Vascular endothelial cell growth factor 165 receptor 1 [neuropilin-1 (NRP-1)] is a protein-coding gene on human chromosome 10p11.22 that codes the NRP-1 protein from 923 amino acids (103 kDa), a cell surface receptor that contains protein domains that allow their participation in different types of signaling pathways that control cell migration (1). A family gene, NRP-2 (human chromosome 2q33.3), encoding a novel member of the family protein neuropilin-2 (NRP-2) that contains 931 amino acids with 104 kDa, was identified as a high-affinity receptor for the Semaphorins (2). Previous studies revealed that NRP family proteins exert multiple functions as co-receptors for vascular endothelial growth factor (VEGF) (3), transforming growth factor beta (TGF-β) (4), hepatocyte growth factor (5), fibroblast growth factor (FGF) (6), and Semaphorin 3 (SEMA3) (7). NRP family proteins are involved in the interaction with multiple ligand receptors, thus NRP family proteins may be involved in cancer occurrence and development and might serve as therapeutic targets for gastric cancer (8), glioma (9), endometrial cancer (10), bladder cancer (11), thyroid cancer (12), breast cancer (13), gallbladder cancer (14), colorectal cancer (15), and pancreatic adenocarcinoma (PDAC) (16). Moreover, NRP signaling has been associated with several biological processes, including pro-tumorigenic cell proliferation, invasion, metastasis, and tumor growth in PDAC (17). NRP signaling can provide resistance to chemotherapeutic reagent exposure in clinical settings by imitating the therapy-resistant cancer stem-cell properties (18). Recent advances in single-cell analysis (SCA) have revealed multiple functional roles of cancer-related cellular proteins (19), but the roles of NRP remain poorly understood. Here, we discuss recent advances in NRP biology in PDAC based on the SCA-based precision study.

NRP-1 contains a large N-terminal extracellular domain, including complement-binding, coagulation factors V/VIII (CF V/VIII), and meprin domains. The two NRP-1 (complement-binding) CUB domains and the amino-terminal CF V/VIII domain are crucial for SEMA3A binding. The amino-terminal NRP-1 CF V/VIII domain remains the only required for binding to VEGF-165. Therefore, NRP-1 exerts its biological functions by binding with Semaphorin ligands (20). A previous study revealed that SEMA3A can inhibit axonal growth and induce neuronal apoptosis after binding to NRP-1, with the membrane-proximal meprin, A5/NRP1, protein tyrosine-phosphatase µ (MAM) domain of NRP-1. NRP-1 is involved in regulating cell survival by mediating the effects of its ligands, such as VEGF. NRP-1 promotes survival in cancer cells by activating signaling pathways, such as the PI3K/AKT pathway (21). The activation of these pathways helps in tumor progression and therapy resistance. Additionally, NRP-1 plays an essential role in cell migration by mediating the effects of Semaphorins and VEGF. NRP-1 can enhance the invasive and migratory capabilities of cancer cells. NRP-1, by interacting with its ligands, can activate downstream signaling pathways, such as Src kinases, which modulate cytoskeletal dynamics and cell adhesion, thereby promoting cell migration and invasion (22). This causes tumor metastasis, where cancer cells spread to other body parts. These results indicate that the meprin domain is involved in forming a higher-order receptor complex. NRP may play a key role in cell-to-cell interaction via their responses to ligands (Fig. 1) (23). Moreover, a recent report indicated the involvement of the NRP-1 signal in the symmetric cell division to expand breast cancer stem-like cells (24). NRP-1 has been overexpressed in various cancer types, including lung, breast, pancreatic, and prostate cancers. NRP-1 affects cell survival, migration, and attraction by binding to ligands and various co-receptors and may serve as a cancer biomarker of refractory tumors (25).

NRP-2 is characterized by a transmembrane protein that binds to the SEMA domain, immunoglobulin domain (Ig), Semaphorin 3C (SEMA3C), and Semaphorin 3F (SEMA3F) (26), and NRP-2 interacts with VEGF (27). NRP-1 binds with high affinity to the three structurally related Semaphorins, such as SEMA3, SEMAE, and SEMA4, whereas NRP-2 shows high-affinity binding to SEMAE and SEMA4, but not SEMA3 (2). NRP-2 is involved in cardiovascular development, axon guidance, and tumorigenesis (28,29).

Neuropilins (NRPs) are transmembrane glycoproteins that act as co-receptors for a variety of ligands, including vascular endothelial growth factor (VEGF), semaphorins (SEMA), and transforming growth factor-beta (TGF-β). These ligands bind to NRPs, which then interact with and enhance the signaling of their respective receptors, such as VEGF receptor (VEGFR) and TGF-β receptor (TGFBR). VEGF is a key regulator of angiogenesis, and its binding to NRP-1 enhances VEGFR-2 signaling, leading to endothelial cell proliferation and migration. SEMA3s are involved in axon guidance and immune regulation, and their binding to NRP-1 and NRP-2 can activate downstream signaling pathways such as RhoA/ROCK and PI3K/Akt. TGF-β is a multifunctional cytokine that plays a critical role in cell growth, differentiation, and immune regulation. Its binding to NRP-1 enhances TGFBR signaling, leading to downstream activation of Smad2/3 and other signaling pathways. NRPs have been reported to interact with various signaling pathways, including TGF-β, PDGF, FGF, c-Met, and others (Fig. 1). Despite some controversy surrounding these interactions, current knowledge suggests that NRP-1 has been involved in cancer stem-cell maintenance and progression through the Wnt/β-catenin signaling pathway (30) whereas NRP-2 has been associated with lymphangiogenesis and lymphatic metastasis in certain cancer types (31).

