Because N2 is expressed together with N1 on HSCs (Fig. 1 D), it is conceivable that N2 is able to compensate for the loss of N1 function during T lineage commitment when N1^–/– HSCs are cultured on DL1-expressing OP9 cells. To test this hypothesis, we sorted and cultured N2^–/– and N1N2^–/– HSCs on DL1-expressing OP9 cells. After 10 d of OP9-DL1 culture, N2^–/– HSCs gave rise to immature DN1–3 T cell progenitors similar to Ctrl and N1^–/– HSCs (Fig. 1 B). In contrast, N1N2^–/– HSCs do not develop into T cell progenitors; instead, they exhibit a developmental block at the putative DN1 stage characterized by the accumulation of CD44⁺CD25^– cells. This phenotype is very reminiscent of the defect observed in vivo in inducible N1^–/– mice, where CD44⁺CD25^– cells accumulated in the thymus and were identified as B220⁺CD19⁺ B cells (Fig. 1 A) (8). Therefore, Ctrl, N1^–/–, N2^–/–, and N1N2^–/– HSCs were assessed for their ability to develop into B cells on OP9-DL1–expressing stromal cells. Only HSCs derived from N1N2^–/– HSCs developed into B cells after 18 d of culture, whereas Ctrl, N1^–/–, or N2^–/– cells did not. These data confirm the hypothesis that DL1-mediated N2 signaling can compensate for the loss of N1 function during T lineage commitment in vitro and that the presence of either N1 or N2 alone is sufficient to block B cell development.

N2 cannot compensate for the loss of N1 function during T cell maturation
Notch signaling is not only essential for T lineage commitment but is also continuously required for the successful differentiation of all DN thymocyte subsets into CD4⁺CD8⁺ DP cells (14). Because N2 can instruct N1^–/– HSCs to adopt a T cell fate on OP9-DL1–expressing stromal cells, it is conceivable that N2 signaling would be sufficient to allow the subsequent DN to DP transition. To this end, Ctrl and N1^–/– HSCs were cultured for 28 d on OP9-DL1 stromal cells and subsequently analyzed for the development of DP T cells. Although Ctrl HSCs differentiated very efficiently into DP T cells, >90% of the N1^–/– cells appeared to be blocked in the DN compartment (Fig. 2 A).

View larger version (65K): [in this window] [in a new window] [Download PPT slide]   Figure 2. N2 cannot compensate for the loss of N1 function during T cell maturation in vitro. (A) KLS cells from Ctrl and induced N1–/– mice were sorted and cultured on OP-DL1 cells for 20 d. A representative flow cytometric analysis of CD4 versus CD8 of WT thymocytes, and Ctrl and N1–/– KLS cells cultured on OP9-DL1 are shown. (B) Indicated cells were electronically gated on lineage-negative DN thymocytes and analyzed for the expression of CD44 and CD25. Representative histograms for intracellular TCRß (iTCRß) expression on DN3 and DN4 thymocytes derived from Ctrl and N1–/– KLS cells 20 d after culture on OP9-DL1 are shown. The numbers above the bars indicate the percentage ± SD of iTCRß+ cells (n = 4 for WT thymocytes and in vitro culture experiments).

N2 mediates T lineage commitment in vivo in the absence of N1 signaling at extrathymic sites after BM transplantation
Although N1 is the key receptor for T lineage commitment in the thymus, our in vitro data raise the possibility that, under certain conditions (when encountering the DL1 ligand), the N2 receptor might be able to induce T lineage commitment at extrathymic sites in vivo.

