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| |width=100px|{{#pwImage:Pathway:WP2868|250px||TCA Cycle Nutrient Utilization and Invasiveness of Ovarian Cancer}} | | |width=100px|{{#pwImage:Pathway:WP2868|250px||TCA Cycle Nutrient Utilization and Invasiveness of Ovarian Cancer}} |
| [http://dx.doi.org/10.1002/msb.20134892 Yang et al. Metabolic shifts toward glutamine regulate tumor growth, invasion and bioenergetics in ovarian cancer] | | [http://dx.doi.org/10.1002/msb.20134892 Yang et al. Metabolic shifts toward glutamine regulate tumor growth, invasion and bioenergetics in ovarian cancer] |
- | |width=100px|{{#pwImage:Pathway:WP2866|250px||mir34a and TGIF2 in osteoclastogenesis}} | + | |width=100px|{{#pwImage:Pathway:WP3674|250px||mir34a and TGIF2 in osteoclastogenesis}} |
| [http://dx.doi.org/10.1038/nature13375 Krzeszinski et al. miR-34a blocks osteoporosis and bone metastasis by inhibiting osteoclastogenesis and Tgif2] | | [http://dx.doi.org/10.1038/nature13375 Krzeszinski et al. miR-34a blocks osteoporosis and bone metastasis by inhibiting osteoclastogenesis and Tgif2] |
| |width=100px|{{#pwImage:Pathway:WP2811|250px||mir219 in Oligodendrocyte Differentiation and Myelination}} | | |width=100px|{{#pwImage:Pathway:WP2811|250px||mir219 in Oligodendrocyte Differentiation and Myelination}} |
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| |width=100px|{{#pwimage:Pathway:WP1545|250px||miRNAs involved in DNA damage response}} | | |width=100px|{{#pwimage:Pathway:WP1545|250px||miRNAs involved in DNA damage response}} |
| |width=100px|{{#pwImage:Pathway:WP2249|250px||Metastatic Brain Tumor}} | | |width=100px|{{#pwImage:Pathway:WP2249|250px||Metastatic Brain Tumor}} |
- | |width=100px|{{#pwimage:Pathway:WP1901|250px||Regulatory RNA pathways}} | + | |width=100px|{{#pwimage:Pathway:WP673|250px||ErbB Signaling Pathway}} |
| |- | | |- |
| |width=100px|{{#pwImage:Pathway:WP2431|250px||Spinal Cord Injury}} | | |width=100px|{{#pwImage:Pathway:WP2431|250px||Spinal Cord Injury}} |
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| |width=100px|{{#pwimage:Pathway:WP2857|250px||Mesodermal Commitment Pathway}} | | |width=100px|{{#pwimage:Pathway:WP2857|250px||Mesodermal Commitment Pathway}} |
| |width=100px|{{#pwImage:Pathway:WP1991|250px||SRF and miRs in Smooth Muscle Differentiation and Proliferation}} | | |width=100px|{{#pwImage:Pathway:WP1991|250px||SRF and miRs in Smooth Muscle Differentiation and Proliferation}} |
- | |width=100px|{{#pwimage:Pathway:WP673|250px||ErbB Signaling Pathway}}
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| |} | | |} |
Image does not exist T-Cell Receptor and Co-stimulatory Signaling
Takahashi et al. Long non-coding RNA in liver diseases
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Image does not exist IL1 and megakaryotyces in obesity
Beaulieu et al. Interleukin 1 receptor 1 and interleukin 1beta regulate megakaryocyte maturation, platelet activation, and transcript profile during inflammation in mice and humans
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Image does not exist miRNA mechanism of action and biogenesis
Ozpolat et al. Liposomal siRNA nanocarriers for cancer therapy
Thomas et al. Eri1: a conserved enzyme at the crossroads of multiple RNA-processing pathways
|
Image does not exist Extracellular vesicle-mediated signaling in recipient cells
Gangoda et al. Extracellular vesicles including exosomes are mediators of signal transduction: Are they protective or pathogenic?
