Project description:Wnt signaling is a highly conserved metazoan pathway that plays a crucial role in cell-fate determination and morphogenesis during development. Wnt ligands can induce disparate cellular responses. The exact mechanism behind these different outcomes is not fully understood but may be due to interactions with different receptors on the cell membrane. PTK7/Otk is a transmembrane receptor that is implicated in various developmental and physiological processes including cell polarity, cell migration, and invasion. Here we examine two roles of Otk1 and Otk2 in patterning and neurogenesis. We find that Otk1 is a positive regulator of signaling and Otk2 functions as its inhibitor. We propose that PTK7/Otk functions in signaling and in particular cell migration and polarity contributing to the diversity of cellular responses seen in Wnt-mediated processes.

Project description:The Hippo-YAP1 pathway is an evolutionally conserved signaling cascade that controls organ size and tissue regeneration. Its dysregulation has been well-studied to promote tumor initiation and progression, including gastric cancer (GC). Although the Hippo-YAP1 signaling pathway regulates the expression of thousands of target genes, how these target genes contribute to the oncogenic program driven by YAP1 remains unknown. Here we identified the vital role of FOXP4 in YAP1-driven gastric carcinogenesis by maintaining stemness and promoting peritoneal metastasis. Knocking down FOXP4 impairs GC spheroid formation and inhibits stemness marker expression, while its upregulation potentiates the cancer cells with more stemness. RNA-seq analysis revealed SOX12 as functional downstream of FOXP4 in the YAP1-induced carcinogenesis. Targeting FOXP4 by 42-(2-Tetrazolyl) rapamycin in GC cells enhanced the 5-FU efficacies. Our findings have unveiled FOXP4 as a novel stemness marker that promotes tumorigenesis by upregulating SOX12. Additionally, we have identified FOXP4 as a direct target for modulating YAP1 signaling in GC. Therefore, the YAP1-FOXP4-SOX12 axis presents a promising therapeutic target for GC.

Project description:Full-length membrane PTK7 and its N-terminal and C-terminal proteolytic fragments induced differential transcriptional profiles in HT1080 cells. Pseudokinase PTK7 is an essential regulator of planar cell polarity (PCP) and directional cell motility in the course of vertebrate development and embryogenesis, and regulates both the non-canonical Wnt/PCP and canonical Wnt pathways. In contrast to its well-appreciated, crucial role in embryo development, the functional importance of the intact full-length PTK7 in malignancy is still a matter of debate. In humans, the full-length membrane PTK7 consists of seven extracellular immunoglobulin-like (Ig) domains, a transmembrane region, a juxtamembrane region and a catalytically inert cytoplasmic tyrosine kinase (PTK) domain. Because pericellular proteolysis plays a primary role in cell migration, especially in the directional locomotion of tumor cells, it is likely that proteolysis and PCP converge to promote efficient directed cancer cell migration. In agreement, the functionality of PTK7 is directly regulated by proteolysis. Ubiquitous membrane type-1 matrix metalloproteinase (MT1-MMP), arguably the primary enzyme in pericellular proteolysis and cancer cell migration, cleaves the PKP621↓LI sequence in the seventh Ig-like domain of membrane PTK7 and this cleavage results in the liberation of the N-terminal soluble PTK7 fragment (sPTK7). MT1-MMP proteolysis is followed by the cleavage of the C-terminal residual portion of PTK7 by ADAMs, including ADAM17. The ectodomain shedding is a prerequisite for the intramembrane cleavage of PTK7 by γ-secretase. This cleavage releases the C-terminal cytoplasmic tail fragment of PTK7, which is then either degraded by the proteasome or transported to the nucleus.The limited pre-existing data suggest that the full-length membrane PTK7 and its proteolytic products cause an opposing effect on the efficiency of cell migration. Thus, the continuing presence of the full-length membrane PTK7 on the plasma membrane down-regulated the myosin light chain (MLC) phosphorylation (a downstream event of the Wnt/PCP pathway) and, in agreement, reduced migration efficiency of fibrosarcoma HT1080 cells. MT1-MMP proteolysis of PTK7 reversed the inhibitory effect of the full-length membrane PTK7, resulted in the accumulation of the stable N-terminal sPTK7 fragment in the extracellular milieu and promoted cell invasion of HT1080 cells. Expression of the Chz PTK7 mutant that exhibited an additional PEK↓LK503 MT1-MMP cleavage site in the junction region between the fifth and the sixth Ig-like domains stimulated cell migration even further. These effects suggest the existence of the intriguing and specific downstream mechanisms by which the intact PTK7, its digest fragments and the homo- and heterodimeric complexes between the PTK7 membrane, soluble and intracellular portions control cell function. These mechanisms, however, have not been precisely investigated in the earlier works by us and others. Understanding of these mechanisms will shed additional light on the role that PTK7 alone as well as in its combination with MT1-MMP, ADAMs and γ-secretase plays in cancer cell migration.