Recent studies by Maillard et al. (31), Lancrin et al. (32), and Arcangeli et al. (33) showed that early T cell development occurs in the spleen and LNs after BM transplantation. This pool of splenic T cell progenitors can efficiently contribute to donor-derived thymopoiesis by migrating from the spleen to the thymus (31), where they complete T cell maturation. The generation of these splenic T cell progenitors after BM transplantation is Notch signaling dependent (31), because it is blocked by the expression of a dominant-negative form of the Notch coactivator mastermind-like 1 (31). However, it is not clear whether these extrathymically derived T cell progenitors are generated in a N1- and/or N2-dependent manner. To address this question, we transplanted CD45.2⁺ Ctrl, N1^–/–, N2^–/–, and N1N2^–/– BM cells into lethally irradiated CD45.1⁺ C57BL/6 recipients. Donor-derived lin^– cells in the spleen were analyzed 12 d after BM transplantation by staining for Thy1.2, CD44, and CD25. As previously reported, Thy1.2 and CD44 staining identified two populations within the lin^– donor-derived cells in mice receiving Ctrl BM cells (32, 33). The CD44⁺Thy1.2^– population has previously been shown to have multilineage potential, whereas the CD44^lo/–Thy1.2⁺ population is T lineage restricted (Fig. 3) (33). The Thy1.2⁺ cells appear to be heterogeneous for the expression of CD25, as 50% express this marker, which normally defines the DN2 and DN3 subsets of immature thymocytes. A similar population of splenic Thy1.2⁺ T cell progenitors was identified in hosts receiving Ctrl, N1^–/–, and N2^–/– BM. In contrast, no Thy1.2⁺ cells were observed in the lin^– donor-derived population of hosts receiving N1N2^–/– BM (Fig. 3). These results demonstrate that splenic T cell progenitors can be generated in the absence of N1 after BM transplantation in a N2-dependent manner. Thus, either N2 or N1 signaling is sufficient for T lineage commitment in the spleen after BM transplantation.

View larger version (54K): [in this window] [in a new window] [Download PPT slide]   Figure 3. N2 is sufficient to specify T lineage progenitors in the spleen after BM transplantation. CD45.2+ Ctrl, N1–/–, N2–/–, or N1N2–/– BM cells were injected into lethally irradiated CD45.1+ hosts. The spleens of host mice were analyzed 12 d after BM transplantation. Representative flow cytometric analyses of donor-derived lineage-negative cells for the expression of CD44 and Thy1.2, and Thy1.2 and CD25, respectively, are shown. Data are representative of four independent experiments.

View larger version (41K): [in this window] [in a new window] [Download PPT slide]   Figure 4. Expression of N1 and N2 in immature DN thymocytes. cDNA was prepared from sorted cells cultured on OP9-DL1 cells for 16 d (corresponding to the DN1–4 subsets), and WT DN1–4 thymocyte subsets. Transcripts of N1 and N2 were analyzed by semiquantitative RT-PCR of threefold dilutions of the cDNA. The cDNA input was normalized according to the expression of the control tubulin gene.

View larger version (64K): [in this window] [in a new window] [Download PPT slide]   Figure 5. Comparison of DL1- and DL4-mediated T cell development in vitro. (A) Histograms show flow cytometric analyses of GFP expression of uninfected OP9-cells (dashed line) and DL1 (shaded histogram) and DL4 (continuous line) retrovirally transduced OP9 cells. Ctrl BM HSCs were sorted and cultured side by side on OP9-DL1 and -DL4 cells and anaylzed by flow cytometry for the expression of CD4 and CD8 30 d after culture. (B) Sorted BM HSCs derived from either Ctrl, N1–/–, or N2–/– mice were cultured for the indicated times on either OP9-DL1 or -DL4 cells and subsequently analyzed by flow cytometry for the expression of CD44 and CD25 (electronically gated on lineage-negative cells) and the presence of B220+CD19+ B cells. Data are representative of four independent experiments.

View larger version (56K): [in this window] [in a new window] [Download PPT slide]   Figure 6. Binding of purified DL1- and DL4-IgG fusion proteins to thymocytes. (A) DL1- (lanes 1 and 3) and DL4-IgG fusion proteins (lanes 2 and 4) before (lanes 1 and 2) and after (lanes 3 and 4) purification over a protein A column were stained with Coommassie blue (left). A Western blot analysis of DL1- (lane 5) and DL4-IgG (lane 6) fusion proteins using an anti–human IgG–horseradish peroxidase–conjugated antibody is also shown (right). (B) The purified DL1- and DL4-IgG fusion proteins were used to stain immature WT thymocytes. Thymocytes were stained with lineage cocktail and anti-CD117, -CD44, and -CD25 antibodies together with DL1- or DL4-IgG fusion proteins. Representative histograms show the staining of DL1- (gray line) and DL4-IgG (bold line) fusion proteins or IgG isotype control (continuous line) gated on the DN1 (CD117+CD44+CD25–), DN2 (CD117+CD44+CD25+), DN3 (CD44–CD25+), and DN4 (CD44–CD25–) thymocyte subpopulations. (C) Representative histograms showing staining of DL1- (gray line) and DL4-IgG (bold line) fusion proteins gated on ISP (CD8+TCRß–), DP (CD4+CD8+), CD4SP (CD4+TCRß+), and CD8SP (CD8+TCRß+) thymocytes. In the more mature thymocyte subsets (ISP, DP, and SP), DL1-IgG staining was indistinguishable from the IgG isotype control, which is therefore not shown in C. Data are representative of four independent experiments, and numbers within the histograms indicate means ± SD of the mean fluorescence intensity for DL4. (D) Semiquantitative RT-PCR for the Notch target genes Deltex1 and Hes1. cDNA was prepared from DN thymocytes, either cultured for 20 h on IgG-, (DL1-IgG) DL1-Fc–, and DL4-Fc–coated plastic dishes or on OP9-DL1 or -DL4 cells. Transcripts of Deltex1 and Hes1 were analyzed by semiquantitative RT-PCR of threefold dilutions of the cDNA. The cDNA input was normalized according to the expression of the control HPRT gene.

