HOME HELP FEEDBACK SUBSCRIPTIONS ARCHIVE SEARCH TABLE OF CONTENTS		QUICK SEARCH:   [advanced] Author: Keyword(s): Year:  Vol:  Page:

This Article Abstract Full Text (PDF) Alert me when this article is cited Alert me if a correction is posted Citation Map Services Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Citing Articles Citing Articles via HighWire Citing Articles via Google Scholar Google Scholar Articles by Chen, Y.-T. Articles by Kung, J. T. Search for Related Content PubMed PubMed Citation Articles by Chen, Y.-T. Articles by Kung, J. T.

Age-Associated Rapid and Stat6-Independent IL-4 Production by NK1^-CD4⁺8^- Thymus T Lymphocytes¹

Institute of Molecular Biology, Academia Sinica, Taipei, Taiwan, Republic of China; and Graduate Institute of Immunology, College of Medicine, National Taiwan University, Taipei, Taiwan, Republic of China

	Abstract

Top Abstract Introduction Materials and Methods Results and Discussion References

 
The source of IL-4 required for priming naive T cells into IL-4-secreting effectors has not been clearly identified. Here we show that upon TCR stimulation, thymus NK1^-CD4⁺8^- T cells produced IL-4, the magnitude of which was inversely correlated with age. This IL-4 production response by Th2-prone BALB/c mice was 9-fold that of Th1-prone C57BL/10 mice. More than 90% of activated NK1^-CD4⁺8^- thymocytes did not use the invariant V14-J281 chain characteristic of typical CD1-restricted NK1⁺CD4⁺ T cells. Stat6-null NK1^-CD4⁺8^- thymocytes produced bioactive IL-4, with induction of IL-4 mRNA expression within 1 h of stimulation. Our results support the possibility that TCR repertoire-diverse conventional NK1^-CD4⁺ T cells are a potential IL-4 source for directing naive T cells toward Th2/type 2 CD8⁺ T cell (Tc2) effector development.

	Introduction

Top Abstract Introduction Materials and Methods Results and Discussion References

 
Substances of widely different structure, such as pollens, foods, drugs, fungi, and molds, are some of the most common allergens that elicit IgE-mediated immediate hypersensitivity in humans. IL-4, originally described as B cell growth factor, is a pleiotropic cytokine that plays critical roles in the induction of IgE response at two well-defined points. First, IL-4 is required for the priming of naive T cells into IL-4-secreting Th2/type 2 CD8⁺ T cell (Tc2)³ effector cells (1, 2, 3). Second, IL-4 produced by Th2/Tc2 acts on activated B cells to direct IgE switching with subsequent IgE secretion (reviewed in Ref. 4). Although work by many researchers has focused on the cellular origin of IL-4 that is used for priming naive T cells into IL-4 secreting effectors, no unifying conclusion has emerged.

Two likely characteristics can be expected of a cell capable of providing IL-4 used for priming naive T cells into IL-4-secreting effectors: 1) IL-4-independent IL-4 gene inducibility and 2) rapid induction kinetics. Cells that fulfill both these criteria include NK1 T cells, mast cells, basophils, and eosinophils (5, 6, 7). However, it is difficult to envisage how allergens of such widely diverse structures can all activate IL-4 production by either NK1 T cells that express a highly limited TCR repertoire (reviewed in Ref. 8) or by mast cells, basophils, and eosinophils that express no Ag-specific receptor at all. Considering the large structural repertoire of allergens and the highly Ag-specific nature of the response they induce, it would seem most straightforward to propose conventional T cells, cells known to express a diverse TCR repertoire, as the source of IL-4 that is used to initiate the cascade of events that lead ultimately to IgE production. The major stumbling block to this idea is that little, if any, IL-4 can be detected for naive T cells upon TCR stimulation (1, 2, 3). We re-examined relevant literature on this subject because 1) the origin of IL-4 that is used to direct Th2/Tc2 development potentially lies at the most upstream regulatory point of IgE response and 2) Th2 responses independent of NK1 CD4⁺ T cells have been reported (9, 10, 11, 12, 13, 14). In the absence of intentional IL-4 priming, CD4⁺ cells that have been reported to produce IL-4 include neonatal spleen and thymus CD4⁺ T cells (15, 16), adult thymus heat-stable Ag (HSA)^lowCD4⁺8^- thymocytes (15, 17, 18), and NK1⁺CD4⁺8^- thymocytes (19, 20). Two key reports are noteworthy. First, IL-4 production by adult thymus CD4⁺8^- T cells was confined to the NK1⁺ subset with nearly no demonstrable IL-4 activity within the NK1^- subset (20). The second is the readily demonstrable IL-4-producing cells for the CD44^- subset of thymus HSA^lowCD4⁺8^- thymocytes, although its frequency was 3-fold lower than the CD44⁺ subset (17). If indeed all IL-4 production is attributed to NK1⁺ T cells (20), one would have expected a much lower frequency of IL-4-producing cells among HSA^lowCD44^-4⁺8^- thymocytes than that reported (17), due to the uniformly CD44^high nature of NK1⁺CD4⁺ T cells (21). Although it is not immediately clear as to the reason for the inconsistent results concerning IL-4 production by NK1^-CD4⁺8^- thymocytes, a major difference was the age of the mice used. While Bendelac et al. (17) used 6-wk-old mice to demonstrate IL-4 production by HSA^lowCD44^-4⁺8^- thymocytes, Arase et al. (20) found no IL-4 production by NK1^-CD4⁺8^- thymocytes from mice 10 to 13 wk of age. This age difference, together with the observation that neonatal T cells are able to produce IL-4 (15, 16) and mount Th2 responses (22, 23), raised the possibility of an age-dependent decline of IL-4 inducibility in NK1^-CD4⁺8^- thymus T cells. In this paper we present supporting data for the age-dependent nature of IL-4 inducibility in NK1^-CD4⁺8^- thymus T cells. In addition, other characteristics consistent with NK1^-CD4⁺8^- thymus T cells as a potential source of IL-4 used for Th2/Tc2 priming are also presented.

	Materials and Methods

Top Abstract Introduction Materials and Methods Results and Discussion References

 
Mice

C57BL/10ScN breeders originally obtained from the Division of Research Service, National Cancer Institute, National Institutes of Health (Frederick, MD) were bred and housed under specific pathogen-free conditions at the Institute of Molecular Biology Animal Facility, Academia Sinica (Taipei, Taiwan). BALB/cByJ mice were obtained from the National Laboratory of Animal Breeding and Research Center (Taipei, Taiwan). Stat6-null mice on a mixed B6/129 background were kindly provided by Cynthia Watson and Dr. William E. Paul (Laboratory of Immunology, National Institute of Allergy and Infectious Diseases, National Institutes of Health, Bethesda, MD).

