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Previous Article | Next Article
Volume 16, Number 13, Issue of July 1, 1996 pp. 4080-4088
Copyright ©1996 Society for Neurosciencegp120-Induced Neurotoxicity in Hippocampal Pyramidal Neuron Cultures: Protective Action of TGF-
1
Olimpia Meucci and Richard J. Miller Department of Pharmacological and Physiological Sciences, The University of Chicago, Chicago, Illinois 60637
ABSTRACT
We found that TGF-
Key words: AIDS; HIV-1; NMDA receptors; intracellular calcium; cell death; neurotoxicity1, a cytokine that previously has been reported to have neuroprotective effects, was able to prevent the toxicity induced by the HIV-1 coat protein gp120 in hippocampal pyramidal neuron cultures. In the presence of glia, gp120 induced time- and dose-dependent cell death, which was more pronounced in mature (7-19 d in culture) than in young neurons (2-7 d in culture). Staining with nuclear dyes (propidium iodide and Hoechst 33342), in situ detection of DNA fragments, and DNA analysis on agarose gels indicated that apoptosis was mainly responsible for the death caused by the viral protein. However, after several days of treatment, death-displaying necrotic features also occurred. Neurotoxicity induced by gp120 was dependent on the activation of NMDA receptors and required the presence of glia as well as new protein synthesis. Thus, the effect of gp120 was abolished by the NMDA receptor antagonist APV and partially reduced by cycloheximide. Only modest neurotoxicity was observed in pure neuronal cultures deprived of the glia feeder layer. Fura-2-based videoimaging showed that treatment with gp120 enhanced the ability of NMDA to increase neuronal [Ca2+]i. The impairment of neuronal Ca2+ homeostasis was prevented completely by TGF-
INTRODUCTION
In a recent study on lymph nodes from HIV-infected children, Finkel et al. (1995)observed that DNA fragmentation was rare in productively infected cells and that the virus was detected rarely in apoptotic cells. This suggests that apoptosis occurs predominantly in uninfected cells. Similar conclusions come from studies on local cell death in lymph nodes from mice infected by different HIV-1 isolates (Mosier et al., 1993
An analogous situation occurs in the central nervous system of AIDS patients. Despite the inability of HIV-1 to infect neurons directly, severe neuronal loss occurs in different brain areas, resulting in multiple types of neurological disorders (Navia et al., 1986
The cellular mechanisms responsible for gp120-induced neurotoxicity are understood only partially. It is still unclear, for example, whether the envelope protein has a direct effect on neurons, as most of the studies have been performed on mixed cultures of neurons and glia. However, there is evidence showing that the presence of non-neuronal cells (macro and microglia) is necessary for HIV-related neurotoxicity to occur (for review, see Lipton, 1994a
TGF-
MATERIALS AND METHODS
Hippocampal neuronal cultures Treatments in the presence of glia. Neuronal cultures were prepared from the hippocampi of 17- to 18-d-old rat embryos. Dissection and dissociation were performed in a Ca2+/Mg2+-free solution (D1) containing glucose (3.25 gm/l), sucrose (7.5 gm/l), HEPES (10 mM), NaCl (8 gm/l), KCl (400 mg/l), Na2HPO4 (180 mg/l), KH2PO4 (30 mg/l), pH 7.4 (320-330 mOsm). Tissues were incubated for 20 min in 0.25% (w/v) trypsin, washed twice in D1, and dissociated by trituration in the presence of DNase (150 µg/ml). Cells were plated in DMEM containing 10% horse serum at a density of 5 × 104 cells/cm2 on 15 mm glass coverslips coated with polylisine (1 mg/ml). After 2-4 hr, coverslips were transferred to plates containing N2.1-defined media (2 ml) and a confluent bed of astroglia (Abele et al., 1990Treatments in the absence of glia. Neurons treated in the absence of glia were dispersed and plated as above. After 2-4 hr, they were moved to 35 mm culture dishes containing defined neurobasal medium (Life Technologies, Gaithersburg, MD) supplemented with 0.5 mM L-glutamine, 25 µM glutamate, and 5 µg/l human fibronectin. In these cultures, gp120 was added at 7 d in culture (DIC).
