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Mice Deficient for N-ras

Impaired Antiviral Immune Response and T-Cell Function¹

Department of Pathology and Kaplan Comprehensive Cancer Center, New York University School of Medicine, New York, New York 10016

	ABSTRACT

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Ras proteins have a key role in the regulation of several cellular functions, and are involved in a significant percentage of human tumors. However, the specific functions of the different Ras isoforms are poorly understood. In this work, we show for the first time a specific role for N-ras in T-cell function and development. Mice defective for N-ras have low numbers of CD8 single positive thymocytes and decreased thymocyte proliferation in vitro. In Ras signaling and activation assays, KO-N-ras thymocytes showed a defective response to T-cell activation. In turn, these deficiencies resulted in a significant reduction in the production of interleukin 2 on thymocyte activation. We have also detected in vivo the functional consequences of N-ras deficiency. KO-N-ras mice showed an increased sensitivity to influenza infection, especially when low doses of virus were used. Finally, we have detected an abnormal activation pattern of downstream Ras molecules in T-cell receptor-activated KO-N-ras thymocytes that is consistent with the defective T-cell function found in these animals. All of the results derived from this work constitute a significant contribution to the knowledge of N-ras-specific functions.

	INTRODUCTION

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Ras proteins are small, guanine-nucleotide-binding polypeptides that have a key role in the regulation of several cellular functions like proliferation, differentiation, or apoptosis. These proteins are involved in a significant percentage of human tumors and are a central point for many signal transduction pathways in the cell (1) . Ras proteins can rapidly cycle between an inactive GDP-bound and an active GTP-bound state. Activated Ras proteins are then able to interact with downstream effector molecules and propagate the signal. Two different groups of molecules are involved in the regulation of Ras proteins: the guanine nucleotide exchange factors that promote the transition from the GDP-bound to the active GTP-bound state, and the GTPase-activating proteins that are able to inhibit Ras by stimulating the Ras GTPase activity.

Despite the similarity between the three mammalian ras isoforms (H-ras, K-ras, and N-ras), several differences have been found among them. Although for the first 80 amino acids N-, H-, and K-ras are identical, and for the next 80 they exhibit 85% identity between any pair of Ras isoforms, Ras proteins differ substantially in their COOH-terminal region with fewer than 15% conserved residues (2) . This region is very important for the maturation and posttranslational modifications of the Ras products that are involved in the association of Ras proteins to the membranes and their subsequent activity (3, 4, 5) .

Other functional differences between the Ras isoforms have been reported (1) . For instance, the GTPase-activating protein NF1 has a 4-fold higher affinity for H-ras than for N-ras (6) . Among the guanine nucleotide exchange factors, SmgGDS, Ras-GRF, and RasGRP2 activate differentially the three Ras isoforms (7, 8, 9) . Regarding downstream ras effectors, in vitro assays also suggest differences in Ras isoform-dependent activation of PI3K, Raf-1, and Rac (10 , 11) . A specific role of K-ras and H-ras has been reported in the proliferation of human renal fibroblasts (12 , 13) , whereas N-ras signaling has been related recently in the cell survival of immortalized fibroblasts (14) . Differences have also been found in the role of Ras proteins in tumorigenesis because different ras genes have been found mutated in different tumor types (15 , 16) . Finally, mice defective for the different ras isoforms exhibit different developmental phenotypes. N-ras and H-ras knockout mice develop and reproduce normally (17, 18, 19) , whereas K-ras is essential for the embryonic development (20) .

It has been demonstrated that, in lymphocytes, Ras plays an important role in the signaling pathways that activate cytokine gene induction and in the control of B-cell and T-cell development (21) . Since the activation of Ras on T-cell activation was first demonstrated (22) , several groups have confirmed the key role of Ras activation in antigen receptor-activated lymphocytes (23, 24, 25) . In fact, the loss of Ras function prevents the normal activation of proliferation, cytokine production, and lymphocyte development that is induced by the recognition of the antigen (26 , 27) .

