FGF induces a switch in death receptor pathways in neuronal cells.

Basic fibroblast growth factor (FGF2) has many roles in neuronal development and maintenance including effects on mitogenesis, survival, fate determination, differentiation, and migration. Using a conditionally immortalized rat hippocampal cell line, H19-7, and primary hippocampal cultures, we now demonstrate that FGF2 treatment differentially regulates members of the tumor necrosis factor (TNF) superfamily of death domain receptors and their ligands. H19-7 cells transferred from serum to defined (N2) medium undergo apoptosis by a Fas-dependent mechanism similar to primary neurons. In contrast, H19-7 cells treated with FGF undergo apoptosis by a Fas-independent mechanism. FGF suppresses the Fas death pathway but also induces apoptosis by activation of a TNFalpha death pathway in both H19-7 and hippocampal progenitor cells. Expression of the TNF receptor 1 (TNFR1) or TNFR2 in H19-7 cells is sufficient to sensitize the cells to TNFalpha, similar to the effects of FGF. Because TNFalpha can be either proapoptotic or antiapoptotic, these results provide an explanation for the divergent trophic effects of FGF2 treatment and the observation that multiple trophic inputs are required for the survival of specific neurons.

Different protein kinase C isoforms determine growth factor specificity in neuronal cells.

Although mitogenic and differentiating factors often activate a number of common signaling pathways, the mechanisms leading to their distinct cellular outcomes have not been elucidated. In a previous report, we demonstrated that mitogen-activated protein (MAP) kinase (ERK) activation by the neurogenic agents fibroblast growth factor (FGF) and nerve growth factor is dependent on protein kinase Cdelta (PKCdelta), whereas MAP kinase activation in response to the mitogen epidermal growth factor (EGF) is independent of PKCdelta in rat hippocampal (H19-7) and pheochromocytoma (PC12) cells. We now show that EGF activates MAP kinase through a PKCzeta-dependent pathway involving phosphatidylinositol 3-kinase and PDK1 in H19-7 cells. PKCzeta, like PKCdelta, acts upstream of MEK, and PKCzeta can potentiate Raf-1 activation by EGF. Inhibition of PKCzeta also blocks EGF-induced DNA synthesis as monitored by bromodeoxyuridine incorporation in H19-7 cells. Finally, in embryonic rat brain hippocampal cell cultures, inhibitors of PKCzeta or PKCdelta suppress MAP kinase activation by EGF or FGF, respectively, indicating that these factors activate distinct signaling pathways in primary as well as immortalized neural cells. Taken together, these results implicate different PKC isoforms as determinants of growth factor signaling specificity within the same cell. Furthermore, these data provide a mechanism whereby different growth factors can differentially activate a common signaling intermediate and thereby generate biological diversity.

Akt, a target of phosphatidylinositol 3-kinase, inhibits apoptosis in a differentiating neuronal cell line.

Phosphatidylinositol (PI) 3-kinase has been suggested to mediate cell survival. Consistent with this possibility, apoptosis of conditionally (simian virus 40 Tts) immortalized rat hippocampal H19-7 neuronal cells was increased in response to wortmannin, an inhibitor of PI 3-kinase. Downstream effectors of PI 3-kinase include Rac1, protein kinase C, and the serine-threonine kinase Akt (protein kinase B). Here, we show that activation of Akt is one mechanism by which PI 3-kinase can mediate survival of H19-7 cells during serum deprivation or differentiation. While ectopic expression of wild-type Akt (c-Akt) does not significantly enhance survival in H19-7 cells, expression of activated forms of Akt (v-Akt or myristoylated Akt) results in enhanced survival which can be comparable to that conferred by Bcl-2. Conversely, expression of a dominant-negative mutant of Akt accelerates cell death upon serum deprivation or differentiation. Finally, the results indicate that Akt can transduce a survival signal for differentiating neuronal cells through a mechanism that is independent of induction of Bcl-2 or Bcl-XL or inhibition of Jun kinase activity.

Insulin gene expression in immortalized rat hippocampal and pheochromocytoma-12 cell lines.