When gp120 was added at 2 DIC, neurons were cultured in the presence of glia for the first 48 hr. Before gp120 was added, coverslips with neurons were moved to a new culture dish containing their old, conditioned medium (DMEM + N2.1).
Cell survival and apoptosis detection Fluorescein diacetate (10 µM) and propidium iodide (5 µM) were used to stain viable and dead cells, respectively. Hoechst 33342 (5 µM) was used to evaluate differences between normal and apoptotic nuclei. Cells were counted by using a Leitz microscope (Nuhsbaum, McHenry, IL) with optics for fluorescence and Nomarski. Five to ten microscopic fields were counted for each coverslip, and two to three coverslips per treatment were used for each experiment. Because the cell death induced by gp120 occurred progressively and was caused mainly by apoptosis (see below), only neurons positive to fluorescein were counted for the final analysis of cell survival. Indeed, long treatments were necessary to see a significant effect of gp120, and dead cells could have been removed by changing the culture medium and/or by the action of microglia. Furthermore, the maintenance of the membrane integrity in the early stage of apoptosis did not allow the entrance of propidium iodide into the nucleus of apoptotic cells. Also, the terminal deoxynucleotidyl transferase-mediated dUTP-biotin nick end labeling (TUNEL) technique (Gavrieli et al., 199270°C for at least 15 min). Samples were loaded in a 1.5% agarose gel after a 30 min incubation at 37°C and a 10 min incubation at 65°C in the presence of RNase (10 mg/ml). Fura-2 videoimaging Cells were loaded with 2 µM fura-2 acetoxymethylester using a balanced salt solution (standard buffer) of the following composition (in mM): NaCl 159, KCl 5, MgSO4 0.4, MgCl2 0.5, KH2PO4 0.64, NaHCO3 3, HEPES 20, glucose 5, Na2HPO4 0.33, CaCl2 2, and BSA 0.2% (330 mOsm/kg), pH-adjusted to 7.35. The cells were incubated with fura-2 for 30 min at room temperature to avoid probe compartmentalization and then incubated for a further 30 min at room temperature to allow deesterification of the fura-2 dye. Coverslips were mounted on a coverslip chamber for fluorescence measurements. All measurements were made at room temperature, as previously described (Meucci et al., 1995), using standard buffer supplemented with 10 µM glycine. Each cell in the image was analyzed independently for each time point in the captured sequence. All individual cell [Ca2+]i traces shown are representative responses for a given field of cells. For the calibration of fluorescent signals, we used cells loaded with fura-2; Rmax and Rmin, ratios at saturating and zero Ca2+, respectively, were obtained by perfusing cells with standard buffer containing 10 mM CaCl2 and 4 µM ionomycin and, subsequently, with a Ca2+-free solution containing 10 mM EGTA. The values of the obtained Rmax and Rmin, expressed as gray-level mean, were used to calculate the calibration curve by TARDIS software. The [Ca2+]i was determined according to the equation of Grynkiewicz et al. (1985)
RESULTS
The effect of recombinant gp120 on the survival of hippocampal pyramidal neurons depends on the age of the culture and the presence of glia
Purified gp120 has been shown to cause significant neuronal cell loss in rodent hippocampal cultures (Brenneman et al., 1988In the presence of glia, the addition of gp120 to differentiated neurons (7 DIC) that showed a complex network of neurites clearly affected neuronal survival and caused a time- and dose-dependent reduction in the number of surviving cells (Fig. 1A). Neuronal death developed slowly, and at least 4-5 d of treatment were required to see a significant reduction in the number of viable cells.
Fig. 1. Effect of recombinant gp120 on the survival of differentiated hippocampal neurons. Treatment started at 7 DIC in the presence (A) or in the absence (B) of glia (see Materials and Methods). Survival was evaluated 4, 5, 6, and 12 d after the addition of gp120 in A and after 4, 6, and 9 d in B. Data shown in the figure are mean ± SEM and come from three different experiments for each treatment. (*p < 0.05 vs control).