However, the specific roles, if any, of the different Ras isoforms in lymphocyte function are poorly understood. N-ras is the main ras gene found activated in human myeloid and lymphoid disorders (15 , 16) . Moreover, although transgenic mouse lines that express either the N-ras proto-oncogene or its oncogenic form show a high incidence of lymphomas (28) , transgenic mice generated with the H-ras oncogene under the same promoter had a low or null incidence of those tumors (29 , 30) . Therefore, N-ras might play an important role in the regulation of lymphocyte function. To test this hypothesis, we investigated the specific role of N-ras in T-cell function and development using an N-ras-deficient mouse model.

	MATERIALS AND METHODS

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Mice.
Age-matched wild-type mice (N-ras+/+ mice from the same litters), and KO-N-ras mice (17) were housed under pathogen-free conditions. BALB/c mice were purchased from The Jackson Laboratory, Bar Harbor, ME. All of the work with mice conformed to guidelines approved by the Institutional Animal Care and Use Committee of New York University School of Medicine.

Antibodies and Plasmids.
FITC-conjugated monoclonal antibodies specific for CD4, CD8, CD11b; phycoerythrin-conjugated monoclonal antibodies specific for CD8, CD69, CD25, F4/80, and CD44; a tri-color-conjugated monoclonal antibody specific for CD4; and unlabeled goat antihamster IgG (H+L) were purchased from Caltag. Phycoerythrin-conjugated monoclonal antibody specific for NK1.1 and unlabeled hamster antimouse CD3 and CD28 were purchased from PharMingen. Antibodies used for ras detection included anti-pan-ras Y13–259 (31) , monoclonal antibodies for mouse N-ras (Santa Cruz Biotechnology) and for H-ras and K-ras (Oncogene Science). Antibodies for activated or total ERK,⁶ and activated AKT and JNK were from Promega.

Proliferation and Apoptosis Assays Using Lymphocytes.
For proliferation experiments, thymocytes that were isolated from mice were washed and resuspended in complete medium (RPMI 1640 plus 10% FBS, 100 units/ml penicillin, 100 µg/ml streptomycin, and 50 µM 2-mercaptoethanol). Thymocytes (2 x 10⁵/well) were incubated in 96-well plates and incubated for 72 h at 37°C in 5% CO₂ in air, with or without the following stimuli: plate-bound anti-CD3 (10 µg/ml) with or without plate-bound anti-CD28 (10 µg/ml), and PMA (100 ng/ml) plus ionomycin (500 ng/ml). Cells were pulsed during the last 10 h of incubation with [³H]thymidine, and the incorporation of radiolabel was measured by scintillation counting.

For apoptosis assays, thymocytes were incubated for 24 and 48 h in 6-well-plates (2 x 10⁶/well) with plate-bound anti-CD3 plus anti-CD28, PMA (100 ng/ml) plus ionomycin (500 ng/ml), or dexamethasone (1 µM). Apoptosis was monitored using an annexin V apoptosis detection kit (PharMingen).

Flow Cytometric Analysis and Cytokine Quantification.
To examine the expression of surface antigens, cells were washed and then resuspended in PBS containing 0.2% BSA. Saturating concentrations of antibodies were added, and the cells were incubated for 30 min at 4°C in the dark. Cells were washed three times and fixed in 0.5% paraformaldehyde in PBS for analysis on a FACScan flow cytometer (Becton Dickinson). Fluorescence data were analyzed using the CellQuest software. Dead cells and debris were excluded by characteristic forward and scatter profiles.

IL-2 production was measured in culture supernatants from stimulated thymocytes 20 h after activation by ELISA (R&D Systems).

Influenza A Virus Infection Experiments.
For the survival experiments, 6–9-week-old mice were anesthetized and inoculated intranasally with different doses of influenza A virus (WSN strain) diluted in PBS. Mice were monitored daily, and survival was scored after 14 days. For comparison of subsets of immune cells and pathogenesis, mice were infected with 100 PFU of influenza virus and monitored at days 3, 5, 7, and 10 postinfection. Five mice of each genotype were sacrificed per day, and the left lung was removed for flow cytometric analysis to characterize the subsets of immune cells, and the right lung was used to carry out histological studies. In the last case, samples were fixed in 10% buffered formalin, embedded in paraffin, and 5-µm sections were stained with H&E and analyzed under the microscope.

