Complex roles of discoidin domain receptor tyrosine kinases in cancer.

Discoidin domain receptors, DDR1 and DDR2 are members of the receptor tyrosine kinase (RTK) family that serves as a non-integrin collagen receptor and were initially identified as critical regulators of embryonic development and cellular homeostasis. In recent years, numerous studies have focused on the role of these receptors in disease development, in particular, cancer where they have been reported to augment ECM remodeling, invasion, drug resistance to facilitate tumor progression and metastasis. Interestingly, accumulating evidence also suggests that DDRs promote apoptosis and suppress tumor progression in various human cancers due to which their functions in cancer remain ill-defined and presents a case of an interesting therapeutic target. The present review has discussed the role of DDRs in tumorigenesis and the metastasis.

Targeting Discoidin Domain Receptor 1 (DDR1) Signaling and Its Crosstalk with ß1-integrin Emerges as a Key Factor for Breast Cancer Chemosensitization upon Collagen Type 1 Binding.

Collagen type 1 (COL1) is a ubiquitously existing extracellular matrix protein whose high density in breast tissue favors metastasis and chemoresistance. COL1-binding of MDA-MB-231 and MCF-7 breast cancer cells is mainly dependent on ß1-integrins (ITGB1). Here, we elucidate the signaling of chemoresistance in both cell lines and their ITGB1-knockdown mutants and elucidated MAPK pathway to be strongly upregulated upon COL1 binding. Notably, Discoidin Domain Receptor 1 (DDR1) was identified as another important COL1-sensor, which is permanently active but takes over the role of COL1-receptor maintaining MAPK activation in ITGB1-knockdown cells. Consequently, inhibition of DDR1 and ERK1/2 act synergistically, and sensitize the cells for cytostatic treatments using mitoxantrone, or doxorubicin, which was associated with an impaired ABCG2 drug efflux transporter activity. These data favor DDR1 as a promising target for cancer cell sensitization, most likely in combination with MAPK pathway inhibitors to circumvent COL1 induced transporter resistance axis. Since ITGB1-knockdown also induces upregulation of pEGFR in MDA-MB-231 cells, inhibitory approaches including EGFR inhibitors, such as gefitinib appear promising for pharmacological interference. These findings provide evidence for the highly dynamic adaptation of breast cancer cells in maintaining matrix binding to circumvent cytotoxicity and highlight DDR1 signaling as a target for sensitization approaches.

Discoidin domain receptor 1 regulates endochondral ossification through terminal differentiation of chondrocytes.

Chondrocytes in growth plates are responsible for longitudinal growth in long bones during endochondral ossification. Discoidin domain receptor 1 (Ddr1) is expressed in chondrocytes, but the molecular mechanisms by which DDR1 regulates chondrocyte behaviors during the endochondral ossification process remain undefined. To elucidate Ddr1-mediate chondrocyte functions, we generated chondrocyte-specific Ddr1 knockout (CKOΔDdr1) mice in this study. The CKOΔDdr1 mice showed delayed development of the secondary ossification center and increased growth plate length in the hind limbs. In the tibial growth plate in CKOΔDdr1 mice, chondrocyte proliferation was reduced in the proliferation zone, and remarkable downregulation of Ihh, MMP13, and Col-X expression in chondrocytes resulted in decreased terminal differentiation in the hypertrophic zone. Furthermore, apoptotic chondrocytes were reduced in the growth plates of CKOΔDdr1 mice. We concluded that chondrocytes with Ddr1 knockout exhibit decreased proliferation, terminal differentiation, and apoptosis in growth plates, which delays endochondral ossification and results in short stature. We also demonstrated that Ddr1 regulates the Ihh/Gli1/Gli2/Col-X pathway to regulate chondrocyte terminal differentiation. These results indicate that Ddr1 is required for chondrocytes to regulate endochondral ossification in skeletal development.

Dichotomy of the function of DDR1 in cells and disease progression.

Discoidin domain receptors DDR1 and DDR2 are collagen receptor tyrosine kinases that have many roles in tissue development and disease progression. Under physiological conditions, DDR1 is predominantly expressed in epithelial cells and functions to maintain cell differentiation and tissue homeostasis. A switch in expression from DDR1 to DDR2 occurs during epithelial-to-mesenchymal transition. However, opposite effects of DDR1 are reported to be involved in the progression of cancer and fibrotic diseases. Accumulating evidence suggests that DDR1 is involved in pro-metastasis and pro-survival signals. This review summarizes the roles of DDR1 in epithelial cell differentiation, cell migration, cancer progression and tissues fibrosis and highlights how the dichotomous functions of DDR1 may relevant to different cell types and statues. Elucidation of the underlying mechanism of the dichotomous functions of DDR1 will help to develop DDR1 as a therapeutic target.