Because the binding assays were performed with WT thymocytes, we were unable to distinguish binding of DL4-IgG to the N1 and/or N2 receptor. Our results presented in Fig. 5 show that DL4, in contrast to DL1, cannot induce T lineage commitment via N2. This result is compatible with two hypotheses: either DL4 cannot bind efficiently to N2 or, alternatively, DL4 can bind N2 but cannot transmit a signal via the N2 receptor. To distinguish between these two possibilities, we examined the binding efficiency of DL1- and DL4-IgG fusion proteins to 293T cells transiently expressing either N1- or N2–enhanced GFP (EGFP) fusion proteins. As shown in Fig. 7 (B and C, top), DL4-IgG fusion proteins bind N1 very efficiently, whereas binding to the N2 receptor is not detectable above background. Interestingly, DL1-IgG fusion proteins bind N1 weakly but do not bind N2 above levels of the IgG isotype control.

View larger version (41K): [in this window] [in a new window] [Download PPT slide]   Figure 7. Binding of DL1- and DL4-IgG fusion proteins to N1 and N2. (A) Semiquantitative RT-PCR for the Lfng gene. cDNAs were prepared from DN thymocytes and 293T cells. Transcripts were analyzed by semiquantitative RT-PCR of fivefold dilutions of the cDNA. The cDNA input was normalized according to the expression of the control HPRT gene. 293T cells were transiently transfected with N1- (B) or N2-EGFP (C) together with or without Lfng expression vectors and stained 48 h after transfection with either human IgG1 isotype control or DL1- or DL4-IgG fusion proteins. Data are representative FACS profiles of four independent experiments. Extremely high EGFP-expressing cells were gated out as the fusion proteins were trapped inside the cells.

Enforced expression of DL4 but not DL1 induces efficient T cell development in vivo
In vitro, DL4 is unable to induce T lineage commitment in the absence of a functional N1 receptor, suggesting that DL4 must specifically interact with N1 to specify the T lineage. To exclude that this observation is caused by a peculiarity of our in vitro culture system, we investigated the ability of DL1 and DL4 to induce T cell development in vivo in the presence and absence of N1. Previous studies demonstrated that retroviral overexpression of DL4 in hematopoietic cells is sufficient to promote thymus-independent T cell development to the DP stage in vivo (13, 23, 24). We therefore transduced CD45.2⁺ Ctrl and N1^–/– BM cells with a retrovirus expressing either GFP alone (MIG), or DL1 or DL4 together with GFP, and subsequently transplanted these cells into lethally irradiated CD45.1⁺ C57BL/6 mice. The BM transduction efficiency of MIG and MIG expressing either DL1 or DL4 virus (based on GFP expression) was between 55 and 60% for both Ctrl and N1^–/– BM cells (Fig. 8 A). Reconstituted hosts were analyzed 9 wk after transplantation for the presence of GFP⁺ donor-derived cells in PBLs. 72% of Ctrl PBLs and 64% of N1^–/– PBLs in host mice that were transplanted with MIG-transduced BM cells were GFP⁺. Comparable percentages of PBLs were GFP⁺ in hosts receiving either DL1- or DL4-expressing Ctrl and N1^–/– BM cells, indicating that the relative number of virus-expressing Ctrl and N1^–/– donor cells was comparable even 9 wk after transplantation (Fig. 8 B, right). Only forced expression of DL4 but not DL1 resulted in the efficient development of DP T cells (Fig. 8, B–D). DL4-induced DP T cells were exclusively found in the PBLs (13%), BM (86%), and spleen (48%) of Ctrl but not of N1^–/– chimeras, suggesting that enforced DL4 expression can only induce T cell development of N1-expressing progenitors in vivo. These results confirm our in vitro results using the DL4-expressing OP9 cells.

