6 ± 3.6 kb, respectively. Regional localisation of 66 clones (52 EagI, 14 NotI) was achieved using a panel of 20 somatic cell hybrids that contained different overlapping deletions of chromosomes 11 or Xp. Thirty-nine clones (36 EagI, 3 NotI) were localised to chromosome 11; 17 of these were clustered in 11q13 and another nine were clustered in 11q14–q23.1. Twenty-seven clones (16 EagI, 11 NotI) were localised to Xp and 10 of these were clustered in Xp11. The 66 clones were assessed for seven different microsatellite repetitive sequences; restriction fragment length polymorphisms for five clones from 11q13 were also identified. These EagI and NotI clones, which supplement those previously mapped to chromosome 11 and Xp, should facilitate the generation of more detailed maps and the identification of genes that are associated with CpG-rich islands. Received: 27 December 1995 / Revised: 30 January 1996     

Quick Identification and Localization of CpG Islands in Large Genomic Fragments by Partial Digestion with Hpa II and Hha I

More than 50% of mammalian genes are associated with CpG islandsand thus they serve as a good gene marker. We have devised asimple method to scan large pieces of native or cloned genomicDNA for CpG islands. The method is based on the presence ofmultiple Hpa II and Hha I sites in CpG islands, at a frequency30 times higher than in the rest of the genome. The steps includecomplete digestion of DNA with a rare-cutting restriction endonuclease(to produce large fragments with defined ends), partial digestionwith Hpa II and Hha I, and subsequent Southern hybridizationwith an end probe. This identifies a CpG island as a clusterof sub-bands and, based on their electrophoretic mobility, onecan immediately locate the island relative to the ends. Formany vectors, universal probes flanking the cloning site areavailable, enabling the simultaneous analysis of a large numberof samples. We demonstrated the usefulness of the method byanalyzing known CpG islands in native genomic DNA and lambda,cosmid and P1 clones, and by isolating two novel transcribedislands from anonymous cosmid clones. Our method is quick, inexpensive,and can detect CpG islands with few or even no rare-cutter sites.     

Cloning of the Promoter Regions of Mouse TGF-{beta} Receptor Genes by Inverse PCR with Highly Overlapped Primers

In order to isolate promoters of mouse TGF-ß receptorgenes, we used inverse PCR with highly overlapped primers correspondingto the 5' sequence of the receptor cDNAs. Nested primer setsonly covered a 30- to 40-base region of the sequences. HinfI-digestedand self-ligated mouse genomic DNA was used as a PCR template.Only one band for each receptor was seen after PCR. The amplifiedDNA fragments could direct luciferase production when the luciferasecoding sequence was ligated after the fragments. The sequenceof the fragment which correspond to the type II receptor showedpartial homology with the promoter region of the human TGF-ßtype II receptor. Thus, the inverse PCR with highly overlappedprimers could be an easy way to isolate the promoter regionsof many genes.     

Analysis of CpG islands of trophoblast giant cells by restriction landmark genomic scanning

Rat trophoblast giant cells each contain at least 100 times more genomic DNA per nucleus than diploid cells. This unusual phenomenon appears to be of interest in relation to the molecular mechanism of cell differentiation and gene expression in the placenta. In the present study, we analyzed the CpG islands of trophoblast giant cells by restriction landmark genomic scanning (RLGS) using the methylation-sensitive landmark enzymes, Not I and Bss HII. More than 1,000 and 1,900 spots were detected by RLGS using Not I and Bss HII, respectively, in the placental junctional zone, where more than 90% of genomic DNA is present in the cells with higher DNA content. Of these, 97% (1,009 spots) and 99% (1,911 spots) of the spots found in the junctional zone showed an identical pattern and identical intensity with those of diploid cell controls, for which genomic DNA was extracted from the labyrinth zone and maternal kidney. Therefore, the giant cells are basically polyploid. More importantly, 24 tissue-specific spots were detected by RLGS using Not I. Subsequent cloning and sequencing of four typical spots of the genomic DNA confirmed that these DNA fragments contained abundant CpG dinucleotides and showed characteristics of CpG islands. Of these 24 spots, there were ten spots specific for the placenta, and three of them were specific for the junctional zone, indicating that methylation status of CpG islands in the placental tissue differed between the junctional zone and labyrinth zone. These results suggest that multiple rounds of endoreduplication and modification of CpG islands by cytosine methylation occur during the differentiation process of giant cells. Dev. Genet. 22:132–140, 1998. © 1998 Wiley-Liss, Inc.     