Employing reverse transcription-polymerase chain reaction and clonal cell lines derived by retroviral transduction of the temperature sensitive simian virus 40 large T-antigen into dispersed rat embryonic hippocampal cells, we detected the ancestral gene-insulin II mRNA in three progenitor subcloned cell lines. These cell lines upon differentiation are known to express markers indicative of commitment to either neuronal (H19-7; NF + , GFAP -), glial (H19-5; GFAP +, NF -), or bipotential (H583-5, NF +, GFAP + ) lineages. No duplicated, i.e., insulin I gene expression, was observed in any of the three cell lines. Induction of differentiation was associated with the persistence of insulin II mRNA and in the cells expressing a neuronal phenotype (H19-7; NF +, GFAP -) a relative doubling in insulin II mRNA level was present (P < 0.05). Minimal cellular insulin immunoreactivity was detected only in a subpopulation of cells with a differentiated neuronal phenotype. Radioimmunoassayable insulin peptide in the H19-7 cellular conditioned medium revealed a 5-fold increase in the differentiated state. In contrast, peripheral sympathetic PC-12 neuronal cells both in the undifferentiated and nerve growth factor-driven differentiated states, failed to express both insulin I and insulin II genes. We conclude that insulin II is expressed by cultured rat hippocampal clonal cell lines, and not by the peripheral sympathetic PC-12 neuronal cell line.

Apoptosis induced by differentiation or serum deprivation in an immortalized central nervous system neuronal cell line.

To characterize the nature of programmed cell death (PCD) induced in neuronal cells during development, three regulators of apoptosis were investigated: one, the bcl-2-related genes, modulate cell survival, and the other two, the interleukin-1 beta converting enzyme (ICE)-related enzymes and the tumor suppressor protein p53, have been implicated as mediators of apoptosis. These regulators were studied in H19-7 cells, an SV40 Tts-immortalized rat hippocampal neuronal cell line that can be differentiated with basic fibroblast growth factor at the nonpermissive temperature, resulting in a rapid attrition of cells by apoptosis. PCD occurred by two mechanisms in H19-7 cells: The first was initiated by removal of serum from undifferentiated cells, and the second was a consequence of neuronal differentiation. In differentiated H19-7 cells, the survival time was increased by both human bcl-2 and bcl-xL, and this could be reversed by bcl-xs. Addition of a peptide inhibitor of the ICE enzyme family to H19-7 cells resulted in a transient protection against differentiation-associated apoptosis, whereas no further protection was observed in the BCL-2- or BCL-XL-expressing cells. Shifting the differentiated cells to 33 degrees C to inactivate p53 did not significantly affect the apoptotic process, indicating that apoptosis induced by neuronal differentiation is not dependent on the continued presence of p53. By contrast, in undifferentiated cells, cell loss induced by transfer to serum-free media occurred more rapidly on inactivation of large T, consistent with p53 involvement. This medium-induced decrease in cell survival could not be rescued by the ICE inhibitor but was partially rescued by BCL-2 or BCL-XL. Furthermore, studies involving expression of BCL-2 and BCL-XL alone or together revealed differences in the survival dependent on the cellular environment. These results suggest that apoptosis of neuronal cells occurs by at least two processes: one in undifferentiated cells initiated by removal of serum and one linked to differentiation. The data implicate the ICE enzyme family but not p53 in apoptosis induced by differentiation and demonstrate that either BCL-2 or BCL-XL can prolong the survival of differentiated neuronal cells.

Beta-adrenergic receptor activation promotes process outgrowth in an embryonic rat basal forebrain cell line and in primary neurons.