View larger version (51K): [in this window] [in a new window] [Download PPT slide]   Figure 8. Comparative in vivo analysis of DL1 and DL4 for their ability to promote ectopic T cell development. (A) Bar diagrams show percentages of GFP+ Ctrl and N1–/– BM cells after transduction with the control virus (MIG) and virus expressing DL1 and DL4. (B) Histograms show the percentage of GFP+ cells within total PBLs in host mice 9 wk after BM transplantation. Flow cytometric analysis for the presence of CD4- and CD8-expressing T cells was performed on PBLs (B) and BM and spleen (C) of host animals that were transplanted with WT and N1–/– BM cells expressing the indicated ligands.

	DISCUSSION

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Notch–Delta interactions are not only required for T cell lineage commitment but also for further maturation of DN CD25⁺ immature thymocytes to the DP stage both in vivo (25) and in vitro (14). A critical aspect of this maturation process is productive VDJ rearrangement of the TCRß locus, leading to expression of a TCRß protein and functional pre-TCR. In the OP9 system, it is known that both DL1 and DL4 can promote TCRß rearrangement and progression to the DP stage when WT BM precursors are plated (18). However, DL1 was unable to promote the further maturation of DN CD25⁺ precursors that had developed via N2 (i.e., in the absence of N1). Furthermore, this defect in the generation of DP thymocytes was accompanied by a failure to express TCRß protein in DN CD25⁺ cells. Collectively, these data indicate that N2–DL1 interactions, though sufficient to promote T cell lineage commitment in vitro, are unable to induce subsequent T cell maturation. Thus, it is possible that N2–DL1 interactions in the OP9 system are of lower avidity than N1–DL1 and, especially, N1–DL4 interactions, as further suggested by direct binding assays of DL1 and DL4 fusion proteins on N1- or N2-transfected 293T cells. Nevertheless, N2–DL1 interactions are readily detected in the presence of high levels of Lfng in transfected 293T cells, raising the possibility that the failure of N2–DL1 to induce T cell maturation in vitro could be explained by limiting concentrations of Lfng in thymic progenitors. Alternatively, N2 may signal less efficiently than N1 because of its weaker transactivation domain (4).

An even more stringent requirement for Notch–Delta interactions in T cell maturation was observed in an in vivo model where DL1 and DL4 were retrovirally transduced in WT and N1^–/– BM precursors that were subsequently used to reconstitute lethally irradiated hosts. In agreement with several other reports (13, 23, 24), large numbers of DP cells developed after 9 wk in the BM, spleen, and PBLs of mice reconstituted with DL4-expressing WT BM precursors. In contrast, DL1-expressing WT BM precursors did not generate detectable numbers of DP cells. Importantly, DL4-induced generation of DP cells was totally dependent on N1, because it did not occur when reconstitution was performed with DL4-transduced N1^–/– BM precursors. These results point to a highly specific N1–DL4 interaction as being essential for extrathymic T cell maturation to the DP stage in vivo when Delta expression is restricted to hematopoietic cells. The unique N1–DL4 specificity in this system could be related to the fact that the N1–DL4 interaction is less dependent on Lfng than other Notch–Delta interactions. According to this scenario, putative low levels of Lfng in HSCs could restrict their ability to undergo T cell maturation in the BM unless they encounter DL4 on hematopoietic cells. This stringent requirement may be overcome in the OP9-DL1 system, where high levels of expression of DL1 and/or other co-stimulatory properties of OP9 stromal cells may compensate for the putatively weaker N1–DL1 interaction.

The hierarchal nature of Notch–Delta interactions in immature thymocytes raises the important issue of whether high avidity Notch–Delta binding correlates with Notch signaling. In this respect, analysis of Notch target genes in DN thymocytes stimulated by DL1 or DL4 (expressed on OP9 cells or immobilized on plastic) revealed a considerably better induction of Deltex1 by DL4, consistent with the hierarchy of ligand binding. However, induction of Hes1 in DN thymocytes by DL1 and DL4 was comparable. Collectively, these data favor a scenario in which differences in Notch–Delta binding avidity translate into differences in some Notch signaling outcomes but not in others, presumably because activation of downstream Notch signaling pathways is hierarchal in nature. According to this model, the ability of N1–DL1 interactions to drive T cell lineage commitment and maturation on OP9 cells in vitro would reflect a low-threshold Notch signaling requirement.

