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PAK4
Screening Differentially Expressed Genes of Pancreatic Cancer Between Mongolian and Han People Using Bioinformatics Technology
An in Cellulo-Derived Structure of PAK4 in Complex with Its Inhibitor Inka1
Phospho-PAK4 (Ser474)/PAK5 (Ser602)/PAK6 (Ser560) Antibody Detects Endogenous 12
Screening of Potential Genes and Transcription Factors Of
Transcriptome Analysis of Human Diabetic Kidney Disease
Proximity Proteomics Identifies PAK4 As a Component of Afadin–Nectin
PAK4 Signaling in Health and Disease
Identification of Key Genes and Pathways for Alzheimer's Disease
Glioblastomas Require Integrin Avb3/PAK4 Signaling to Escape Senescence Aleksandra Franovic1,2, Kathryn C
P21-Activated Kinase 4 Interacts with Integrin Αvß5 and Regulates Αvß5
Xo PANEL DNA GENE LIST
Tracing Paks from GI Inflammation to Cancer
CDC42 Binds PAK4 Via an Extended Gtpase-Effector Interface
The Perfect Redox System
Probe Set Name Symbol 1598 G at Growth Arres
Pathway Analysis of Commonly Expressed Genes Found in Primates and in Mouse During Naïve State of Pluripotenc Keggid Kegg Names
Mirna Expression Changes in Arsenic-Induced Skin Cancer in Vitro and in Vivo
SUPPLEMENTARY APPENDIX Exome Sequencing Reveals Heterogeneous Clonal Dynamics in Donor Cell Myeloid Neoplasms After Stem Cell Transplantation
Top View
Modulation of Cellular Microrna by HIV-1 in Burkitt Lymphoma Cells—A Pathway to Promoting Oncogenesis
Autocrine IFN Signaling Inducing Profibrotic Fibroblast Responses By
Publications (2005-2020)
Type II P21-Activated Kinases (Paks) Are Regulated by an Autoinhibitory Pseudosubstrate
INKA2, a Novel P53 Target That Interacts with the Serine/Threonine Kinase PAK4
PAK4 Phosphorylates P53 at Serine 215 to Promote Liver Cancer
Pathway Analysis of Commonly Expressed Genes Found in Humans and in Non-Human Primates During Naïve State O Keggid Kegg Namesig
Proteomic Landscape of the Human Choroid–Retinal Pigment Epithelial Complex
Supplementary Materials: the Contribution of Micrornas to the Inflammatory and Neoplastic Characteristics of Erdheim–Chester Disease
PAK4 Signaling in Development and Cancer PAK4 Signaling in Development and Cancer
Metabolic Interplay Between the Immune System and Melanoma Cells: Therapeutic Implications
Reciprocal Regulation of PKA and Rac Signaling
Screening Differentially Expressed Genes of Pancreatic Cancer Between Mongolian and Han People Using Bioinformatics Technology
Supplementary Data
Glucose-Regulated and Drug-Perturbed Phosphoproteome Reveals Molecular Mechanisms Controlling Insulin Secretion
Multifaceted Functions of Protein Kinase D in Pathological Processes and Human Diseases
PAK4, Active Human (P7248)
Phospho-PAK4/PAK5/PAK6-S474/S560/S602 Rabbit Mab
PAK4 Suppresses RELB to Prevent Senescence-Like Growth Arrest in Breast Cancer
Responsive Nuclear Proteins in Collecting Duct Cells
Knockdown of PAK4 Or PAK1 Inhibits the Proliferation of Mutant KRAS Colon Cancer Cells Independently of RAF/MEK/ERK and PI3K/AKT Signaling
Therapeutic Potential of Targeting PAK Signaling
SUPPLEMENTARY APPENDIX Deltex-1 Mutations Predict Poor Survival in Diffuse Large B-Cell Lymphoma
PAK Signaling in Cancer
Genomic Alterations Link Rho Family of Gtpases to the Highly Invasive Phenotype of Pancreas Cancer
1 PAK4 Regulates Stemness and Progression in Endocrine Resistant ER-Positive Metastatic Breast Cancer Angélica Santiago-Gómez
P21-Activated Kinase 4 Promotes Prostate Cancer Progression Through CREB
Karyotypic Imbalances and Differential Gene Expressions in the Acquired Doxorubicin Resistance of Hepatocellular Carcinoma Cells
Type II P21-Activated Kinases (Paks) Are Regulated by an Autoinhibitory Pseudosubstrate
Phosphoproteomic Profiling Reveals a Defined Genetic Program for Osteoblastic Lineage Commitment of Human Bone Marrow–Derived Stromal Stem Cells
Supplementary Table 1: Primer Sequence Used in Real-Time PCR for Binding Site Validation