Novel human bronchial epithelial cell lines for cystic fibrosis research.

Immortalization of human bronchial epithelial (hBE) cells often entails loss of differentiation. Bmi-1 is a protooncogene that maintains stem cells, and its expression creates cell lines that recapitulate normal cell structure and function. We introduced Bmi-1 and the catalytic subunit of telomerase (hTERT) into three non-cystic fibrosis (CF) and three DeltaF508 homozygous CF primary bronchial cell preparations. This treatment extended cell life span, although not as profoundly as viral oncogenes, and at passages 14 and 15, the new cell lines had a diploid karyotype. Ussing chamber analysis revealed variable transepithelial resistances, ranging from 200 to 1,200 Omega.cm(2). In the non-CF cell lines, short-circuit currents were stimulated by forskolin and inhibited by CFTR(inh)-172 at levels mostly comparable to early passage primary cells. CF cell lines exhibited no forskolin-stimulated current and minimal CFTR(inh)-172 response. Amiloride-inhibitable and UTP-stimulated currents were present, but at lower and higher amplitudes than in primary cells, respectively. The cells exhibited a pseudostratified morphology, with prominent apical membrane polarization, few apoptotic bodies, numerous mucous secretory cells, and occasional ciliated cells. CF and non-CF cell lines produced similar levels of IL-8 at baseline and equally increased IL-8 secretion in response to IL-1beta, TNF-alpha, and the Toll-like receptor 2 agonist Pam3Cys. Although they have lower growth potential and more fastidious growth requirements than viral oncogene transformed cells, Bmi-1/hTERT airway epithelial cell lines will be useful for several avenues of investigation and will help fill gaps currently hindering CF research and therapeutic development.

A system for shuttling 200-kb BAC/PAC clones into human cells: stable extrachromosomal persistence and long-term ectopic gene activation.

A novel shuttle vector, pBH140, has been constructed that allows stable maintenance of large genomic inserts as human artificial episomal chromosomes (HAECs) in mammalian cells. The vector, essentially a hybrid BAC-HAEC, contains an F-based replication system as in a bacterial artificial chromosome (BAC) and the Epstein-Barr virus (EBV) latent origin of replication system, oriP, for replication in human cells. A 185-kb DNA insert containing the entire human beta-globin locus, including its locus control region (LCR), was retrofitted into this vector. The resulting beta-globin BAC-HAEC clone, p148BH, was transfected into human cells and analyzed for episomal maintenance and expression of the beta-globin gene. FISH revealed an association of the vector with different human chromosomes but no integration. The beta-globin BAC-HAECs were present at an average copy number of 11-15 per nucleus in the stably transformed human cells. After 1 year of continuous in vitro cultivation, the HAECs persisted as structurally intact 200-kb episomes. While no beta-globin transcription could be detected in the parental D98/Raji cells, correctly spliced RT-PCR products were produced at significant levels in long-term cultures of the BAC-HAEC-transduced cells. The wide availability of BAC and PAC libraries, the ease in manipulating cloned DNA in bacteria, and the episomal stability of the pBH140 vector make this system ideal for studies on gene expression and other genomic functions in human cells. The potential significance of large, functionally active episomes for gene therapy is discussed.

Epstein-Barr-based episomal chromosomes shuttle 100 kb of self-replicating circular human DNA in mouse cells.

We describe the microcell fusion transfer of 100-200 kb self-replicating circular human minichromosomes from human into mouse cells. This experimental approach is illustrated through the shutting of the latent 170 kb double-stranded DNA genome from the human herpesvirus, Epstein-Barr virus, into nonpermissive rodent cells. Using this interspecies transfer strategy, circular episomes carrying 95-105 kb of human DNA were successfully established at low copy number in mouse A9 cells. Selected episomes were stably maintained for 6 months, and unselected episomes were characterized by a 95% episomal retention per cell division. The establishment of a mouse artificial episomal chromosome system should facilitate evolutionary and therapeutic studies of large human DNA in rodent genetic backgrounds.

Engineering a mini-herpesvirus as a general strategy to transduce up to 180 kb of functional self-replicating human mini-chromosomes.

The engineering of therapeutic human artificial episomal chromosomes, HAECs, requires the development of strategies to deliver large functional self-replicating extrachromosomal DNA in target cells. Members of the herpesviral family are among the largest episomal double-stranded DNA viruses. As model systems of this family of endemic infectious agents, vectors derived from the human herpes 4 Epstein-Barr virus (EBV) were constructed which transferred up to 180 kb of DNA packaged as infectious virions. Such a transduction strategy was based on a non-oncogenic helper-dependent mini-EBV carrying minimal cis elements for latent replication and virus production. After exposure of human B lymphoma and lymphoblastoid cells to mini-EBVs transducing lacZ and human HPRT minigenes, stable cell transformants were selected which carried the delivered multimeric linear DNAs as circular episomes up to 160-180 kb in size. Following transduction of Lesch-Nyhan disease cells with a mini-EBV/HPRT, normal human HPRT function was restored in cells carrying large episomal HPRT minigenes. Direct visualization of the therapeutic mini-EBV by fluorescent in situ hybridization (FISH) on metaphase and interphase nuclei indicated that 99% (556/563) of the transduced mini-EBV DNA was episomal with an average copy number of one to two per nucleus. This system should allow the delivery of large genes in common diseases such as hemophilia A and codelivery of multiple genes in cells from polygenic diseases such as cancer. The extrachromosomal mini-EBV-based strategy offers an alternative to integrative or non-replicating gene therapy infectious vectors, which may be generally applicable to other herpesviruses characterized by different tropisms.