Finally, it is worth noting that the hierarchy of Notch–Delta interactions described in this study has potential implications for T cell lineage commitment and maturation under physiological conditions in the thymus. In this context, it is of particular interest that N2 is capable of promoting T cell commitment via interaction with DL1 (but not DL4) both on OP9 stromal cells and during extrathymic T cell development in the spleen. This raises the obvious question of why N2 cannot compensate for N1 during T cell lineage commitment in the thymus. Because N2 is expressed on HSCs and early intrathymic T cell precursors, one possible explanation for the inability of N2 to support T cell commitment would be that DL1 is not present or available in the thymus. Because N2 cannot promote T cell commitment via DL4 even in the sensitive OP9 stromal system, it is unlikely that N2–DL4 interactions would induce T cell development in vivo. This scenario would therefore imply that DL4 is in fact the physiological ligand for N1 during intrathymic T cell development and, more generally, that tissue-specific compartmentalization of Delta family members is a mechanism to assure Notch receptor–ligand specificity in cell fate determination.

A second aspect of hierarchal Notch–Delta interactions that is relevant to the identification of the physiological ligand of N1 during thymus development is the unique ability of DL4 to specifically bind to immature thymocytes with apparent high avidity. Conditional inactivation of N1 in BM precursors (8, 9) and at early stages of intrathymic development (25) has clearly demonstrated that signaling via N1 is required in immature DN thymocytes until they have completed VDJß rearrangement at the CD25⁺ DN3 stage, whereas later N1 inactivation (from the DN4 stage onwards) has no impact on subsequent thymus development (36). Interestingly, binding of DL4 by N1 in thymus subsets closely parallels this functional requirement, because DL4 binding is high from the DN1 to DN3 stages and declines in DN4 to become undetectable in subsequent DP and SP stages. This result is again consistent with the hypothesis that DL4 is the physiological N1 ligand responsible for both T cell lineage commitment and subsequent thymic maturation. Moreover, the strict correlation between N1–DL4 binding and N1 function during this process further suggests that N1 signaling on developing thymocytes is regulated at the level of ligand binding. Because N1–DL4 binding activity appears to be relatively independent of Lfng (at least in transfected 293T cells), it could be speculated that N1 function during thymic maturation is largely controlled at the level of N1 expression.

Expression studies of DL1 and DL4 in the thymus, though not definitive, also favor the hypothesis that DL4 may be the physiological N1 ligand for T-lineage commitment and maturation. Thus, semiquantative PCR analysis indicates that DL4 is more strongly expressed than DL1 in the embryonic (18) as well as adult (15, 30) thymus epithelium. More convincingly, in situ hybridization studies, as well as lacZ gene–targeted (knock-in) reporter mice demonstrated clearly that DL4 is expressed at relatively high levels in situ in both embryonic and adult thymus (13, 16, 17), whereas DL1 expression is barely or not detectable (unpublished data) (16, 37). At the protein level, one group has reported broad expression of DL1 in the adult thymus (14); however, the specificity of the polyclonal anti-DL1 antibody used in that study has been challenged (15). Collectively, these data are consistent with the possibility that DL4 rather than DL1 is the physiological thymic ligand for N1. Indeed, conditional inactivation of DL1 in the thymic epithelium does not impair T cell development (30). Nevertheless, it remains possible that DL1 and DL4 function redundantly in N1-mediated T cell lineage commitment. Conditional gene targeting of DL4 will be required to definitively resolve this important issue.

	MATERIALS AND METHODS

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Mice and induction of the Cre-mediated inativation of the floxed N1 and N2 genes.
Experiments were performed according to Swiss guidelines and authorized by the veterinary authorities of the Canton de Vaud (authorization nos. 1099.2 and 1099.3). CD45.1⁺ C57BL/6 mice were purchased from the Jackson Laboratory. N1^{lox/lox&Mx-Cre} mice were generated as previously described (8). For N2^lox/lox mice, the generation of the N2 targeting vector was based on a genomic DNA fragment including the exons b to h and the 5' part of exon i (according to the nomenclature previously described [38]) from the mouse N2 locus. Exons d and e (coding for the C-terminal part of the RAM23 domain and nuclear localization sequence) were flanked by loxP sites. Cre recombinase–mediated N2 inactivation results in the expression of a truncated N2 protein, lacking the intracellular part. The generated mice carrying the loxP-targeted exons d and e are referred to here as the floxed N2 allele (N2^lox).

