Functional characterization of human nucleosome assembly protein-2 (NAP1L4) suggests a role as a histone chaperone.

Histones are thought to play a key role in regulating gene expression at the level of DNA packaging. Recent evidence suggests that transcriptional activation requires competition of transcription factors with histones for binding to regulatory regions and that there may be several mechanisms by which this is achieved. We have characterized a human nucleosome assembly protein, NAP-2, previously identified by positional cloning at 11p15.5, a region implicated in several disease processes including Wilms tumor (WT) etiology. The deduced amino acid sequence of NAP-2 indicates that it encodes a protein with a potential nuclear localization motif and two clusters of highly acidic residues. Functional analysis of recombinant NAP-2 protein purified from Escherichia coli demonstrates that this protein can interact with both core and linker histones. We demonstrate that recombinant NAP-2 can transfer histones onto naked DNA templates. Deletion mutagenesis of NAP-2 demonstrates that both NH3- and COOH-terminal domains are required for histone transfer activity. Subcellular localization studies of NAP-2 indicate that it can shuttle between the cytoplasm and the nucleus, suggesting a role as a histone chaperone. Given the potential role of the human NAP-2 gene (HGMW-approved symbol NAP1L4) in WT etiology, we have elucidated the exon/intron structure of this gene and have analyzed the mutational status of NAP-2 in sporadic WTs. Our results, coupled with tumor suppression assays in G401 WT cells, do not support a role for NAP-2 in the etiology of WT. A putative role for NAP-2 in regulating cellular differentiation is discussed.

A 500-kb physical map and contig from the Harvey ras-1 gene to the 11p telomere.

A contiguous physical map was constructed from the Harvey ras-1 (HRAS1) gene to the 11p telomere. The contig spans approximately 500 kb and is minimally composed of a telomere-containing YAC and P1 and cosmid clones. Included in the contig are 11 sequence-tagged sites derived from P1 and cosmid ends. Three genes were placed on the contig in the following order: telomere-ribonuclease/angiogenin inhibitor (RNH)-Harvey ras-1 (HRAS1)-HRAS1-related complex (HRC). Two novel tetranucleotide repeats (heterozygosity of 66 and 68%) and a complex CA repeat (heterozygosity of 78%) were isolated and characterized.

A high-resolution physical map of human chromosome 11.

The development of a highly reliable physical map with landmark sites spaced an average of 100 kbp apart has been a central goal of the Human Genome Project. We have approached the physical mapping of human chromosome 11 with this goal as a primary target. We have focused on strategies that would utilize yeast artificial chromosome (YAC) technology, thus permitting long-range coverage of hundreds of kilobases of genomic DNA, yet we sought to minimize the ambiguities inherent in the use of this technology, particularly the occurrence of chimeric genomic DNA clones. This was achieved through the development of a chromosome 11-specific YAC library from a human somatic cell hybrid line that has retained chromosome 11 as its sole human component. To maximize the efficiency of YAC contig assembly and extension, we have employed an Alu-PCR-based hybridization screening system. This system eliminates many of the more costly and time-consuming steps associated with sequence tagged site content mapping such as sequencing, primer production, and hierarchical screening, resulting in greater efficiency with increased throughput and reduced cost. Using these approaches, we have achieved YAC coverage for >90% of human chromosome 11, with an average intermarker distance of <100 kbp. Cytogenetic localization has been determined for each contig by fluorescent in situ hybridization and/or sequence tagged site content. The YAC contigs that we have generated should provide a robust framework to move forward to sequence-ready templates for the sequencing efforts of the Human Genome Project as well as more focused positional cloning on chromosome 11.

Systematic screening of an arrayed cDNA library by PCR.

We have developed a PCR-based method for rapid and effective screening of arrayed cDNA libraries. This strategy directly addresses the limitations of conventional hybridization-based schemes and provides a more rapid, cost-effective, and sensitive method compatible with large-scale and routine cDNA clone recovery. To prepare arrayed libraries, 1-2 x 10(6) cDNA clones were propagated as individual plaques on solid medium in 24-well culture dishes at approximately 250 plaque-forming units per well. Phage suspensions were prepared from each well and transferred to a 96-well format. To screen the library, pools were generated that correspond to each individual 96-well plate and to each row and column within "blocks" of six plates each. Library screening for specific cDNA clones was conducted in a systematic and hierarchical fashion beginning with the plate pools. Next, the row/column pools corresponding to each positive plate pool were screened. Finally, isolated clones from within each positive well were identified by hybridization. We have applied this approach to the screening of an arrayed human brain cDNA library resulting in the recovery of cDNAs corresponding to > 25 genes and expressed sequence tags.

IRE-bubble PCR: a rapid method for efficient and representative amplification of human genomic DNA sequences from complex sources.

A significant issue in the analysis of any genomic DNA segment is the generation of a unique set of short single-copy sequences that are representative of that region. In this report we describe a novel technique, IRE-bubble PCR, which was designed to amplify the human DNA content of somatic cell hybrids, YACs, cosmids, and lambda phage and result in greater complexity and representation than standard inter-IRE PCR. Here we demonstrate that IRE-bubble PCR is species specific and that it results in the generation of a product that is at least 10-fold more complex and representative than that produced by standard inter-IRE PCR. In addition, we have addressed the factors that contribute to the representation of the IRE-bubble PCR product and show how they may be used to further increase the complexity of this reaction. Finally, we have illustrated how the complexity and distribution of products generated by IRE-bubble PCR can be exploited and applied to FISH mapping and "chromosome painting" as well as to the generation of STSs targeted to specific chromosomal or subchromosomal regions.