[View Larger Version of this Image (28K GIF file)]
Experiments on younger cultures in the presence of glia (treatments started at 2 DIC) showed that immature neurons were less sensitive to gp120 toxicity. For treatments shorter than 7 d, only the highest concentration of gp120 induced significant cell death. After longer treatments, both 20 and 200 pM gp120 effectively reduced the percentage of live cells (Table 1).
Table 1. Effect of gp120 on neuronal survival in young cultures
Cell survival (% of control) After 4 d After 6 d After 9 d gp120 (20 pM) 84 ± 9 88 ± 12 64 ± 12* gp120 (200 pM) 76 ± 15 62 ± 16* 33 ± 15* Treatment of neurons with gp120 started at 2DIC in the presence of glia. The number of surviving cells (stained by fluorescein diacetate) was assessed at the indicated times. Data are mean ± SEM (n = 3, *p < 0.05). To test the effect of gp120 in the absence of glia, two different experimental protocols were used for immature (2 DIC) and mature (7 DIC) neurons, because the older cultures could not be deprived of glia without affecting their survival. Thus, when gp120 was added at 2 DIC, neurons were grown for the first 48 hr in the presence of the glia feeder layer. At the time of treatment, neurons were moved to a culture plate without glia while still in the presence of their conditioned medium. In these experiments, a modest effect of the gp120 was observed (80 ± 2.9 and 74 ± 4.4% survival for 20 and 200 pM, respectively, vs control after 8 d of treatment; n = 3). Similar results were obtained with mature neurons grown in the absence of glia by the use of a chemically defined medium (see Materials and Methods) and treated with gp120 at 7 DIC (Fig. 1B). In these experiments, cell survival after a 4 d treatment with gp120 was ~20% less than for untreated neurons (control = 100%, 20 pM gp120 = 72 ± 3.7%, 200 pM gp120 = 85 ± 2.5%; n = 4). Longer treatments with gp120 did not produce a further decrease in cell survival. (Maximum length of treatment was 9 d.)
Both apoptosis and necrosis are responsible for gp120-induced neuronal death
Although necrosis and apoptosis generally have been considered to be two distinct types of cell death exhibiting different biochemical and morphological characteristics, sometimes it can be difficult to evaluate which cell-death type is responsible for cell loss. Thus, both necrotic and apoptotic cell death may coexist in the same cell population (Bonfoco et al., 1995
Fig. 2. Alterations in the nuclear density of neurons during treatment with gp120. Neurons are stained with fluorescein diacetate (yellow/green), propidium iodide (red), and Hoechst 33342 (white/blue). After 72 hr of treatment, the first changes in the nuclei, which are still negative to propidium iodide, are visible (A-D, large arrows). At this stage, blebs on the neurites are also present (C, small arrow). Dead neurons (not stained with fluorescein diacetate; A, B, small arrows) are stained with both propidium iodide and Hoechst 33342 and display either an enlarged (E, F, small arrows) or a fragmented (E, F, large arrows) nucleus. Note that nuclei stained with both dyes are brighter (white) than normal nuclei, which are stained only with Hoechst 33342 (blue) (magnification, 500×).
[View Larger Version of this Image (146K GIF file)]
Fig. 3. In situ DNA fragmentation induced by gp120 in hippocampal neurons assessed by the TUNEL technique. A, Control neurons at 11 DIC; B, gp120-treated neurons (20 pM); C, gp120/TGF-treated (5 ng/ml) neurons. Treatments were started at 7 DIC.
[View Larger Version of this Image (100K GIF file)]
In situ labeling for DNA fragmentation, assessed by using the TUNEL technique, also showed that gp120 greatly increased the number of apoptotic cells, as shown in Figure 3. (Also note that most of the cells stained show condensed nuclei.) Using this method, we estimated that apoptotic cell death increased from 10 ± 3.6% in control to 47 ± 5.5 and 50 ± 2.6% in neurons treated for 4 d with 20 and 200 pM gp120, respectively (n = 3; 307 cells for control, 142 cells for 20 pM, and 148 cells for 200 pM gp120). Similar results have been described very recently in hippocampal organotypic explants after a 48 hr treatment with gp120 (Charriaut-Marlangue et al., 1996
Analysis of DNA on agarose gels also showed that soluble DNA obtained from neurons treated with gp120 for 3 d displayed a fragmentation pattern, although the amount of fragmented DNA was very low (data not shown). In summary, these data show that both apoptosis and necrosis may occur during gp120-induced neurotoxicity in rat hippocampal cultures. In particular, although apoptosis seems to represent the main pathway of death during the first 4 d, the situation becomes more complex after longer treatment and/or at high concentrations of gp120.
