Ontogeny of CLCN3 chloride channel gene expression in human pulmonary epithelium.

Human fetal bronchopulmonary epithelia secrete liquid, and this chloride (Cl)-dependent process is important for normal lung growth. At the time of birth there is a maturational transition from a secretory to an absorptive phenotype. The pathways for Cl exit from the apical membrane which are required for fetal lung liquid secretion are unknown but are thought to be independent of the cystic fibrosis transmembrane conductance regulator. We determined the ontogeny of expression of the CLCN family of voltage-dependent Cl channel genes (CLCN2 through 6, K(a) and K(b)) in the human lung to identify potential pathways for pulmonary liquid secretion. Only CLCN3 and CLCN6 messenger RNA were detected by Northern analysis of fetal whole lung tissue. Ribonuclease protection assays confirmed the expression of CLCN3 and also revealed expression of CLCN2. The ontogeny of expression of these two channels was similar, peaking in midgestation and declining postnatally. In situ hybridization localized the CLCN2 and CLCN3 messages to airway and distal pulmonary epithelia and to pulmonary blood vessels. We conclude that CLCN3 is expressed in human airway epithelia and expression is developmentally regulated. The contribution of these channels to pulmonary epithelial liquid transport and lung development remains to be determined.

ClC-2 chloride channels contribute to HTC cell volume homeostasis.

Membrane Cl(-) channels play an important role in cell volume homeostasis and regulation of volume-sensitive cell transport and metabolism. Heterologous expression of ClC-2 channel cDNA leads to the appearance of swelling-activated Cl(-) currents, consistent with a role in cell volume regulation. Since channel properties in heterologous models are potentially modified by cellular background, we evaluated whether endogenous ClC-2 proteins are functionally important in cell volume regulation. As shown by whole cell patch clamp techniques in rat HTC hepatoma cells, cell volume increases stimulated inwardly rectifying Cl(-) currents when non-ClC-2 currents were blocked by DIDS (100 microM). A cDNA closely homologous with rat brain ClC-2 was isolated from HTC cells; identical sequence was demonstrated for ClC-2 cDNAs in primary rat hepatocytes and cholangiocytes. ClC-2 mRNA and membrane protein expression was demonstrated by in situ hybridization, immunocytochemistry, and Western blot. Intracellular delivery of antibodies to an essential regulatory domain of ClC-2 decreased ClC-2-dependent currents expressed in HEK-293 cells. In HTC cells, the same antibodies prevented activation of endogenous Cl(-) currents by cell volume increases or exposure to the purinergic receptor agonist ATP and delayed HTC cell volume recovery from swelling. These studies provide further evidence that mammalian ClC-2 channel proteins are functional and suggest that in HTC cells they contribute to physiological changes in membrane Cl(-) permeability and cell volume homeostasis.

Characterization of promoter function and cell-type-specific expression from viral vectors in the nervous system.

Viral vectors have become important tools to effectively transfer genes into terminally differentiated cells, including neurons. However, the rational for selection of the promoter for use in viral vectors remains poorly understood. Comparison of promoters has been complicated by the use of different viral backgrounds, transgenes, and target tissues. Adenoviral vectors were constructed in the same vector background to directly compare three viral promoters, the human cytomegalovirus (CMV) immediate-early promoter, the Rous sarcoma virus (RSV) long terminal repeat, and the adenoviral E1A promoter, driving expression of the Escherichia coli lacZ gene or the gene for the enhanced green fluorescent protein. The temporal patterns, levels of expression, and cytotoxicity from the vectors were analyzed. In sensory neuronal cultures, the CMV promoter produced the highest levels of expression, the RSV promoter produced lower levels, and the E1A promoter produced limited expression. There was no evidence of cytotoxicity produced by the viral vectors. In vivo analyses following stereotaxic injection of the vector into the rat hippocampus demonstrated differences in the cell-type-specific expression from the CMV promoter versus the RSV promoter. In acutely prepared hippocampal brain slices, marked differences in the cell type specificity of expression from the promoters were confirmed. The CMV promoter produced expression in hilar regions and pyramidal neurons, with minimal expression in the dentate gyrus. The RSV promoter produced expression in dentate gyrus neurons. These results demonstrate that the selection of the promoter is critical for the success of the viral vector to express a transgene in specific cell types.

