Construction of bacteriophage P1 libraries with large inserts.

The bacteriophage P1 cloning system was originally developed as an alternative to YAC and cosmid systems for cloning high-molecular-weight genomic DNA. This unit details the preparation of the bacteriophage P1 library. Three support protocols provide the raw materials for the basic procedure, including the vector (pAd10sacBII), the mammalian DNA inserts, and the two packaging extracts that contain the viral proteins necessary to construct a P1 bacteriophage incorporating the vector and insert. A fourth support protocol describes how to induce replication of the plasmids cloned in the basic protocol, isolate the cloned DNA, and analyze the final products.

Genomewide search for type 2 diabetes susceptibility genes in four American populations.

Type 2 diabetes is a serious, genetically influenced disease for which no fully effective treatments are available. Identification of biochemical or regulatory pathways involved in the disease syndrome could lead to innovative therapeutic interventions. One way to identify such pathways is the genetic analysis of families with multiple affected members where disease predisposing genes are likely to be segregating. We undertook a genomewide screen (389-395 microsatellite markers) in samples of 835 white, 591 Mexican American, 229 black, and 128 Japanese American individuals collected as part of the American Diabetes Association's GENNID study. Multipoint nonparametric linkage analyses were performed with diabetes, and diabetes or impaired glucose homeostasis (IH). Linkage to diabetes or IH was detected near markers D5S1404 (map position 77 cM, LOD = 2.80), D12S853 (map position 82 cM, LOD = 2.81) and GATA172D05 (X-chromosome map position 130 cM, LOD = 2.99) in whites, near marker D3S2432 (map position 51 cM, LOD = 3.91) in Mexican Americans, and near marker D10S1412 (map position 14 cM, LOD = 2.39) in African Americans mainly collected in phase 1 of the study. Further analyses showed evidence for interactions between the chromosome 5 locus and region on chromosome 12 containing the MODY 3 gene (map position 132 cM) and between the X-chromosome locus and region near D12S853 (map position 82 cM) in whites. Although these results were not replicated in samples collected in phase 2 of the GENNID study, the region on chromosome 12 was replicated in samples from whites described by Bektas et al. (1999).

Direct sequencing of bacterial and P1 artificial chromosome-nested deletions for identifying position-specific single-nucleotide polymorphisms.

A loxP-transposon retrofitting strategy for generating large nested deletions from one end of the insert DNA in bacterial artificial chromosomes and P1 artificial chromosomes was described recently [Chatterjee, P. K. & Coren, J. S. (1997) Nucleic Acids Res. 25, 2205-2212]. In this report, we combine this procedure with direct sequencing of nested-deletion templates by using primers located in the transposon end to illustrate its value for position-specific single-nucleotide polymorphism (SNP) discovery from chosen regions of large insert clones. A simple ampicillin sensitivity screen was developed to facilitate identification and recovery of deletion clones free of transduced transposon plasmid. This directed approach requires minimal DNA sequencing, and no in vitro subclone library generation; positionally oriented SNPs are a consequence of the method. The procedure is used to discover new SNPs as well as physically map those identified from random subcloned libraries or sequence databases. The deletion templates, positioned SNPs, and markers are also used to orient large insert clones into a contig. The deletion clone can serve as a ready resource for future functional genomic studies because each carries a mammalian cell-specific antibiotic resistance gene from the transposon. Furthermore, the technique should be especially applicable to the analysis of genomes for which a full genome sequence or radiation hybrid cell lines are unavailable.

The human DNA polymerase beta gene structure. Evidence of alternative splicing in gene expression.

DNA polymerase beta (beta-pol) is a single-copy gene that is considered to be part of the DNA repair machinery in mammalian cells. Using two human genomic libraries we have cloned the complete human beta-pol gene and determined the organization of the beta-pol coding sequence within the gene. The human beta-pol gene spans 33 kb and contains 14 exons that range from 50 to 233 bp. The 13 introns vary from 96 bp to 6.5 kb. Information derived from this study was used in defining the location of a deletion/insertion type restriction fragment length polymorphism (RFLP) 5' to exon I of the human beta-pol gene. This RFLP was utilized in linkage analysis of DNAs from CEPH families and the results confirm the previous assignment of the human beta-pol gene to chromosome 8 (p12-p11). Analysis of mRNA from six human cell lines using the polymerase chain reaction showed the expression of two beta-pol transcripts. Sequence analysis revealed that the size difference in these transcripts was due to deletion of the 58 bp sequence encoded by exon II, suggesting that the smaller transcript results from an alternative splicing of the exon II sequence during processing of the beta-pol precursor RNA.

Preparation and screening of an arrayed human genomic library generated with the P1 cloning system.