Key Features of Cereal Genome Organization as Revealed by the Use of Cytosine Methylation-Sensitive Restriction Endonucleases

Unlike mammalian genomes, cereal (Gramineae) genomes exhibit little suppression of CpG dinucleotides. In cereal genomes, however, most of the numerous potential recognition sites for CpG methylation-sensitive restriction enzymes are methylated. Analysis of cereal genomic libraries and of regions flanking genes indicates that unmethylated NotI sites are useful landmarks for regions containing genes/single-copy sequences. Studies of a rye chromosome arm indicate that its pericentromeric region has a reduced density of unmethylated NotI (and MluI) sites and therefore of genes. Unmethylated MluI and NruI sites are distributed nonrandomly in the genomes of wheat, barley, and rice. Analysis of the genomic blocks defined by these sites in wheat and barley indicates that they are most likely to have arisen by amplification. These observations form the basis of a proposed model for the organization and evolution of the wheat, barley, and rice genomes.     

Molecular analysis of the human MHC class I region using yeast artificial chromosome clones

The cloning of large genomic fragments corresponding to the major histocompatibility complex (MHC) class I region provides the necessary framework for a better understanding of its organization and for the localization of new genes involved in MHC-associated disease. Two human genomic libraries constructed in yeast artificial chromosomes (YACs) have been prepared using complete Not I or Mlu I digestion of source DNA. From these libraries three YAC clones with inserts belonging to the MHC class I region have been isolated. They correspond to exact copies of three genomic fragments of 210, 145, and 50 kilobases (kb), respectively and have been precisely located in the restriction map of the region. Detailed rare-cutter restriction maps of the inserts have been generated. Within these clones we have demonstrated the presence of two class I genes, one of which is HLA-E, and of at least three Hpa II tiny fragment (HTF) islands, corresponding to three putative new transcribed sequences. End clones, which are of particular interest in the extension and refinement of the regional map, have been rescued by systematic subcloning of purified YACs.     

HpaII library indicates ‘methylation-free islands’ in wheat and barley

Summary A library of wheat genomic DNA HpaII tiny fragments (HTF), sized below 500 bp, has been constructed. Of the clones in the library 80% belong to the single/low-copy category, while 12% of the clones are nuclear repetitive sequences and 8% originate from the chloroplast and mitochondrial DNA. This result shows a substantial enrichment in the single/low-copy sequences of the wheat genome, which contains at least 80% repetitive sequences. Twenty-nine random single/lowcopy clones were analysed further for wheat chromosome location, cross-hybridisation to barley DNA and their association with rare-cutting, C-methylation-sensitive restriction sites. The results show that the HTF clones are associated more frequently than expected with NotI, MluI, NruI and PstI sites in wheat and barley genomic DNA. The 12% repetitive fraction of the clones contain both moderately and highly repetitive sequences, but no tandemly repeated sequences. The level of enrichment for single/low-copy sequences indicates that libraries of this type are a valuable source of probes for RFLP mapping. In addition, the close association of the HTF clones with rare-cutting restriction enzyme sites ensures that HTF clones will have a useful role in the construction of long-range physical maps in wheat.     

<Emphasis Type="Italic">Not</Emphasis>I Sequence-Tagged Sites as Markers of Genes on Human Chromosome 3

Using nucleotide sequences from jumping and linking NotI libraries of human chromosome 3, 94 NotI-STS markers for 72 individual NotI clones were developed. The positions of the NotI-STS markers and their order on the chromosome were determined by a combination of RH-mapping (our data), contig mapping, cytogenetic mapping, and in silico mapping. Comparison of NotI-STS DNAs with human genome sequences revealed two gaps in the regions 3p21.33 (marker NL1-256) and 3p21.31 (NL3-005), and a segmental duplication. Identical DNA fragments were found in the regions 12q and 3p22–21.33 (marker NL3-007). In the 3q28–q29 region (marker NLM-084), a fragment was detected whose identical copies were also present on chromosomes 1, 2, 15, and 19. For 69 NotI-STSs, significant homologies to nucleotide sequences of 70 genes and 2 cDNAs were detected (with homologies in NotI-STS 5′- and 3′-terminal sequences being taken into account). An association between NotI-STSs and genes is confirmed by a strong correlation between the density distributions of genes and NotI-STS markers on the map of human chromosome 3. Our results indicate that the NotI map may be regarded as a gene map of human chromosome 3. Thus, NotI-STSs are applicable as gene markers.__________Translated from Molekulyarnaya Biologiya, Vol. 39, No. 4, 2005, pp. 687–701.Original Russian Text Copyright © 2005 by Sulimova, Rakhmanaliev, Klimov, Kompaniytsev, Udina, Zabarovsky, Kisselev.     