Expression of CLCN voltage-gated chloride channel genes in human blood vessels.

Chloride (Cl) ion channels play a critical role in the response of both vascular smooth muscle (VSM) and endothelial (ENDO) cells to agonist stimulation. In VSM, agonist-induced Cl currents produce membrane depolarization, resulting in calcium influx through voltage-sensitive channels. ENDO cells also activate Cl currents after either agonist application or perturbation of cell volume. Although some of these currents have been characterized biophysically, the genes involved have not been identified. The CLCN family of voltage-dependent Cl channel genes comprises nine members (CLCN1-7, Ka and Kb) which demonstrate quite diverse functional characteristics while sharing significant sequence homology. We used Northern-blot analysis to study the expression of these Cl channel genes in cultured human aortic and coronary VSM cells and in aortic ENDO cells. CLCN3 is by far the most abundant CLC channel mRNA in both VSM and ENDO cells. Lower levels of expression are seen for CLCN2, CLCN4, CLCN5 and CLCN6. Expression levels were similar in VSM and ENDO cells except for CLCN4 which was more highly expressed in ENDO cells. In situ hybridization was used to confirm the expression of CLCN3 in intact human fetal lung. CLCN3 message was seen in VSM and ENDO cells of both large and small pulmonary vessels, indicating that their detection by Northern blotting was not an artifact of cell culture. CLCN3 is also expressed in pulmonary epithelial and bronchial smooth muscle cells but not in chondrocytes or pulmonary interstitial cells. Recent studies suggest that CLCN3 may encode the swelling-induced Cl conductance. We used whole cell patch clamp recording to demonstrate swelling-induced Cl currents in these cultured VSM cells. This suggests that the CLCN3 protein is expressed; however, the functional role of this current in VSM remains to be determined.

A replication-incompetent adenovirus vector with the preterminal protein gene deleted efficiently transduces mouse ears.

Adenoviruses offer great potential as gene therapy agents but are limited by the strong inflammatory response that occurs in response to the recombinant virus. Since the degree of inflammation correlates in part with the potential of the viral vector for replication, we constructed a preterminal protein (pTP) deletion mutant adenovirus type 5 vector, Ad5dl308DeltapTPbeta-gal, that is replication incompetent due to deletion of the pTP gene and that has the E1 genes replaced by the Escherichia coli lacZ reporter gene under the control of the cytomegalovirus major immediate-early promoter. This virus was compared with a first-generation, replication-defective adenovirus vector, Ad5dl308beta-gal, that is isogenic except that it contains a wild-type pTP gene. To examine transduction efficiency and induction of inflammation, we developed a novel system involving intradermal injection of BALB/c mouse ears. Mouse ears can be accurately measured to determine the degree of edema as an indirect measurement of inflammation. Edema and inflammation were induced in a dose- and time-dependent manner by both viruses and correlated well. LacZ activity correlated inversely with edema and inflammation. The pTP-defective vector Ad5dl308DeltapTPbeta-gal transduced mouse ears much more efficiently and induced edema and inflammatory cell infiltration approximately 10-fold less efficiently than the first-generation vector Ad5dl308beta-gal. The diminished inflammatory response and increased efficiency of transduction observed with Ad5dl308DeltapTPbeta-gal indicate its promise as a gene therapy agent for other tissues. The results also demonstrate that the mouse ear model offers potential for the study of adenovirus-induced inflammation because of the ready access of the ears, the relative ease of continuous measurement, and the sensitivity to adenovirus transducing vectors.

Expression of mRNA for the elav-like neural-specific RNA binding protein, HuD, during nervous system development.

The expression of mRNA for the neuronal antigen HuD (Elavl4) associated with paraneoplastic encephalomyelitis and sensory neuronopathy was evaluated in the developing and adult rat nervous system. Using RNase protection assay and non-radioactive in situ hybridization histochemistry HuD expression was shown to be expressed at high levels at the earliest time point observed (E15), but declined significantly during the first postnatal week to levels which were maintained into adulthood. In the adult, HuD expression became restricted primarily to large pyramidal-like neurons. Exceptions of note were many smaller neurons within a variety of thalamic nuclei. Expression of HuD was observed to be coincident with terminal differentiation of all neuronal structures evaluated regardless of the timing of their development, providing correlative evidence for a role in neuronal differentiation or the maintenance of neuronal phenotype. The marked restriction of HuD mRNA expression with maturity suggests that its functional role in adult neurons varies significantly throughout the CNS.