T cell isolation

Single-cell thymocyte suspensions were twice depleted of CD8⁺ cells by adherence to culture plates coated with anti-CD8 mAb by a modified procedure used to deplete spleen CD8⁺ T cells (24). For the first-cycle CD8⁺ cell depletion, 5 x 10⁷ to 7.5 x 10⁷ total thymocytes in 5 ml of HBSS + 5% FCS were added to each 100 x 20 mm Nunclone culture plate (Nunc, Roskilde, Denmark) that was previously coated with 10 µg of anti-CD8 (clone 3.155, Ref. 25), at room temperature for 50 min. Nonadherent cells from two to three first-cycle anti-CD8-coated plates were pooled and added to another culture plate that had been coated with 20 µg of anti-CD8, again at room temperature for 50 min. Two-cycle CD8-depleted C57BL/10 thymocytes were stained with a combination of FITC-anti-NK1 (clone PK136, Ref. 26), PE-anti-CD4 (clone GK1.5, Ref. 27), Cy5-anti-CD44 (clone IM7, Ref. 28), and Texas Red (TR)-anti-CD8 (clone 2.43, Ref. 25). The stained cells were subjected to electronic cell sorting using a FACStar^Plus fluorescence-activated cell sorter equipped with dual laser excitation (Becton Dickinson, San Jose, CA). NK1^-CD4⁺8^- phenotype was used as the sorting criteria for conventional C57BL/10 CD4⁺ T cells used in Figs. 1 and 2. NK1^-CD44^low4⁺8^- was used as the sorting criteria for C57BL/10 and Stat6-null CD4⁺ T cells used in Figs. 3–6. For BALB/c mice, CD44^lowCD4⁺8^- phenotype was used as the sorting criteria for cells throughout. Sort purity was monitored by reanalysis of sorted cells and was always >98%.

View larger version (14K): [in this window] [in a new window]   FIGURE 1. Age-dependent decline of IL-4 inducibility in thymus NK1-CD4+ T cells. NK1-CD4+8- T cells (105 cells/0.1 ml/well) from thymuses of 28 individual C57BL/10 mice ranging from 25 to 104 days of age were stimulated by plate-bound anti-CD3/CD28. Due to the lengthiness of cell sorting, single cultures were set up for each individual mouse. Day 3 culture supernatants were assayed for IL-4 using the CT.4S bioassay (A). Unstimulated T cell controls were included in some experiments and never produced detectable IL-4. The lower IL-4 assay detection limit ranged from 1 to 3 U/ml. B, Total (unfractionated) C57BL/10 thymocytes from 29 mice of indicated age were stained with FITC-anti-NK1 + PE-anti-CD4 + Cy5-anti-CD44 + TR-anti-CD8, analyzed by flow cytometry, and the percentage of NK1+ cells among CD4+8- T cells are shown. C, Total number of NK1+CD44high4+8- thymocytes per thymus from 23 individual C57BL/10 mice of indicated age.

View larger version (26K): [in this window] [in a new window]   FIGURE 2. Heightened IL-4 production by thymus CD44low4+8- T cells from Th2-prone BALB/c mice. C57BL/10 NK1-CD4+8- T cells and BALB/c CD44lowCD4+8- T cells were obtained from the thymus and spleen, divided into <2 mo and >2 mo age groups, stimulated, and assayed for IL-4 production as in Fig. 1. The total number of C57BL/10 thymuses analyzed were: <2 mo, n = 18; >2 mo, n = 14 (A). The total number of C57BL/10 spleens analyzed were: <2 mo, n = 6; >2 mo, n = 5 (C). BALB/c thymus (B) and spleen (D) responses were derived from five mice per age group. To facilitate comparison, average IL-4 production amounts are shown.

View larger version (36K): [in this window] [in a new window]   FIGURE 3. Minimal V14-J281 usage by IL-4-producing thymus NK1-CD4+8- T cells. C57BL/10 thymus NK1-CD44low4+8- T cells (32 days of age), C57BL/10 thymus NK1+CD44high4+8- T cells (88 days of age), and BALB/c thymus CD44low4+8- T cells (39 days of age) were stimulated for 45 h as in Fig. 1. Activated cells were deposited one cell per Terasaki well and analyzed by RT-PCR for IL-4, V14-J281, and C expression. Of the total of 180 and 600 single BALB/c and C57BL/10 thymus CD4+8- T cells analyzed, 15 (8.33%) and 11 (1.83%) expressed IL-4 mRNA, respectively. A, Representative BALB/c CD44low (NK1- equivalent) single CD4+ cell IL-4 mRNA analysis. Of the 10 NK1+CD44high4+8- T cells analyzed, all expressed IL-4 and 9 (90%) expressed V14-J281. There was one each V14-J281+ cells among the 15 BALB/c and 11 C57BL/10 single T cells identified to be positive for IL-4 mRNA expression. All analyzed single cells expressed C. Lane numbers of PCR products are as indicated.

View larger version (22K): [in this window] [in a new window]   FIGURE 4. Stat6-independent IL-4 production by thymus NK1-CD4+8- T cells. Thymus NK1-CD44low4+8- T cells from C57BL/10 (33 days of age) and Stat6-null (30 days of age) mice were stimulated as in Fig. 1 at 8.0 x 104 cells/0.1 ml/well. At 0-, 1-, 2-, 4-, 7-, 16-, 24-, and 40-h stimulation time points, cells were assayed for relative IL-4 mRNA expression (A) and culture supernatant assayed for bioactivity using the CT.4S assay (B). Competitive RT-PCR was performed using a fixed amount of 500 cell equivalent and 3000 cell equivalent total RNA for ß-actin and IL-4 analyses, respectively. For each given RNA sample, the fine tuning of ß-actin expression consisted of the following competitor DNA final concentrations: 0, 1.104, 2.208, 3.312, 4.416, and 5.52 fM; the fine tuning of IL-4 expression consisted of the following competitor DNA final concentrations: 0, 0.04, 0.12, 0.24, and 0.4 fM for cells that expressed relative low IL-4 mRNA, and 0, 6.592, 9.888, 13.184, 16.48, and 19.776 fM for cells that expressed relative high levels of IL-4 mRNA. The relative IL-4/ß-actin ratios for 0-, 1-, 2-, 4-, 7-, 16-, 24-, and 40-h stimulated C57BL/10 thymus NK1-CD44lowCD4+8- T cells were 0.0121, 0.373, 0.663, 0.829, 0.829, 0.995, 0.995, and 0.746, respectively. The relative IL-4/ß-actin ratios for 0-, 1-, 2-, 4-, 7-, 16-, 24-, and 40-h stimulated Stat6-null thymus NK1-CD44lowCD4+8- T cells were 0.0091, 0.299, 0.498, 0.663, 0.746, 0.829, 0.829, and 0.622, respectively. Data shown are typical of one of two independently performed experiments.

View larger version (29K): [in this window] [in a new window]   FIGURE 5. Minimal V14-J281 usage by IL-4-producing Stat6-null thymus NK1-CD4+8- T cells. C57BL/10 thymus NK1-CD44low4+8- T cells (40 days of age), C57BL/10 thymus NK1+CD44high4+8- T cells (88 days of age), and Stat6-null thymus CD44low4+8- T cells (43 days of age) were stimulated for 45 h as in Fig. 1. Activated cells were deposited one cell per Terasaki well and analyzed by RT-PCR for IL-4, V14-J281, and C expression. There were 12 or 2.0% (12 ÷ 600) IL-4 mRNA+ cells among a total of 600 C57BL/10 thymus NK1-CD44low4+8- T cells. For Stat6-null thymus, there were 11 or 1.8% (11 ÷ 600) IL-4 mRNA+ cells among a total of 600 single-cell assayed. There was one each V14-J281+ cells among the 11 C57BL/10 and 12 Stat6-null single T cells identified to be IL-4 mRNA+. Of the 12 IL-4 mRNA+ NK1+CD44high4+8- T cells analyzed, 10 or 83.3% (10 ÷ 12) expressed V14-J281. All analyzed single cells expressed C. Lane numbers of PCR products are as indicated.