Cytotoxicity Assays.
For the generation of primary CTLs in vitro, responder cells (5 x 10⁵) from KO-N-ras and wild-type spleens were cultured in a total of 2 ml of complete RPMI 1640 with stimulator splenocytes (2.5 x 10⁵) from BALB/c mice that were previously irradiated (2000 rads). After 4 days, cells were harvested and CTL activity was determined using P815 cells as targets. For the NK activity assay, fresh splenocytes were used as effector cells, whereas YAC-1 cells were used as target cells. In vitro CTL activity and NK lysis were analyzed by incubating different numbers of effector cells with 2 x 10⁴ target cells for 4 h at 37°C. The cytotoxicity of both CTL and NK cells was measured using the CytoTox 96 nonradioactive cytotoxicity assay (Promega). All of the reactions were performed in quadruplicate.

Protein Expression and Ras Activation.
For the detection of Ras proteins in thymus, proteins (400 µg/sample) were immunopurified using an anti-pan-ras immunoaffinity column, fractionated on 15% SDS polyacrylamide gels, and detected using antibodies specific for each isoform. For signaling and Ras activation experiments, thymocytes were isolated in RPMI and incubated at 37°C for 2 h. For TCR activation, 2 x 10⁷ cells were incubated for 30 min on ice in the presence or absence of anti-CD3 (10 µg/ml) an/or anti-CD28 (10 µg/ml). After washing them in cold PBS, cells were activated by resuspension for 1 min in 37°C PBS containing cross-linking mouse antihamster antibodies. Cells were lysed in 400 µl of lysis buffer [10% glycerol, 1% NP40, 50 mM Tris-HCl (pH 7.4), 200 mM NaCl, 2.5 mM MgCl₂, 1 mM phenylmethylsulfonyl fluoride, 1 µM leupeptin, 10 µg soybean trypsin inhibitor per ml and 0.1 µM aprotinin]. Lysates were incubated overnight at 4°C with Gluthatione-S-Transferase-Raf-RBD (Ras-binding domain) fusion protein (a gift from J. L. Bos, Utrecht University, Utrecht, the Netherlands) coupled to glutathione agarose beads to collect GTP-bound Ras. Beads were pelleted and washed three times with lysis buffer, and ras proteins were detected by Western blot. Active ERK, JNK, and AKT proteins were detected in the primary lysates in accordance with the manufacturer’s recommendations (Promega). Lysates were also probed with anti-ERK to confirm that comparable amounts of total protein were present.

	RESULTS

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Impaired CD8-positive Selection in KO-N-ras Thymocytes.
To determine the role of N-ras in T-cell development, we analyzed thymocyte and splenocyte cellularity and subsets from wild-type and KO-N-ras mice by flow cytometric analysis. Although all of the thymocyte subsets are present in the KO-N-ras mice, the percentage of both single positive CD4 and CD8 thymocytes was lower among KO-N-ras cells than among wild-type cells (Table 1) . This reduction was more apparent for CD8⁺ thymocytes, which showed a significant reduction of 25% of the average value found among wild-type thymocytes (P = 0.015). Interestingly, the population of splenocytes showed a similar result in the number of CD8⁺ cells (15% decrease), although in this case, differences did not reach a significant value (P = 0.089).