Ontogeny of cation-Cl- cotransporter expression in rat neocortex.

Neuronal precursors and immature cortical neurons actively accumulate Cl- and as a consequence depolarize in response to GABAA receptor activation. With maturity, intracellular Cl- decreases resulting in a shift towards GABAA inhibition. These observations suggest that changes in expression of cation-Cl- cotransporters may have a significant role in the ontogeny of neuronal Cl- homeostasis. Using ribonuclease protection analysis and in situ hybridization we examined the developmental expression of all presently known members of the cation-Cl- cotransporter gene family in rat brain. Of the inwardly directed cotransporters, NKCC-1, NKCC-2, and NCC-1, only NKCC-1 was detected at significant levels in brain. NKCC-1 was expressed in neurons, appearing first in cortical plate but not in ventricular or subventricular zone. Expression levels peaked by the third postnatal week and were maintained into adulthood. The outwardly directed cotransporters, KCC-1 and KCC-2, demonstrated significantly different levels and time courses of expression. KCC-1 was expressed prenatally at very low levels which increased little over the course of development. In contrast, KCC-2 expression appeared perinatally and increased dramatically after the first week of postnatal life. Differential changes in expression of this gene family occurred during periods of critical shifts in chloride homeostasis and GABA response suggestive of a role in these processes. Furthermore the absence of expression of known inwardly directed cotransporters in Cl- accumulating neuroepithelia and lack of evidence for glial expression suggests that as yet unidentified members of this gene family may be involved in chloride homeostasis in immature neuronal precursors and neuroglia.

Developmental expression of C1C-2 in the rat nervous system.

Regulation of expression of the voltage-gated chloride channel, C1C-2, was investigated during development and adult life in rat brain. RNase protection assays demonstrated a marked increase in levels of expression of C1C-2 in brain during early postnatal development which was also detected in adult brain. In situ hybridization of E15 and E18 rat brains demonstrated C1C-2 expression in deep brain nuclei and scattered cells within the neuroepithelial layers, but not in the regions of subventricular zone that primarily give rise to glial populations. By E18 all neurons within the emerging cortical plate and its equivalent in other areas of the CNS were heavily labeled. During the first postnatal week, C1C-2 was highly expressed in most neurons. By P7 a pattern of differential expression emerged with evidence of decreased expression of C1C-2 mRNA in many neuronal populations. In adult rat brain, C1C-2 was expressed at highest levels in large neurons as found within layer V of cortex, Ammon's Horn of hippocampus, or mitral cells of the olfactory bulb and Purkinje cells within the cerebellum. Many smaller neurons within the diencephalon maintained significant levels of expression. A functional conductance was readily detected in hippocampal neurons during the first postnatal week, which had the same characteristic properties as the conductance observed in adult neurons. The observed expression and functional presence of C1C-2 suggest a widespread role in neuronal chloride homeostasis in early postnatal life, and demonstrated that cell specific shut-down resulted in the adult pattern of expression.

The effect of luting agents on the retention and marginal adaptation of the CeraOne implant system.

In this study, various luting agents were evaluated to determine their retentive strengths as they pertain to the CeraOne single-tooth implant system. Ten samples of five different luting agents (zinc oxide-eugenol, glass-ionomer cement, hybrid glass-ionomer cement, composite resin, and zinc phosphate) were tested for retentive strength of the CeraOne gold cylinder to the CeraOne abutment. Under the conditions of the experiment, zinc phosphate showed a mean retentive strength 164% greater than that of glass-ionomer cement and 49% greater than that of composite resin cement. Scanning electron micrographs were taken to evaluate the effect of various luting agents on marginal opening. The measurements revealed that zinc phosphate had the greatest marginal opening, although its mean value of 62 microns is within clinically acceptable limits.

Reovirus infection and tissue injury in the mouse central nervous system are associated with apoptosis.