Alteration of cell cycle kinase complexes in human papillomavirus E6- and E7-expressing fibroblasts precedes neoplastic transformation.

Expression of viral oncoproteins results in the loss of cell cycle checkpoint control and the accumulation of chromosomal abnormalities. Expression of both human papillomavirus type 16 oncoproteins, E6 and E7, in normal human fibroblasts completely dissociates p21 and proliferating cell nuclear antigen from the quarternary cyclin-cyclin-dependent kinase (CDK) complexes present in normal cells, causes disruption of the cyclin D-CDK4 complex and replacement with a CDK4-p16 complex, and leaves binary complexes of cyclin B1-CDC2 and cyclin A-CDK2 intact. These results are identical to those observed in fully transformed cells. The expression of the individual oncoproteins dramatically affects the association of proliferating cell nuclear antigen into the complexes while leaving the total cellular levels unaltered. Expression of low-risk human papillomavirus has no effect on cyclin complexes. These findings provide evidence for the gross alteration of cyclin-CDK complexes in preneoplastic cells and links this alteration to the loss of genomic stability.

Therapeutic gene delivery in human B-lymphoblastoid cells by engineered non-transforming infectious Epstein-Barr virus.

The B-lymphotrophic human herpes Epstein-Barr virus (EBV) is a 160-kilobase double-stranded DNA episomal virus carried in a persistent asymptomatic state by more than 90% of the worldwide adult population. We engineered a helper-dependent mini-EBV, with the minimal cis-EBV elements for episomal replication, viral amplification and packaging, for use as a gene delivery system. The therapeutic potential of this system was established by stably transducing B-lymphoblastoid cells from a Fanconi anaemia group C (FA-C) patient with a mini-EBV constitutively expressing the normal FACC cDNA and showing in vitro correction of the FA phenotype. In the absence of selective pressure, episomal expression persisted with a half-life of 30 days in actively growing transduced cells, indicating a retention rate of 98% expression per cell doubling. This work demonstrates the generation of an infectious non-transforming viral vector that can potentially deliver large therapeutic genes efficiently and selectively into human B cells.

Suppression of the tumorigenic phenotype of a rat liver epithelial tumor cell line by the p11.2-p12 region of human chromosome 11.

Comparative chromosomal mapping studies and investigations of tumor-associated chromosomal abnormalities suggest that the development of hepatic tumors in humans and rats may share a common molecular mechanism that involves inactivation of the same tumor suppressor genes or common genetic loci. We investigated the potential of human chromosomes 2 and 11 to suppress the tumorigenic phenotype of rat liver epithelial tumor cell lines. These tumor cell lines (GN6TF and GP7TB) display elevated saturation densities in culture, efficiently form colonies in soft agar, and produce subcutaneous tumors in 100% of syngeneic rat hosts with short latency periods. Introduction of human chromosome 11 by microcell fusion markedly altered the tumorigenicity and the transformed phenotype of GN6TF cells. In contrast, the tumorigenic potential and phenotype of GP7TB cells was unaffected by the introduction of human chromosome 11, indicating that not all rat liver tumor cell lines can be suppressed by loci carried on this chromosome. Introduction of human chromosome 2 had little or no effect on the tumorigenicity or cellular phenotype of either tumor cell line, suggesting the involvement of chromosome 11-specific loci in the suppression of the GN6TF tumor cell line. The GN6TF-11neo microcell hybrid cell lines displayed significantly reduced saturation densities in monolayer cultures, and their ability to grow in soft agar was completely inhibited. Although GN6TF-11neo cells ultimately formed tumors in 80-100% of syngeneic rat hosts, the latency period for tumor formation was much longer. Molecular characterization of GN6TF-11neo microcell hybrid cell lines indicated that some of the clonal lines had spontaneously lost significant portions of the introduced human chromosome, partially delineating the chromosomal location of the putative tumor suppressor locus to the region between the centromere and 11p12. Molecular examination of microcell hybrid-derived tumor cell lines further defined the minimal portion of human chromosome 11 capable of tumor suppression in this model system to the region 11p11.2-p12.

Differential disruption of genomic integrity and cell cycle regulation in normal human fibroblasts by the HPV oncoproteins.

Genomic integrity is maintained by a network of cellular activities that assess the status of the genome at a given point in time, provide signals to proceed with or halt cell cycle progression, and provide for repair of damaged DNA. Mutations in any part of these pathways can have the ultimate effect of disturbing chromosomal integrity. Recent work suggests that p53 performs this integrator function in mammalian cells. Our present study demonstrates that in mortal cells, the expression of E6 and E7 viral oncoproteins of type 16 human papillomavirus each disrupts the integration of these signals by diverged pathways. Cells expressing E6 protein, which binds and degrades the p53 protein, exhibited alterations in cell cycle control when placed in drug and displayed the ability to amplify the CAD gene. The expression of E7, which binds different cellular proteins important for transformation, including Rb, led to a p53-independent alteration in cell cycle control, a widespread cytocidal response, and polyploidy as a mechanism of drug resistance. These results demonstrate that diverse perturbations of molecular pathways can have different effects on chromosomal integrity.

