DDA3 stabilizes microtubules and suppresses neurite formation.

We have previously shown that DDA3 - also known as proline/serine-rich coiled-coil protein 1 (PSRC1) - is a microtubule-associated protein that promotes cell growth by stimulating the ß-catenin pathway. Here, we report that DDA3 can bundle and stabilize microtubules in vivo and in vitro. We found that overexpression of DDA3 increased the abundance of acetylated and tyrosinated microtubules. We employed PC12 and N2a cell lines, as well as cultured hippocampal neurons, and demonstrated that overexpression of DDA3 suppressed neurite/axon outgrowth, whereas its depletion accelerated neurite/axon formation and elongation. Knockdown of DDA3 reduced ß3-tubulin levels in N2a cells, which contributed to the spontaneous neurite formation caused by DDA3 depletion. Consistent with its role in suppressing neuritogenesis, DDA3 was downregulated during induced neuronal differentiation. Moreover, expression of DDA3 was detected in the rat brain at embryonic (E) day E15 and in the cortical region at E17, the period of active neurogenesis. Levels of cortical DDA3 decreased at the beginning of E19, when active neuritogenesis is completed. Overall our results demonstrate that DDA3 is a so-far-unknown microtubule-stabilizing protein that is involved in regulating neurite formation and elongation.

Mechanisms underlying the pro-survival pathway of p53 in suppressing mitotic death induced by adriamycin.

The p53 tumor suppressor responds to chemotherapeutic stress by triggering apoptosis or eliciting pro-survival pathway through arresting cell cycle progression for DNA damage repair. Here we examined the pro-survival activity of p53 on the adriamycin-induced stress using H1299 cells stably expressing tsp53 V143A, a temperature-sensitive mutant activating only the subset of p53 target genes related to growth arrest and DNA repair, but not apoptosis. At 38 degrees C, cells evaded from adriamycin-induced G2 arrest and died of apoptosis and mitotic catastrophe, which could be inhibited by Cdk inhibitors. Activation of functional tsp53 V143A at 32 degrees C led to suppression of Cdk1/2 activities and Cyclin B1/Cdk1 expression, cells exhibited prolonged G2 arrest, regained reproductive potential and were protected from mitotic catastrophe induced by adriamycin. Inhibition of mitotic catastrophe and Cyclin B1/Cdk1 expression was ablated upon silencing p21 Waf1 expression in tsp53 V143A-H1299 cells or in HCT116 cells. Together we show that p21 Waf1 is a key component of G2 checkpoint necessary and sufficient for protecting tumor cells against adriamycin-induced mitotic catastrophe.

Human DDA3 is an oncoprotein down-regulated by p53 and DNA damage.

Mouse DDA3 (mDDA3) is a microtubule-associated protein that promotes cell growth. mDDA3 contains an intronic p53 binding motif that is absent in human DDA3 (hDDA3), and is transcriptionally activated during DNA damage in a p53-dependent way. We now report that hDDA3 mRNA and protein levels were suppressed by p53, as well as in DNA damaged cells harboring wild type, but not mutant-p53 expression. We have located three consensus El-Deiry decamers at -1478/-1403 of the hDDA3 gene, and shown by chromatin immunoprecipitation that p53 bound to the region. Luciferase analysis showed that the hDDA3 promoter containing the putative p53 binding motif was responsible for p53-mediated repression. Expression of hDDA3 decreased the cell's requirement for serum, furthermore, overexpression of hDDA3 mRNA was detected in hepatoma tissues. Together our results show that hDDA3 is a p53- and DNA-damage down-regulated target that exhibits oncogenic characteristics.

p53 target DDA3 binds ASPP2 and inhibits its stimulation on p53-mediated BAX activation.