Reovirus serotype 3 strains infect neurons within specific regions of the neonatal mouse brain and produce a lethal meningoencephalitis. Viral replication and pathology colocalize and have a predilection for the cortex, hippocampus, and thalamus. We have shown previously that infection of cultured fibroblasts and epithelial cells with reovirus type 3 Dearing (T3D) and other type 3 reovirus strains results in apoptotic cell death, suggesting that apoptosis is a mechanism of cell death in vivo. We now report that T3D induces apoptosis in infected mouse brain tissue. To determine whether reovirus induces apoptosis in neural tissues, newborn mice were inoculated intracerebrally with T3D, and at various times after inoculation, brain tissue was assayed for viral antigen by immunostaining and apoptosis was identified by DNA oligonucleosomal laddering and in situ terminal deoxynucleotidyl transferase-mediated dUTP nick end labeling. Cells were also stained with cresyl violet to detect morphological changes characteristic of apoptosis, including chromatin condensation and cell shrinkage. DNA laddering was detected in T3D- but not in mock-infected brain tissue. Apoptotic cells were restricted to the same regions of the brain in which infected cells and tissue damage were observed. These findings suggest that virus-induced apoptosis is a mechanism of cell death, tissue injury, and mortality in reovirus-infected mice. The correlation between apoptosis and pathogenesis in vivo identifies apoptosis as a potential target for molecular and pharmacological strategies designed to curtail or prevent diseases resulting from induction of this cell death pathway.

Differential expression of an inwardly rectifying chloride conductance in rat brain neurons: a potential mechanism for cell-specific modulation of postsynaptic inhibition.

A voltage-sensitive inwardly rectifying chloride (Cl-) conductance (GCl(V) is present in hippocampal pyramidal but not dentate gyrus neurons and has a significant role in modulation of neuronal inhibition by GABA. GCl(V) has the same activation properties as the cloned and expressed Cl- channel CIC-2. In brain, CIC-2 was detected selectively in neurons, and in hippocampus was detected in the same populations of neurons that demonstrate GCl(V). CIC-2 mRNA expression varied widely in different neuronal populations in brain but was greatest in pyramidal and other large neurons and least in interneurons. The observed differential expression of CIC-2 provides a potential molecular basis for the paradoxical excitation produced by GABAA receptor activation in selected neuronal populations.

Expression of GAP43 mRNA in normally developing and transplanted neurons from the rat ventral mesencephalon.

These experiments were designed to determine whether the neuronal growth-related protein GAP43 is expressed at high levels by neurons that collateralize extensively or have long periods of synaptogenesis. We also evaluated the effects of target availability on GAP43 expression. Dopaminergic neurons of the rat ventral mesencephalon (VM) were chosen for investigation because they undergo extensive collateralization and synaptogenesis during postnatal development. Double label in situ hybridization histochemistry (ISHH) and immunocytochemistry (ICC) were used to measure changes in GAP43 mRNA levels within tyrosine hydroxylase (TH)-immunoreactive and -nonimmunoreactive neurons of the VM during postnatal development (p5-adult). TH neurons show higher levels of GAP43 mRNA than do non-TH neurons throughout normal postnatal development and in the adult. This result may be due to more extensive axonal arborization and synaptic remodeling on the part of TH neurons as they innervate the striatum. To test the effects of target availability on GAP43 utilization, grafts of embryonic (e15) VM were placed within previously 6-hydroxydopamine (6-OHDA)-lesioned striata and allowed to develop for 10-28 days. Levels of GAP43 mRNA in grafted TH neurons were reduced at all time points. The short distance to target in the graft paradigm may shorten the overall axonal process length, resulting in lower requirements for growth-related proteins such as GAP43. However, grafted non-TH neurons had elevated levels of GAP43 mRNA, perhaps attributable to prolonged target seeking by neurons that have been isolated from their normal targets.

Programmed cell death in developing grafts of fetal substantia nigra.