View larger version (20K): [in this window] [in a new window]   FIGURE 6. IL-4 inducibility in mature HSAlow subset of thymus NK1-CD44low4+8- T cells. Mature (HSAlow) and immature (HSAhigh) subsets of NK1-CD44low4+8- T cells were obtained by electronic cell sorting of C57BL/10 CD8- thymocytes (32 days of age) that have been stained with FITC-anti-HSA (48 ), biotin-anti-CD8, biotin-anti-NK1, Cy5-anti-CD44, TR-anti-CD4, followed by detection of biotinyl groups with PE-streptavidin. Sorted cells were anti-CD3/CD28-stimulated (3 x 105 cells/ml) in cultures that were supplemented with IL-2 (0.5 ng/ml) to ensure growth/activation of immature HSAhigh cells. At 48 h poststimulation, relative IL-4 mRNA expression (A) and IL-4 bioactivity (B) were determined. Details of competitive RT-PCR determinations of ß-actin and IL-4 mRNA determinations were as described in Fig. 4. Relative IL-4/ß-actin mRNA ratios for 48-h activated NK1-CD44low4+8- T cells were: 0.663 for HSAlow subset, 0.0091 for HSAhigh subset, and 0.622 for total HSAall cells. Unstimulated control HSAall cells had an IL-4/ß-action mRNA ratio of 0.0072. IL-4 values from 48-h activated culture supernatant as determined by the CT.4S bioassay were: 99.2 U/ml for HSAlow subset, 3.7 U/ml for HSAhigh subset, and 79.1 U/ml for total HSAall cells. Data shown are typical of one of two independently performed experiment.

T cells were stimulated by plate-bound anti-CD3 + anti-CD28. Individual wells of 96-well culture plates (Nunc) were coated overnight with 50 µl of anti-CD3 (clone 500A.A2, Ref. 29) + anti-CD28 (clone 37.51, Ref. 30), each at 10 µg/ml in PBS. The indicated number of T cells was added per well in 0.1 ml of Mishell-Dutton medium (31) containing 5% FCS (HyClone, Logan, UT), 50 mM HEPES, and 5 x 10^-5 M 2-ME. Where indicated, rIL-2 (Biogen, Cambridge, MA; expressed in weight amounts equivalent to a reference standard provided by Dr. Craig Renolds, Biological Response Modifiers Program, National Cancer Institute, National Institutes of Health, Frederick, MD) was added at 0.5 ng/ml.

Purification and fluorochrome conjugation of mAbs

Purified mAbs were obtained from hybridoma culture supernatant by affinity chromatography. Columns containing Sepharose 4B beads conjugated with mouse anti-rat mAb (clone MAR18.5, Ref. 32) were used to purify 3.155, 2.43, and IM7 as previously described (24). Protein A-Sepharose columns were used to purify PK136 and 500A.A2 as previously described (24). Anti-CD28 mAb was similarly purified except that a polyvalent goat anti-hamster Ig-conjugated Sepharose 4B column was used. FITC conjugation was performed as previously described (33). Cy5 (Amersham, Buckinghamshire, U.K.) and TR (Molecular Probes, Eugene, OR) conjugations were performed according to manufacturer’s suggestions. Staining by all fluorochrome-conjugated Abs was specific because >98% of the observed fluorescence was inhibited by relevant unlabeled Ab but unaffected by irrelevant control Ab.

Cytokine bioassay

Culture supernatant from activated T cells was 2-fold serially titrated and assayed for IL-4 using the CT.4S indicator cells (34). One unit of IL-4 was defined as the amount that induced half maximal proliferation as assessed by [³H]thymidine incorporation of CT.4S indicator cells. Because all IL-4 bioassys were performed in microwells containing 0.1 ml of culture medium, 1 U of IL-4 under our assay condition is equivalent to 10 U/ml. The lower limit of detection was arbitrarily defined by 3 SD above the mean of [³H]thymidine incorporated by CT.4S cells cultured in medium alone. IL-4 detected by the CT.4S bioassay was verified by addition of 11B11 anti-IL-4 mAb (35) which blocked the activity to background levels. Using recombinant IL-4 (provided by Dr. William E. Paul) as a reference standard, 1 ng/ml of IL-4 was found to be equivalent to 2000 U/ml derived from the CT.4S assay as performed in our laboratory.

Cytokine quantitation by competitive RT-PCR

Expression of IL-2 and IL-4 mRNA was analyzed by competitive RT-PCR essentially as described (36), except that ß-actin was used as a control instead of hypoxanthine phosphoribosyltransferase. The ß-actin competitive DNA was constructed as follows. A 285-bp PFU (Stratagene, La Jolla, CA)-amplified PCR product (forward, 5'-AAGGTGTGATGGTGGGAATG-3' and reverse, 5'-ATGGCTACGTACATGGCTGG-3') was blunt-end cloned into HincII-digested pBlueScript II KS(+/-) (Stratagene). A 100-bp spacer DNA derived from an intron of mouse IL-12 p35 gene was cloned into the BglII site internal of the 285-bp actin fragment. Total RNA from indicated cells was extracted (Ultraspec RNA Isolation System; Biotecx, Houston, TX). Escherichia coli tRNA (Sigma, St. Louis, MO) was added at 3 µg/sample. RNA samples in 7 µl of diethyl pyrocarbonate water were denatured for 5 min at 65°C, quickly chilled on ice, and reverse transcribed into cDNA in a total volume of 21.5 µl reverse transcription (RT) buffer (50 mM Tris-HCl, pH 8.3, 75 mM KCl, and 3 mM MgCl₂) containing 100 U Moloney murine leukemia virus reverse transcriptase (Life Technologies, Gaithersburg, MD), 20 U RNasin (Promega, Madison, WI), 50 µg/ml random hexamer primers (Amersham Pharmacia, Uppsala, Sweden), 0.3 mM dNTP (Amersham Pharmacia), and 10 mM DTT. The reaction was stopped by incubation at 95°C for 5 min. Quantitation of mRNA expression was performed in a two-stage procedure. In the first stage, rough estimates of gene expression were determined using 10-fold serial titrating amounts of competitive DNA. Based on stage 1 results, competitive DNA was added in small increments to cDNA from a fixed number of activated T cells to determine equivalence points (36). The PCR was run for 35 cycles (94°C for 30 s, 56°C for 45 s, and 72°C for 40 s) and the products analyzed by 2% agarose gel electrophoresis. Primers for IL-4 were as previously described (36). Actin primers were as described above. The amount of competitive DNA at the equivalence point was arbitrarily normalized to the amount of wild-type mRNA of 500 activated T cells. Relative cytokine mRNA expression was then determined by taking the ratio of cell number-normalized cytokine equivalence to control ß-actin equivalence.