Pancreatic cancer, also known as PDAC, is one of the most aggressive cancers globally. A PDAC diagnosis carries a 5-year survival rate of <10% (32,33). PDAC's clinical aggressiveness has been attributed to the i) lack of PDAC-specific symptoms (rendering early-stage detection difficult) (34–36), ii) early metastases (typically spreading to marginal tissues and distant organs, including the liver) (34,35), and iii) chemo- and radiotherapy resistance (34,37). Importantly, many other factors, such as topographical, vascular, and ductal pancreatic anatomy (38), and the complex involvement of stromal components of PDAC (39), may be involved in high disease recurrence rates.

Studies of six cohorts, comprising 136,000 cells from 71 cases with PDAC, indicated that PDAC contains various cells, including cancer-associated fibroblasts (CAFs) to understand the complexity of PDAC's cellular components. CAFs facilitate cell-to-cell communication and are involved in PDAC spread and therapeutic resistance (40,41). They were classified into several subpopulations, including inflammatory CAF (iCAF), myofibroblast CAF (myCAF), and antigen-presenting CAF (apCAF), based on gene expression (41). Diverse CAF subpopulations were reported for nine cancer types (42). PDAC that is characterized by iCAFs, which express interleukin 6 (IL6), collagen type XIV alpha 1 chain (COL14A1), lymphocyte antigen 6 complex locus C1 (LY6C), etc., was classified as ‘classic-type’ with a strong inflammatory profile (41). PDAC that is characterized by myCAFs, which express actin alpha 2, smooth muscle (ACTA2/aSMA), transgelin (TAGLN), thrombospondin 2 (THBS2), leucine-rich repeat containing 15 (LRRC15), etc., was considered as ‘basal-type’ with a strong myofibroblast profile (41). ApCAFs, which represent a distinct subset of CAFs expressing major histocompatibility complex class II (MHC II) and CD74, possess antigen-presenting capabilities. However, they notably lack the expression of co-stimulatory molecules, such as CD40, CD80, and CD86, resulting in the inability to initiate the typical activation response in CD4⁺ T cells. The specific role of apCAFs remains unclear, but a widely accepted hypothesis indicates that they might attract CD4⁺ T cells by expressing MHCII and subsequently interfering with their normal functionality. This interference causes CD4⁺ T cell inactivation or differentiation into regulatory T cells, thereby potentially contributing to the development of an immunosuppressive tumor microenvironment (43,44). Inter-cellular communication via ligands and their receptors indicated that sonic hedgehog (Shh)-mediated signals in CAFs suppressed cancer cell proliferation and progression in a PDAC model (45).

Few reports have focused on NRP expression at the single-cell level in PDAC, thus we used a published single-cell database (https://zenodo.org/record/6024273#.Y7T3tNXP1D8) to examine 136,000 cells from 71 patients with PDAC (41). We revealed various NRP expressions in human PDAC cells, which expressed both NRP-1 and NRP-2. In contrast, ductal cell type 1, another cell cluster, was positive for NRP-1 but not NRP-2. Thus, NRP-1 and NRP-2 appear to allow ductal cells in the pancreas to fulfill different functions. NRP-1 expression, in stellate cells, was higher than NRP-2. Fibroblasts, macrophages, and endothelial cells expressed substantial amounts of both NRP-1 and NRP-2. Endocrine cells featured very few NRP-1 or NRP-2 expressions, indicating that cases with aggressive phenotypes demonstrate fewer endocrine cells. MyCAF cells tend to express both NRP-1 and NRP-2 at high levels, while iCAF cells express only NRP-1 at high levels. Additionally, SEMA3A expression was similar in myCAF and iCAF, but the number of FGF1-expressing cells appeared slightly higher in myCAF. Targeting NRP signaling may represent a potential PDAC therapy approach, considering the high expression of NRP-1 and NRP-2 in ductal cells and fibroblasts.

Therapeutic targeting of NRP-1-positive cells in PDAC can regulate endothelial-to-mesenchymal transition (EndMT), which is an important source of fibroblasts in pathological disorders, thereby reducing tumor fibrosis and PDAC progression (46). The tumor-penetrating peptide was reported via a transcytosis transport pathway that is regulated by NRP-1. This system enhances the transcytosis of silicasome-based chemotherapy for PDAC in NRP-1-positive cells (47). Chimeric antigen receptor T cell (CAR-T) immunotherapy allows T cells to recognize an antigen and attach to antigen-positive cells, thus CAR-T targeting NRPs might be a potential PDAC therapy (8).

Precision medicines that target the NRP axis might improve the diagnoses and treatment of patients with PDAC. The NRP axis contains potential therapeutic targets that could be used to develop new and individualized PDAC treatments.

Various approaches have been used to target the NRP-1 and NRP-2 axes, including gene editing, small molecule inhibitors, and monoclonal antibodies. These approaches help identify novel therapeutic targets that may improve patient outcomes and biomarkers for risk-based patient stratification, as well as the selection of the most effective treatment for each patient. Precision medicines that target the NRP axis are leading the field in an exciting new direction that may revolutionize our ability to treat this deadly disease.