A clonal cell line, AS583-8.E4.22, from the embryonic day 15 rat basal forebrain was established using retrovirus-mediated transduction of a temperature-sensitive mutant of the simian virus 40 (SV40) large tumour antigen. The cell line expresses cytoskeletal and neurotransmitter features indicative of neuronal commitment. In response to agents that increase intracellular cAMP, including forskolin and catecholamines, the cell line exhibits rapid process outgrowth and growth cone formation that does not require new gene expression or protein synthesis. The neurite outgrowth induced by catecholamines is mediated by beta 2-adrenergic receptors and is characterized by a rapid, reversible redistribution of filamentous actin. Neurons from primary cultures of embryonic day 15 basal forebrain were also found to respond to beta-adrenergic receptor agonists by enhancing growth cone formation. These results suggest that catecholamines provide cues that induce cytoskeletal rearrangements leading to neuronal process outgrowth and growth cone formation in the developing basal forebrain and possibly other neuronal progenitor cell populations. The neuronal basal forebrain cell line provides an ideal model to study the signalling mechanisms underlying the catecholamine-induced process outgrowth.

Raf, but not MEK or ERK, is sufficient for differentiation of hippocampal neuronal cells.

To elucidate signal transduction pathways leading to neuronal differentiation, we have investigated a conditionally immortalized cell line from rat hippocampal neurons (H19-7) that express a temperature sensitive simian virus 40 large T antigen. Treatment of H19-7 cells with the differentiating agent basic fibroblast growth factor at 39 degrees C, the nonpermissive temperature for T function, resulted in the activation of c-Raf-1, MEK, and mitogen-activated protein (MAP) kinases (ERK1 and -2). To evaluate the role of Raf-1 in neuronal cell differentiation, we stably transfected H19-7 cells with v-raf or an oncogenic human Raf-1-estrogen receptor fusion gene (deltaRaf-1:ER). deltaRaf-1:ER transfectants in the presence of estradiol for 1 to 2 days expressed a differentiation phenotype only at the nonpermissive temperature. However, extended exposure of the deltaRaf-1:ER transfectants to estradiol or stable expression of the v-raf construct yielded cells that extended processes at the permissive as well as the nonpermissive temperature, suggesting that cells expressing the large T antigen are capable of responding to the Raf differentiation signal. deltaRaf-1:ER, MEK, and MAP kinase activities in the deltaRaf-1:ER cells were elevated constitutively for up to 36 h of estradiol treatment at the permissive temperature. At the nonpermissive temperature, MEK and ERKs were activated to a significantly lesser extent, suggesting that prolonged MAP kinase activation may not be sufficient for differentiation. To test this possibility, H19-7 cells were transfected or microinjected with constitutively activated MEK. The results indicate that prolonged activation of MEK or MAP kinases (ERK1 and -2) is not sufficient for differentiation of H19-7 neuronal cells and raise the possibility that an alternative signaling pathway is required for differentiation of H19-7 cells by Raf.

Conditional immortalization of neuronal cells from postmitotic cultures and adult CNS.

To determine whether postmitotic neurons can be immortalized by oncogenic transduction, we used two approaches involving conditional expression of a temperature-sensitive SV40 large T antigen (Tts). Initially, Tts was introduced into E17 rat embryonal hippocampal cells that were then cultured at the non-permissive temperature to enrich for postmitotic pyramidal neurons, and subsequently cloned at the permissive temperature. One clonal line (HMR10-3) expressed neuron-specific proteins upon differentiation, was capable of generating action potentials, and formed synapses with primary rat neurons in co-culture. Replating of these postmitotic cells at the permissive temperature resulted in reversible loss of neurofilament expression. Conditionally immortalized cell lines were also generated from the brain of an adult mouse carrying an inducible Tts transgene. These lines proliferated in a T antigen-dependent manner and expressed neuron-specific proteins upon differentiation at the non-permissive temperature. These results suggest that postmitotic neurons can be induced to enter the cell cycle without losing their commitment to a neuronal lineage.

Activation of mitogen-activated protein kinase by epidermal growth factor in hippocampal neurons and neuronal cell lines.