Single-cell RT-PCR

Using the automated cell deposition unit attachment of FACStar⁺ cell sorter (Becton Dickinson), activated T cells were deposited one cell into each Terasaki well (Robbins Scientific, Sunnyvale, CA) containing 4 µl of RT buffer (50 mM Tris-HCl, 75 mM KCl, 3 mM MgCl₂ (pH 8.3) containing 2% Triton X-100, 0.1 mg/ml BSA, 0.5 mM spermidine, 10 ng/µl oligo(dT_12–18) (Amersham Pharmacia), 0.5 mM dNTP, 0.8 U/µl RNasin, and 5 U/µl murine leukemia reverse transcriptase). Identical sources of dNTP, RNasin, and murine leukemia reverse transcriptase as described above were used. The RT reaction mixture was incubated for 90 min at 37°C and stored frozen at -70°C until PCR was performed. Nested IL-4 PCR was first started using the external primer set to amplify one-third cell equivalent of the RT reaction product. One-tenth of the first PCR product was subjected to a second PCR using internal primers. PCR products were analyzed by 2% agarose gel electrophoresis. Single cells that were identified to be IL-4 mRNA⁺ were subjected to analysis of V14-J281 and TCR -chain constant region (C) expression, also by nested PCR. Identical conditions (40 cycles at 94°C for 30 s, at 55°C for 60 s, and at 72°C for 90 s) were used for all nested PCR amplification. The nested PCR product sizes for IL-4, V14-J281, and C were 159, 173, and 289 bp, respectively, and the primer sequences were IL-4 external forward, 5'-CATCGGCATTTTGAACGAGGTCA-3' and IL-4 external reverse, 5'-CTTATCGATGAATCCAGGCATCG-3'; IL-4 internal forward, 5'-CCTCACAGCAACGAAGAAC-3' and IL-4 internal reverse, 5'-AAGCCCGAAAGAGTCTCTG-3'; V14-J281 external forward, 5'-GGTGGTTCAAACAGGACAC-3' and V14-J281 external reverse, 5'-GTTTTGTCAGTGATGAACGT-3'; V14-J281 internal forward, 5'-GTCAAATGGGAGATACTCAGC-3' and V14-J281 internal reverse, 5'-CAGGTATGACAATCAGCTGAGTCC-3'; C external forward, 5'-CAGAACCTGCTGTGTACCAG-3' and C external reverse, 5'-GATTCGGAGTCCCATAACTG-3'; C internal forward, 5'-CCCTCTGCCTGTTCACCGACTT-3' and C internal reverse, 5'-CGGAGTCCCATAACTGACAG-3'.

	Results and Discussion

Top Abstract Introduction Materials and Methods Results and Discussion References

 
Age-associated decline in IL-4 production by NK1^-CD4⁺8^- T cells from thymus

C57BL/10 NK1^-CD4⁺8^- thymus T cells were stimulated by plate-bound anti-CD3 + anti-CD28 mAb. Significantly more IL-4 was produced by NK1^-CD4⁺8^- thymocytes from young adolescent than older mice, displaying an inverse correlation for mice within the 25- to 50-day age window (Fig. 1A). For mice >50 days of age, IL-4 production was uniformly low. Consistent with already published results (21, 37, 38), an age-dependent increase in NK1⁺CD4⁺8^- T cells, expressed either as percentage of total CD4⁺8^- T cells (Fig. 1B) or as total cell number per thymus (Fig. 1C), was observed. Therefore, the age-dependent nature of IL-4 inducibility in NK1^-CD4⁺ T cells follows a pattern distinct and opposite that of NK1⁺CD4⁺ T cell development.

The nonobese diabetic (NOD) mouse develops insulin-dependent diabetes mellitus spontaneously. Although periinsulitis characterized by mononuclear cell infiltration is detectable as early as 3 wk of age, clinical diabetes marked by islet destruction does not develop until quite some time later and is most evident in 3- to 4-mo-old NOD mice (39). In view of our observed age-dependent decline of IL-4 production by thymus NK1^-CD4⁺ T cells in mice <50 days (or 7 wk) of age, and the protection of autoimmune diabetes by systemic IL-4 administration (40) or by pancreatic ß cell-specific IL-4 transgene expression (41), it is tempting to speculate that the failure of young adolescent NOD mice to develop clinical symptoms, despite periinsulitis, is due to the IL-4 production by recent thymic emigrants that have infiltrated the pancreas.

Heightened IL-4 production by CD4⁺8^- thymus T cells from Th2-prone BALB/c mice

For NK1^-CD4⁺8^- T cells to be considered as the source of IL-4 that directs Th2/Tc2 development, their IL-4-producing capacity might be expected to be significantly higher in the prototypic Th2-prone BALB/c mice than the Th1-prone C57BL/10 mice (reviewed in Ref. 42). Because PK136 anti-NK1.1 mAb does not detect NK1⁺ T cells in BALB/c mice and because virtually all NK1⁺CD4⁺ T cells are CD44^high (21), we used CD44^low4⁺8^- phenotype as the criteria for isolation of NK1^-CD4⁺-equivalent T cells. For mice under 2 mo of age, the average IL-4 production by BALB/c thymus CD44^lowCD4⁺ T cells was 1842 U/ml (n = 5; Fig. 2B), a value 9-fold higher than the 197 U/ml observed for their counterparts in C57BL/10 thymuses (n = 18; Fig. 2A). For mice >2 mo of age, IL-4 production by C57BL/10 and BALB/c thymus CD44^lowCD4⁺ T cells was 43 U/ml (n = 14) and 776 U/ml (n = 5), respectively (Fig. 2, A and B). Age-associated change indexed by (<2 mo) ÷ (> 2 mo) average IL-4 production values revealed a more significant decline factor of 4.6 for C57BL/10 than the 2.4 for BALB/c. Although the BALB/c genetic background may be intrinsically more resistant to an age-associated decline, the absorption/utilization of IL-4 by activated T cells can be expected to bias ratio determination of bioactivity in culture supernatant (production - consumption), especially for low IL-4-producing cells.

Our observation of heightened IL-4 production by BALB/c thymus CD44^low4⁺8^- T cells correlates well with elevated IL-4 production during the early phase (3–4 days) of Leishmania infection of nonhealing BALB/c but not healing C3H or B6 strains (43, 44), supporting a role for thymus NK1^-CD4⁺ T cells in the initiation of Th2 immune response.

TCR stimulation of <2 mo BALB/c spleen CD44^low4⁺8^- T cells resulted in IL-4 production that ranged from 62 to 524 U/ml, with an average value of 173 U/ml (Fig. 2D). IL-4 production by similarly stimulated C57BL/10 NK1^-CD44^low4⁺8^- T cells ranged from 10 to 20 U/ml with an average of 15 U/ml (Fig. 2C). Despite the generalized low IL-4 production levels by spleen CD4⁺ T cells, Th2-prone BALB/c spleen CD4⁺ T cells nevertheless produced on average >10-fold more IL-4 than their Th1-prone C57BL/10 counterparts. This relationship was not seen in mice >2 mo of age as uniformly low 24 U/ml of IL-4 production was observed for both BALB/c and C57BL/10 spleen CD4⁺ T cells (Fig. 2, C and D).