Unique chromosomal rearrangement and mucin production in a novel salivary myoepithelial cell strain.

Pleomorphic adenoma is the most frequently occurring benign neoplasm of the salivary glands. We describe the culture characteristics, biochemical properties, immunohistochemical staining, and genetic rearrangements found in a novel cell strain (UNC4) established from a human benign pleomorphic adenoma. Serum and/or butyrate stimulation of UNC4 cultures results in upregulation of mucin production. This is confirmed by periodic acid-Schiff, periodic acid-Schiff digest, alcian blue, and mucicarmine staining as well as by gel electrophoresis. Fluorescent immunohistochemical studies detect cellular cytokeratin, desmin, and epithelial membrane antigen. Immunofluorescent staining for S100 protein is negative. Examination of the karyotype of UNC4 reveals a unique rearrangement between one chromosome 8 and the two chromosome 9s involving the 8q12 locus. UNC4 represents an in vitro model of a benign salivary gland neoplasm that can provide the basis for further molecular and biochemical studies on genetic rearrangement and salivary mucin production.

Multiple mechanisms of N-(phosphonoacetyl)-L-aspartate drug resistance in SV40-infected precrisis human fibroblasts.

Normal and SV40-infected human fibroblasts were grown in the presence of the drug N-(phosphonoacetyl)-L-aspartate (PALA) and examined for evidence of genetic instability. Both cell populations were precrisis and showed a normal, diploid karyotype at early passage. In contrast to the normal IMR-90 cells, which showed growth arrest and did not form colonies in PALA, the SV40-infected IMR-90 cells formed colonies at a very high frequency and continued to cycle in the drug. The drug-resistant colonies senesced after continued growth in culture, indicating that this change in ability to amplify preceded immortalization. This is the first observation of mortal human cells overcoming the drug-induced growth arrest. Although all previously isolated PALA-resistant colonies demonstrated CAD gene amplification as the mechanism of the drug-resistant phenotype, these SV40-infected human cells also showed alternative mechanisms, including increases in gene copy number by aneuploidy and formation of an isochromosome 2p.

Altered cell cycle arrest and gene amplification potential accompany loss of wild-type p53.

Gene amplification occurs at high frequency in transformed cells (10(-3)-10(-5)), but is undetectable in normal diploid fibroblasts (less than 10(-9)). This study examines whether alterations of one or both p53 alleles were sufficient to allow gene amplification to occur. Cells retaining one wild-type p53 allele mimicked the behavior of primary diploid cells: they arrested growth in the presence of drug and failed to demonstrate amplification. Cells losing the second p53 allele failed to arrest when placed in drug and displayed the ability to amplify at a high frequency. Thus, loss of wild-type p53 may lead to amplification, possibly caused by changes in cell cycle progression. Other determinants can by-pass this p53 function, however, since tumor cells with wild-type p53 have the ability to amplify genes.

Human chromosome 11 contains two different growth suppressor genes for embryonal rhabdomyosarcoma.

The identification of acquired homozygosity in human cancers implies locations of tumor suppressor genes without providing functional evidence. The localization of a defect in embryonal rhabdomyosarcomas to chromosomal region 11p15 provides one such example. In this report, we show that transfer of a normal human chromosome 11 into an embryonal rhabdomyosarcoma cell line elicited a dramatic loss of the proliferative capacity of the transferrants. Indeed, the majority of the viable microcell hybrids had either eliminated genetic information on the short arm of the transferred chromosome 11 or increased the copy number of the rhabdomyosarcoma-derived chromosomes 11. Cells that possessed only the long arm of chromosome 11 also demonstrated a decreased growth rate. In contrast, all microcell hybrids retained the ability to form tumors upon inoculation into animals. These functional data support molecular studies indicating loss of genetic information on chromosome 11p15 during the development of embryonal rhabdomyosarcoma. In addition, our studies demonstrate the existence of a second gene on the long arm, previously unrecognized by molecular analyses, which negatively regulates the growth of embryonal rhabdomyosarcoma cell lines.

Suppression of tumorigenicity in Wilms tumor by the p15.5-p14 region of chromosome 11.

Wilms tumor has been associated with genomic alterations at both the 11p13 and 11p15 regions. To differentiate between the involvement of these two loci, a chromosome 11 was constructed that had one or the other region deleted, and this chromosome was introduced into the tumorigenic Wilms tumor cell line G401. When assayed for tumor-forming activity in nude mice, the 11p13-deleted, but not the 11p15.5-p14.1-deleted chromosome, retained its ability to suppress tumor formation. These results provide in vivo functional evidence for the existence of a second genetic locus (WT2) involved in suppressing the tumorigenic phenotype of Wilms tumor.