Three new developments in P1 cloning. Increased cloning efficiency, improved clone recovery, and a new P1 mouse library

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.

Calbindin D(9k) knockout mice are indistinguishable from wild-type mice in phenotype and serum calcium level

Since the discovery of calbindin D(9k), its role in intestinal calcium absorption has remained unsettled. Further, a wide distribution of calbindin D(9k) among tissues has argued for its biological importance. We discovered a frameshift deletion in the calbindin D(9k) gene in an ES cell line, E14.1, that originated from 129/OlaHsd mice. We produced mice with the mutant calbindin D(9k) gene by injecting the E14.1 ES cell subline into the C57BL/6 host blastocysts and proved that these mice lack calbindin D(9k) protein. Calbindin D(9k) knockout mice were indistinguishable from wild-type mice in phenotype, were able to reproduce, and had normal serum calcium levels. Thus, calbindin D(9k) is not required for viability, reproduction, or calcium homeostasis.

Minimal cross-recombination between wild-type and loxP511 sites in vivo facilitates truncating both ends of large DNA inserts in pBACe3.6 and related vectors

Contrary to several earlier reports, we find that cross-recombination between wild-type and the mutant loxP511 sites is <0.5% of that between two wild-type sites if Cre protein is expressed by phage P1 during an infection. The finding enabled us to develop a procedure to truncate DNA progressively from both ends of large genomic inserts flanked by these two loxP sites in pBACe3.6 and related vectors with transposons carrying either a wild-type or a loxP511 sequence. Newly constructed loxP511 transposons contained either a kanamycin resistance gene or no marker. Insert DNA ends in deletions were sequenced with primers unique to each transposon-end remaining after the respective recombination. End-sequencing 223 deletions confirmed that the low level of cross-recombination, observed between those sites during the P1 transductions, does not complicate the procedure: truncations from the unintended end of genomic inserts did not occur. Multiple BACs pooled together could also be processed in a single tube to make end-deletions. This deletion technology, utilizing the very minimal cross-recombination between the mutant and wild-type loxP sites of most BAC clones in the public domain and a heterologous one inserted as a transposon, should facilitate functionally mapping long-range gene regulatory sequences and help to isolate genes with defined functional boundaries in numerous projects including those of therapeutic interest.

Mutually exclusive recombination of wild-type and mutant loxP sites in vivo facilitates transposon-mediated deletions from both ends of genomic DNA in PACs

Recombination of wild-type and mutant loxP sites mediated by wild-type Cre protein was analyzed in vivo using a sensitive phage P1 transduction assay. Contrary to some earlier reports, recombination between loxP sites was found to be highly specific: a loxP site recombined in vivo only with another of identical sequence, with no crossover recombination either between a wild-type and mutant site; or between two different mutant sites tested. Mutant loxP sites of identical sequence recombined as efficiently as wild-type. The highly specific and efficient recombination of mutant loxP sites in vivo helped in developing a procedure to progressively truncate DNA from either end of large genomic inserts in P1-derived artificial chromosomes (PACs) using transposons that carry either a wild-type or mutant loxP sequence. PAC libraries of human DNA were constructed with inserts flanked by a wild-type and one of the two mutant loxP sites, and deletions from both ends generated in clones using newly constructed wild-type and mutant loxP transposons. Analysis of the results provides new insight into the very large co-integrates formed during P1 transduction of plasmids with loxP sites: a model with tri- and possibly multimeric co-integrates comprising the PAC plasmid, phage DNA, and transposon plasmid(s) as intermediates in the cell appears best to fit the data. The ability to truncate a large piece of DNA from both ends is likely to facilitate functionally mapping gene boundaries more efficiently, and make available precisely trimmed genes in their chromosomal contexts for therapeutic applications.