View larger version (18K): [in this window] [in a new window] [Download PPT slide]   Fig. 1. Impaired CD8+ positive selection in KO-N-ras thymocytes. A, CD69 expression on CD4/CD8 double positive wild-type and KO-N-ras thymocytes. Top, representative histograms of KO-N-ras (shaded histogram), and wild-type (open histogram) thymocytes. Bottom, percentages of CD69-positive cells among CD4/CD8 double positive thymocytes (n = 5 in each group). B, CD4 and CD8-positive differentiation in wild-type and KO-N-ras thymocytes. Total thymocytes were treated with plate-bound CD3 and CD28 antibodies for 72 h. Graph shows single positive CD4 and CD8 cells relative to the nontreated thymocytes among wild type (white bars) and KO-N-ras (black bars). Data are shown as mean ± SE. Samples were compared using unpaired t tests. **, P < 0.01.

Defective Antiviral Response in KO-N-ras Mice.
CD8⁺ T lymphocytes are crucial components of the cell-mediated immune response. The murine influenza pneumonia model is one of the better-defined experimental systems to study cell-mediated immune response in virus infections. CD8⁺ T cells rapidly increase from virtually undetectable in the naïve host to high numbers in the primary response to influenza virus infection (33) and play a critical role in viral clearance from influenza-infected mice (34) . Because KO-N-ras thymocytes have low numbers of CD8⁺ single positive cells, we decided to test whether this alteration could affect the antiviral response in N-ras-deficient mice challenged with influenza virus. Although KO-N-ras were more sensitive than wild-type mice to 10,000 and 1,000 PFU of influenza virus (Fig. 2, A and B) , differences were significant when 100 PFU of virus were used in the infection (P = 0.0014; Fig. 2C ). Although this dose was barely lethal for wild-type mice (90.5% survival), it clearly affected the viability of KO-N-ras mice (45.8% survival).

View larger version (14K): [in this window] [in a new window] [Download PPT slide]   Fig. 2. Defective antiviral response in KO-N-ras mice. Survival of mice after influenza virus infection. Wild-type () and KO-N-ras () mice were infected with three different doses of virus: 10000 (A), 1000 (B), and 100 PFU (C). Number of mice per genotype and dose: n = 3–5 (A); n = 15 (B); n = 21–24 (C).

View larger version (70K): [in this window] [in a new window] [Download PPT slide]   Fig. 3. Cytolytic function in KO N-ras cells and histological analysis in KO-N-ras lungs infected with influenza virus. A, normal cytolytic function in KO-N-ras mice. Spleen cells isolated from wild-type () and KO-N-ras () mice (n = 3 in each group) were used in a cytotoxicity assay as described in "Materials and Methods." Results are representative of three independent experiments. B, representative photomicrographs of histological sections of lungs from KO-N-ras and wild-type mice infected with influenza virus. At day 3 postinfection, wild-type lungs showed a diffuse inflammatory response, whereas a focal inflammatory response was more frequent among KO-N-ras infected lungs. At day 10 postinfection, wild-type infected lungs showed exuberant repair in comparison with KO-N-ras infected lungs, among which diffuse alveolar damage (arrows) was found at these late stages of the infection.

We also monitored pulmonary histopathology in the same infected mice. Again, clear differences were found by this comparative study (Fig. 3B) . Both KO-N-ras and wild-type mice showed bronchiolitis characterized by high numbers of lymphocytes. However, this inflammatory response was stronger among wild-type mice than among KO-N-ras mice. Whereas wild-type lungs showed a diffuse inflammatory process, 38% of the studied KO-N-ras lungs showed a focal bronchiolitis. Moreover, interstitial inflammation (pneumonitis) was also found more frequently among wild-type mice than in KO-N-ras mice (40 versus 14%, respectively). Finally, at late stages of the infection diffuse alveolar damage was also found in KO-N-ras mice, whereas wild-type mice lungs were characterized by repair processes.

Decreased Thymocyte Proliferation in KO-N-ras Mice.
In the previous experiments, we determined that KO-N-ras T-cells were defective in proliferation in vivo. To characterize the molecular mechanisms responsible for this phenotype, we decided to test in vitro the proliferative response of KO-N-ras thymocytes. Significant differences between wild-type and KO-N-ras mice were observed when thymocytes were stimulated with anti-CD3, anti-CD3 plus anti-CD28, or PMA plus ionomycin (Fig. 4A) . However, whereas the reduction in the case of PMA plus ionomycin was only 1.43-fold, a higher reduction was observed for anti-CD3 stimulation (4.50-fold) and CD3 plus CD28 stimulation (4.05-fold).