Because immune responses take place in specialized peripheral lymphoid compartments such as the spleen and not the thymus, it is difficult to explain our finding of much lower IL-4 production by spleen than thymus NK1^-CD4⁺8^- T cells if peripheral NK1^-CD4⁺ T cells indeed are the IL-4 source for Th2/Tc2 priming. On the other hand, although the amount of IL-4 produced by spleen NK1^-CD44^lowCD4⁺ T cells is rather low, it is nevertheless detectable, particularly in spleens of young BALB/c mice (Fig. 2D). The critical question is whether the relatively low level IL-4 production by spleen NK1^-CD44^lowCD4⁺ T cells we observed is sufficient to direct Th2/Tc2 development. Although our results do not address this question directly, understanding the nature of the depressed IL-4 inducibility by spleen NK1^-CD44^lowCD4⁺ T cells in comparison with their immediate thymic precursors may shed some light on this seeming paradox. First, it is possible that T cells possessing prompt IL-4 gene inducibility do not exit the thymus, implicating an intrathymic IL-4 role. If this were the case, one would expect to find IL-4 expression in freshly isolated thymus NK1^-CD4⁺ T cells. Because no IL-4 was detected in freshly isolated NK1.1^-CD44^lowCD4⁺ T cells (see Figs. 4 and 6), it appears unlikely that IL-4 plays an intrathymic role. This conclusion is also consistent with the reported normal intrathymic T cell development in IL-4-null mice (45). Alternatively, prompt IL-4 gene inducibility in thymus NK1^-CD44^lowCD4⁺ T cells is temporally expressed, due either to its developmental stage-specific nature or to the rapid death rate of cells that express this phenotype. Elegant work by Bendalac et al. (17) showed that IL-4-producing CD4⁺8^- thymocytes can and do leave the thymus, a process associated with a rapid loss of IL-4 inducibility. Although it is likely that a substantial fraction of recent thymic emigrants capable of IL-4 production are NK1⁺CD4⁺ T cells, this was not formally established because markers specific for NK1 CD4⁺ T cells were not used in the identification of recent thymic emigrants (17). Related to this was the finding of IL-4-producing cells among CD44^lowHSA^lowCD4⁺8^- thymocytes, although its frequency was 3-fold less than that of CD44^highHSA^lowCD4⁺8^- thymocytes (17). Because NK1 CD4 T cells are uniformly CD44^high (21) and Arase et al. (20) reported that all the IL-4-producing activity was found within the minor subset of NK1⁺CD4⁺8^- thymocytes, it is not clear as to why IL-4-producing cells were so readily identified for CD44^lowHSA^lowCD4⁺8^- thymocytes in the Bendelac report. One major difference between these reports was the age of the mice used. While Bendelac et al. used 5-wk-old mice, 10- to 13-wk-old mice were used for the Arase study. It is therefore possible that the IL-4-producing CD44^lowHSA^lowCD4⁺8^- thymocytes from 5-wk-old mice reported by Bendelac et al. contained a significant number of NK1^-CD4⁺ T cells, in addition to NK1 (CD44^high) CD4⁺ T cells. Indeed, this possibility is directly supported by our finding of age-associated decline in IL-4 inducibility among NK1^-CD4⁺8^- thymus T cells (Fig. 1A). Whether the previously demonstrated postthymic down-regulation of IL-4 inducibility (17) can also be applied to NK1^-CD4⁺ T cells in addition to the nonconventional CD1-restricted NK1 CD4⁺ T cells is now an open question.

Minimal V14-J281 TCR usage by IL-4-producing NK1^-CD4⁺ T cells

Because the pattern of age-dependent IL-4 inducibility in NK1^-CD4⁺ T cells is opposite that of NK1⁺CD4⁺ T cell development (Fig. 1), it is possible that NK1^-CD4⁺ T cells with the potential to make IL-4 are the direct precursors of NK1⁺CD4⁺ T cells and the age-dependent nature is simply a reflection of NK1^- NK1⁺ conversion. If this were the case, one would expect a strong bias toward invariant TCR V14-J281 chain usage, a known characteristic of NK1⁺CD4⁺ T cells (reviewed in Ref. 8). To address this possibility, CD44^low4⁺8^- T cells were stimulated by plate-bound anti-CD3/CD28. Day 2 activated single cells were subjected to RT-PCR analysis using IL-4, V14-J281, and C-specific primer sets. Of the 600 activated C57BL/10 NK1^-CD44^low4⁺8^- T cells analyzed, 11 (1.8%) expressed IL-4 mRNA. Of these 11 IL-4 producers, only one (9%) was V14-J281⁺, whereas all were positive for C mRNA (Fig. 3B). For activated BALB/c conventional CD44^low4⁺8^- thymocytes, a higher frequency of IL-4-producing cells (15 IL-4 producers or 8.3% of 180 analyzed single cells) was observed (Fig. 3A), consistent with the higher IL-4 production levels in bulk cultures reported in Fig. 2. Of the 15 BALB/c IL-4 producers, one (6.7%) was V14-J281⁺, whereas 15 of 15 (100%) were positive for C mRNA (Fig. 3B). Consistent with previously published results (8), 90% (9 of 10) IL-4-producing NK1⁺CD4⁺ T cells expressed V14-J281 mRNA, whereas all expressed C. Therefore, the vast majority of thymus NK1^-CD4⁺8^- T cells capable of producing IL-4 do not use V14-J281 and are therefore unrelated to the NK1⁺CD4⁺ T cell lineage.

Stat6-independent and prompt IL-4 production by thymus NK1^-CD4⁺8^- T cells

Two criteria expected of the IL-4 source for Th2/Tc2 priming response are 1) rapid production kinetics and 2) Stat6 independence (46, 47). The kinetics of IL-4 gene activation by NK1^-CD44^low4⁺CD8^- thymocytes was analyzed for Stat6-null and wild-type C57BL/10 control mice by competitive RT-PCR (Fig. 4A) and by CT.4S bioassay (Fig. 4B). Extremely rapid and similar induction patterns were observed for both C57BL/10 (wild-type) and Stat6-null NK1^-CD44^lowCD4⁺8^- thymocytes such that within 1 h of TCR stimulation, IL-4 mRNA induction reached 31-fold (0.373 ÷ 0.0121) for C57BL/10 and 33-fold (0.299 ÷ 0.0091) for Stat6-null cells. This rapid IL-4 gene induction kinetics for in vitro-activated NK1^-CD4⁺8^- T cells was similar to that of in vivo activated NK1 T cells (19) and qualifies thymus NK1^-CD4⁺8^- T cells as a potential source of IL-4 for Th2/Tc2 priming. IL-4 mRNA expression continued to increase after 1 h and peak induction levels of 82-fold (0.995 ÷ 0.0121) for C57BL/10 and 91-fold (0.829 ÷ 0.0091) for Stat6-null cells were similarly observed at 16 h poststimulation. IL-4 mRNA expression was clearly detectable for the entire 40-h observation period, although slightly lower induction levels (62-fold for C57BL10 and 68-fold for Stat6-null) were observed by the 40-h time point. Similar levels of IL-4 bioactivity were detected by 16 h after anti-TCR stimulation for both C57BL/10 and Stat6-null NK1^-CD44^low4⁺8^- thymocytes. Time-dependent and steadily increasing amounts of IL-4 bioactivity in culture supernatant is consistent with the finding of significant IL-4 mRNA induction levels at all time points studied during the entire 40-h observation period (Fig. 4A).