The p53 tumor suppressor functions in maintaining the integrity of the genome. We have previously reported that DDA3 is an oncoprotein transcriptionally regulated by p53. To explore mechanisms underlying DDA3 action, we searched for its interacting proteins by yeast two-hybrid screening, and identified ASPP2, a p53 binding protein, as its binding partner. The DDA3/ASPP2 binding was confirmed in vitro by GST pull-down and in vivo by immunofluorescence assay, which indicated colocalization of DDA3 and ASPP2. Interacting domain of DDA3 was mapped to amino acids 118-241, whereas both the N- and C-terminal regions of ASPP2 were capable of binding to DDA3. DDA3 dose-dependently inhibited ASPP2 in stimulating the p53-mediated BAX promoter activation without interfering the binding of ASPP2 to p53. Together these results identify ASPP2 as a bona fide DDA3 interacting protein, and suggest that the ASPP2/DDA3 interaction may inhibit ASPP2 in stimulating the apoptotic signaling of p53.

The inhibition of osteogenesis with human bone marrow mesenchymal stem cells by CdSe/ZnS quantum dot labels.

CdSe/ZnS quantum dots (QDs) have recently been used as cell tracers for long term imaging of live cells. A number of studies indicate that introduction of quantum dots to cells have no apparent deleterious effects on the morphology or growth of cells. In the present study, the human bone marrow mesenchymal stem cells (hBMSCs) were used as a model to examine the effects of QDs on the growth and osteogenic differentiation of the cells. The CdSe/ZnS QDs were delivered into hBMSCs by liposome-mediated transfection with high efficiency; analysis by transmission electron microscopy revealed that the internalized QDs could be located in the endosome-like vesicles. Uptake of QDs into hBMSCs did not affect the proliferation and cell cycle distribution of the cells. When induced to differentiate along the osteogenic lineage, the QD-containing-hBMSCs were shown to have mineral deposition on the extracellular matrix. However, the cells displayed lower alkaline phosphatase activity as compared to those without QDs. Analysis by reverse transcriptase polymerase chain reaction further demonstrated that the expression of two osteogenic markers, osteopontin and osteocalcin, was significantly inhibited. Together our results show that the presence of QDs in hBMSCs prevents the full response of the cells to induced osteogenic differentiation.

The internalized CdSe/ZnS quantum dots impair the chondrogenesis of bone marrow mesenchymal stem cells.

Mesenchymal stem cells (MSCs) are capable of differentiating into multiple cell lineages and are useful for therapeutic applications. Labeling the MSCs with fluorescent probes is beneficial in tracing the fate of MSCs after implantation. We have introduced the CdSe/ZnS quantum dots (QDs) into the human bone marrow MSCs and examined the effects of QDs on the proliferation and chondrogenesis of the cells. The internalized QDs were found localized in perinuclear regions and remained there after a number of cell passages. The presence of QDs did not affect the proliferation of cells or the size of chondrospheres formed, when subjected to chondrogenesis induction. However, the expression of mRNA and protein of type II collagen and aggrecan in the chondrospheres was significantly inhibited in cells labeled with QDs, suggesting impaired chondrogenesis. Our results that the presence of QDs interferes with the chondrogenic differentiation of MSCs raise concerns in using the QDs as fluorescence tracers for stem cells.

The prosurvival activity of p53 protects cells from UV-induced apoptosis by inhibiting c-Jun NH2-terminal kinase activity and mitochondrial death signaling.

The cytoprotective function of p53 recently has been exploited as a therapeutic advantage for cancer prevention; agents activating the prosurvival activity of p53 are shown to prevent UV-induced damages. To explore the mechanisms of p53-mediated protection from UV-induced apoptosis, we have established stable clones of H1299 lung carcinoma cells expressing a temperature-sensitive p53 mutant, tsp53(V143A). At the permissive temperature of 32 degrees C, the tsp53(V143A)-expressing cells were arrested in G(1) phase without the occurrence of apoptosis; consistent with this is the preferential induction of genes related to growth arrest and DNA damage repair. Previous expression of functional tsp53(V143A) for > or =18 hours inhibited the release of proapoptotic molecules from mitochondria and protected the cells from UV-induced apoptosis; moreover, it suppressed the activation of c-Jun NH(2)-terminal kinase (JNK) signaling and relieved the effect of UV on p53 target gene activation. p53 associated with JNK and inhibited its kinase activity. Using the p53-null H1299 cells, we showed that inhibition of JNK blocked the UV-elicited mitochondrial death signaling and caspase activation. Our results suggest that the ability of p53 to bind and inactivate JNK, together with the activation of the p53 target genes related to cell cycle arrest and DNA damage repair, is responsible for its protection of cells against UV-induced apoptosis.

