MiniSOX9, a dominant-negative variant in colon cancer cells.

Inherited and acquired changes in pre-mRNA processing have significant roles in human diseases, especially cancer. Characterization of aberrantly spliced mRNAs may thus contribute to understand malignant transformation. We recently reported an anti-oncogenic potential for the SOX9 transcription factor in the colon. For instance, the Sox9 gene knock out in the mouse intestine results in an excess of proliferation with appearance of hyperplasia. SOX9 is expressed in colon cancer cells but its endogenous activity is weak. We looked for SOX9 variants that may impair SOX9 activity in colon cancer cells and we discovered MiniSOX9, a truncated version of SOX9 devoid of transactivation domain as a result of retention of the second intron. A significant overexpression of MiniSOX9 mRNA in human tumor samples compared with their matched normal tissues was observed by real-time reverse transcriptase-PCR. Immunohistochemistry revealed that MiniSOX9 is expressed at high levels in human colon cancer samples whereas it is undetectable in the surrounding healthy tissues. Finally, we discovered that MiniSOX9 behaves as a SOX9 inhibitor, inhibits protein kinase Cα promoter activity and stimulates the canonical Wnt pathway. This potential oncogenic activity of the SOX9 locus gives new insights on its role in colon cancer.

CEACAM1, a SOX9 direct transcriptional target identified in the colon epithelium.

A deletion of the transcription factor SOX9 gene in the mice intestine affects the morphology of the colon epithelium and leads to hyperplasia. Nevertheless, direct transcriptional targets of SOX9 in this tissue are still unknown. A microarray analysis identified the tumor suppressor carcinoembryonic antigen-related cell adhesion molecule 1 (CEACAM1) as a possible SOX9 target gene and we demonstrate here that SOX9 upregulates CEACAM1 in human colonic cells. Moreover, CEACAM1 expression is reduced in colon of SOX9-deficient mouse, suggesting an important function for SOX9 in the transcriptional activation of the CEACAM1 gene. We further identified SOX9-binding sequences in the human and rat CEACAM1 promoters, and an electrophoretic mobility shift together with a chromatin immunoprecipitation provided an additional evidence of the SOX9 binding to the human promoter. In addition, we established that histone acyl-transferase p300 behaves as an SOX9 co-activator of the rat and human CEACAM1promoters. These results highlight CEACAM1 as the first direct target of SOX9 identified in the colon epithelium.

Protein kinase C(alpha) actively downregulates through caveolae-dependent traffic to an endosomal compartment.

Receptor desensitization occurs through receptor internalization and targeting to endosomes, a prerequisite for sorting and degradation. Such trafficking processes may not be restricted to membrane associated receptors but may also play an important role in the downregulation of cytoplasmic transducers such as protein kinase C (PKC). It is demonstrated here that acute TPA exposure induces the transport of activated PKC(alpha) from the plasma membrane to endosomes. This process requires PKC activity and catalytically competent PKC can even promote a similar process for a truncated regulatory domain PKC(&agr;) protein. It is established that PKC(&agr;) is targeted to the endosome compartment as an active kinase, where it colocalizes with annexin I, a substrate of PKC. Thus, PKC(alpha) downregulation shares features with plasma membrane associated receptor sorting and degradation. However, it is shown that PKC(&agr;) delivery to the endosome compartment is not a Rab5 mediated process in contrast to the well characterised internalisation of the transferrin receptor. An alternative route for PKC(alpha) is evidenced by the finding that the cholesterol binding drugs nystatin and filipin, known to inhibit caveolae mediated trafficking, are able to block PKC(alpha) traffic and down regulation. Consistent with this, the endosomes where PKC(alpha) is found also contain caveolin. It is concluded that the initial step in desensitisation of PKC(alpha) involves active delivery to endosomes via a caveolae mediated process.

Membrane targeting and cytoplasmic sequestration in the spatiotemporal localization of human protein kinase C alpha.

In order to map the molecular determinants that dictate the subcellular localization of human protein kinase C alpha (hPKCalpha), full-length and deletion mutants of hPKCalpha were tagged with the green fluorescent protein (GFP) and transiently expressed in GH3B6 cells. We found that upon thyrotropin-releasing hormone (TRH) or phorbol 12-myristate 13-acetate stimulation, hPKCalpha-GFP was localized exclusively in regions of cell-cell contacts. Surprisingly, PKCalpha failed to translocate in single cells despite the presence of TRH receptors, as attested by the TRH-induced rise in intracellular calcium concentration in these cells. TRH-stimulated translocation of hPKCalpha-GFP from the cytoplasm to cell-cell contacts was a biphasic process: a fast (measured in seconds) and transient phase, followed by a slower (approximately 1 hour) and long lasting phase. The latter and the translocation induced by phorbol 12-myristate 13-acetate absolutely required the N-terminal V1 region. In contrast to the full-length hPKCalpha, the N-terminal regulatory domain alone or associated with the V3 hinge region was spontaneously and uniformly localized at the plasma membrane of single and apposed cells. However, treatment with the calcium chelator BAPTA/AM induced a differential cytoplasmic/nuclear redistribution of the regulatory domain, depending on its association with V3, which suggests the existence of a mechanism controlling the cytoplasmic sequestration of inactive hPKCalpha and involving the V3 region. By using other deletion mutants, we were able to map the sequence required for this sequestration to the C2+V3 regions. This work points to the existence of a complex interplay between membrane targeting and cytoplasmic sequestration in the control of the spatiotemporal localization of hPKCalpha.

