Project description:The lymphatic system maintains tissue fluid balance, and its dysfunction can result in lymphedema. Although cholesterol is essential for cellular function, its role in lymphatic development has remained unknown. Here, we identify APOA1 binding protein (AIBP) as a key regulator that promotes lymphatic endothelial cell (LEC) fate specification and lymphangiogenesis. Mechanistically, AIBP reduces plasma membrane cholesterol content, thereby enhancing VEGFR3 signaling by disrupting caveolae—small plasma membrane invaginations formed by the scaffolding protein caveolin-1 (CAV-1)—and relieving CAV-1–mediated inhibition. In zebrafish and mice, AIBP loss impairs VEGFR3 signaling and lymphatic development, defects that can be rescued by CAV-1 deletion or by a VEGFR3 mutant (VEGFR3AAA) lacking CAV-1 binding. Administration of recombinant AIBP augments VEGFC-induced lymphangiogenesis and accelerates the resolution of secondary lymphedema in adult mice. These findings define the AIBP–CAV-1 axis as a critical regulator of VEGFR3 signaling and lymphatic growth, offering new therapeutic opportunities for treating lymphatic dysfunction.

Project description:The development of a differentiated and functional vasculature requires coordinated control of cell fate specification, lineage differentiation and vascular network growth. Cellular proliferation is spatiotemporally regulated in developing vessel networks but how this is achieved and differentially controlled in specific lineages is unknown. Using a zebrafish forward genetic screen for mutants that form blood vessels but fail to form lymphatic vessels, we uncovered a mutant for the RNA helicase Ddx21. Ddx21 cell-autonomously regulates the early development of lymphatic endothelial cells. Ddx21 is essential for Vegfc-Vegfr3 driven endothelial cell proliferation. Ddx21 is an established regulator of ribosomal RNA transcription and in the absence of Ddx21, mutant lymphatic endothelial cells show reduced ribosome biogenesis. Ultimately, loss of Ddx21 leads to a p53-p21 dependent cell cycle arrest that blocks embryonic lymphangiogenesis. Thus, the RNA helicase Ddx21 coordinates the endothelial cell proliferative response to Vegfc-Vegfr3 signalling by balancing ribosome biogenesis and p53-p21 signalling. This mechanism may have therapeutic potential in diseases of excessive lymphangiogenesis such as in cancer metastasis or lymphatic malformation.

Project description:The development of a differentiated and functional vasculature requires coordinated control of cell fate specification, lineage differentiation and vascular network growth. Cellular proliferation is spatiotemporally regulated in developing vessel networks but how this is achieved and differentially controlled in specific lineages is unknown. Using a zebrafish forward genetic screen for mutants that form blood vessels but fail to form lymphatic vessels, we uncovered a mutant for the RNA helicase Ddx21. Ddx21 cell-autonomously regulates the early development of lymphatic endothelial cells. Ddx21 is essential for Vegfc-Vegfr3 driven endothelial cell proliferation. Ddx21 is an established regulator of ribosomal RNA transcription and in the absence of Ddx21, mutant lymphatic endothelial cells show reduced ribosome biogenesis. Ultimately, loss of Ddx21 leads to a p53-p21 dependent cell cycle arrest that blocks embryonic lymphangiogenesis. Thus, the RNA helicase Ddx21 coordinates the endothelial cell proliferative response to Vegfc-Vegfr3 signalling by balancing ribosome biogenesis and p53-p21 signalling. This mechanism may have therapeutic potential in diseases of excessive lymphangiogenesis such as in cancer metastasis or lymphatic malformation.

Project description:Colorectal cancer (CRC) is one of the major causes of cancer-related death in Western countries and is associated with increased numbers of lymphatic vessels (LVs) and tumor-associated macrophages (TAMs). The VEGFC/VEGFR3 pathway is regarded as the principal inducer of lymphangiogenesis and it contributes to metastases; however, no data are available on its role during CRC development. We found that both VEGFC and VEGFR3 were upregulated in human non-metastatic CRC, with VEGFR3 localising on both LVs and TAMs. We further proved in different preclinical models of CRC, that VEGFC/VEGFR3 axis can shape both LECs and TAMs to synergically inhibit anti-tumor immunity and promote primary CRC growth. VEGFR3-directed therapy could be envisioned for the treatment of non-metastatic CRC.

