Studies by Vacca et al. (25) suggest that non-canonical Notch3 signaling regulates T-cell development and leukemia through activation of the NF-κB pathway. In their transgenic mouse model, Notch3 overexpression, specifically in T cells, led to the development of leukemia (25). This group showed that increased Notch3 expression enabled constitutive activation of NF-κB and demonstrated that Notch3 interacts with IKKα to maintain NF-κB activity (25).

In human myelogenous leukemia cells, Notch1 directly interacts with the transcription factor, YY1, to drive expression of the oncogenic transcription factor c-myc independently of CSL (26). In HPV-driven human cervical cancer, non-canonical Notch signaling enables oncogenesis, independently of CSL, via PI3K pathway (27). However, little is known about how non-canonical Notch signaling drives transformation in these situations.

Raafat et al. (28), using conditional RBPJκ knockout mice, revealed that non-canonical Notch4 signaling is involved in mammary gland tumorigenesis, whereas canonical Notch4 was required for the development of mammary glands (28). This differential regulation provides an attractive opportunity for targeting non-canonical Notch signaling to dampen oncogenesis while enabling intact tissue homeostasis and development to occur via canonical Notch signaling. Another study suggests an RBPJκ-independent role for Notch4 signaling in the survival of endothelial cell lines (29). Furthermore, during breast cancer progression, Notch signaling plays a role in epithelial transformation independent of CSL (30). These studies further emphasize the importance of non-canonical Notch signaling in breast cancer cell survival and progression.

Additionally, in breast cancer cell lines, non-canonical Notch signaling is known to regulate IL-6 expression, and IL-6, in turn, acts on tumor cells to further increase their oncogenic potential. In this study, cytoplasmic NICD interaction with the NF-κB pathway induced IL-6 expression (31). These studies, in addition to those reported above in leukemic T cells (25), support a role for non-canonical Notch signaling via NF-κB pathway in oncogenesis.

Non-canonical Notch signaling also is implicated in the regulation of metabolism in tumor cells. Recent studies from Perumalsamy et al. (32) demonstrated that non-nuclear, either cytoplasmic or membrane tethered, NICD blocks starvation-induced apoptosis in HeLa, a cervical cancer cell line. This group also showed that nuclear retention of NICD abrogates its anti-apoptotic activity thus demonstrating that, in their system, Notch controls apoptosis via a non-canonical, cytosolic pathway. Their data further suggest that non-canonical Notch regulation of apoptosis occurs through the mTOR–Rictor pathway (32). Another study linking Notch to metabolism examined the role of Notch in regulating neuronal stem cells (33). This report demonstrated an interaction between Notch and the PTEN-induced kinase 1 (PINK1) and provides evidence that the Notch/PINK1 interaction influences mitochondrial function and activates the mTORC2/Akt pathway. This non-canonical Notch signaling induced proliferation and tumor stem cell maintenance through mitochondrial and metabolic pathways. Additionally, in this study, the authors observed localization of full length Notch1 on the mitochondrial membrane further linking at least some forms of non-canonical Notch signaling to the mitochondria (33).

Non-canonical Notch signaling is known to regulate hypoxic pathways in transformed human cell lines (34). In this study, it was shown that NICD sequesters a negative regulator of HIF-1α resulting in increased protein levels of HIF-1α and, in turn, increasing its downstream effects (34). Since hypoxia and metabolic changes are hallmarks of tumor tissue, the emerging role of non-canonical signaling in these pathways implies that there will be increased recognition of non-canonical Notch signaling mechanisms and cross-talk with other important pathways in a variety of tumor settings (35).

Notch is important in driving the differentiation of naïve CD4⁺ T cells into specific T helper (Th) subsets and targeting Notch signaling in Th cells provides the opportunity for immune modulation. Studies in our lab demonstrate that GSI treatment significantly reduces Th1, Th17, and induced Treg (iTreg) polarization (44, 45). Studies by other labs using different methods to block Notch signaling showed that Th2 polarization is also driven by Notch signaling (46, 47). We demonstrated a significant decrease in Th1 and iTreg differentiation in conditional Notch1 knockout Th cells and through the use of conditional RBPJκ knockout T cells, revealed that Notch regulates Th cell differentiation into different Th cell fates independent of RBPJκ and hence is non-canonical. Furthermore, our data showed that both activation and proliferation of CD4⁺ T cells are not impaired by conditional deletion of RBPJκ (45). Thus, CD4⁺ T-cell activation, proliferation, and differentiation all require non-canonical Notch signaling, and recent data from our lab suggest Notch, in conjunction with NF-κB, and regulate this non-canonical signaling in CD4⁺ T cells. (45).