Development of a BAC library for yellow-poplar (Liriodendron tulipifera) and the identification of genes associated with flower development and lignin biosynthesis

Liriodendron tulipifera L., a member of the Magnoliaceae, occupies an important phylogenetic position as a basal angiosperm that has retained numerous putatively ancestral morphological characters, and thus has often been used in studies of the evolution of flowering plants and of specific gene families. However, genomic resources for these early branching angiosperm lineages are very limited. In this study, we describe the construction of a large-insert bacterial artificial chromosome (BAC) library from L. tulipifera. Flow cytometry estimates that this nuclear genome is approximately 1,802 Mbp per haploid genome (±16 SD). The BAC library contains 73,728 clones, a 4.8-fold genome coverage, with an average insert size of 117 kb, a chloroplast DNA content of 0.2%, and little to no bacterial sequences nor empty vector content clones. As a test of the utility of this BAC library, we screened the library with six single/low-copy genic probes. We obtained at least two positive clones for each gene and confirmed the clones by DNA sequencing. A total of 182 paired end sequences were obtained from 96 of the BAC clones. Using BLAST searches, we found that 25% of the BAC end sequences were similar to DNA sequences in GenBank. Of these, 68% shared sequence with transposable elements and 25% with genes from other taxa. This result closely reflected the content of random sequences obtained from a small insert genomic library for L. tulipifera, indicating that the BAC library construction process was not biased. The first genomic DNA sequences for Liriodendron genes are also reported. All the Liriodendron genomic sequences described in this paper have been deposited in the GenBank data library. The end sequences from shotgun genomic clones and BAC clones are under accession DU169330–DU169684. Partial sequences of Gigantea, Frigida, LEAFY, cinnamyl alcohol dehydrogenase, 4-coumarate:CoA ligase, and phenylalanine ammonia-lyase genes are under accession DQ223429–DQ223434. Electronic supplementary material Supplementary material is available in the online version of this article at and is accessible for authorized users.     

Reproducible Alterations of DNA Methylation at a Specific Population of CpG Islands during Blast Formation of Peripheral Blood Lymphocytes

We investigated the changes in the methylation patterns of CpGislands associated with blast formation of human peripheralblood lymphocytes activated by anti-CD3 and interleukin-2 (IL-2),using restriction landmark genomic scanning with a methylation-sensitiverestriction enzyme (RLGS-M) system. Of about 2,100 Not I spot/lociwhich were analyzed, only 10 showed changes, whereas drasticchanges have been observed in cases of malignant and SV40 transformation.These changes were highly reproducible for samples from boththe same and different individuals. Even the timing of the changesafter cultivation was the same. Thus, we concluded that at leastthe genomic DNA methylation state in vivo was essentially retainedin T blast cells activated in vitro by induction with IL-2 andanti-CD3, which are commonly used in biological experimentsas well as clinical diagnosis and therapy.     

Nucleotide Sequence of a 28-kb Mouse Genomic Region Comprising the Imprinted Igf2 Gene

The mouse insulin-like growth factor II gene (Igf2) is physicallylinked to the insulin II gene (Ins2) and both are subject totissue-specific genomic imprinting. The paternal-specific expressionof Igf2 has been associated with hypermethylation of some CpGsites in the 5' flanking region and in the body of the gene.As a first step in analyzing the structural features of thisimprinted locus, we here report the complete nucleotide sequenceof Igf2, including all introns and the intergenic region adjacentto Ins2. This 28-kb segment of mouse chromosome 7 exhibits 80%overall identity with the corresponding rat sequence and hasa high GC content of 52%. In addition to the known CpG islandwithin the second Igf2 promoter, another island was identifiedapproximately 2 kb 5' to the first exon. Other features of thislocus include a 35-fold tandem repeat of an 11-bp sequence thatoverlaps Igf2 pseudo-exon 2, and a B2 repeat element in theintergenic region between Ins2 and Igf2. The GC-richness andthe presence of CpG islands associated with tandem repeats arecommon features of imprinted genes and thus may play a rolein the imprinting mechanism.