Multisite dephosphorylation and desensitization of conventional protein kinase C isotypes.

The generation of antisera specific for the priming phosphorylation sites on protein kinase Calpha (PKCalpha) has permitted analysis of the dephosphorylation of these sites in relation to the down-regulation of the protein. It was demonstrated that these priming sites are subject to agonist-induced dephosphorylation, consistent with inactivation of the protein. Further, the process is shown to be blocked by a PKC inhibitor, indicating a requirement for PKC catalytic activity. This was corroborated by showing that a constitutively active fragment of PKCalpha is able to stimulate the dephosphorylation of wild-type PKCalpha in transfected cells. Consistent with a membrane-traffic event, the process controlled by PKC that leads to dephosphorylation is shown to be temperature-sensitive and to correlate with transient accumulation of PKCalpha on cytoplasmic vesicular structures. It was established that the dephosphorylation of priming sites in PKCalpha is not unique and occurs with other conventional PKC isotypes, demonstrating that this is a general desensitization process for this subclass of kinases. The physiological importance of this desensitization is evidenced by the behaviour of PKCbeta1 in U937 cells, where dephosphorylation of the activation loop site is shown to be a function of cell density.

Imaging protein kinase Calpha activation in cells.

Spatially resolved fluorescence resonance energy transfer (FRET) measured by fluorescence lifetime imaging microscopy (FLIM), provides a method for tracing the catalytic activity of fluorescently tagged proteins inside live cell cultures and enables determination of the functional state of proteins in fixed cells and tissues. Here, a dynamic marker of protein kinase Calpha (PKCalpha) activation is identified and exploited. Activation of PKCalpha is detected through the binding of fluorescently tagged phosphorylation site-specific antibodies; the consequent FRET is measured through the donor fluorophore on PKCalpha by FLIM. This approach enabled the imaging of PKCalpha activation in live and fixed cultured cells and was also applied to pathological samples.

Selective loss of substrate recognition induced by the tumour-associated D294G point mutation in protein kinase Calpha.

The tumour-associated D294G mutant of protein kinase Calpha (PKCalpha) was recently shown not to be translocated to the plasma membrane on stimulation with PMA, in contrast with the wild-type enzyme. Using recombinant wild-type and mutant PKCalpha, we establish here that, although the PKCalpha intrinsic lipid-dependent catalytic activity remains unaltered by the D294G mutation, the mutant enzyme exhibits a selective loss of substrate recognition. Indeed, whereas the mutant enzyme is still able to phosphorylate histone IIIS with comparable efficiency to that of the wild-type enzyme, it exhibits a lack of kinase activity towards the previously cloned 35F and 35H substrates for PKC. Overlay experiments demonstrate that this selective loss of kinase activity is correlated with a decrease in binding of D294G PKCalpha to the 35F and 35H proteins compared with that of the wild-type enzyme. Because the 35H and 35F proteins are predicted to be PKCalpha-anchoring proteins, these findings suggest a selective loss of PKCalpha-protein interactions that might fail to stabilize the location of the PKCalpha mutant at the plasma membrane.

Breast cancer cell invasiveness: correlation with protein kinase C activity and differential regulation by phorbol ester in estrogen receptor-positive and -negative cells.

Increased protein kinase C (PKC) activity in malignant breast tissue and in most aggressive breast cancer cell lines has suggested a possible role of PKC in breast carcinogenesis and tumor progression. We have investigated here the involvement of PKC in the in vitro invasiveness and motility of several breast cancer cell lines. Modulation of PKC activity by treatment with a phorbol ester (TPA), drastically increased the invasiveness of 2 estrogen receptor-positive (ER+) lines (MCF7 and ZR 75.1), whereas it markedly decreased the invasiveness of 2 ER- cell lines (MDA-MB-231 and MDA-MB-435). A PKC inhibitor (H7) reversed the TPA effects in MCF7 cells, whereas it mimicked TPA action in MDA-MB-231 cells. All of these effects of TPA also were observed to a similar extent for cell chemotaxis, and they were not dependent on protein neo-synthesis. In parallel, short TPA treatment induced cell spreading and microtubule organization in MCF7 cells and inverse morphological changes in MDA-MB-231 cells. In ER+ cells, constitutive PKC activity and PKCalpha expression were very low as compared to ER- cells, and this correlated with the invasive potential of the cells. The opposed effects of TPA in ER+ and ER- cells could be due to the abnormal TPA regulation of PKCalpha observed in ER- cells.