Pituitary hypoplasia and respiratory distress syndrome in Prop1 knockout mice

Mutations in Prophet of PIT1 (Prop1), one of several homeodomain transcription factors that are required for the development of the anterior pituitary gland, are the predominant cause of MPHD (multiple pituitary hormone deficiency) in humans. We show that deletion of Prop1 in mice causes severe pituitary hypoplasia with failure of the entire Pit1 lineage and delayed gonadotrope development. The pituitary hormone deficiencies cause secondary endocrine problems and a high rate of perinatal mortality due to respiratory distress. Lung atelectasis in mutants correlates with reduced levels of NKX2.1 and surfactant. Lethality of mice homozygous for either the null allele or a spontaneous hypomorphic allele is strongly influenced by genetic background. Prop1-null mice are an excellent model for MPHD and may be useful for testing the efficacy of pharmaceutical intervention for neonatal respiratory distress.

Genomic structure of mouse PIR-A6, an activating member of the paired immunoglobulin-like receptor gene family

The gene for one of the activating members of the paired Ig-like receptor family, Pira6, was isolated from a genomic library and sequenced. The first of 9 exons in the approximately 8.2 kb Pira6 gene encodes the 5' untranslated region, the translation initiation site, and approximately half of the signal sequence. The second exon encodes the rest of the signal sequence, exons 3-8 each encode a single Ig-like extracellular domain, and exon 9 encodes the transmembrane region, cytoplasmic tail and 3' UTR with four polyadenylation signals and six mRNA instability sequences. A soluble form of PIR-A6 may be generated by alternative splicing. The exonic sequences account for approximately 42% of the Pira6 gene and approximately 34% for the single inhibitory Pirb gene, thus defining Pira and Pirb as genes with relatively short intronic sequences. Extensive sequence homology was found between Pira6 and Pirb from approximately 2 kb upstream of the ATG initiation site to the beginning of intron 8. The Pir genes appear to be distributed in three regions of the proximal end of chromosome 7 based on the present data and an analysis of currently available mouse genomic sequence databases. One region contains a single Pir gene which is almost identical to Pira6, and the other two contain multiple Pir genes in opposite transcriptional orientations. Potential binding sites for hemopoiesis-specific and ubiquitous transcription factors were identified upstream of the Pira6 transcription start sites that reside within the initiator consensus sequence motif. These results provide important clues to the coordinate regulation observed for PIR-A and PIR-B expression during hematopoiesis.

Alternative splicing of brain-specific PTB defines a tissue-specific isoform pattern that predicts distinct functional roles

Splicing of neural-specific exons is differentially regulated in neuronal and non-neuronal cells. The polypyrimidine tract binding protein (PTB) has been implicated as a negative regulator for exon splicing, whereas the brain-specific homolog of PTB, termed nPTB, promotes exon splicing exclusively in neurons. We have now isolated a novel mRNA splice variant of nPTB from non-neuronal cells. In contrast to the neural nPTB transcript, the expression of this novel isoform was absent from brain tissue and was generated in non-neuronal cells by alternative splicing to include five additional amino acid residues encoded by exon 9. In addition, we identified a brain-specific transcript containing a novel, alternatively spliced, internal exon 10. The exclusion of this 34-nucleotide exon 10 in non-neuronal tissues generates a premature termination codon and results in the truncation of the open reading frame. Our findings suggest that alternative splicing of nPTB has an important role in regulation of tissue-specific gene expression and thus in the functional activity of nPTB in neuronal and non-neuronal cells.

Lymphopenia in the BB rat model of type 1 diabetes is due to a mutation in a novel immune-associated nucleotide (Ian)-related gene

The BB (BioBreeding) rat is one of the best models of spontaneous autoimmune diabetes and is used to study non-MHC loci contributing to Type 1 diabetes. Type 1 diabetes in the diabetes-prone BB (BBDP) rat is polygenic, dependent upon mutations at several loci. Iddm1, on chromosome 4, is responsible for a lymphopenia (lyp) phenotype and is essential to diabetes. In this study, we report the positional cloning of the Iddm1/lyp locus. We show that lymphopenia is due to a frameshift deletion in a novel member (Ian5) of the Immune-Associated Nucleotide (IAN)-related gene family, resulting in truncation of a significant portion of the protein. This mutation was absent in 37 other inbred rat strains that are nonlymphopenic and nondiabetic. The IAN gene family, lying within a tight cluster on rat chromosome 4, mouse chromosome 6, and human chromosome 7, is poorly characterized. Some members of the family have been shown to be expressed in mature T cells and switched on during thymic T-cell development, suggesting that Ian5 may be a key factor in T-cell development. The lymphopenia mutation may thus be useful not only to elucidate Type 1 diabetes, but also in the function of the Ian gene family as a whole.