View larger version (32K): [in this window] [in a new window] [Download PPT slide]   Fig. 4. Defective proliferation and IL-2 production in KO-N-ras thymocytes. A, proliferative responses of thymocytes from wild-type () and KO-N-ras () mice. Cells from four mice of each genotype were treated with plate-bound anti-CD3, anti-CD3 plus anti-CD28, or PMA plus ionomycin (ION) for 3 days. [3H]thymidine incorporation was measured during the last 10 h. Values are average stimulation indices ± SE. *, P < 0.05; **, P < 0.01. B, role of N-ras in the survival of stimulated thymocytes. Thymocytes were cultured with anti-CD3 plus anti-CD28, PMA plus ionomycin (ION), or dexamethasone (dex) for 24 h. Cells undergoing apoptosis were identified by annexin-V detection and PI staining. Graphs show average values of annexin-V-single-positive (A+/PI-) and annexin-V/PI-double positive cells (n = 3). C, decreased IL-2 production by KO-N-ras thymocytes. Wild-type () and KO-N-ras () thymocytes were extracted from 6–8-week-old wild-type and KO-N-ras mice and were cultured with stimuli for 20 h. Values are average stimulation indices ± SE (n = 3). D, IL-2R expression in stimulated KO-N-ras and wild-type thymocytes. Cells were stimulated for 72 h with the indicated stimuli. IL-2R and CD4 or CD8 were detected by flow cytometric analysis. Values are the average of the mean values found for IL-2R expressed as the percentage of the wild-type indices ± SE (n = 9).

Production of IL-2 is one of the most important and is one of the earliest events in T-cell activation in which Ras has been implicated (35) . As shown in Fig. 4C , N-ras-deficient thymocytes, stimulated with anti-CD3 plus anti-CD28 or PMA plus ionomycin, showed lower levels of IL-2 than did wild-type samples. However, whereas in N-ras-deficient cells stimulated with PMA plus ionomycin, the reduction of IL-2 production was not significant (19.3%), the same cells showed a significant reduction (90.7%) of IL-2 production when they were treated with anti-CD3 plus anti-CD28 (P < 0.05).

IL-2 promotes T-cell proliferation by binding to a high-affinity receptor composed of three transmembrane proteins (, ß, _c chains). Because the chain is undetectable on resting T cells, and its expression is correlated with their proliferative responses, we analyzed its expression in stimulated wild-type and KO-N-ras thymocytes. No differences were detected in either group for the expression of IL-2R chain in CD4⁺ stimulated thymocytes (Fig. 4D) . Interestingly, for CD8⁺ cells, KO-N-ras mice showed significantly lower levels of IL-2R chain when cells were incubated with CD3 plus CD28, whereas no differences were detected when CD8⁺ cells were treated with PMA plus ionomycin (Fig. 4D) .

Activation and Protein Levels of Ras Isoforms in Mouse Thymocytes.
The alterations described for KO-N-ras mice in this work could be attributable either to decreased levels of total Ras or to the lack of an N-ras-specific function. To test the first possibility, we determined the levels of total Ras in thymi from KO-N-ras and wild-type mice. No significant differences were found between KO-N-ras and wild-type mice for the levels of total Ras (Fig. 5A , top panel). We also compared the levels of each Ras isoform between KO-N-ras and wild-type samples (Fig. 5A , bottom panels). Interestingly, K- and H-ras levels were increased in KO-N-ras thymi, suggesting an up-regulation of H-ras and K-ras in the thymus of N-ras-deficient mice to keep constant the levels of total Ras.