Mouse DDA3 gene is a direct transcriptional target of p53 and p73.

The p53 tumor suppressor is a transcription factor that activates the expression of many target genes. We have previously reported the identification of a p53-regulated mouse gene DDA3. The 5' upstream genomic region of the mouse DDA3 was cloned, and sequence analysis revealed the presence of a potential p53 response element (RE2) residing at nucleotides +390 approximately +409 relative to the first translation start site. When fused upstream to a luciferase reporter gene, 5' genomic regions of the DDA3 gene containing RE2 were shown to be responsive to the wild-type, but not mutant p53, in a transient transfection assay. RE2 was sufficient to confer the transactivation responsiveness to p53. Furthermore, gel mobility shift analysis showed that RE2 formed specific complexes with wild-type p53. Induction of DDA3 was found in adriamycin treated normal mouse embryonic fibroblast cells (MEF), but not in p53 knockout (p53(-/-)) MEF. Overexpression of p73 induced DDA3 mRNA expression, and luciferase reporter analysis indicated that RE2 was responsive to transactivation by members of the p73 family proteins. Consistent with these findings, elevated expression of p73 protein and DDA3 mRNA were observed concomitantly in the p53(-/-) MEF cells treated with cisplatin. These results together demonstrated that DDA3 is a transcriptional target gene of p53 and its related-protein p73.

Identification of transcriptional start sites and splicing of mouse thiamine transporter gene THTR-1 (Slc19a2).

We have previously reported the cDNA cloning of the mouse thiamine transporter THTR-1 as a p53 transcriptional target gene (renamed THTR-1a hereinafter). The mouse THTR-1a is predicted to encode a protein of 12 hydrophobic stretches and a hydrophilic loop of 87 amino acids between transmembrane helices VI and VII. The mouse THTR-1 gene has been cloned, two major transcriptional start sites located at -175 and -183 relative to the translation start codon were identified. In addition, we have cloned a spliced variant, designated THTR-1b, from mouse liver cDNA library. This isoform is characterized by an inframe deletion of 114 nucleotides from the 3'-terminal region of exon 2, predicting the expression of a truncated protein lacking the central 38 amino acids of the loop region. THTR-1b coexpressed with THTR-1a in many of the mouse tissues and in day-7 to day-17 embryos, but in lower levels than the THTR-1a. When expressed in mammalian cells, both isoforms were able to mediate the transport of thiamine. Therefore, the transport function of the mouse THTR-1 is not determined by the central 38 amino acids of its loop region.

Cloning and characterization of human and mouse DDA3 genes.

We have previously reported the identification of the mouse DDA3 as a p53- and p73-inducible gene that encodes a protein capable of suppressing cell growth when ectopically expressed. We now report the cloning of the DDA3 cDNA of human as well as the genomic DDA3 DNA of human and mouse. Human DDA3 contains a 1002-bp open reading frame encoding a protein of 333 amino acids that shares 68.2% identity in amino acid sequence to the mouse protein. Expression of the human DDA3 transcript was detectable in various adult and fetal tissues examined, and was most abundantly expressed in the adult brain and fetal thymus. The DDA3 genes for human (7.7 kb) and mouse (6.7 kb) were sequenced; both contained eight exons, the genomic organization and the exon-intron junction sequences were highly conserved. The human DDA3 is located on chromosome 1p13.1, and the mouse gene is mapped to a syntenic region of chromosome 3. Analysis of a 300-kb genomic regions surrounding the mouse and human DDA3 genes revealed that the composition and orders for flanking genes were identical. Together, these results indicate that the newly cloned human gene is an orthologue of the mouse DDA3.

Modulation of caspase activation and p27(Kip1) degradation in the p53-induced apoptosis in IW32 erythroleukemia cells.