NMDA-receptor activation and protein synthesis are necessary for gp120-induced neuronal death
There is evidence suggesting that the neuronal damage caused by gp120 is related to its ability to potentiate glutamatergic neurotransmission, Ca2+ influx, and NO production (Dreyer et al., 1990Consistent with these findings, the NMDA receptor antagonist 2-amino-5-phosphonovalerate (APV; 25 µM) was able to inhibit NMDA-stimulated [Ca2+]i increases by ~70% under our experimental conditions (data not shown). As shown in Figure 4, APV also was able to almost completely prevent neuronal death caused by gp120 (95 ± 4% viability in the presence of 20 pM gp120 and 91 ± 6.7% in the presence of 200 pM gp120), thus confirming previous observations suggesting a role of NMDA receptors in gp120-mediated neurotoxicity (Lipton, 1994b
Fig. 4. Effect of the NMDA receptor antagonist APV (25 µM) and the protein synthesis inhibitor CHX (0.5 µg/ml) on gp120-induced neurotoxicity of mature hippocampal cultures. Treatments started at 7 DIC, and survival was assessed after 5 d. Data are expressed as mean ± SEM from three experiments (*p < 0.05 vs control).
[View Larger Version of this Image (19K GIF file)]
The protein synthesis inhibitor cycloheximide (CHX; 0.5 µg/ml) also was able to reduce gp120-induced neurotoxicity, although it caused a 10-15% decrease in neuronal survival by itself (Fig. 4). The protective action of CHX could be caused by interference with some active processes in the cell-death program triggered by gp120, as reported for other cases of apoptosis (Martin et al., 1988
Impairment of intracellular calcium responses caused by long-term treatment with gp120
Because NMDA receptor activation is an important event in gp120 neurotoxicity, we studied the effect of the long-term treatment (3-4 d) with gp120 on NMDA-induced [Ca2+]i responses in hippocampal neurons. Figure 5A shows the typical [Ca2+]i response we observed on the addition of NMDA (50 µM, 4 min) in most control neurons (82%)a rapid increase of [Ca2+]i (1672 ± 120 nM; mean ± SEM; n = 59) and a plateau (849 ± 396 nM), which returned to basal levels after agonist removal (see also Prehn et al., 1994
Fig. 5. Typical NMDA-evoked (50 µM) [Ca2+]i increases in control neurons (A) and in gp120-treated neurons (B). Experiments were performed at 10 DIC in the presence of glycine (10 µM) and Mg2+ (see Materials and Methods). Treatment with gp120 (20 pM) started at 7 DIC. Representative traces from control and treated neurons are shown in the figure.
[View Larger Version of this Image (26K GIF file)]
In neurons treated previously with gp120 (3 d, 20 pM), the increases in [Ca2+]i evoked by NMDA were more pronounced [2722 ± 186 nM (mean ± SEM; n = 47; p < 0.05) vs 1672 ± 120 nM] and frequently were continuous with a high plateau (2724 ± 833 nM). Indeed, only 36 ± 9% of the neurons examined exhibited a ``peak and plateau'' [Ca2+]i response to NMDA as in untreated neurons. In the majority of neurons (64%), a monophasic response of high amplitude occurred (Fig. 5B). Only 5 of 52 cells examined showed a [Ca2+]i response within the range of those observed in control neurons (peak [Ca2+]i value, 1476 ± 226 nM). In control neurons, a second stimulus with NMDA, 15 min after washout of the first challenge, also induced a peak and plateau slightly smaller than the initial response (first NMDA peak, 1864 ± 138 nM; second NMDA peak, 1194 ± 120 nM; mean ± SEM; n = 41; p < 0.05) (Fig. 6A,B). We rarely observed a reduction in the [Ca2+]i response to a second NMDA challenge in most of the gp120-treated neurons (Fig. 6C,D). Indeed, many cells did not recover at all after the second NMDA stimulus (data not shown). The [Ca2+]i rise induced by the first NMDA application in these cells was 2763 ± 132 nM; mean ± SEM; n = 38. The [Ca2+]i response to the second NMDA stimulus was just as large in 79% of neurons (2437 ± 160 nM; mean ± SEM; n = 30), and it was reduced in the remaining cells (1166 ± 133 nM; mean ± SEM; n = 8; p < 0.05).