Project description:Leiomyoma with bizarre nuclei (LM-BN) is a rare variant of leiomyoma with a benign clinical course. In contrast, leiomyosarcoma (LMS) is a high-grade, malignant neoplasm characterized by high recurrence rates and poor survival. While LM-BN and LMS show distinct morphologies, they share similar immunoprofile and molecular alterations, with both considered “DNA unstable”. Rare cases of LM-BN associated with LMS have been reported, however the histogenesis and molecular relationship between these two tumors remains unclear. In this study, we assessed 11 cases of LMS arising in conjunction with LM-BN and further analyzed the clinical, histologic, and molecular characteristics of these lesions. Tumor slides were examined by histology and immunohistochemistry to confirm the presence of both LMS and LM-BN components. LM-BN and LMS had similar p16 and p53 IHC patterns, but LMS had a higher Ki-67 index and lower ER/PR expression. Digital image analysis based on nuclear and cytologic features revealed spatial relationships between LMS and LM-BN. Genomic copy number alteration (CNA) demonstrated the same clonal origin of LMS from existing LM-BN through conserved copy number alterations. LMS harbored higher CNAs and frequent loss of the TP53, Rb, PTEN, and/or CDKN2A genomic region than LM-BN, indicative of tumor progression. Spatial transcriptome analysis defined uniquely expressed gene signatures in a geographical distribution, demonstrating molecular evidence of regional cell specific differences of LM-BN and LMS. Mutation analysis of large oncogenic panel revealed many shared functional gene alterations in both LM-BN and LMS, but more highly enriched in LMS. Our findings for the first time suggest that a subset of LMS arise from an existing LM-BN.

Project description:Uterine leiomyosarcoma (LMS) is the worst malignancy among the gynecologic cancers. Uterine leiomyoma (LM) is a benign tumor of myometrial origin and is the most common among women of childbearing age. Because the symptoms of women with LMS such as abnormal vaginal bleeding, palpable pelvic mass, and pelvic pain resemble with those of women with LM, it is difficult to preoperatively distinguish LMS and LM only by ultrasound and pelvic MRI. While histopathological diagnosis after hysterectomy is the current major means to distinguish them postoperatively, unusual histologic variants of LM tend to be misdiagnosed as LMS. Furthermore, the low incidence of LMS has been preventing elucidating its causal mechanisms and developing effective diagnoses and treatments. Therefore, development of molecular diagnosis as an alternative or confirmatory means helps diagnosing LMS more accurately. We adopted omics-based technologies to identify genome-wide features to distinguish LMS from LM, and revealed that copy-number, gene expression, and DNA methylation profiles successfully distinguished between these tumors. LMS was found to possess features typically observed in malignant solid tumors, such as extensive chromosomal abnormalities, overexpression of cell cycle –related genes, and hypomethylation spreading through large genomic regions as well as frequent hypermethylation at polycomb group target gene and cadherin gene loci. We also identified candidate expression and DNA methylation markers, which will help establishing diagnostic tests using conventional quantitative assays. While the identified omics-signatures and certain markers specific to LMS need to be further validated in larger numbers of LM and LMS samples, our results demonstrate the practical feasibility of establishing a postoperative diagnostic test to distinguish LMS from LM with high accuracy, and also suggest the future possibility of developing preoperative and non-invasive diagnostic methods.