To examine the p53-mediated biological activities and signalling pathways, we generated stable transfectants of the p53-null IW32 murine erythroleukemia cells expressing the temperature-sensitive p53 mutant DNA, tsp53(val135). Two clones with different levels of p53 protein expression were selected for further characterization. At permissive temperature, clone 1-5 cells differentiated along the erythroid pathway, and clone 3-2 cells that produced greater levels (3.5-fold) of p53 underwent apoptosis. Apoptosis of 3-2 cells was accompanied by mitochondrial cytochrome c release and caspase activation as well as by cleavage of caspase substrates. Bax protein was induced to a similar extent in these clones by wild-type p53; expression of p21(Cip1/Waf1) and p27(Kip1) proteins was also increased. However, significantly lesser extent of induction for both CDK inhibitors was detected in the apoptotic 3-2 clone. The general caspase inhibitor benzyloxycarbonyl-Val-Ala-Asp-fluoromethyl ketone (z-VAD.fmk) blocked the p53-induced apoptosis in 3-2 cells, with a concomitant elevation of p27(Kip1), suggesting that p27(Kip1) protein underwent caspase-dependent proteolysis in the apoptotic 3-2 cells. Together these results linked a pathway involving cytochrome c release, caspase activation and p27(Kip1) degradation to the p53-induced apoptosis in IW32 erythroleukemia cells.

Osteogenic enrichment of bone-marrow stromal cells with the use of flow chamber and type I collagen-coated surface.

The stromal cells of the bone marrow are able to attach to the surface and differentiate into cells with bone-forming capability when stimulated with osteogenic supplements. In this study, we have employed a flow-chamber device containing a collagen-coated surface to enrich the potential osteoprogenitor cells from bone marrow stromal cells (BMSCs). The population of the cells attached to the collagen-coated substratum is about twice that attached to the uncoated surface. In the flow chamber, almost all marrow cells attached on the untreated glass were flushed out at the shear stress of 1.10 dyne/cm(2). On the other hand, 25% of the marrow cells remained attached to the collagen-coated glass, even under the shear stress of 1.30 dyne/cm(2). The collagen-attached marrow cells exhibited similar, specific alkaline phosphatase activity compared with that of the cells attached to the uncoated dish in the early stage of culturing. Nevertheless, only the collagen-attached marrow cells later expressed significant amounts of osteocalcin, which is a specific marker for osteoblast cells. Thus, we have successfully developed a protocol that uses a collagen-coated surface efficiently in a flow chamber to enrich the osteogenic cells from the BMSCs. This provides a useful tool to obtain osteogenic cells from bone marrow for biologic and clinical applications.

Suppression of Polo like kinase 1 (PLK1) by p21(Waf1) mediates the p53-dependent prevention of caspase-independent mitotic death.

Polo-like kinase 1 (Plk1) plays key roles in many aspects of mitosis. We have previously shown that induction of p21(Waf1) by p53 is responsible for protection of cells against adriamycin-induced polyploidy formation and mitotic catastrophe. Here we show that adriamycin treatment suppressed Plk1 expression in a p53- and p21(Waf1)-dependent manner. Ablation of p21(Waf1) inhibited the adriamycin-induced p53 activation, and this inhibition was alleviated by knockdown of Plk1, suggesting that p21(Waf1)-dependent suppression of Plk1 expression is responsible for maintaining p53 activation during stress response. Plk1 associated with p53 and disrupted its interaction with target gene promoters in cells treated with adriamycin. Overexpression of Plk1 inhibited the p53-mediated prevention of caspase-independent mitotic death, but not polyploidy formation, in adriamycin-treated cells. Together our results indicate that suppression of Plk1 by p21(Waf1) is responsible for p53-dependent protection against adriamycin-induced caspase-independent mitotic death.

Rad is a p53 direct transcriptional target that inhibits cell migration and is frequently silenced in lung carcinoma cells.

The p53 tumor suppressor exerts its function mainly as a transcriptional activator. Here we show that the Ras-related small GTPase Rad, an inhibitor of Rho kinase, is a direct transcriptional target of p53. Expression of Rad messenger RNA (mRNA) and protein was induced by DNA damage in a p53-dependent manner. The -2934/-2905-bp Rad promoter region, to which p53 bound, was required for p53-mediated Rad gene activation. Treatment by DNA damaging agents increased p53 occupancy and histone acetylation in the region of Rad promoter containing the p53-binding site. Expression of Rad diminished the inhibitory phosphorylation at Ser3 of cofilin, a regulator of actin dynamics, and suppressed migration and invasiveness of cancer cells. Knockdown of Rad promoted cell migration and alleviated the p53-mediated migration suppression. Frequent loss of Rad mRNA and protein expression was observed in non-small cell lung carcinoma tissues. Together our results reveal a mechanism that p53 may inhibit cell migration by disrupting actin dynamics via Rad activation and implicate a tumor suppressor role of Rad in lung cancer.