We describe here the construction and initial characterization of a 3-fold coverage genomic library of the human haploid genome that was prepared using the bacteriophage P1 cloning system. The cloned DNA inserts were produced by size fractionation of a Sau3AI partial digest of high molecular weight genomic DNA isolated from primary cells of human foreskin fibroblasts. The inserts were cloned into the pAd10sacBII vector and packaged in vitro into P1 phage. These were used to generate recombinant bacterial clones, each of which was picked robotically from an agar plate into a well of a 96-well microtiter dish, grown overnight, and stored at -70 degrees C. The resulting library, designated DMPC-HFF#1 series A, consists of approximately 130,000-140,000 recombinant clones that were stored in 1500 microtiter dishes. To screen the library, clones were combined in a pooling strategy and specific loci were identified by PCR analysis. On average, the library contains two or three different clones for each locus screened. To date we have identified a total of 17 clones containing the hypoxanthine-guanine phosphoribosyltransferase, human serum albumin-human alpha-fetoprotein, p53, cyclooxygenase I, human apurinic endonuclease, beta-polymerase, and DNA ligase I genes. The cloned inserts average 80 kb in size and range from 70 to 95 kb, with one 49-kb insert and one 62-kb insert.

Isolation of P1 bacteriophage clones containing large contiguous segments of the human and mouse loci for the T-cell coreceptor molecule CD8.

The T-lymphocyte coreceptor molecules CD8 (composed of CD8 alpha and CD8 beta chains) and CD4 undergo a complex pattern of regulated expression during T-cell maturation. In the thymus, the most immature cells progress from expressing neither molecule (the double-negative [DN] stage) to an intermediate stage at which both are coexpressed (the double-positive [DP] stage). As a result of thymic selection and further differentiation, DP cells give rise to the most mature thymic cells and peripheral T cells that express either CD8 or CD4 (the single-positive [SP] stage). Our previous studies of the transcriptional regulatory mechanisms controlling CD8 alpha expression during the DN-->DP and DP-->SP transitions suggest the existence of important cis-acting elements located a considerable distance from the CD8 alpha gene and that these elements might serve to regulate both CD8 alpha and CD8 beta. While both genes and intergenic DNA span approximately 60 kb in the mouse, the relevant cis elements could lie either within or beyond this region. As a result, we sought to isolate large contiguous segments of DNA in P1 bacteriophage that covered at least this region from the mouse and human CD8 locus. Our initial physical characterization of these clones demonstrates the value of the P1 system as all isolated clones were found to contain single contiguous 85- to 95-kb segments of DNA that are faithful replicas of the chromosomal locus. The presence of abundant native flanking DNA both upstream and downstream of the intact coding regions will make these clones extremely useful for identifying physiological CD8 cis-active regulatory elements by virtue of their ability to direct appropriate lineage- and stage-specific expression in transfected and transgenic T cells.

The P1 vector system for the preparation and screening of genomic libraries.

In retrospect, it is remarkable how swiftly the P1 cloning system has progressed in only a few years from a novel cloning system to one now widely used for the production of recombinant libraries and the building of physical maps. As the libraries become larger, better characterized and more widely distributed, we certainly will see a blossoming of research articles and techniques based on the use of P1 recombinant clones. Specifically, we can look forward to scanning P1 clones for expressed sequences (N. Sternberg, personal communication), routine retrofitting of P1 clones with a combination of transposon and P1 transduction techniques (3), the random or loxP-directed (68,69) insertion of P1 clones into host genomes and the subsequent production of transgenic animals (63), a further use of P1 clones in the building of contigs and physical maps, an a higher in vitro cloning efficiency due to the purification of the P1 pacase proteins used during in vitro packaging (70). In summary, P1 bacteriophage cloning is favorably impacting research today and will continue to fill an important niche as a genomic cloning system.

Genetic and molecular characterization of a-mrh-Mrh, a new mutable system of Zea mays.

A new allele of the maize A1 gene, a gene required for anthocyanin pigment biosynthesis, was identified in a genetic stock exhibiting a high frequency of chromosome breakage at the second microspore mitosis. This allele, a-mrh, is unstable in both somatic and germinal tissue when an independent locus, Mrh, is present in the genome. a-mrh was molecularly cloned, and a 246 bp DNA insertion with characteristics of a transposable element was identified within the fourth exon of the gene. Southern blot analysis of germinal derivatives of a-mrh suggests that the DNA insert rMrh is excised from the locus when a wild-type phenotype is restored. Genetic crosses with components of other two-element mutable systems of maize failed to induce mutability. We therefore conclude that rMrh is a member of a new, two-element transposon system of maize. The genetic and molecular characteristics of the elements involved are discussed with respect to stress-activated transposition, response of an element to developmental signals, and a possible new role of plant transposons in gene evolution.

Molecular characterization of rDt, a maize transposon of the "Dotted" controlling element system.