The Role of Discoidin Domain Receptor 1 in Inflammation, Fibrosis and Renal Disease.

Discoidin domain receptors (DDRs) are a family of 2 non-integrin collagen receptors, DDR1 and DDR2, which display a tyrosine kinase activity. They are mainly expressed during embryonic development and their role during adulthood is very limited. DDR1 has been widely studied in several types of cancers, in atherosclerosis and fibrosis, but also in chronic kidney disease (CKD). This review focuses on the role of DDR1 in chronic nephropathies and on the effect of its deletion in the pathological processes involved in renal disease progression. DDR1 was shown to be de novo expressed in several models of experimental CKD. Its genetic or pharmaco-genetic inhibition led to the preservation of renal structure and function, and to decreased inflammatory influx and fibrosis. Furthermore, delayed pharmaco-genetic inhibition of DDR1 led to significant protection in models of renal disease. These results demonstrate the involvement of DDR1 in inflammatory and fibrotic processes occurring during CKD and the beneficial effect of its inhibition. Thus, DDR1 could be an interesting therapeutic target to treat renal pathologies.

The impact of EBV and HIV infection on the microenvironmental niche underlying Hodgkin lymphoma pathogenesis.

The pathogenesis of classical Hodgkin lymphoma (cHL) is still enigmatic, largely because its tumor cells, the so-called Hodgkin and Reed-Stenberg (HRS) cells, invariably reside in a prominent reactive microenvironment, are rare and therefore difficult to analyze. On the other hand, the broadly investigated cHL-derived cell lines are not unequivocally considered as suitable and representative models for this puzzling disease. Based on current knowledge, it appears that the cross talk between the tumor cells and the reactive infiltrate of the microenvironment is complex and that multiple mechanisms occur, making cHL a very heterogeneous disease. In 20-40% of cHL cases, HRS cells carry a monoclonal infection by Epstein Barr virus (EBV), which is considered a tumor-initiating factor. In these cases, EBV shows a latency type II infection pattern with the expression of latent membrane protein-1 (LMP-1), a viral oncoprotein that mimics CD40 activation. This scenario is particularly intriguing for the pathogenesis of cHL arising in HIV-infected patients, which, for still obscure reasons, is invariably EBV-associated with LMP-1 expression in HRS cells. Recent evidences are consistent with the occurrence of different pathogenic pathways variably triggered by virus infections (EBV and HIV), genetic alterations, and interactions with critical microenvironmental components. This review focuses on the different microenvironmental niches that characterize cHL of the general population as well as cases of HIV-infected patients. A more comprehensive understanding of the complex interplay existing between HRS and tumor microenvironment is pivotal for the development of more effective treatments, particularly for relapsed or refractory diseases.

DDR1 enhances invasion and metastasis of gastric cancer via epithelial-mesenchymal transition.

In this study, we investigated the effects of DDR1 on the invasion and metastasis in gastric cancer (GC) via epithelial-mesenchymal transition (EMT). Immunohistochemistry analysis was used to detect DDR1, E-cadherin, and Vimentin expression in GC tissues as well as DDR1 expression in GC cell lines and normal gastric epithelial cells. The relationship between DDR1 expression and EMT in GC cell lines was explored by down and upregulating DDR1 and examining corresponding changes in the expression of EMT-related proteins and in biological characteristics. Furthermore, a nude mice model with a transplantation tumor generating from stably transfected GC cells with DDR1 overexpression was established and performed to further reveal the effects of DDR1 expression on cellular morphology and growth of GC. Our results showed that DDR1 was highly expressed in GC tissues and cell lines compared with adjacent tissues and normal cell line, and its expression was significantly higher in GC having poor differentiation (p < 0.01), advanced depth of wall invasion (p = 0.020), lymph node metastasis (p = 0.0001), liver metastasis (p < 0.01), and high TNM stage (p < 0.01). Western blot analyses revealed that DDR1 overexpression resulted in a significant decrease in the expression of E-cadherin (p < 0.01) and an increase in the expression of Vimentin and Snail (p < 0.01), while knockdown of DDR1 led to opposite outcomes. We further demonstrated that DDR1 overexpression promoted GC cell proliferation (p < 0.05), migration (p < 0.01), and invasion (p < 0.01), and accelerated the growth (p < 0.05) as well as the microvessel formation (p < 0.01) of transplantation tumor in nude mice. Our study establishes that DDR1 enhances invasion and metastasis of gastric cancer via EMT.