Project description:Full-length membrane PTK7 and its N-terminal and C-terminal proteolytic fragments induced differential transcriptional profiles in HT1080 cells. Pseudokinase PTK7 is an essential regulator of planar cell polarity (PCP) and directional cell motility in the course of vertebrate development and embryogenesis, and regulates both the non-canonical Wnt/PCP and canonical Wnt pathways. In contrast to its well-appreciated, crucial role in embryo development, the functional importance of the intact full-length PTK7 in malignancy is still a matter of debate. In humans, the full-length membrane PTK7 consists of seven extracellular immunoglobulin-like (Ig) domains, a transmembrane region, a juxtamembrane region and a catalytically inert cytoplasmic tyrosine kinase (PTK) domain. Because pericellular proteolysis plays a primary role in cell migration, especially in the directional locomotion of tumor cells, it is likely that proteolysis and PCP converge to promote efficient directed cancer cell migration. In agreement, the functionality of PTK7 is directly regulated by proteolysis. Ubiquitous membrane type-1 matrix metalloproteinase (MT1-MMP), arguably the primary enzyme in pericellular proteolysis and cancer cell migration, cleaves the PKP621M-bM-^FM-^SLI sequence in the seventh Ig-like domain of membrane PTK7 and this cleavage results in the liberation of the N-terminal soluble PTK7 fragment (sPTK7). MT1-MMP proteolysis is followed by the cleavage of the C-terminal residual portion of PTK7 by ADAMs, including ADAM17. The ectodomain shedding is a prerequisite for the intramembrane cleavage of PTK7 by M-NM-3-secretase. This cleavage releases the C-terminal cytoplasmic tail fragment of PTK7, which is then either degraded by the proteasome or transported to the nucleus.The limited pre-existing data suggest that the full-length membrane PTK7 and its proteolytic products cause an opposing effect on the efficiency of cell migration. Thus, the continuing presence of the full-length membrane PTK7 on the plasma membrane down-regulated the myosin light chain (MLC) phosphorylation (a downstream event of the Wnt/PCP pathway) and, in agreement, reduced migration efficiency of fibrosarcoma HT1080 cells. MT1-MMP proteolysis of PTK7 reversed the inhibitory effect of the full-length membrane PTK7, resulted in the accumulation of the stable N-terminal sPTK7 fragment in the extracellular milieu and promoted cell invasion of HT1080 cells. Expression of the Chz PTK7 mutant that exhibited an additional PEKM-bM-^FM-^SLK503 MT1-MMP cleavage site in the junction region between the fifth and the sixth Ig-like domains stimulated cell migration even further. These effects suggest the existence of the intriguing and specific downstream mechanisms by which the intact PTK7, its digest fragments and the homo- and heterodimeric complexes between the PTK7 membrane, soluble and intracellular portions control cell function. These mechanisms, however, have not been precisely investigated in the earlier works by us and others. Understanding of these mechanisms will shed additional light on the role that PTK7 alone as well as in its combination with MT1-MMP, ADAMs and M-NM-3-secretase plays in cancer cell migration. To evaluate in detail the effects of PTK7 and its proteolytic fragments on genome-wide transcriptional regulation, we specifically employed fibrosarcoma HT1080 cells. These highly invasive cells express low endogenous levels of PTK7 but high levels of active MT1-MMP and ADAMs. Because of these parameters, we could manipulate this preudokinase functionality using HT1080 cells transfected with the recombinant PTK7 constructs. The cells we employed included the PTK7 knock-out cells (shPTK7 cells), cells with the enforced overexpression of the original membrane PTK7 (PTK7 cells) and its Chuzhoi (Chz) mutant that exhibited an additional PEKM-bM-^FM-^SLK503 MT1-MMP cleavage site (Chz cells), and the cells, which overexpresssed multiple deletion species of PTK7. These species represented the soluble (sPTK7), membrane and cytoplasmic C-terminal digest fragments that resulted because of PTK7 cleavage by MT1-MMP (cPTK7/622-1070) and ADAM/gammaM-bM-^@M-^Ssecretase (cPTK7/726-1070). Expression of these constructs allowed us to specifically determine the downstream effect of PTK7 proteolysis on gene expression. HT1080 cells were stably transfected with the PTK7 constructs. Cells (1 x 10^4/ml) were plated in DMEM- 10% FBS in a 100-mm dish and grown for 72 h to produce a subconfluent culture. Total cellular RNA was extracted using a Direct-zol RNA MiniPrep kit (Zymo Research). Biotin-labeled cRNA samples were prepared using the Illumina RNA Amplification Kit (Ambion). The labeled cRNA (750 ng) was hybridized for 18 h at 58M-BM-0C to the HumanHT-12 v4 Expression BeadChip (Illumina). BeadChips were then developed using fluorolink streptavidin-Cy3 (GE Healthcare). Array chips were scanned using an Illumina BeadArray Reader. The initial data extraction and normalization were performed using the BeadArray Reader and GeneSpring GX software (Agilent).

