Induction of macrophage-like differentiation of HL-60 leukemia cells by tumor necrosis factor-alpha: potential role of fos expression.

Tumor necrosis factor-alpha (TNF-alpha) is a macrophage-derived cytokine elicited during cellular responses to various microbial infections. TNF-alpha exerts direct cytotoxicity toward some tumor cells in vitro and produces hemorrhagic tumor necrosis in vivo. In human promyelocytic HL-60 leukemia cells, human recombinant TNF-alpha (rTNF-alpha) exhibits a small early proliferative effect (within 48 h), followed by marked cytostatic activity at 96 h after the addition of rTNF-alpha. Cytostasis is contiguous with an induction of cell differentiation along the monocyte/macrophage lineage. The cell proliferation effects and the induction of the differentiated phenotype are preceded by an approximate 5-fold increase in c-fos mRNA levels within 90 min after rTNF-alpha treatment of log phase HL-60 cells. Nuclear in vitro transcription assays indicate that the effect of rTNF-alpha on c-fos mRNA abundance is controlled at the transcriptional level. We have also used a postembedding immunocolloidal gold electron microscopy technique to localize and semiquantitate pp55c-fos proto-oncoprotein levels in the nucleus of both control and rTNF-alpha-treated HL-60 leukemia cells. In response to rTNF-alpha, we have observed a rapid and transient accumulation of pp55c-fos in discrete nuclear substructures within 2 h after treatment. C-fos staining appears in clusters, which are preferentially localized over semi-condensed chromatin and interchromatin granules. These results suggest that pp55c-fos is involved in the signal transduction system initiated by rTNF-alpha during the induction of HL-60 differentiation.

Modification of development by the CFTR gene in utero.

The in utero infection of rats at 16-17 days gestation with a recombinant adenovirus carrying the human cystic fibrosis transmembrane conductance regulator (cftr) gene resulted in altered lung development and morphology. These structural alterations prompted an evaluation of concurrent functional changes in the cftr-treated lung. CFTR protein could be detected in treated lungs for up to 30 days postinfection, although it was not detected in the intestines at this time. Increased levels of secreted glycoconjugates and lipids were found in lungs treated in utero with human cftr and large vacuoles containing glycoconjugates were detected within cells of the intestines. The scope and durability of these changes suggested that in utero cftr treatment influenced the activity of secretory cells in the developing lung. Altered secretory products in the lungs of cystic fibrosis patients are thought to be associated with increased susceptibility to Pseudomonas aeruginosa infection. We challenged 3-month-old rats (treated in utero with the human cftr gene) with a lethal, intratrachial dose of this bacteria. Rats treated with cftr exhibited enhanced resistance to Pseudomonas infection when compared to controls. These animals displayed little or no associated inflammatory response. No evidence of the adenovirus transgene was detectable at the time of P. aeruginosa inoculation, indicating that continuous ectopic expression of hcftr was not required for enhanced protection. These data demonstrate that in utero, cftr expression influenced the development and function of cells involved in the primary host defense against bacterial infection in the lung.

Molecular pathophysiology of cystic fibrosis based on the rescued knockout mouse model.

Cystic fibrosis transmembrane conductance regulator (cftr) gene mutations are thought to result in cystic fibrosis due to an absence of the protein's chloride channel. Recently, the lethal intestinal blockage in the cftr knockout mouse was reversed by a single in utero dose of a recombinant adenovirus containing the human cftr gene. The rescue of these animals did not require continuous expression of the gene and the cAMP-dependent chloride channel was not permanently restored. These data suggested that cftr was required for normal development of the intestine but not for normal function of the adult organ. Phenotypic changes in the intestines and lungs of in utero cftr-treated knockout and heterozygous mice revealed that altered development was induced. The intestines of the untreated knockout mice were shown to be deficient in both intracellular calcium and UTP receptors. Both of these deficiencies were partially corrected in the rescued knockout mice, whereas treatment of heterozygous animals disrupted the normal pattern of these markers. Examination of the lungs of knockout cftr (-/-) mice with lectins showed an increase in secreted glycoconjugates containing alpha(2,6)-sialic acid and fucose as compared with control heterozygotes. The in utero-treated knockouts showed an increase in this material as well, but it was contained in intracellular vesicles. Electron microscopy of these tissues confirmed the developmental alteration of secretory cell differentiation in the lungs. These data show that cftr is required in both the lung and intestines for normal differentiation of a secretory cell population and that in its absence these cells fail to develop properly.

CFTR modulates lung secretory cell proliferation and differentiation.

We have permanently reversed the lethal phenotype in the cystic fibrosis (CF) transmembrane conductance regulator (CFTR)-deficient (knockout) mouse after in utero gene therapy with an adenovirus containing the cftr gene. The gene transfer targeted somatic stem cells in the developing lung and intestine, and these epithelial surfaces demonstrated permanent developmental changes after treatment. The survival statistics from the progeny of heterozygote-heterozygote matings after in utero cftr gene treatment demonstrated an increased mortality in the homozygous normal pups, indicating that overexpression during development was detrimental. The lungs of these pups revealed accelerated secretory cell proliferation and differentiation. The extent of proliferation and differentiation in the secretory cells of the lung parenchyma after in utero transfer of the cftr gene was evaluated with morphometric and biochemical analyses. These studies provide further support of the regulatory role of the cftr gene in the development of the secretory epithelium.

Gene transfer into the fetal primate: evidence for the secretion of transgene product.

In utero adenoviral-mediated transfer of genes via the amniotic fluid results in sustained high-efficiency expression in rodent lung and intestine. Rhesus macaque (Macaca mulatta) fetuses were injected with adenovirus vectors encoding reporter genes at different gestational ages to evaluate feasibility and timing in primates. The fetuses developed normally following gene transfer and no maternal adverse affects were noted. Highly efficient viral uptake and transgene protein expression occurred in the target organs. The lungs exhibited no immune response and transgenic protein was observed up to 30 days postinfection. Unexpectedly, large amounts of reporter gene protein were released, apparently from the lung, into the circulation and accumulated in the renal proximal tubules and bladder. PCR detection for adenovirus DNA was consistently negative in tissues not in contact with the amniotic fluid, such as kidneys, liver, gonads, and eyes. Treatment of primate fetuses at 110 days gestation with an adenovirus expressing the cystic fibrosis transmembrane conductance regulator (cftr) gene resulted in accelerated differentiation of the lung. These studies demonstrate the efficacy of in utero gene therapy in primates and its potential application to genetic diseases.