Project description:Uterine leiomyosarcoma (LMS) is the worst malignancy among the gynecologic cancers. Uterine leiomyoma (LM) is a benign tumor of myometrial origin and is the most common among women of childbearing age. Because the symptoms of women with LMS such as abnormal vaginal bleeding, palpable pelvic mass, and pelvic pain resemble with those of women with LM, it is difficult to preoperatively distinguish LMS and LM only by ultrasound and pelvic MRI. While histopathological diagnosis after hysterectomy is the current major means to distinguish them postoperatively, unusual histologic variants of LM tend to be misdiagnosed as LMS. Furthermore, the low incidence of LMS has been preventing elucidating its causal mechanisms and developing effective diagnoses and treatments. Therefore, development of molecular diagnosis as an alternative or confirmatory means helps diagnosing LMS more accurately. We adopted omics-based technologies to identify genome-wide features to distinguish LMS from LM, and revealed that copy-number, gene expression, and DNA methylation profiles successfully distinguished between these tumors. LMS was found to possess features typically observed in malignant solid tumors, such as extensive chromosomal abnormalities, overexpression of cell cycle –related genes, and hypomethylation spreading through large genomic regions as well as frequent hypermethylation at polycomb group target gene and cadherin gene loci. We also identified candidate expression and DNA methylation markers, which will help establishing diagnostic tests using conventional quantitative assays. While the identified omics-signatures and certain markers specific to LMS need to be further validated in larger numbers of LM and LMS samples, our results demonstrate the practical feasibility of establishing a postoperative diagnostic test to distinguish LMS from LM with high accuracy, and also suggest the future possibility of developing preoperative and non-invasive diagnostic methods.

Project description:The crosstalk between cancer cells and the lymphatic vasculature has long been proposed to define competency for metastasis. Nevertheless, the discovery of selective blockers of lymphovascular niches has been compromised by the paucity of experimental systems for whole-body analyses of tumor progression. Spatio-temporal analyses in autochthonous melanomas and patient-derived xenografts identified double stranded RNA mimics (dsRNA nanoplexes) as potent repressors of lymphangiogenesis and metastasis. Mechanistically, dsRNA nanoplexes were found to suppress lymphangiogenic drivers in both tumor cells and their associated lymphatic vasculature (via MIDKINE and Vegfr3, respectively). This dual inhibitory action, driven by type I interferon, was not shared by FDA-approved antimelanoma treatments or by lymphangiogenic blockers in clinical testing. These results underscore the power of Vegfr3-lymphoreporters for pharmacological testing in otherwise aggressive cancers

Project description:Lymphatic malformation (LM) is a developmental anomaly of the lymphatic system that may lead to disfigurement, organ dysfunction and recurrent infection. Though several treatment modalities exist, pharmacotherapy is often associated with side effects and recurrence is common following surgical interventions. Moreover, despite the recent discovery of PIK3CA mutations in lymphatic endothelial cells of LM patients, the full spectrum of molecular pathways involved in LM pathogenesis is poorly understood. Here, we performed RNA sequencing on blood samples obtained from ten LM patients and nine healthy subjects and found 421 differentially expressed genes that stratify LM subjects from healthy controls. Using this LM gene signature, we identified novel pathway alterations in LM, such as oxidative phosphorylation, MEK/ERK, bone morphogenetic protein (BMP), and Wnt/b-catenin pathways, in addition to confirming the known alterations in cell cycle and the PI3K/AKT pathway. Furthermore, we performed computational drug repositioning analysis to predict existing therapies (e.g. sirolimus) and novel classes of drugs for LM. These findings deepen our understanding of LM pathogenesis and may facilitate non-invasive diagnosis, pathway analysis and therapeutic development.

Project description:Oncogenic mutations in PIK3CA, encoding p110α-PI3K, are a common cause of venous and lymphatic malformations. Vessel type-specific disease pathogenesis is poorly understood, hampering development of efficient therapies. Here, we reveal a new immune-interacting subtype of Ptx3-positive dermal lymphatic capillary endothelial cells (iLECs) that recruit pro-lymphangiogenic macrophages to promote progressive lymphatic overgrowth. Mouse model of Pik3caH1047R-driven vascular malformations showed that proliferation was induced in both venous and lymphatic ECs, but sustained selectively in LECs of advanced lesions. Single-cell transcriptomics identified the iLEC population, residing at lymphatic capillary terminals of normal vasculature, that was expanded in Pik3caH1047R mice. Expression of pro-inflammatory genes, including monocyte/macrophage chemokine Ccl2, in Pik3caH1047R-iLECs was associated with recruitment of VEGF-C-producing macrophages. Macrophage depletion, CCL2 blockade or anti-inflammatory COX-2 inhibition limited Pik3caH1047R-driven lymphangiogenesis. Thus, targeting the paracrine crosstalk between iLECs and macrophages provides a new therapeutic opportunity for lymphatic malformations. Identification of iLECs further indicates that peripheral lymphatic vessels not only respond to but also actively orchestrate inflammatory processes.