Fig. 6. Representative traces of the effect of two consecutive NMDA stimuli on [Ca2+]i in control (A, B) and gp120-treated (C, D) neurons. The second NMDA application (B, D) occurs 15 min after washout of the first challenge.
[View Larger Version of this Image (30K GIF file)]
Despite the marked effect of long-term treatment with gp120 on the NMDA-induced [Ca2+]i rise, we never observed potentiation of NMDA responses after short incubations (30 sec to 30 min) with the protein under the same experimental conditions. As reported previously by Lo et al. (1992)
Also, we tested the effect of gp120 on [Ca2+]i increases induced by KCl (50 mM). In neurons treated for 3 d with 20 pM gp120, we found that exposure to the glycoprotein did not affect the [Ca2+]i responses evoked by KCl in the presence of 25 µM APV (data not shown). However, in the absence of APV, the [Ca2+]i increase evoked by KCl was enhanced slightly in gp120-treated neurons. In these experiments, the peak [Ca2+]i value was 729 ± 58 nM in control neurons (n = 12) and 1021 ± 120 nM in treated neurons (n = 5). Therefore, it is likely that an NMDA component (attributable to glutamate release induced by KCl depolarization) is involved in the [Ca2+]i response evoked by KCl. This suggests that the action of gp120 is specific for NMDA-induced [Ca2+]i signals.
TGF-
Previous studies from this laboratory have shown that the cytokine TGF-
Fig. 7. Effect of TGF-
[View Larger Version of this Image (20K GIF file)]
Fig. 8. Inhibition of gp120-induced apoptosis (20 pM for 5 d) by TGF-
[View Larger Version of this Image (13K GIF file)]
As TGF-
Fig. 9. Representative traces showing the increase in [Ca2+]i induced by NMDA (50 µM) in neurons treated for 3 d with 20 pM gp120 in the absence (B) or in the presence (C) of TGF-
[View Larger Version of this Image (14K GIF file)]
DISCUSSION
The data presented in this study show that the neuronal injury caused by the HIV-1 coat protein gp120 on hippocampal neurons in vitro is associated with features of both apoptosis and necrosis. Although the apoptotic pathway seems dominant, the intra/intercellular mechanisms leading to neuronal damage all result from the activation of NMDA receptors. Thus, the NMDA antagonist APV completely prevented gp120-induced neurotoxicity, consistent with previous data in the literature (Lipton et al., 1991At least two or three different cell types, including diverse neuronal subtypes, microglia, and astocytes, are supposed to contribute to the neurotoxicity caused by gp120 in vitro (Merril and Chen, 1991
There have been some reports suggesting the presence of binding sites for gp120 on neurons (Bhat et al., 1991
The ability of TGF-
2 (for review, see Mallat and Chamak, 1994
FOOTNOTES
Received Feb. 12, 1996; revised April 11, 1996; accepted April 18, 1996.
This research was supported by National Institutes of Health Grants DAO2121, DAO25475, and MH40165. O.M. was supported by Ministero della Sanitá, Italy (borsa AIDS, 1994-1995 and VIII AIDS Grant 9306-21, 1995).
Correspondence should be addressed to Richard J. Miller, Department of Pharmacological and Physiological Sciences, The University of Chicago, 947 East 58th Street, Chicago, IL 60637.
Dr. Meucci is on leave from Unitá di Neuroscienze, Centro di Biotecnologie Avanzate, Largo, Rosanna Benzi 10, 16132 Genova, Italy.
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