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Image does not exist TCA Cycle Nutrient Utilization and Invasiveness of Ovarian Cancer
Yang et al. Metabolic shifts toward glutamine regulate tumor growth, invasion and bioenergetics in ovarian cancer
|
Image does not exist mir34a and TGIF2 in osteoclastogenesis
Krzeszinski et al. miR-34a blocks osteoporosis and bone metastasis by inhibiting osteoclastogenesis and Tgif2
|
Image does not exist mir219 in Oligodendrocyte Differentiation and Myelination
Pusic et al. Youth and environmental enrichment generate serum exosomes containing miR-219 that promote CNS myelination
|
Image does not exist Apoptosis-related network due to altered Notch3 in ovarian cancer
Hu et al. Notch3 pathway alterations in ovarian cancer
|
Image does not exist miR-222 in Exercise-Induced Cardiac Growth
Liu et al. miR-222 Is Necessary for Exercise-Induced Cardiac Growth and Protects against Pathological Cardiac Remodeling
|
Image does not exist Hypoxia-mediated EMT and Stemness
van den Beucken et al. Hypoxia promotes stem cell phenotypes and poor prognosis through epigenetic regulation of DICER
|
Image does not exist DDX1 as a regulatory component of the Drosha microprocessor
Han et al. The RNA-binding protein DDX1 promotes primary microRNA maturation and inhibits ovarian tumor progression
|
Image does not exist EV release from cardiac cells and their functional effects
Danielson and Das, Extracellular Vesicles in Heart Disease: Excitement for the Future?
|
Image does not exist Rac1/Pak1/p38/MMP-2 pathway
Gonzalez-Villasana et al. Rac1/Pak1/p38/MMP-2 Axis Regulates Angiogenesis in Ovarian Cancer
|
Image does not exist eIF5A regulation in response to inhibition of the nuclear export system
Miyake et al. XPO1/CRM1 Inhibition Causes Antitumor Effects by Mitochondrial Accumulation of eIF5A
|
Image does not exist MFAP5-mediated ovarian cancer cell motility and invasiveness
Leung et al. Calcium-dependent FAK/CREB/TNNC1 signalling mediates the effect of stromal MFAP5 on ovarian cancer metastatic potential
|
Image does not exist LncRNA-mediated mechanisms of therapeutic resistance
Parasramka et al. Long non-coding RNAs as novel targets for therapy in hepatocellular carcinoma
|
Image does not exist ApoE and miR-146 in inflammation and atherosclerosis
Li et al. Apolipoprotein E enhances microRNA-146a in monocytes and macrophages to suppress nuclear factor-κB-driven inflammation and atherosclerosis
|
Image does not exist miR-148a/miR-31/FIH1/HIF1α-Notch signaling in glioblastoma
Wong et al. The Cancer Genome Atlas Analysis Predicts MicroRNA for Targeting Cancer Growth and Vascularization in Glioblastoma
|
Image does not exist mir-124 predicted interactions with cell cycle and differentiation
Shields et al. A genome-scale screen reveals context-dependent ovarian cancer sensitivity to miRNA overexpression
|
Image does not exist miR-517 relationship with ARCN1 and USP1
Shields et al. A genome-scale screen reveals context-dependent ovarian cancer sensitivity to miRNA overexpression
|
Image does not exist miR-509-3p alteration of YAP1/ECM axis
Pan et al. miR-509-3p is clinically significant and strongly attenuates cellular migration and multi-cellular spheroids in ovarian cancer
|
Image does not exist H19 action Rb-E2F1 signaling and CDK-β-catenin activity
Ohtsuka et al. H19 Noncoding RNA, an Independent Prognostic Factor, Regulates Essential Rb-E2F and CDK8-β-Catenin Signaling in Colorectal Cancer
|
Image does not exist mir-193a and MVP in colon cancer metastasis
Teng et al. H19 MVP-mediated exosomal sorting of miR-193a promotes colon cancer progression
|
Image does not exist miRNA regulation of p53 pathway in prostate cancer
Moustafa et al. Identification of microRNA signature and potential pathway targets in prostate cancer
|
Image does not exist miRNA regulation of prostate cancer signaling pathways
Moustafa et al. Identification of microRNA signature and potential pathway targets in prostate cancer
|
Image does not exist LncRNA involvement in canonical Wnt signaling and colorectal cancer
Shen et al. To Wnt or Lose: The Missing Non-Coding Linc in Colorectal Cancer
|
Image does not exist Ultraconserved region 339 modulation of tumor suppressor microRNAs in cancer
Vannini et al. Transcribed ultraconserved region 339 promotes carcinogenesis by modulating tumor suppressor microRNAs
|
Image does not exist Extracellular vesicles in the crosstalk of cardiac cells
Bei et al. Extracellular Vesicles in Cardiovascular Theranostics.