Comparative analysis of the genetic structure and chromosomal location of the murine MyD118 (Gadd45beta) gene

The MyD118 (Gadd45beta) protein is a member of a family of structurally related proteins, including Gadd45 (Gadd45alpha) and CR6 (Gadd45gamma), that have critical roles in regulating growth arrest and apoptosis. The MyD118 and other members of its family display distinct patterns of expression in response to stimuli that induce differentiation, growth arrest, or apoptosis. Species-blot analysis showed that MyD118 is an evolutionarily conserved gene, and comparative sequence analysis showed that MyD118 has a gene structure similar to that of other members of its gene family. Comparison of putative transcription factor-binding sites found in sequences of this gene family provides evidence that p53 is involved in regulating the expression of MyD118 and that NF-kappaB may play a role in differential expression of MyD118 and Gadd45(Gadd45alpha). Fluorescence in situ hybridization localized the MyD118 gene to mouse chromosome band 10B5.3, correcting a previous assignment to mouse chromosome 9.

Genetic and physical mapping of the cerebellar deficient folia (cdf) locus on mouse chromosome 6

Cerebellar deficient folia (cdf) is a recessive mouse mutation causing ataxia and cerebellar cytoarchitectural abnormalities, including hypoplasia, foliation defects, and Purkinje cell ectopia. To identify the cdf gene, we have generated a high-resolution genetic map of a 3.24 +/- 0.55 cM (95% CI) region encompassing the cdf gene using 1997 F2 mice generated from a (C3H/HeSnJ-cdf/cdf x CAST/Ei)F1 intercross. Linkage analysis showed that the cdf gene cosegregates with D6Mit208, D6Mit359, and D6Mit225. A contig of five YACs, nine BACs, and three P1s was constructed across the cdf nonrecombinant region. Based on genetic and physical maps, the cdf gene was localized to the 0.28 +/- 0.23 cM (95% CI) interval between D6Mit209 and D6Ack1. These results will greatly facilitate the map-based cloning of the cdf gene, which in turn should further knowledge of the molecular mechanisms of neuronal positioning and foliation during cerebellar development.

Evolutionary divergence of the mouse and human Lgn1/SMA repeat structures

The orthologous genomic segments on mouse chromosome 13D1-D3 and human chromosome 5q11.2-q13.3 have been extensively studied because of their involvement in two distinct disease phenotypes, spinal muscular atrophy (SMA) in human and susceptibility to Legionella pneumophila (determined by Lgn1) in mice. The overlapping intervals in both species contain genomic amplifications of distinct structure, indicating an independent origin. We have endeavored to construct a comprehensive comparative gene map of the mouse and human Lgn1/SMA intervals in the hopes that the origins and maintenance of the genomic amplifications may become clear. Our comparative gene map demonstrates that the only regional gene in common between the amplified segments in mouse and human is the Lgn1 candidate Naip/NAIP. We have also determined that mice of the 129 haplotype harbor seven intact and three partial Naip transcription units arranged in a closely linked direct repeat on chromosome 13. Several, but not all, of these Naip loci are contained within the Lgn1 critical interval. We present a model for the origins of the mouse and human repetitive arrays from a common ancestral haplotype.

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.

Exon organization, coding sequence, physical mapping, and polymorphic intragenic markers for the human neuronal sodium channel gene SCN8A

The voltage-gated sodium channel SCN8A is associated with inherited neurological disorders in the mouse that include ataxia, dystonia, severe muscle weakness, and paralysis. We report the complete coding sequence and exon organization of the human SCN8A gene. The predicted 1980 amino acid residues are distributed among 28 exons, including two pairs of alternatively spliced exons. The SCN8A protein is evolutionarily conserved, with 98.5% amino acid sequence identity between human and mouse. Consensus sites for phosphorylation of serine/threonine and tyrosine residues are present in cyoplasmic loop domains. The polymorphic (CA)n microsatellite marker D12S2211, with PIC = 0.68, was isolated from intron 10C of SCN8A. Single nucleotide polymorphisms in intron 19 and exon 22 were also identified. We localized SCN8A to chromosome band 12q13.1 by physical mapping on a YAC contig. The cDNA clone CSC-1 was reported by others to be a cardiac-specific sodium channel, but sequence comparison demonstrates that it is derived from exon 24 of human SCN8A. The genetic information described here will be useful in evaluating SCN8A as a candidate gene for human neurological disease.