View larger version (28K): [in this window] [in a new window] [Download PPT slide]   Fig. 5. Analysis of Ras expression and activation in wild-type and KO-N-ras thymocytes. A, total Ras and ERK were detected by immunoblotting of a 50-µg sample of the total protein extracts (input; upper panels). Levels of Ras proteins in thymus of wild-type (WT) and N-ras-deficient mice (KO). H-, K-, and N-ras isoforms were detected as described in "Materials and Methods" (three lower panels); at the bottom of each panel, expression levels of each isoform in KO-N-ras thymus relative to the expression in wild-type thymus. Expression was quantified with Quantity One software. B, wild-type (wt) and KO-N-ras thymocytes (2 x 107 cells/lane) were stimulated with anti-CD3 plus anti-CD28, and specific activation for each Ras isoform was measured as described in "Materials and Methods." Bottom graph, the activation levels of each isoform in KO-N-ras and wild-type thymocytes obtained with Quantity One software.

Specific Role of N-ras in Thymocyte Activation.
Our data indicate that N-ras performs a function in mouse thymocytes that cannot be accomplished by other Ras isoforms, even though they are equally activated on TCR stimulation. Therefore, the lack of N-ras activation could imply a defective downstream TCR signaling that is responsible for the impaired T-cell functions found in KO-N-ras thymocytes. To test the specific effect of N-ras in the downstream Ras pathways, we analyzed mitogen-activated protein kinase (MAPK), JNK, and AKT activation in mouse primary thymocytes. When wild-type cells were stimulated with anti-CD3 plus anti-CD28, all of these molecules were activated, whereas a different kinetics of activation for these three molecules was observed in KO-N-ras thymocytes (Fig. 6) . Although the pattern of ERK2 activation was similar in wild-type and KO-N-ras thymocytes, a lower activation was observed in KO-N-ras-activated cells (32 and 27% attenuated signal, 2 and 5 min, respectively, postactivation). In the case of the AKT activation, wild-type and KO-N-ras thymocytes showed similar levels of activation, but a shorter duration of AKT activation was observed in N-ras-deficient cells. The maximum values for activated-AKT in wild-type cells were observed 5 min after the activation of the cells, whereas it was 2 min postactivation for the N-ras-deficient cells. Interestingly, abnormally high levels of steady-state activated JNK were detected in KO-N-ras thymocytes. In addition, no JNK activation was observed after the treatment with anti-CD3 plus anti-CD28, suggesting an inhibition of the activation of this protein by TCR cross-linking in N-ras-deficient cells.

View larger version (19K): [in this window] [in a new window] [Download PPT slide]   Fig. 6. Impaired downstream-Ras signaling in KO-N-ras thymocytes. A, activation of AKT (Akt), ERK2 (p42), and JNK1 (p46) was measured by immunoblotting with antibodies specific for the activated forms of each protein. Thymocytes (5 x 106 cells/lane) were stimulated with anti-CD3 plus anti-CD28 for the indicated times (min). B, results shown in A were quantified with Quantity One software and normalized with immunoblotting for total ERK. Wild-type () and KO-N-ras () values are percentages relative to maximal activation.

	DISCUSSION

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Considerable evidence supports the fact that Ras proteins play a crucial role in the normal function and development of T cells. The loss of Ras function has been related to defective activation of proliferation, cytokine production, and lymphocyte development as well as with the induction of T-cell anergy (26 , 27 , 36) . However, the differential role of Ras isoforms in T-cell function remains unexplored. In this study, using mice carrying a null mutation in the N-ras gene, we provide evidence for an important role of N-ras in T-cell immune function, early T-cell activation, and thymocyte development.

Involvement of N-ras in T-Cell Development and Proliferation.
We have detected a significant reduction for the single positive CD8 thymocytes harvested either from fresh N-ras-deficient thymi or from thymocytes stimulated through the TCR. Therefore, N-ras could be a crucial Ras isoform in the signaling related to the positive selection of CD8 cells, and/or it could be involved indirectly in the development of this type of T-cells. The lack of IL-2 production that we have detected among stimulated KO-N-ras thymocytes supports the second hypothesis. Although IL-2 is not produced by CD8 single positive cells, these cells present receptors for this cytokine. Therefore, the low CD8 numbers among KO-N-ras mice might be attributable more to a defective signaling in the IL-2-secretor cells rather than to an abnormal signaling in CD8 cells themselves.