We have molecularly cloned the rDt transposon, one component of the classic "Dotted" two-element system of controlling elements. The rDt transposon was identified as a DNA insertion in each of two independent mutation events of the maize A1 gene, a gene necessary for the biosynthesis of anthocyanin pigment. Both mutant alleles result in a stable, anthocyaninless phenotype in all plant tissues. When the transposon "Dotted", (Dt), is present in the genome each allele exhibits a characteristic mutable phenotype (spots of anthocyanin pigmentation). The DNA insertion has been designated rDt, for it responds to or is regulated by the Dt element to allow expression of the otherwise mutated gene, and it had not been named in earlier genetic studies. Sequence analysis revealed the rDt element to be an identical 704 bp insertion within the two mutable alleles, but in opposite orientation and in different exons of the gene. rDt contains an imperfect terminal inverted repeat with similarity to transposable elements of various species. A duplication of 8 bp of the target host site is formed upon integration of the element, and the element is excised from the locus in a germinal revertant. The difference in phenotype of the two unstable alleles, a1 and am-1:Cache, is discussed.

Molecular cloning of the a1 locus of Zea mays using the transposable elements En and Mu1.

The a1 locus of Zea mays has been cloned using transposable elements as gene tags. The strategy was to make genomic libraries from maize stocks with a1 mutations induced either by En(Spm) or by Robertson's Mutator-system. These libraries were then screened with either Spm-I8 and En1, for the En-containing mutant, or with Mu1 for the Mu-induced mutation. There are many En and Mu1 hybridizing sequences present in the maize genome, however, by a process of cross-screening of the positives from the two libraries and by molecular analysis of the En-positive clones it was possible to identify clones in both libraries carrying all or part of the a1 gene.

Similarity of the Cin1 repetitive family of Zea mays to eukaryotic transposable elements.

It has been suggested that the middle repetitive class of sequences that make up a large proportion of the eukaryotic genome have been amplified and dispersed by DNA transposition. Transposition is a phenomenon first postulated by Barbara McClintock on the basis of her genetic analysis of mutants in Zea mays. Since then, DNA transposition has been studied genetically in various plant systems and is well documented on the molecular level in both prokaryotes and eukaryotes. This has included the isolation of DNA inserts at various loci in several plants; however, the prevalence of transposition in plants is not established. We report here DNA nucleotide sequence data which show that some members of the Cin1 middle repetitive family of maize have features characteristic of known transposable elements. One cloned Cin1 repeat has a 6-base pair (bp) perfect inverted repeat sequence at its ends. The terminal five base pairs (5' TGTTG . . . CAACA 3') are identical to the termini of Drosophila copia transposable elements. Two other Cin1 alleles are flanked by 5-bp direct repeats. A comparison is made with the long terminal repeat (LTR) of the copia-Ty1-retrovirus families of moveable genetic elements.

Repetitive sequences and their organization on genomic clones of Zea mays.

Fourteen recombinant clones from Zea mays were studied with regard to their composition of unique and repetitive sequences. Southern hybridization experiments were used to classify restriction fragments of the clones into a unique, middle or highly repetitive class of reiteration frequency. All three classes were often found on the same genomic clone. Crosshybridization studies between clones showed that a given repeat might be present on several clones, and thus four families of highly repetitive elements were established. Heteroduplex analysis was used to show the arrangement and size of repeats common between several clones. A short interspersion pattern of unique, middle and highly repetitive DNA was found. The dispersed repetitive elements were 300-1300 bp in length. Analysis of the pattern produced by a given repeat in genomic Southern experiments suggests that some small dispersed repeats may also exist as part of a larger repeating unit elsewhere in the genome.

Synthesis and activity of ribonucleic acid polymerase in Escherichia coli.

The amounts of ribonucleic acid (RNA) polymerase (beta' subunits) and ribosomes (RNA), and the fraction of RNA polymerase actively engaged in transcription, were measured in Escherichia coli B/r as a function of growth rate. By an improved method of quantitating protein bands on electrophoresis gels, the systematic error and reproducibility of the RNA polymerase determination were estimated to be less than 15 and 6%, respectively. For a threefold increase in growth rate, the fractional synthesis of polymerase (relative to protein) increased 1.5-fold, whereas the fractional synthesis of ribosomal protein increased 2.2-fold. The decrease in the amount of RNA polymerase per ribosome with increasing growth rate is interpreted as an expression of the control of the transcriptional read-through from the genes for ribosomal protein, rplJ,L, to the adjacent genes for RNA polymerase subunits, rpoB,C. The number of active RNA polymerase molecules was determined from the synthesis rates of stable and messenger RNA and the known RNA chain growth rates. Comparison of active and total RNA polymerase indicates that the fraction of active enzyme increases from 20 to 30% in the range of growth rates between 0.6 and 2.0 doublings per hour. Possible causes for the inactive enzyme are discussed.

Fenestrated palatal mucosal grafts for vestibuloplasty.

Vestibuloplasties with fenestrated palatal mucosal grafts were successful in eight patients. The fenestrated palatal mucosa provides a tough, full-thickness, resilient mucosal graft from a limited donor site. The operating time is decreased, bleeding is minimized, and healing time of the donor site is shortened. Fenestration allows seepage of blood and tissue fluids from beneath the graft. The fenestrated grafts are readily adaptable to any irregularities of the edentulous mandibular ridge.