Comparative mapping of distal murine chromosome 11 and human 17q21.3 in a region containing a modifying locus for murine plasma von Willebrand factor level

Type 1 von Willebrand disease (VWD) is a common inherited disorder characterized by mild to moderate bleeding and reduced levels of von Willebrand factor (VWF). An animal model for human type 1 VWD, the RIIIS/J mouse strain, exhibits a prolonged bleeding time and reduced plasma VWF levels. We have previously mapped the defect in RIIIS/J to distal mouse Chr 11, distinct from the Vwf locus on Chr 6. This locus, Mvwf, was localized to an approximately 0.5-cM interval, tightly linked to Gip, distal to Ngfr, and proximal to Hoxb. We have now used these genetic markers to construct a contig of yeast and bacterial artificial chromosomes and bacteriophage P1 clones spanning the approximately 300-kb Mvwf nonrecombinant interval. In a comparative mapping approach, mouse homologues of mapped human expressed sequence tags (ESTs) were localized relative to the candidate interval. Twenty-one sequence-tagged sites and ESTs from the corresponding human syntenic region 17q21.3 were ordered using the high-resolution Stanford TNG3 radiation hybrid panel. Based on the resulting radiation hybrid map and our mouse genetic and physical maps, the order of human and mouse genes in a >0.7-cM region appears to be conserved. Six genes localized to the Mvwf nonrecombinant interval by comparative mapping included orthologs of GNGT2, ATP6N1, and a nuclear domain protein. Seven other genes or ESTs were excluded from the candidate interval, including orthologs of PHB, PDK2, a speckle-type protein, and a UDP-galactose transporter. Using exon trapping, 10 additional putative expressed sequences were identified within the Mvwf nonrecombinant interval, including a previously cloned murine glycosyltransferase as well as exons showing sequence similarity to genes for Caenorhabditis elegans and Saccharomyces cerevisiae predicted proteins, an Arabidopsis thaliana ubiquitin-conjugating enzyme, and a Gallus gallus mRNA zipcode-binding protein. Further characterization of these putative genes could identify the dominant mutation responsible for low plasma VWF levels in RIIIS/J mice. These data may also aid in the localization of other disease loci mapped to this region, including the gene for tricho-dento-osseous syndrome and a murine locus for susceptibility to ozone-induced acute lung injury.

High-resolution genetic, physical, and transcript map of the mnd2 region of mouse chromosome 6

The autosomal recessive mutation mnd2 is responsible for a lethal neuromuscular wasting disorder in the mouse. A high-resolution genetic map of the mnd2 region of mouse chromosome 6 was generated by analysis of 1147 F2 offspring from an intersubspecific cross between strains C57BL/6J-mnd2/+ and CAST/Ei. The results localize mnd2 to the 0.2-cM interval between D6Mit164 and D6Mit128. A contig of overlapping YAC, BAC, and P1 clones spanning the nonrecombinant interval was constructed. One novel gene isolated from the contig, D6Mm3e, is a new member of the WD repeat gene family. The observed gene order for the five positional candidate genes previously mapped to the region and five newly isolated genes is centromere-Hexokinase II-D6Mm5e-p62 Dok-Aup1-Rhotekin, D6Mm3e-Dynactin 1-Smooth muscle gamma actin-D6Mm4e-beta-adducin-telomere. Seven of these genes are located within the 400-kb nonrecombinant interval for mnd2. Comparison between wildtype and mutant failed to detect any differences in mRNA size, abundance, or coding sequence for these seven genes. The genes described here are positional candidates for the Parkinson disease susceptibility locus PARK3 that was recently mapped to the corresponding region of human chromosome band 2p13.1.