Ectopic expression of a mutant form of PKCalpha originally found in human tumors: aberrant subcellular translocation and effects on growth control.

A point mutation in PKCalpha was originally discovered in a subpopulation of human pituitary tumors characterized by their invasive phenotype, and the same mutation was also seen in some thyroid neoplasms. To investigate the role of this mutation in tumorigenesis, normal and mutant human PKCalpha cDNAs were overexpressed in Rat6 embryo fibroblasts (R6). When extracts of R6 cells that expressed either the normal or mutant PKCalpha were assayed in the presence of calcium, phosphatidylserine and the phorbol ester TPA, for phosphorylation of either histone IIIS or the EGF-receptor peptide, both extracts gave similar results. However, the subcellular localization of the two proteins differed. Immunohistochemistry studies indicated that after treatment with TPA normal PKCalpha mainly translocated to the plasma membrane, but mutant PKCalpha translocated mainly to the perinuclear region and slightly to the nucleus. Furthermore, the cells that expressed the mutant PKCalpha displayed a decreased requirement for serum when compared to the cells expressing the normal human PKCalpha, and they formed small colonies in soft agar. By contrast, the cells expressing the normal human PKCalpha failed to form colonies in soft-agar. Thus, ectopic expression in rat fibroblasts of this mutant human PKCalpha sequence alters the growth properties of these cells and, when activated, the mutant PKCalpha displays aberrant intracellular translocation. Therefore, this mutation in PKCalpha could contribute to the process of tumor progression in certain human tumors.

Protein kinase C alpha and tumorigenesis of the endocrine gland.

A point mutation in the protein kinase C alpha (PKC alpha) gene has been discovered in a subpopulation of human pituitary tumors characterized by their invasive phenotype. Here we show that: (1) thyroid tumors can express the PKC alpha mutation detected in a subpopulation of follicular adenomas and carcinomas, and (2) mutated PKC alpha has modified enzymatic properties as compared to wild-type PKC alpha. It has lost its capacity to phosphorylate the S17R substrate and exhibits a higher sensitivity to degradation as compared to wild-type PKC alpha. In conclusion, the presence of the PKC alpha mutant in tumors other than pituitary tumors and the observation that the presence of the point mutation induces changes in PKC alpha properties suggest the involvement of this mutant in tumorigenesis.

The natural protein kinase C alpha mutant is present in human thyroid neoplasms.

An altered protein expression of Ca(2+)-dependent protein kinase C (PKC) isoforms and a point mutation in the PKC alpha cDNA (position 908 of the nucleotide sequence, position 294 of the amino acid sequence, substitution of an aspartic acid by a glycine) have been previously described in a subpopulation of human pituitary tumors. In this work, we screened 16 thyroid tissue samples (four follicular adenomas, five colloid adenomas, three papillary carcinomas, one follicular carcinoma and three normal tissues adjacent to the tumors) for the presence of the PKC alpha point mutation and for PKC alpha, beta 1, beta 2, epsilon and delta protein expression. Screening for the presence of the PKC alpha mutant was performed by a subcloning technic. The polymerase chain reaction products were generated using reverse-transcribed cDNAs, subcloned and sequenced (10 clones were routinely sequenced). The PKC alpha point mutation at position 908 of the cDNA sequence was found in four out of the nine adenomas and in the follicular carcinoma. It was neither detected in the papillary carcinomas nor in the adjacent normal tissues (one was the adjacent normal tissue of the follicular carcinoma; in this sample, genomic DNA and cDNA were used to look for the presence of the mutant), demonstrating the somatic nature of this mutant. Western blot analysis of PKC isoforms showed that the expression of all isoforms was higher in the thyroid neoplasms as compared with their adjacent normal tissue (n = 3). It was also higher in the samples containing the PKC mutant (two follicular adenomas, two colloid adenomas and the follicular carcinoma) as compared with the tumors where it was not detected (three papillary carcinomas and five adenomas). Samples could be ordered according to their increasing PKC expression as follows: normal adjacent tissue < follicular adenomas without PKC alpha mutant < or = papillary carcinoma < follicular adenomas with PKC mutant < follicular carcinoma with PKC mutant. In conclusion, the discovery of the PKC alpha mutant in thyroid neoplasms demonstrates that this mutant is not particular to human pituitary tumors where it was originally detected. It is a somatic mutation and its presence is concomitant with high levels of all of the PKC isoforms analysed. The presence of the PKC mutant in thyroid neoplasms raises the question of its importance in thyroid tumorigenesis.