Epidermal growth factor (EGF) functions in a bimodal capacity in the nervous system, acting as a mitogen in neuronal stem cells and a neurotrophic factor in differentiated adult neurons. Thus, it is likely that EGF signal transduction, as well as receptor expression, differs among various cell types and possibly in the same cell type at different stages of development. We used hippocampal neuronal cell lines capable of terminal differentiation to investigate changes in EGF receptor expression, DNA synthesis, and stimulation of mitogen-activated protein (MAP) kinase by EGF before and after differentiation. H19-7, the line that was most representative of hippocampal neurons, was mitogenically responsive to EGF only before differentiation and increased in EGF binding after differentiation. MAP kinase was stimulated by EGF in both undifferentiated and differentiated cells, as well as in primary hippocampal cultures treated with either EGF or glutamate. These results indicate that the activation of MAP kinase by EGF is an early signaling event in both mitotic and postmitotic neuronal cells. Furthermore, these studies demonstrate the usefulness of hippocampal cell lines as a homogeneous neuronal system for studies of EGF signaling or other receptor signaling mechanisms in the brain.

Immortal rat hippocampal cell lines exhibit neuronal and glial lineages and neurotrophin gene expression.

Clonal cell lines of rat embryonic hippocampal origin have been developed by using retroviral transduction of temperature-sensitive simian virus 40 large tumor antigens. The cell lines undergo morphological differentiation at the nonpermissive temperature and in response to differentiating agents. Immunocytochemical analysis indicates that various lines are derived from progenitors of neuronal, glial, and bipotential lineages. Selected neuronal lines differentiate in response to diffusible factors released by primary glia, and one line of glial lineage supports the maturation of primary neurons in culture. Selected cell lines exhibit different patterns of neurotrophin gene expression that change after differentiation. In some lines, the relative levels of neurotrophin 3 and brain-derived neurotrophic factor message expression may reflect the developmental or regional differential expression seen for these genes in the hippocampus in situ. These hippocampal cell lines, which express markers indicative of commitment to neuronal or glial lineages, are valuable for studies of development and plasticity in these lineages, as well as for studies of the regulation of neural trophic interactions.

Differences in burst morphology among baboon species.

Baboon species differ markedly in the proportions of fetal hemoglobin (HbF) they produce in response to hemopoietic stress. Bone marrow erythroid progenitor cells from untreated and stressed baboons of three species were cultured to determine if differences in number, size, or other characteristics of the colonies and bursts could be correlated with the HbF response. BFU-E from adult Papio cynocephalus produced high proportions of macroscopic, well-hemo-globinized bursts, whereas those from P. anubis and P. papio produced only small, moderately hemoglobinized bursts. The species-specific differences in burst characteristics did not correlate with the in vivo HbF response to stress and they were not altered by variations in culture conditions. However, bone marrow BFU-E from P. anubis and P. cynocephalus fetuses produced similar bursts, suggesting developmental regulation of progenitor cell growth patterns. The proportions of macroscopic bursts were reduced in P. cynocephalus animals undergoing hemopoietic stress, suggesting that culture is a more severe erythropoietic stress for P. anubis and P. papio BFU-E than for P. cynocephalus BFU-E.

Genetics of Chlamydomonas reinhardtii diploids. II. The effects of diploidy and aneuploidy on the transmission of non-Mendelian markers.

The transmission of two non-Mendelian drug resistance markers has been studied in crosses of Chlamydomonas reinhardtii involving diploids and aneuploids with different mating type genotypes. Under normal laboratory conditions for gametogenesis, mating and zygote maturation, the transmission pattern of the non-Mendelian markers sr-u-1 (resistance to streptomycin) and spr-u-1-27-3 (resistance to spectinomycin) is primarily determined by the mating type genotypes of the parental cells. Our results confirm and expand an earlier observation suggesting that an apparent codominant function of the female (mt+) allele in regulating chloroplast gene transmission in meiosis appears to be distinct and separate from its recessive function in regulating mating behavior. The chloroplast DNA complement (as indexed by the number of extranuclear DNA-containing bodies) may exert a secondary effect on the transmission of these markers. Within a mating type group (mt+/mt- or mt-/mt-) a cell line with more chloroplast DNA tended to transmit its non-Mendelian markers more frequently than a cell line with less chloroplast DNA.

Homologous recombination between plasmids in mammalian cells can be enhanced by treatment of input DNA.