Generation of the N2 targeting vector and targeting of embryonic stem (ES) cells.
Construction of the targeting vector based on the genomic N2 phage DNA clone 1NT2-2 (provided by Y. Hamada, National Institute of Basic Biology, Okazaki, Japan) containing the distal exons a to i (exon c turned out to consist of two small neighboring exons, designated by us as c1 and c2). A 9.5-kb SphI fragment from 1NT2-2 encompassing N2 exons b to h and the 5' part from exon i was subcloned into the backbone vector pHEBOpl-mod, which was previously created from the plasmid pHEBO (39) by replacement of a 630-bp ClaI/SalI fragment with a polylinker sequence and subsequent deletion of a 2.9-kb MluI fragment. Within the genomic N2 SphI fragment, insertions were made at three positions: (a) at the BsrBI site between exons c2 and d, a loxP-flanked neomycin resistance gene cassette (NeoR) from pEasyFlox (provided by Marat Alimzhanov, Harvard Medical School, Boston, MA; unpublished data; reference 40) containing an additional SacI/SstI recognition site between the 5' loxP site and NeoR was inserted; (b) at the XhoI site between exons e and f, a loxP sequence with a SacI/SstI recognition site at its 3' end was inserted; and (c) a thymidine-kinase expression cassette (XhoI/PvuI fragment from pEasyFlox) was cloned into the SphI site at the 3' end of the genomic N2 sequence (within exon i).

The final targeting vector pU1496-21 was sequenced, linearized by NotI, and electroporated into BALB/c-derived ES cells. G418-resistant and ganciclovir-sensitive colonies were screened for homologous recombination by Southern blot analysis. The cellular DNA was digested with SstI (a SacI isoschizomer) and hybridized with a specific N2 probe (a 490-bp SacI/SphI fragment located just upstream of the 5' end of the genomic N2 sequence in the targeting vector). The WT N2 and the targeted N2 alleles were identified as 7.2- and 2.9-kb fragments, respectively. Clones with homologous recombination were further confirmed by hybridization with an internal probe (NeoR) and a 3' external probe (271-bp SphI/SacI fragment from exon i). Of 768 analyzed ES cell clones, four exhibited correct recombination with the targeting vector.

In one correctly targeted ES cell clone (1G10), the loxP-flanked NeoR was deleted in vitro by transfection with the cre expression vector pIC-cre (41). The resulting single-cell clones were screened for correct deletion of the NeoR cassette by Southern blotting, as decribed in the previous paragraph. The floxed N2 allele could be identified as a 5.7-kb fragment. Two of the ES cell clones with NeoR deletions were reconfirmed by sequencing and injected into C57BL/6 blastocysts, which were then transferred into foster mothers to obtain chimeric mice. Floxed N2 gene–targeted mice were provided by K. Rajewsky (Harvard Medical School, Boston, MA).

Activation of the Cre recombinase was performed as previously described (8, 9). In brief, Ctrl, (N1^lox/lox), N1^{lox/lox&Mc-Cre}, N2^{lox/lox&Mx-Cre}, and N1/N2^{lox/lox&Mx-Cre} mice received five i.p. injections of 250 µg polyI-polyC (pIpC; Sigma-Aldrich) at 2-d intervals. Competitive mixed BM chimeras were set up as previously described (9). In brief, lethally irradiated mice (950 rads 24 h before transfer) that had been treated i.p. 48 h before BM transplantation with 100 µg anti-NK1.1 monoclonal antibodies were reconstituted with a 1:2 mixture (5 x 10⁶:10 x 10⁶) of CD45.1⁺ WT and Ctrl, N1^{lox/lox&Mc-Cre}, N2^{lox/lox&Mx-Cre}, or N1/N2^{lox/lox&Mx-Cre} BM for mixed chimeras. Mice were maintained on antibiotics (Bactrim) containing water, and reconstitution of BM and lymphoid organs by donor-derived cells was analyzed 8 wk later.