We have also demonstrated that thymocytes deficient for N-ras proliferate less than their wild-type counterparts. It is interesting to point out that this phenomenon was not caused by an increase in the induction of apoptosis, and it could be the reason why KO-N-ras mice show a lower thymus cellularity in comparison with wild-type mice (Table 1) . The defective proliferation found among N-ras defective thymocytes in vitro is probably caused by a defect in the first stages of T-cell activation, because the production of IL-2 is especially low up to 20 h after activation. The low levels of IL-2R synthesis in KO-N-ras thymocytes on in vitro stimulation also favor a defective early activation among these cells. De novo synthesis of the chain of the IL2-R complex is one of the first events associated with T-cell activation. In this work, we have demonstrated that the IL-2R chain is underexpressed in KO-N-ras thymocytes that are stimulated with anti-CD3 plus anti-CD28, but it is not underexpressed when cells are stimulated with PMA plus ionomycin. Therefore, N-ras seems to be a crucial molecule for T-cell activation and proliferation induced by TCR transactivation.

N-ras and in Vivo Immune Response.
One of the most important consequences of the deficiency of N-ras that we have identified is related to the T-cell immune function. It is well known that CD4⁺ and CD8⁺ T cells are critical components of the cell-mediated immune response. This is the type of immune response triggered by viral infections. Virus-specific CD4⁺ T-cell response contributes to viral clearance by producing IL-2, which facilitates CD8⁺ T-cell activation and expansion, and by secreting IFN- and tumor necrosis factor (37) . Using a murine influenza pneumonia model, Eichelberger et al. (34) have demonstrated that CD8⁺ T cells play a critical role in the primary response to virus infection. Our in vivo studies showed an altered antiviral immune response in N-ras-deficient mice on influenza virus infection. KO-N-ras mice were more sensitive than wild-type mice to influenza virus infection. Interestingly, at a lower viral dose, the survival differences were higher for both groups. These results suggest that T cells are more sensitive to N-ras deficiency under low external insults or stimuli, which is similar to real-life viral infections.

N-ras deficiency is affecting not only CD8⁺ T-cell immune function but also the complex antiviral response mediated by these cells. A low production of IL-2 in infected lungs, as we observed in CD3 plus CD28-stimulated thymocytes, could imply a lower activation of several types of immune cells involved in the antiviral response. The most common defect was the reduction in cell numbers at day 5 postinfection. This hypothesis is reinforced by the fact that in vitro cytolitic activity of CTLs and NKs is normal among KO-N-ras mice. However, the possibility of a defective cytolitic activity in vivo among N-ras-deficient mice cannot be completely ruled out.

Specific Role of N-ras in the TCR Signaling Network.
Recently, N-ras has been related to cell survival of immortalized fibroblasts (14) . Moreover, the KO-N-ras immortalized fibroblasts showed a high susceptibility to the induction of apoptosis on tumor necrosis factor and FAS treatment. In that system, it was demonstrated that N-ras-defective fibroblasts showed undetectable levels of steady-state activated AKT, and that N-ras promotes cell survival by down-regulation of JNK and p38, whereas ERK activation remained intact (14 , 38) . In our work, using a different cell type (primary thymocytes) we have found alterations in the activation of AKT, JNK, and ERK. In other words, both survival and proliferative pathways located downstream of Ras are affected in this cell type. It is interesting to note that, in both fibroblasts and thymocytes, neither K-ras nor H-ras were able to replace N-ras. On the other hand, in primary thymocytes, the lack of N-ras did not increase either the apoptotic rate of thymocytes treated with different mitogens or the levels of activated JNK in stimulated thymocytes. The different results obtained in fibroblasts and thymocytes defective for N-ras could be explained with the different signaling pathways studied in both cases (apoptosis/survival versus proliferation/differentiation) and/or the molecular context that is characteristic of each one of these cellular types.