We have used the eukaryotic-prokaryotic shuttle vector pSV2Neo to demonstrate that cultured mammalian somatic cells have the enzymatic machinery to mediate homologous recombination and that the frequency of this recombination can be enhanced by pretreatment of the input DNA. Two nonoverlapping deletion mutants of pSV2Neo were constructed, each affecting the bacterial aminoglycoside 3'-phosphorylase gene (the neo gene), which confers resistance to aminoglycoside antibiotics on bacteria and resistance to the antibiotic G418 on mammalian cells. Mammalian cells transfected with either deletion plasmid alone yield no G418 -resistant colonies. Cells cotransfected with both deletion plasmids yield G418 -resistant colonies with high frequency. We show that these resistant colonies result from recombination involving homologous crossing-over or gene conversion between the deletion plasmids by rescuing from the resistant cells both types of reciprocal recombinant, full-length plasmids, and doubly deleted plasmids. Cutting one of the input plasmids to generate a double-stranded gap in the neo gene considerably enhances the frequency of homologous recombination within the gene. This suggests that targeting exogenous DNA to specific sites in mammalian chromosomes could be facilitated by suitable pretreatment of the DNA.

Expression of recessive Aprt- mutations in mouse CAK cells resulting from chromosome loss and duplication.

Karyotypes of recessive mutants at the autosomal adenine phosphoribosyltransferase (Aprt) locus in a clone of the near-diploid mouse CAK cell line have been analyzed. The Aprt located on chromosome 8. One copy of chromosome 8 was morphologically abnormal in the parental clone (CAK-B3-Toyr13) from which Aprt- mutants were isolated. Among 22 mutants, there were ten in which one copy of chromosome 8 had been lost. Four of these were monosomic, and in the others duplication of the remaining homolog had occurred. These findings indicate that newly induced recessive mutations in cultured mammalian cells can be expressed as the result of loss of one chromosome carrying a wild-type allele with or without duplication of the homolog carrying the mutant allele. Loss and duplication would not be detected in cell lines lacking morphologically marked chromosomes.

Genetics of Chlamydomonas reinhardtii diploids. I. Isolation and characterization and meiotic segregation pattern of a homozygous diploid.

A strain of Chlamydomonas reinhardtii has been investigated which, when mated with known wild-types, produces very few viable germination products and transmits its Mendelian markers to more than half of those products. Cytogenetic observations, fluorometric measurements of DNA and genetic data all suggest that the strain, d mt-ery-M3a sr-u-1 is a stable homozygous diploid. This strain has twice as many nuclear chromatin bodies at metaphase and twice as much DNA as its haploid progenitor, and the phenotypes of its meiotic progeny are consistent with predictions based on triploid meiosis. Data from crosses involving d mt-ery-M3a sr-u-1 and from crosses involving hybrid diploids indicate that the frequency of second division segregation increases in triploid zygotes and that mitotic segregation following triploid meiosis is a frequent event which may more often result from mitotic recombination than from chromosome loss.

Chromosome segregation is frequently associated with the expression of recessive mutations in mouse cells.

The genes coding for adenosine kinase (ADK; ATP:adenosine 5'-phosphotransferase, EC 2.7.1.20) and esterase-10 (ES-10; carboxylesterase, carboxylic-ester hydrolase, EC 3.1.1.1) are both located on chromosome 14 in the mouse. The near-diploid mouse cell line CAK is heterozygous for two electrophoretic variants of ES-10. Recessive Adk- mutants of CAK have been isolated and analyzed for Es-10 phenotype and karyotypic abnormalities. Two classes of mutants were found with approximatley equal frequencies: those that remained heterozygous in the expression of Es-10 and those that expressed only one Es-10 allele. Of the mutants that lacked one form of ES-10, approximately half were missing most or all of one copy of chromosome 14; the other contained two copies of 14, frequently in the form of an isochromosome. There were no abnormalities of this chromosome found among the mutants that were Es-10 heterozygotes. These results suggest that the expression of an autosomal recessive mutation in near-diploid mouse cells is frequently associated with events that result in the segregation of a physically linked marker and part or all of a chromosome.