Project description:We found deletion of Foxp4 in mature adipocytes would augment juvenile and mature beige adipocyte thermogenesis.In order to investage the binding site of Foxp4 in the genome of beige adipocytes, we did Foxp4 ChIP-Seq with differentiated SVF cells derived from ingunal adipose tissues.

Project description:As PSCs differentiate, they display characteristics of EMT as well as PTK7 expression. We sought to discover novel markers and regulators of this process by comparing purified PTK7+ and PTK7- populations We used microarrays to detail the global program of gene expression underlying this EMT process and identified distinct classes of up-regulated genes during this process.

Project description:As PSCs differentiate, they display characteristics of EMT as well as PTK7 expression. We sought to discover novel markers and regulators of this process by comparing purified PTK7+ and PTK7- populations We used microarrays to detail the global program of gene expression underlying this EMT process and identified distinct classes of up-regulated genes during this process. PTK7+ and PTK7- populations were purified by FACS and subjected to lysis and RNA extraction. Undifferentiated PSCs and definitive endoderm were washed with PBS, then subjected to lysis and RNA extraction

Project description:In order to investage the role of Foxp4 in adaptive thermogenesis, we knocked out Foxp4 in the adipose tissue of mice by AdipoQ-Cre. After cold exposure for 7 days, we isolated the ingunal white adipose tissue for mRNA expression analysis by RNA-Seq.

Project description:We found deletion of Foxp4 in SVF cells would inhibit beige adipocyte differentiation and thermogenesis.In order to investage the binding sites of Foxp4 on genome of SVF cells, we isolated SVF cells from ingunal adipose tissues and did Foxp4 and H3K27ac ChIP-Seqs after two days' browning differentiaion.

Project description:PTK7 was identified from a meta-analysis of 1905 non-small-cell lung cancer (NSCLC) samples across 12 datasets to be one of seven genes commonly up-regulated in lung adenocarcinoma (ADC). Using ADC cell lines NCI-H1299 and NCI-H2009, disruption of PTK7 resulted in decreased cell viability and induction of apoptosis. A xenotransplantation model of the cell lines with PTK7 knock-down also resulted in decreased tumor burden. We assayed gene expression in these cell lines after PTK7 knock-down by shRNA to uncover deregulated pathways and genes.