Our finding of much more rapid IL-4 production kinetics by in vitro-stimulated NK1^-CD44^low4⁺8^- thymus T cells than NK1 T cells (19) is most consistent with a lack of relatedness between these two types of IL-4-producing cells, a conclusion also supported by the infrequent TCR V14-J281 chain usage by IL-4-producing NK1^-CD4⁺ T cells (Fig. 3).

Minimal V14-J281 TCR usage by IL-4-producing Stat6-null thymus NK1^-CD4⁺ T cells

The nearly identical magnitude and kinetics of IL-4 gene activation for C57BL/10 and Stat6-null NK1^-CD44^low4⁺8^- T cells (Fig. 4) is suggestive of similar (non-V14-J281) TCR usage. However, it is nevertheless important to formally demonstrate the lack of V14-J281 usage by Stat6-null NK1^-CD44^low4⁺8^- T cells. To test this, Stat6-null NK1^-CD44^lowCD4⁺8^- thymocytes were compared against wild-type C57BL/10 thymocytes and V14-J281-biased NK1⁺CD4⁺ thymocytes (Fig. 5). Day 2 anti-CD3/CD28-activated single cells were subjected to RT-PCR analysis using IL-4, V14-J281, and C-specific primer sets. Of the 600 activated Stat6-null NK1^-CD44^lowCD4⁺8^- T cells analyzed, 11 (1.8%) expressed IL-4 mRNA. All of the 11 IL-4 producers expressed C mRNA, but only one (9%) was V14-J281⁺. Similar to results shown in Fig. 3, control C57BL/10 NK1^-CD44^lowCD4⁺8^- T cells contained 2.0% (12 positives of a total of 600 single cells analyzed) IL-4 mRNA⁺ cells. Although all 12 IL-4⁺ cells expressed C mRNA, only one (8.3%) used V14-J281. Consistent with previously published results (8) and results shown in Fig. 3, 83% (10 of 12) IL-4-producing NK1⁺CD4⁺ T cells expressed V14-J281 mRNA and were all C⁺. Because the vast majority (>90%) of IL-4-producing Stat6-null thymus NK1^-CD44^lowCD4⁺8^- T cells did not use V14-J281, they are unrelated to the typical V14-J281-biased lineage of NK1⁺CD4⁺ T cells.

IL-4 production by mature HSA^low subset of thymus NK1^-CD44^low4⁺8^- T cells

Because NK1^-CD44^lowCD4⁺8^- thymocytes contain a continuum of immature to mature T cells, IL-4-producing potential may be maturation stage specific. To address this possibility, NK1^-CD44^lowCD4⁺8^- T cells were separated into mature (HSA^low) and immature (HSA^high) subsets (48, 49) and examined for their abilities to produce IL-4 (Fig. 6). Because immature (HSA^high) thymus CD4⁺ T cells are known to be poor IL-2 producers (50), exogenous IL-2 was supplied to ensure T cell activation induced by anti-CD3/CD28 (51). Competitive RT-PCR (Fig. 6A) and bioassay (Fig. 6B) both showed IL-4 gene activation mainly within the mature (HSA^low) subset of thymus NK1^-CD44^lowCD4⁺8^- T cells, with minimal IL-4 induction in the HSA^high subset. The slight gain in IL-4 expression by HSA^low over HSA^all cells is consistent with a relatively low percentage (3.2%) of immature HSA^high cells among thymus NK1^-CD44^lowCD4⁺8^- T cells. Restriction of IL-4 inducibility to within HSA^low mature thymus CD4⁺ T cells, along with a relatively low frequency of IL-4-producing cells, raises an interesting possibility of a distinct NK1^-CD4⁺ T cell subset/lineage as the IL-4 source for Th2/Tc2 priming. It should be noted that the relatively low percentage of immature HSA^high cells in our preparation of thymus NK1^-CD44^lowCD4⁺8^- T cells appears to differ from the previously reported higher frequency of HSA^high cells among unfractionated thymus CD4⁺8^- T cells (49, 50). The most likely explanation for this apparent discrepancy is that our method of isolating thymus CD4⁺ T cells involved depletion of CD8⁺ cells on plates coated with 3.155 anti-CD8 mAb, a procedure that has been shown to deplete the immature (HSA^high) subset of thymus CD4⁺8^- T cells (51).

Taken together, the results presented here demonstrate the existence of NK1^-CD4⁺ T cells within the thymus capable of rapid and Stat6-independent IL-4 production. The more prominent IL-4 inducibility in young adolescent mice is consistent with the relative ease and frequent development of allergic symptoms in young children (52, 53). The heightened IL-4 inducibility in NK1^--equivalent BALB/c thymus CD4⁺ T cells correlates well with its Th2-prone nature and raises the possibility that genetically linked allergies may stem from prompt IL-4 release by recent thymic emigrant NK1^-CD4⁺ T cells. Furthermore, the likely potential for the IL-4-producing NK1^-CD4⁺ T cells to express a diverse TCR repertoire is also consistent with the widely varying structures of allergic substances.

	Acknowledgments

 
We thank Ya-Min Lin for performing sterile cell sorting. We also thank Cynthia Watson and Dr. William E. Paul for providing Stat6-null mouse breeders.

	Footnotes

 
¹ This work was supported by grants from the Academia Sinica and the National Science Council (NSC88-2311-B-001-112), Taiwan, Republic of China.

² Address correspondence and reprint requests to Dr. John T. Kung, Institute of Molecular Biology, Academia Sinica, Nankang 11529, Taiwan, Republic of China. E-mail address:

³ Abbreviations used in this paper: HSA, heat-stable Ag; TR, Texas Red; C, TCR -chain constant region; RT, reverse transcription.

Received for publication April 9, 1999. Accepted for publication August 16, 1999.