Intracerebral transplants of ventral mesencephalic (VM) tissue have been well characterized. VM grafts contain numerous tyrosine hydroxylase immunoreactive neurons which send axons into the host brain. Transplanted neurons in VM grafts develop normally in that they contain tyrosine hydroxylase and GAP43. An overlooked aspect of graft development is cell death. It has been suggested that cell death in VM grafts was mostly necrotic. However, recent work in this laboratory suggested that developing grafts contain numerous apoptotic cells. In the present paper morphological, histochemical, and molecular correlates of apoptosis were used to assay cell death during VM graft development. At early times (5-15 days) after grafting VM grafts contained numerous apoptotic cells. In older grafts (21 and 28 days) few apoptotic cells were observed. In situ end labeling of fragmented DNA with biotinylated dUTP showed that early grafts contained numerous positive cells. The expression of RP8, a molecular correlate of apoptotic cell death, occurred in early grafts, but was not detectable in older grafts. These results indicate that apoptosis is a normal part of VM graft development. As in naturally developing neural systems, cell death in grafts may function to eliminate cells that fail to connect to appropriate targets.

GAP-43 and 5B4-CAM immunoreactivity during the development of transplanted fetal mesencephalic neurons.

Developing neurons contain high levels of several proteins which are absent or relatively scarce in mature neurons. GAP-43 is a cytoplasmic protein primarily found within neurons; high levels of this protein are correlated with axonal elongation or regeneration. 5B4-CAM, a glycosylated transmembrane protein, is a member of the NCAM family present in growth cones and in plastic CNS structures. Antibodies directed against these two developmentally regulated proteins were used to characterize the time-course of maturation of transplanted fetal mesencephalic neurons. For our experiments unilateral injections of 6-hydroxydopamine were made into the nigrostriatal bundle in Sprague-Dawley rats. The effectiveness of the lesion was verified by apomorphine-induced rotation and by postmortem examination of the substantia nigra. Following behavioral testing, pieces of ventral mesencephalon obtained from E15 fetuses were transplanted into the caudoputamen ipsilateral to the lesion. Immunocytochemistry revealed high levels of GAP-43 and 5B4-CAM at 5, 11, and 15 days post-transplant but relatively lower levels by 3 weeks. At 13 weeks the immunoreactivity present within the transplant tissue was approximately equal to that found within the host striatal neuropil. This time-course of higher GAP-43 and 5B4-CAM immunoreactivities coincides with the time-course of neuritic outgrowth of dopamine containing cell populations within the ventral mesencephalon in situ as well as within ventral mesencephalic transplants. This implies that axon elongation occurs over a period similar to that which occurs during normal development. These data suggest that the effects of transplantation surgery and the altered environment of the host striatum do not significantly affect the time-course of development of ventral mesencephalic neurons.

Specific outgrowth from neurons of ventral mesencephalic grafts to the catecholamine-depleted striatum of adult hosts.

Grafts of fetal ventral mesencephalon including substantia nigra have been used to correct some motor deficits produced by unilateral destruction of the dopaminergic nigrostriatal pathway in rats. Histochemical studies have shown that dopaminergic neurons within the graft send processes from the graft to the host neuropil, wherein they form synapses. The results of numerous immunocytochemical studies indicate, however, that a large proportion of neurons in grafts are not catecholaminergic. Whether or not the nondopaminergic neurons in grafts project to the host brain is unknown. The purpose of the present study was to combine immunocytochemistry and retrograde tracing with fluorogold to identify the cell types which project from grafts to the host striatum. Tissue from the ventral mesencephalon of E15 fetuses was placed into the 6-hydroxydopamine denervated striatum of graft recipients. Six weeks to 6 months following transplantation, fluorogold was pressure injected under stereotaxic control immediately adjacent to the ventral mesencephalic grafts; after 4 days CNS tissue was prepared for light microscopic immunocytochemistry. Ventral mesencephalic grafts contained cell bodies immunoreactive for enkephalin, GAD, substance P, and serotonin in addition to those immunoreactive for tyrosine hydroxylase. Some cells of each immunochemically defined type were retrogradely labeled by the fluorogold injection into the host brain. Nevertheless, more catecholaminergic and serotonergic cells projected from grafts to the fluorogold injection site than did other cell types. Since many of the nonmonoaminergic neurons in grafts are probably projection neurons, our results suggest that the extent of neurite outgrowth from grafted cells is influenced by the surrounding target tissue.