|
Image does not exist Inhibition of exosome biogenesis and secretion by Manumycin A in CRPC cells
Datta et al. Manumycin A suppresses exosome biogenesis and secretion via targeted inhibition of Ras/Raf/ERK1/2 signaling and hnRNP H1 in castration-resistant prostate cancer cells
|
Image does not exist miRNAs in the signaling pathway of the immune response in sepsis
Giza et al. Cellular and viral microRNAs in sepsis: mechanisms of action and clinical applications
|
Image does not exist ncRNAs involved in Wnt signaling in hepatocellular carcinoma
Klingenberg et al. Non-coding RNA in hepatocellular carcinoma: Mechanisms, biomarkers and therapeutic targets
|
Image does not exist ncRNAs involved in STAT3 signaling in hepatocellular carcinoma
Klingenberg et al. Non-coding RNA in hepatocellular carcinoma: Mechanisms, biomarkers and therapeutic targets
|
Image does not exist PDGFRα and STMN1 cooperate to exacerbate the cytotoxic effects of vinblastine
Jun et al. A PDGFRα-driven mouse model of glioblastoma reveals a stathmin1-mediated mechanism of sensitivity to vinblastine
|
Image does not exist Model for regulation of MSMP expression in cancer cells and its proangiogenic role in ovarian tumors
Mitamara et al. Induction of anti-VEGF therapy resistance by upregulated expression of microseminoprotein (MSMP)
|
Image does not exist MicroRNA network associated with Chronic lymphocytic leukemia
Ciccone and Calin, MicroRNAs in Chronic Lymphocytic Leukemia: An Old Disease with New Genetic Insights
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Image does not exist FABP4 in ovarian cancer
Gharpure et al, FABP4 as a key determinant of metastatic potential of ovarian cancer
|
Image does not exist Platelet-mediated interactions with vascular and circulating cells
Koupenova et al, Circulating Platelets as Mediators of Immunity, Inflammation, and Thrombosis
|
Image does not exist Circulating monocytes and cardiac macrophages in diastolic dysfunction
Hulsmans et al, Cardiac macrophages promote diastolic dysfunction
|
Image does not exist Translational regulation by PDGFRα
Zhou et al, Chronic platelet-derived growth factor receptor signaling exerts control over initiation of protein translation in glioma
|
Image does not exist MFAP5 effect on permeability and motility of endothelial cells via cytoskeleton rearrangement
Leung et al, Cancer-associated fibroblasts regulate endothelial adhesion protein LPP to promote ovarian cancer chemoresistance
|
Image does not exist Interactions between immune cells and microRNAs in tumor microenvironment
Cortez et al, Role of miRNAs in immune responses and immunotherapy in cancer
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Image does not exist Alzheimers Disease
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Image does not exist Parkinsons Disease
|
Image does not exist Mir302-367 Promoting Cardiomyocyte Proliferation
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Image does not exist MicroRNAs in cardiomyocyte hypertrophy
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Image does not exist Integrated Lung Cancer Pathway
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Image does not exist miRNA Biogenesis
|
Image does not exist miRNA targets in ECM and membrane receptors
|
Image does not exist Fluoropyrimidine Activity
|
Image does not exist miRNAs involved in DNA damage response
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Image does not exist Metastatic Brain Tumor
|
Image does not exist ErbB Signaling Pathway
|
Image does not exist Spinal Cord Injury
|
Image does not exist miRNA Regulation of DNA Damage Response
|
Image does not exist Parkinsons Disease Pathway (Mus musculus)
|
Image does not exist Hepatitis C and Hepatocellular Carcinoma
|
Image does not exist Metastatic brain tumor
|
Image does not exist Role of Osx and miRNAs in tooth development
|
Image does not exist miR-127 in mesendoderm differentiation
|
Image does not exist Mecp2 and Associated Rett Syndrome
|
Image does not exist miRs in Muscle Cell Differentiation
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Image does not exist Cell Differentiation
|
Image does not exist Signaling Pathways in Glioblastoma
|
Image does not exist REBF and miR33 in cholesterol and lipid homeostasis
|
Image does not exist miR-targeted genes in lymphocytes - TarBase
TarBase
|
Image does not exist miR-targeted genes in muscle cell - TarBase
TarBase
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Image does not exist miR-targeted genes in leukocytes - TarBase
TarBase
|
Image does not exist miR-targeted genes in squamous cell - TarBase
TarBase
|
Image does not exist miR-targeted genes in epithelium - TarBase
TarBase
|
Image does not exist TarBasePathway
TarBase
|
Image does not exist miR-targeted genes in adipocytes - TarBase
TarBase
|
Image does not exist Ectoderm Differentiation
|
Image does not exist Endoderm Differentiation
|
Image does not exist Mesodermal Commitment Pathway
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Image does not exist SRF and miRs in Smooth Muscle Differentiation and Proliferation
|