In this work, we have observed that, all of the defective characteristics found in KO-N-ras thymocytes were always more pronounced when cells were stimulated through the TCR than when they were activated by a TCR-independent stimulus. These results indicate that N-ras is a key downstream molecule in TCR signaling. Because the levels of total Ras in N-ras-deficient T-cells are the same as those found in wild-type T cells, an explanation for the key role of N-ras in T-cell function could be its molecular specificity. In fact, although we have found an increase in the activation of both K-ras and H-ras in KO-N-ras thymocytes on TCR activation, this overactivation was not able to rescue the phenotype observed in N-ras-deficient thymocytes. Therefore, some molecule(s) (mainly guanine nucleotide exchange factors) that are involved in TCR signaling could bind and activate preferentially N-ras, and/or specific downstream effectors could be activated in an isoform-specific fashion by N-ras and not by K- or H-ras. Another possible explanation for the specific role of N-ras in T-cell function and development could be a differential microlocalization of N-ras with respect to the other ras isoforms.

In summary, we have demonstrated that neither K-ras nor H-ras are able to completely replace the specific role of N-ras in development of CD8 thymocytes, thymocyte proliferation, and antiviral immune response. Moreover, the results presented here indicate that although K-ras and, in a lesser manner, H-ras, as well as N-ras, can be activated by TCR stimulation, the presence of N-ras is crucial to reach T-cell activation thresholds and a proper downstream Ras signaling, especially under low antigen stimuli, which should be the more physiological situation. Our study of KO-N-ras mice reveals the crucial role of this Ras isoform in T-cell function and thymocyte development and opens the way to dissect the signal transduction pathways specifically induced by N-ras in thymocytes. Furthermore, given the key role of oncogenic N-ras in hematopoietic tumors, the conclusions derived from this work will be an important contribution to understand the molecular pathogenesis of T-cell tumorigenesis, and they will be very useful for future therapeutic strategies for these types of tumors based on the inactivation of oncogenic N-ras.

	ACKNOWLEDGMENTS

 
We thank Drs. Alan Frey, Sasa Radoja, Ramon Gimeno, and David Levy for their multiple suggestions, helpful discussions, and critical comments on the manuscript. We also thank John Hirst for his help with flow cytometric analysis. We are grateful to David Levy (New York University, New York, NY) and Johannes Bos (Utrecht University, Utrecht, the Netherlands) for providing reagents. We also thank Raju Kucherlapati for generously embarking on the construction of the N-ras knockout mice.

	FOOTNOTES

 
The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore be hereby marked advertisement in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

¹ Supported by a NIH Grant CA36327 (to A. P.). I. P. d. C. was a recipient of a fellowship from the Ministry of Education and Science (Madrid, Spain).

² Present address: Molecular Oncology Program, Centro Nacional de Investigaciones Oncologicas, E-28029 Madrid, Spain.

³ Present address: Division of Molecular Carcinogenesis, The Netherlands Cancer Insitute, 1066 CX Amsterdam, the Netherlands.

⁴ Present address: Department of Pathology, The University of Texas at San Antonio Medical School, San Antonio, TX 78229-3900.

⁵ To whom requests for reprints should be addressed, at Department of Pathology, New York University School of Medicine, 550 First Avenue, New York, NY 10016. Phone: (212) 263-5342; Fax: (212) 263-8211; E-mail: pellia01{at}med.nyu.edu

⁶ The abbreviations used are: ERK, extracellular signal-regulated kinase; NK, natural killer; TCR, T-cell receptor; JNK, c-Jun NH₂-terminal kinase; PMA, phorbol 12-myristate 13-acetate; IL, interleukin; PFU, plaque-forming unit(s); PI, propidium iodide; KO-N-ras, knock-out-N-ras; PI3K, phosphoinositide 3-kinase; IL-2R, interleukin-2 receptor alpha.

Received 6/24/02. Accepted 1/27/03.

	REFERENCES

Top ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

 

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