	References

Top Abstract Introduction Materials and Methods Results and Discussion References

 

1. Le Gros, G., S. Z. Ben-Sasson, R. Seder, F. D. Finkelman, W. E. Paul. 1990. Generation of interleukin 4 (IL-4)-producing cells in vivo and in vitro: IL-2 and IL-4 are required for in vitro generation of IL-4-producing cells. J. Exp. Med. 172:921.[Abstract/Free Full Text]
2. Swain, S. L., A. D. Weinberg, M. English, and G. Huston, G. 1990. IL-4 directs the development of Th2-like helper effectors. J. Immunol. 145:3796.
3. Erard, F., M. T. Wild, J. A. Garcia-Sanz, G. Le Gros. 1993. Switch of CD8 T cells to noncytolytic CD8^-CD4^- cells that make TH2 cytokines and help B cells. Science 260:1802.[Abstract/Free Full Text]
4. Paul, W. E., J. Ohara. 1987. B-cell stimulatory factor-1/interleukin 4. Annu. Rev. Immunol. 5:429.[Medline]
5. Ben-Sasson, S. Z., G. Le Gros, D. H. Conrad, F. D. Finkelman, W. E. Paul. 1990. Cross-linking Fc receptors stimulate splenic non-B, non-T cells to secrete interleukin 4 and other lymphokines. Proc. Natl. Acad. Sci. USA 87:1421.[Abstract/Free Full Text]
6. Seder, R. A., W. E. Paul, A. M. Dvorak, S. J. Sharkis, A. Kagey-Sobotka, Y. Niv, F. D. Finkelman, S. A. Barbieri, S. J. Galli, M. Plaut. 1991. Mouse splenic and bone marrow cell populations that express high-affinity Fc receptors and produce interleukin 4 are highly enriched in basophils. Proc. Natl. Acad. Sci. USA 88:2835.[Abstract/Free Full Text]
7. Sabin, E. A., M. A. Kopf, E. J. Pearce. 1996. Schistosoma mansoni egg-induced early IL-4 production is dependent upon IL-5 and eosinophils. J. Exp. Med. 184:1871.[Abstract/Free Full Text]
8. Bendelac, A., M. N. Rivera, S. H. Park, J. H. Roark. 1997. Mouse CD1-specific NK1 T cells: development, specificity, and function. Annu. Rev. Immunol. 15:535.[Medline]
9. Brown, D. R., D. J. Fowell, D. B. Corry, T. A. Wynn, N. H. Moskowitz, A. W. Cheever, R. M. Locksley, S. L. Reiner. 1996. ß₂-microglobulin-dependent NK1⁺ T cells are not essential for T helper cell 2 immune responses. J. Exp. Med. 184:1295.[Abstract/Free Full Text]
10. Guery, J. C., F. Galbiati, S. Smiroldo, L. Adorini. 1996. Selective development of T helper 2 cells induced by continuous administration of low dose soluble proteins to normal and ß₂-microglobulin-deficient BALB/c mice. J. Exp. Med. 183:485.[Abstract/Free Full Text]
11. Von der Weid, T., A. M. Beebe, D. C. Roopenian, R. L. Coffman. 1996. Early production of IL-4 and induction of Th2 responses in the lymph node originate from an MHC class I-independent CD4⁺NK1.1^- T cell population. J. Immunol. 157:4421.[Abstract]
12. Smiley, S. T., M. H. Kaplan, M. J. Grusby. 1997. Immunoglobulin E production in the absence of interleukin-4-secreting CD1-dependent cells. Science 275:977.[Abstract/Free Full Text]
13. Chen, Y. H., N. M. Chiu, M. Mandal, N. Wang, C. R. Wang. 1997. Impaired NK1⁺ T cell development and early IL-4 production in CD1-deficient mice. Immunity 6:459.[Medline]
14. Mendiratta, S. K., W. D. Martin, S. Hong, A. Boesteanu, S. Joyce, L. Van Kaer. 1997. CD1d1 mutant mice are deficient in natural T cells that promptly produce IL-4. Immunity 6:469.[Medline]
15. Bendelac, A., R. H. Schwartz. 1991. CD4⁺ and CD8⁺ T cells acquire specific lymphokine secretion potentials during thymic maturation. Nature 353:68.[Medline]
16. Adkins, B., K. Hamilton. 1992. Freshly isolated, murine neonatal T cells produce IL-4 in response to anti-CD3 stimulation. J. Immunol. 149:3448.[Abstract]
17. Bendelac, A., P. Matzinger, R. A. Seder, W. E. Paul, R. H. Schwartz. 1992. Activation events during thymic selection. J. Exp. Med. 175:731.[Abstract/Free Full Text]
18. Hayakawa, K., B. T. Lin, R. R. Hardy. 1992. Murine thymic CD4⁺ T cell subsets: a subset (Thy0) that secretes diverse cytokines and overexpresses the Vß8 T cell receptor gene family. J. Exp. Med. 176:269.[Abstract/Free Full Text]
19. Yoshimoto, T., W. E. Paul. 1994. CD4^pos, NK1.1^pos T cells promptly produce IL-4 in response to in vivo challenge with anti-CD3. J. Exp. Med. 179:1285.[Abstract/Free Full Text]
20. Arase, H., N. Arase, K. Nakagawa, R. A. Good, K. Onoe. 1993. NK1.1⁺ CD4⁺ CD8^- thymocytes with specific lymphokine secretion. Eur. J. Immunol. 23:307.[Medline]
21. Bendelac, A., N. Killeen, D. Littman, R. H. Schwartz. 1994. A subset of CD4⁺ thymocytes selected by MHC class I molecules. Science 263:1774.[Abstract/Free Full Text]
22. Sarzotti, M., D. S. Robbins, P. M. Hoffman. 1996. Induction of protective CTL responses in newborn mice by a murine retrovirus. Science 271:1726.[Abstract]
23. Forsthuber, T., H. C. Yip, P. V. Lehmann. 1996. Induction of TH1 and TH2 immunity in neonatal mice. Science 271:1728.[Abstract]
24. Fichtner, A. T., S. Anderson, M. G. Mage, S. O. Sharrow, III C. A. Thomas, J. T. Kung. 1987. Subpopulations of mouse Lyt-2⁺ T cells defined by the expression of an Ly-6-linked antigen, B4B2. J. Immunol. 138:2024.[Abstract]
25. Sarmiento, M., A. L. Glasebrook, F. W. Fitch. 1980. IgG or IgM monoclonal antibodies reactive with different determinants on the molecular complex bearing Lyt 2 antigen block T cell-mediated cytolysis in the absence of complement. J. Immunol. 125:2665.[Abstract]
26. Koo, G. C., J. R. Peppard. 1984. Establishment of monoclonal anti-Nk-1.1 antibody. Hybridoma 3:301.[Medline]
27. Dialynas, D. P., Z. S. Quan, K. A. Wall, A. Pierres, J. Quintans, M. R. Loken, M. Pierres, F. W. Fitch. 1983. Characterization of the murine T cell surface molecule, designated L3T4, identified by monoclonal antibody GK1.5: similarity of L3T4 to the human Leu-3/T4 molecule. J. Immunol. 131:2445.[Abstract]
28. Trowbridge, I. S., J. Lesley, R. Schulte, R. Hyman, J. Trotter. 1982. Biochemical characterization and cellular distribution of a polymorphic, murine cell-surface glycoprotein expressed on lymphoid tissues. Immunogenetics 15:299.[Medline]
29. Havran, W. L., M. Poenie, J. Kimura, R. Tsien, A. Weiss, J. P. Allison. 1987. Expression and function of the CD3-antigen receptor on murine CD4⁺8⁺ thymocytes. Nature 330:170.[Medline]
30. Gross, J. A., E. Callas, J. P. Allison. 1992. Identification and distribution of the costimulatory receptor CD28 in the mouse. J. Immunol. 149:380.[Abstract]
31. Mishell, R. I., R. W. Dutton. 1967. Immunization of dissociated spleen cell cultures from normal mice. J. Exp. Med. 126:423.[Abstract]
32. Lanier, L. L., G. A. Gutman, D. E. Lewis, S. T. Griswold, N. L. Warner. 1982. Monoclonal antibodies against rat immunoglobulin chains. Hybridoma 1:125.[Medline]
33. Kung, J. T., S. O. Sharrow, A. Ahmed, R. Habbersett, I. Scher, W. E. Paul. 1982. B lymphocyte subpopulation defined by a rat monoclonal antibody, 14G8. J. Immunol. 128:2049.[Abstract]
34. Hu-Li, J., J. Ohara, C. Watson, W. Tsang, W. E. Paul. 1989. Derivation of a T cell line that is highly responsive to IL-4 and IL-2 (CT.4R) and of an IL-2 hyporesponsive mutant of that line (CT.4S). J. Immunol. 142:800.[Abstract]
35. Ohara, J., W. E. Paul. 1985. Production of a monoclonal antibody to and molecular characterization of B-cell stimulatory factor-1. Nature 315:333.[Medline]
36. Renier, S. L., S. Zheng, D. B. Corry, R. M. Locksley. 1993. Constructing polycompetitor cDNAs for quantitative PCR. J. Immunol. Met. 165:37.[Medline]
37. Ohteki, T., and H. R. MacDonald, H. R. 1994. Major histocompatibility complex class I related molecules control the development of CD4⁺8^- and CD4^-8^- subsets of natural killer 1.1⁺ T cell receptor-/ß⁺ cells in the liver of mice. J. Exp. Med. 180:699.
38. Fowlkes, B. J., A. M. Kruisbeek, H. Ton-That, M. A. Weston, J. E. Coligan, R. H. Schwartz, D. M. Pardoll. 1987. A novel population of T-cell receptor ß-bearing thymocytes which predominantly expresses a single Vß gene family. Nature 329:251.[Medline]
39. Bach, J. F.. 1994. Insulin-dependent diabetes mellitus as an autoimmune disease. Endocr. Rev. 15:516.[Abstract]
40. Rapoport, M. J., A. Jaramillo, D. Zipris, A. H. Lazarus, D. V. Serreze, E. H. Leiter, P. Cyopick, J. S. Danska, T. L. Delovitch. 1993. Interleukin 4 reverses T cell proliferative unresponsiveness and prevents the onset of diabetes in nonobese diabetic mice. J. Exp. Med. 178:87.[Abstract/Free Full Text]
41. Mueller, R., T. Krahl, N. Sarvetnick. 1996. Pancreatic expression of interleukin-4 abrogates insulitis and autoimmune diabetes in nonobese diabetic (NOD) mice. J. Exp. Med. 184:1093.[Abstract/Free Full Text]
42. Reiner, S. L., R. M. Locksley. 1995. The regulation of immunity to Leishmania major. Annu. Rev. Immunol. 13:151.[Medline]
43. Reiner, S. L., S. Zheng, Z. E. Wang, L. Stowring, R. M. Locksley. 1994. Leishmania promastigotes evade interleukin 12 (IL-12) induction by macrophages and stimulate a broad range of cytokines from CD4⁺ T cells during initiation of infection. J. Exp. Med. 179:447.[Abstract/Free Full Text]
44. Scott, P.. 1991. IFN- modulates the early development of Th1 and Th2 responses in a murine model of cutaneous leishmaniasis. J. Immunol. 147:3149.[Abstract]
45. Kuhn, R., K. Rajewsky, W. Muller. 1991. Generation and analysis of interleukin-4 deficient mice. Science 254:707.[Abstract/Free Full Text]
46. Kaplan, M. H., U. Schindler, S. T. Smiley, M. J. Grusby. 1996. Stat6 is required for mediating responses to IL-4 and for the development of Th2 cells. Immunity 4:313.[Medline]
47. Shimoda, K., J. van Deursen, M. Y. Sangster, S. R. Sarawar, R. T. Carson, R. A. Tripp, C. Chu, F. W. Quelle, T. Nosaka, D. A. Vignali, et al 1996. Lack of IL-4-induced Th2 response and IgE class switching in mice with disrupted Stat6 gene. Nature 380:630.[Medline]
48. Bruce, J., F. W. Symington, T. J. McKearn, J. Sprent. 1981. A monoclonal antibody discriminating between subsets of T and B cells. J. Immunol. 127:2496.[Abstract]
49. Crispe, I. N., M. J. Bevan. 1987. Expression and functional significance of the J11d marker on mouse thymocytes. J. Immunol. 138:2013.[Abstract]
50. Ramsdell, F., M. Jenkins, Q. Dinh, B. J. Fowlkes. 1991. The majority of CD4⁺8^- thymocytes are functionally immature. J. Immunol. 147:1779.[Abstract]
51. Nikolic-Zugic, J., M. J. Bevan. 1990. Functional and phenotypic delineation of two subsets of CD4 single positive cells in the thymus. Int. Immunol. 2:135.[Abstract/Free Full Text]
52. Marsh, D. G., W. B. Bias. 1988. The genetics of atopic allergy. ed. In Immunological Diseases Vol. 2:1027. Little Brown, Boston.
53. Barbee, R. A., M. Halonen, M. Lebowitz, B. B. Burrows. 1981. Distribution of IgE in a community population sample: correlations with age, sex, and allergen skin test reactivity. J. Allergy Clin. Immunol. 68:106.[Medline]