Genomics, Isoforms, Expression, and Phylogeny of the MHC Class I-Related MR1 Gene

A growing number of non-MHC-encoded class I-related molecules have been shown to perform diverse, yet essential, functions. These include T cell presentation of bacterially derived glycolipidic Ags by CD1, transcytosis of maternal IgG by the neonatal Fc receptor, enriched presence and plausible function within exocrine fluids of the Zn-α2-glycoprotein, subversion of NK cytolytic activity by the CMV UL18 gene product, and, finally, crucial involvement in iron homeostasis of the HFE gene. A recently described member of this family is the MHC class-I related (MR1) gene. The most notable feature of MR1 is undoubtedly its relatively high degree of sequence similarity to the MHC-encoded classical class I genes. The human chromosome 1q25.3 MR1 locus gives rise not only to the originally reported 1,263-bp cDNA clone encoding a putative 341-amino acid polypeptide chain, but to many additional transcripts in various tissues as well. Here we define the molecular identity of all human and murine MR1 isoforms generated through a complex scenario of alternative splicing, some encoding secretory variants lacking the Ig-like α3 domain. Moreover, we show ubiquitous transcription of these MR1 variants in several major cell lineages. We additionally report the complete 18,769-bp genomic structure of the MR1 locus, localize the murine orthologue to a syntenic segment of chromosome 1, and provide evidence for conservation of a single-copy MR1 gene throughout mammalian evolution. The 90% sequence identity between the human and mouse MR1 putative ligand binding domains together with the ubiquitous expression of this gene favor broad immunobiologic relevance.

Expression of polycystin in mouse metanephros and extra-metanephric tissues

The presence of messenger RNA for the mouse homologue of the polycystic kidney disease 1 gene (PKD1) was demonstrated by reverse transcription-polymerase chain reaction (RT-PCR) methods in mouse embryo messenger RNA. A single locus for the PKD1 gene was detected on mouse chromosome 17 by fluorescent in situ hybridization. Immunoprecipitation of proteins from [35S] methionine-labeled mouse metanephric explants with an anti-polycystin antibody (Pc1) revealed high molecular weight bands, the highest being > 400 kDa. Immunoperoxidase staining of mouse embryos with Pc1 revealed expression of polycystin as early as day 8 gestation. The expression was seen in epithelial cells of the ureteric bud, in condensing blastemal cells of the developing metanephros and, subsequently, in cells of the nascent tubules. In addition, Pc1 immunoreactivity was seen in hepatocytes and biliary epithelium, cardiac and skeletal muscle, neural tissue, gut, and bronchial epithelium. In post-natal and adult mouse kidney and liver persistent slight to moderate immunoreactivity was observed. Immunofluorescent studies of cultured 13-day mouse metanephroi revealed polycystin expression in ureteric bud epithelium, early glomerular structures (that is, condensates, S-shaped and comma-shaped bodies) and in proximal and distal tubular epithelia. These data indicate that the mouse has a single gene homologous to human PKD1 on chromosome 17, and polycystin is expressed in a variety of tissues during embryonic development.

The mouse extracellular signal-regulated kinase 2 gene. Gene structure and characterization of the promoter

ERK2 (extracellular-signal regulated kinase 2, also known as p42 mitogen-activated protein kinase) is an integral member of the mitogen-activated protein kinase cascade that is crucial for many cellular events such as proliferation and differentiation. Here, we determined the genomic organization of the Erk2 gene and characterized its promoter. The Erk2 gene spans over 60 kilobases, and the coding region is split into eight exons. In the coding region, exon-intron organization was exactly conserved between the two mouse genes for ERK2 and ERK1 except one junction shifted by one nucleotide. Primer extension and S1 nuclease analyses identified two major transcription start sites located at -219 and -223 relative to the translation start site. The 5'-flanking sequence lacked TATA box but contained a CCAAT box located approximately 60 base pairs upstream of transcription start sites. Sequencing of the 5'-flanking region also revealed potential cis-acting elements for multiple transcriptional regulatory factors including Sp1, zif268, Ets, CREB, and PuF sites. The promoter activity of the 5'-flanking region was examined using chloramphenicol acetyltransferase as a reporter gene. Transient transfection experiments using Chinese hamster ovary cells defined a maximal promoter activity in a 371-base pair region immediately upstream of the translation start site. Furthermore, we demonstrated, using mouse P19 embryonal carcinoma cells, that this 371-base pair sequence is likely to be sufficient to confer the transcriptional activation of the ERK2 promoter during the retinoic acid-induced differentiation of P19 cells.