The possibility that non-canonical Notch signaling may occur through activation of NF-κB is not surprising since links between Notch and NF-κB have been documented by several groups including our own (48, 49). In cells of the immune system, Notch3 in collaboration with NF-κB is reported to cooperatively regulate FoxP3 expression (50). Additionally, we recently reported that Notch1 can initiate NF-κB activation via cytosolic interactions with components of the T-cell signalosome. In particular, cytosolic Notch1 drives the formation of the CARMA1, BCL10, and MALT1 (CBM) complex that is essential for NF-κB activation in T cells. These data demonstrated that cytosolic, rather than nuclear, Notch1 drives CBM complex formation emphasizing the non-canonical role of Notch1 in this process (49).

In addition to Notch signaling through NF-κB, non-canonical Notch signaling is implicated in T-cell metabolism and cell survival. Upon lymphocyte activation, there is an immense change in the metabolic activity of T cells to enable the production of building blocks for cell division and growth as well as ATP production. This metabolic switch is closely linked with cell survival. As described above, Perumalsamy et al. (32) described a link between non-canonical Notch signaling and the mTORC2-Akt cascade (32). In this report, they also provide evidence that cell survival of activated T cells is regulated by the interaction of cytoplasmic or membrane tethered NICD with the mTORC2-Akt cascade and this may also be involved in cell metabolism (32). The same group had previously demonstrated that interaction of Notch1 and kinases involved in early T-cell activation (PI3K and p56^lck) regulates an anti-apoptotic program in T cells through Akt signaling (51). Interestingly, another group has demonstrated mitochondrial localization of full length Notch1 protein in neuronal cells providing additional evidence in another system for non-canonical Notch signaling in metabolism and cell survival (33).

As described above, canonical Notch signaling begins with the interaction between Notch and its ligand and this interaction catalyzes a series of events leading to cleavage and release of NICD. A conundrum in the immune system is the observation by our group and others, that activation of the T-cell receptor leads to rapid release of NICD (52, 53) and this may occur in the absence of ligand. While the mechanism of Notch activation through the TCR is poorly understood, a possible hint to this process is suggested by studies of Drosophila immune cells showing NICD can be generated independently of ligand interaction and this is dependent upon HIF-1α-mediated stabilization of NICD (52). Since ligand-independent Notch activation can occur through HIF-1α in Drosophila immune cells, it is tempting to speculate that this also may occur in mammals (54). The observed ligand-independent activation in immune cells of Drosophila may possibly be physiologically relevant in mammals. There is no evidence that Th cells express Notch ligands in the circulation while trafficking to effector sites after initial priming in lymph nodes and continuous Notch signaling could provide survival and differentiation signals in the circulation; however, this remains speculative.

A role for membrane tethered Notch is found in dendritic cells, a cell found at the nexus of the innate and adaptive immune system. According to one recent study, in dendritic cells, membrane bound Notch activates PI3 kinase. This non-canonical Notch signaling regulates the production of the immune suppressive cytokine, IL10, by dendritic cells in response to LPS (55).

Notch signaling in the immune system, while required for normal immune function, also is linked to several diseases of the immune system (38–41, 56–60). Aberrant Notch signaling is implicated in several autoimmune diseases including bone marrow failure, experimental autoimmune encephalomyelitis, rheumatoid arthritis, and type 1 diabetes (59, 61–63). Many of these diseases are caused, at least in part, by auto-reactive T cells. Since we know that Th1 and Th17 cell differentiation requires non-canonical Notch signaling, it is reasonable to envision a therapeutic strategy that would block non-canonical Notch signaling perhaps leaving intact other Notch signaling pathways important for normal function of other cells and tissues. However, to achieve such a goal, it is essential that we better understand the various pathways of non-canonical Notch signaling.