This article has been cited by other articles:

				Y.-T. Chen and J. T. Kung CD1d-Independent Developmental Acquisition of Prompt IL-4 Gene Inducibility in Thymus CD161(NK1)-CD44lowCD4+CD8- T Cells Is Associated with Complementarity Determining Region 3-Diverse and Biased V{beta}2/V{beta}7/V{beta}8/V{alpha}3.2 T Cell Receptor Usage J. Immunol., November 15, 2005; 175(10): 6537 - 6550. [Abstract] [Full Text] [PDF]

				M. Koyanagi, K.'i. Imanishi, Y. Arimura, H. Kato, J. Yagi, and T. Uchiyama Immunologic immaturity, but high IL-4 productivity, of murine neonatal thymic CD4 single-positive T cells in the last stage of maturation Int. Immunol., February 1, 2004; 16(2): 315 - 326. [Abstract] [Full Text] [PDF]

				L.-R. Huang, F.-L. Chen, Y.-T. Chen, Y.-M. Lin, and J. T. Kung Potent induction of long-term CD8+ T cell memory by short-term IL-4 exposure during T cell receptor stimulation PNAS, March 28, 2000; 97(7): 3406 - 3411. [Abstract] [Full Text] [PDF]

This Article Abstract Full Text (PDF) Alert me when this article is cited Alert me if a correction is posted Citation Map Services Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Citing Articles Citing Articles via HighWire Citing Articles via Google Scholar Google Scholar Articles by Chen, Y.-T. Articles by Kung, J. T. Search for Related Content PubMed PubMed Citation Articles by Chen, Y.-T. Articles by Kung, J. T.