Flow cytometry and cell sorting.
The following monoclonal antibody conjugates were purchased from eBioscience: CD117 (2B8)-PE and -PE-Cy5.5; Sca-1 (D7)-PE and -APC; CD19 (MB-19.1)-PE and (6D5)-PE-Cy5.5; B220 (RA3.6B2)-PE-Cy5.5 and –Alexa Fluor 647; CD44 (IM781)-PE-Cy5.5; CD25 (PC61)-APC; CD4 (L3T4)-PE-Cy5.5; CD45.2 (104)-PE-Cy5.5; TCRß (H57)-PE and -APC; CD161 (PK136)-FITC; CD90.1 (HIS15)-PE; and CD90.2 (30H12)-PE. TCR (GL3)-PE and TCRß (H57)-biotin were purchased from BD Biosciences. CD25 (PC61)-PE was purchased from Caltag. CD19 (ID3)–Alexa Fluor 647; B220 (RA3.6B2)–Alexa Fluor 647; CD4 (GK1.5)-FITC and -PE; CD8 (53.6.7)-FITC and –Alexa Fluor 647; CD45.1 (A20)–Alexa Fluor 647; CD45.2 (104)–Alexa Fluor 647; TCRß (H57)-FITC; TCR (GL3)-FITC; Gr1 (RB6.8C5)-FITC; Ter119-FITC; CD11b (M1/70)-FITC, -PE, and –Alexa Fluor 647; and CD3 (17A2)-FITC were purified from hybridoma supernatants and conjugated in our laboratory according to standard protocols. Alexa Fluor 647 conjugates were prepared using the appropriate Alexa Fluor protein labeling kits (Invitrogen). APC and PE conjugates were prepared using kits purchased from Prozyme. Intracellular staining for TCRß was performed as previously described (42). Single-cell suspensions were stained with the respective antibodies and analyzed using a FACSCalibur or FACScanto flow cytometer (Becton Dickinson). The cells were sorted with a FACSVantage or a FACSAria flow cytometer (Becton Dickinson). Dead cells and debris were eliminated by appropriate gating on forward and side scatter. The data were analyzed using either CellQuest Pro (BD Biosciences) or FlowJo (TreeStar, Inc.) software.

OP9 cell co-cultures.
OP9 stromal cells engineered to express GFP and the mouse DL1 gene (OP9-DL1 cells, provided by J.C. Zuniga-Pflücker, University of Toronto, Toronto, Canada) or GFP and the mouse DL4 gene (OP9-DL4 cells provided by A. Cumano, Institut Pasteur, Paris, France) were cultured in MEM supplemented with 20% FBS (Sigma-Aldrich). HSCs were isolated from adult mouse BM and sorted as lin^–CD117^hiSca-1^hi. HSCs were seeded at 4 x 10³ cells/well onto 80% confluent monolayers of OP9 cells (24-well plates) in DMEM with 10% FBS. Every third day, 1 ml of the culture supernatant was exchanged with fresh medium. Co-cultures were harvested by pipetting at the time points indicated in the figures, and contaminating OP9 cells were eliminated by filtering the lymphocytes through a 70-µm cell strainer (BD Biosciences) before replating or flow cytometric analysis. All co-cultures were performed in the presence of 5 ng/ml rmIL-7 and rhFlt3L (PeproTech).

Semiquantitative RT-PCR.
Total RNA was isolated using TRIZOL reagent (Invitrogen), and semiquantitative PCR was performed using the Onestep RT-PCR kit (QIAGEN). All PCR reactions were performed using the same serially diluted RNA samples normalized to an tubulin– or hypoxanthine guanine phosphoribosyl transferase (HPRT)–specific signal. Gene–specific primer sequences were as follows: N1, (forward) 5'-TGTGACAGCCAGTGCAACTC-3' and (reverse) 5'-GCAGTGCTTCCAGAGTGCCA-3'; N2, (forward) 5'-ACATCATCACAGACTTGGTC-3' and (reverse) 5'-GGCAGCTGCTGTCAATAATG-3'; tubulin, (forward) 5'-TCACTGTGCCTGAACTTACC-3' and (reverse) 5'-GGAACATAGCCGTAAACTGC-3'; mouse and human HPRT, (forward) 5'-AAGGAGATGGGAGGCCATCAC-3' and (reverse) 5'-CTTGTCTGGAATTTCAAATCCAAC-3'; Deltex1, (forward) 5'-CACTGGCCCTGTCCACCCAGCCTTGGCAGG-3' and (reverse) 5'-GGGAAGGCGGGCAACTCAGGCCTCAGG-3'; Hes1, (forward) 5'-ATCATGGAGAAGAGGCGAAGGG-3' and (reverse) 5'-TGATCTGGGTCATGCAGTTGG-3'; and mouse and human Lfng, (forward) 5'-CGCGCCACAAGGAGATGACGTTC-3' and (reverse) 5'-TGGGCACCTGCTGCAGGTTCT-3'. PCR products were resolved by agarose gel electrophoresis and visualized by ethidium bromide staining. All PCR products shown correspond to the expected molecular size (Figs. 1, 4, 6, and 7).