Isolating large nested deletions in bacterial and P1 artificial chromosomes by in vivo P1 packaging of products of Cre-catalysed recombination between the endogenous and a transposed loxP site

A general approach for isolating large nested deletions in P1 artificial chromosomes (PACs) and bacterial artificial chromosomes (BACs) by retrofitting with a loxP site-containing Tn10 mini-transposon is described. Cre-mediated recombination between the loxP site existing in these clones and one introduced by transposition leads to deletions and inversions of the DNA between these sites. Large deletions are selectively recovered by transducing the retrofitted PAC or BAC clones with P1 phage. The requirement that both loxP sites in the cointegrate be packaged into a P1 head ensures that only large deletions are rescued. PCR analyses identified these deletions as products of legitimate recombination between loxP sites mediated by Cre protein. BACs produce deletions much more efficiently than PACs although the former cannot be induced to greater than unit copy in cells. Mammalian cell-responsive antibiotic resistance markers are introduced as part of the transposon into genomic clone deletions for subsequent functional analysis. Most importantly, the loxP site retrofitting and P1 transduction can be performed in the same bacterial host containing these clones directly isolated from PAC or BAC libraries. These procedures should facilitate physical and functional mapping of genes and regulatory elements in these large plasmids.

The mouse rostral cerebellar malformation gene encodes an UNC-5-like protein

Migration of neurons from proliferative zones to their functional sites is fundamental to the normal development of the central nervous system. Mice homozygous for the spontaneous rostral cerebellar malformation mutation (rcm(s)) or a newly identified transgenic insertion allele (rcm(tg)) exhibit cerebellar and midbrain defects, apparently as a result of abnormal neuronal migration. Laminar structure abnormalities in lateral regions of the rostral cerebellar cortex have been described in homozygous rcm(s) mice. We now demonstrate that the cerebellum of both rcm(s) and rcm(tg) homozygotes is smaller and has fewer folia than in the wild-type, ectopic cerebellar cells are present in midbrain regions by three days after birth, and there are abnormalities in postnatal cerebellar neuronal migration. We have cloned the rcm complementary DNA, which encodes a transmembrane receptor of the immunoglobulin superfamily. The sequence of the rcm protein (Rcm) is highly similar to that of UNC-5, a Caenorhabditis elegans protein that is essential for dorsal guidance of pioneer axons and for the movement of cells away from the netrin ligand, which is encoded by the unc-6 gene. As Rcm is a member of a newly described family of vertebrate homologues of UNC-5 which are netrin-binding proteins, our results indicate that UNC-5-like proteins may have a conserved function in mediating netrin-guided migration.

Retrofitting high molecular weight DNA cloned in P1: introduction of reporter genes, markers selectable in mammalian cells and generation of nested deletions

The bacteriophage P.1. cloning system is proving to be quite useful for the cloning and analysis of genomic DNA inserts of up to 95 kb in size. In an effort to use that DNA directly in biological experiments we have embarked on a scheme to retrofit the P.1. DNA using a mini-Tn10 transposon system. This transposon system is used in two ways: (i) to introduce a variety of sequence signals that are recognizable in mammalian cells, such as mammalian cell-responsive resistance markers and reporter genes, and (ii) to generate a nested set of deletions in a P.1. clone by using a ioxP site located within the transposon. In this report we show that such transpositions into P.1. DNA are efficient, distributed throughout the entire length of the genomic fragment and do not disrupt the DNA in any location other than the site of insertion of the transposon. The Tn10-based P.1. transduction system described here provides a general scheme for retrofitting any large genomic DNA cloned in a P.1. vector, thus facilitating the use of clones from the current P.1. recombinant libraries in cellular transformation studies.