Transcriptional upregulation of DDR2 by ATF4 facilitates osteoblastic differentiation through p38 MAPK-mediated Runx2 activation.

Deficiency of the collagen receptor discoidin domain receptor tyrosine kinase (DDR2) in mice and humans results in dwarfism and short limbs, of which the mechanism remains unknown. Here we report that DDR2 is a key regulator of osteoblast differentiation. DDR2 mRNA expression was increased at an early stage of induced osteoblast differentiation. In the subchondral bone of human osteoarthritic knee, DDR2 was detected in osteoblastic cells. In mouse embryos, DDR2 expression was found from E11 to E15, preceding osteocalcin (OCN) and coinciding with Runx2 expression. Activating transcription factor 4 (ATF4) enhanced DDR2 mRNA expression, and knockdown of ATF4 expression delayed DDR2 induction during osteoblast differentiation. A CCAAT/enhancer binding protein (C/EBP) binding site at -1150 bp in the DDR2 promoter was required for ATF4-mediated DDR2 activation. C/EBPß bound to and cooperated with ATF4 in stimulating DDR2 transcription; accordingly, the ATF4 mutants deficient of C/EBPß binding were incapable of transactivating DDR2. Overexpression of DDR2 increased osteoblast-specific gene expression. Conversely, knockdown of DDR2 suppressed osteogenic marker gene expression and matrix mineralization during the induced osteogenesis. The stimulation of p38 MAPK by DDR2 was required for DDR2-induced activation of Runx2 and OCN promoters. Together our findings uncover a pathway in which ATF4, by binding to C/EBPß transcriptionally upregulates DDR2 expression, and DDR2, in turn, activates Runx2 through p38 MAPK to promote osteoblast differentiation.

Requirement of nuclear localization and transcriptional activity of p53 for its targeting to the yolk syncytial layer (YSL) nuclei in zebrafish embryo and its use for apoptosis assay.

We expressed zebrafish p53 protein fused to GFP by a neuron-specific HuC promoter in zebrafish embryos. Instead of displaying neuronal expression patterns, p53-GFP was targeted to zebrafish YSL nuclei. This YSL targeting is p53 sequence-specific because GFP fusion proteins of p63 and p73 displayed neuronal-specific patterns. To dissect the underlying mechanisms, various constructs encoding a series of p53 mutant proteins under the control of different promoters were generated. Our results showed that expression of p53, in early zebrafish embryo, is preferentially targeted to the nuclei of YSL, which is mediated by importin. Similarly, this targeting is abrogated when p53 nuclear localization signal is disrupted. In addition, the transcriptional activity of p53 is required for this targeting. We further showed that fusion of pro-apoptotic BAD protein to p53-GFP led to apoptosis of YSL cells, and subsequent imperfect microtubule formation and abnormal blastomere movements.

5'-Heterogeneity of mouse Dda3 transcripts is attributed to differential initiation of transcription and alternative splicing.

We have previously shown that mouse Dda3 gene is a p53 and p73 transcriptional target whose expression suppresses tumor cell growth. Here, we report the identification of multiple variants of Dda3 transcripts with diverse 5' sequences through 5'] rapid amplification of cDNA ends (5'-RACE) and RT-PCR. Analysis by primer extension and RNase protection revealed that the 5'-heterogeneity was generated by transcription initiation at multiple sites in exon 1 and intron 1 and by alternative splicing. These transcripts, both coding and non-coding, exhibited distinct expression patterns in various adult tissues and were developmentally regulated. Furthermore, they were induced in a p53-dependent manner by various stress signals. These data demonstrated that differential initiation of transcription and alternative splicing both participate in the regulation of Dda3 gene expression.