Purified DL1- and DL4-IgG were also used to stimulate in vitro DN thymocytes. In brief, 24-well plates were coated with 10 µg/ml protein A overnight at 4°C. 10 µg/ml of purified DL1- and DL4-IgG was added to the plates for 1 h at 4°C. Lineage-depleted DN thymocytes were subsequently plated on DL fusion protein–coated plates at 2 x 10⁶ cells/well. After 20 h of culture, DN thymocytes were harvested to analyze gene expression by semiquantitative RT-PCR.

Spleen CFU (CFU-S) assay.
CD45.1⁺ C57BL/6 mice were exposed to lethal whole-body irradiation (950 rads) from a ¹³⁷Cs source and maintained on water containing antibiotics (Bactrim). The next day, total BM cells (12 x 10⁴) from either Ctrl, N1^–/–, N2^–/–, or N1N2^–/– mice were injected i.v. via the retroorbital sinus. After 12 d, spleens of the recipient mice were removed, and single-cell suspensions were prepared for FACS analysis.

In vitro stimulation of 5-FU–treated BM cells.
1 wk after the last polyI-polyC injection, N1^lox/lox and N1^{lox/lox&Mx-Cre} mice were treated with 3 mg/20 g body weight of 5-fluorouracil (Sigma-Aldrich). 5 d later, BM cells were harvested and, after red blood cell lysis, single-cell suspensions were prepared in stem cell–activating (SA) medium containing IMDM supplemented with 10% FBS, 100 ng/ml rmSCF (R&D Systems), 50 ng/ml rmTPO (R&D Systems), and 50 ng/ml rmFlt-3L (R&D Systems). The cells were incubated overnight at 37°C in 5% CO₂ before the retroviral infection.

Retrovirus production and infection procedure.
Empty (MIG) or recombinant (DL1 and DL4) retroviruses (provided by A. Freitas, Institut Pasteur, Paris, France) were obtained after transfection of Bosc23 packaging cells using lipofectamine 2000 (Invitrogen). Retrovirus-containing supernatants were collected 48 h after transfection. 3-cm petri dishes were coated with 1 ml of RetroNectin (r-fibronectin fragment CH-296; TaKara) solution (12.5 µg/ml in PBS) for 2 h at room temperature. After removal of the RetroNectin, 2 ml PBS + 2% BSA was added to each dish for 30 min. After washing the plates with PBS, the retroviral supernatant was added to the coated plates for 1 h at 37°C. The prestimulated BM cells were spun down, resuspended in 1 ml of fresh SA medium, and added to the retroviral supernatant. The next day, 1–3 x 10⁶ cells were injected i.v. into lethally irradiated CD45.1⁺ C57BL/6 mice.

To ensure similar functionality and/or expression of DL1 and DL4, the retroviruses were assessed before BM infection by Western blot analysis, as well as by infecting OP9 cells that were subsequently tested for their ability to induce T cell development in vitro. Based on these criteria, DL1 and DL4 retroviruses were equivalent (Fig. S1, available at http://www.jem.org/cgi/content/full/jem.20061442/DC1).

Expression plasmids and transfections.
The mouse cDNA coding for the extracellular domain of either DL1 or DL4 was cloned via HindIII/BamHI and EcoRI/SalI, respectively, into the PS 521 expression vector (43) to generate DL1- and DL4-IgG fusion proteins. The corresponding expression vectors were transfected into 293T cells using the calcium-phosphate method, and IgG fusion proteins were subsequently purified over protein A columns according to the manufacturer's instructions (HiTrap rProtein A FF; GE Healthcare). Purity of the fusion proteins was verified by Coomassie blue staining and Western blot analysis. Full-length N1 and N2 cDNAs were cloned in frame into the pEGFP-N1 expression vector (CLONTECH Laboratories, Inc.). The mouse cDNA coding for the Lfng was cloned via BamHI into pcDNA3.1^– (Invitrogen). 293T cells were transiently transfected with 5 µg N1- and N2-EGFP expression vectors, respectively, with or without the Lfng expression vector. 48 h later, the cells were indirectly stained with DL1- or DL4-IgG fusion proteins (0.5 µg/10⁶ cells). Binding of the fusion proteins to the Notch receptors was detected using biotinylated anti–human IgG antibodies.

Online supplemental material.
Fig. S1 shows a functional test for DL1- and DL4-expressing retroviruses. Online supplemental material is available at http://www.jem.org/cgi/content/full/jem.20061442/DC1.