Christiane Christophe-Hobertus

Nuclear targeting of proteins: how many different signals?

The nuclear import of proteins into the cell nucleus involves the recognition of a nuclear localization signal sequence, borne by the protein to be transported, by complex molecules called importins, that will subsequently mediate the crossing over of the nuclear envelope. The most frequently encountered signal sequence is made up of short stretches of basic amino acid residues and is recognized by importins alpha and/or beta. Other signal sequences have been described, and some have been shown to mediate the association with importins other than importin alpha or beta. Recently, approaches have been developed that allow the cloning, on a functional basis, of sequences able to specify the nuclear localization of proteins. A variety of peptidic motifs of limited size which do not contain previously described signal sequences were isolated in such assays. It reveals that the spectrum of sequences that are able to target a protein to the cell nucleus may be wider than currently expected. It will probably also lead to the identification of novel target sequences for importins and will demonstrate the implication of additional members of this family of proteins in nuclear transport.

Identification of a transcriptional enhancer upstream from the bovine thyroglobulin gene

The DNA sequences corresponding to a DNaseI-hypersensitive region identified previously in bovine thyroglobulin gene chromatin (Hansen et al. (1988) Eur. J. Biochem. 178, 387-393) exhibited the properties of a transcriptional enhancer in a transient assay in primary cultured dog thyrocytes, but did not so in transfected HeLa cells. By contrast to the thyroglobulin proximal promoter, the enhancer element did not require cyclic AMP stimulation of the thyrocytes to be active. Using a bi-directional deletion approach, the minimal region displaying enhancer activity has been localized between positions -1906 and -1744 relative to the thyroglobulin gene transcription start. DNA-footprinting experiments revealed the presence of several binding sites for the thyroid-specific transcription factor TTF-1 within the enhancer sequence.

Delimitation and functional characterization of the bidirectional THOX―DUOXA promoter regions in thyrocytes

The THOX and DUOXA genes encode components of the oxidative machinery involved in thyroid hormone biosynthesis. Both of these genes are duplicated in mammalian genomes and are positioned in a head-to-head configuration, THOX1 facing DUOXA1 and THOX2 facing DUOXA2, respectively. The intergenic regions in both couples of genes exhibit dissimilar compositions, being highly GC-rich in the case of THOX1-DUOXA1 but not in the other case. In this study we localized precisely the transcription starts of all four genes using the RLM-RACE technique. It revealed that the distance between THOX1 and DUOXA1 transcription units is of about 70bp only, whereas THOX2 and DUOXA2 transcription starts are separated by 170bp. Analysis of these putative promoter regions revealed the presence of several potential binding sites for transcription factor Sp1 within the THOX1-DUOXA1 intergenic space, and of a TATA box and an Inr element in front of DUOXA2 and THOX2 genes, respectively. The putative promoter regions were inserted into a specifically designed vector harbouring two distinct reporter genes facing each other and their activity was investigated in transient transfection experiments in rat thyroid PCCl3 cells. Both regions exhibited bidirectional promoter activity in the assay. Gel shift experiments using extracts obtained from PCCl3 cells demonstrated the existence of at least one functional Sp1 binding site within the THOX1-DUOXA1 promoter. When Sp1 binding was abolished by mutation of the DNA sequence, a clear reduction in promoter activity in both THOX1 and DUOXA1 directions was observed in the functional assay. As these promoter sequences are well conserved in mammalian genomes, it appears very likely that the results we obtained here in the rat may be extended to the other species.

Human Thyroid Oxidases genes promoter activity in thyrocytes does not appear to be functionally dependent on Thyroid Transcription Factor-1 or Pax8.

Thyroid Oxidases (ThOX/DUOX) genes encode proteins that are thought to play a crucial role in the biosynthesis of thyroid hormone by providing the oxidizing agent required to allow the organification of iodine. The expression of these genes is not restricted to the thyroid, but the corresponding mRNAs are found in the thyrocyte more abundantly than in several other cell types. It raises the question whether the same transcription factors, namely Thyroid Transcription Factor-1 (TTF-1) and Pax8, that control the expression of other genes involved in the differentiated thyroid function, also regulate ThOX/DUOX gene transcription in the thyrocyte. We set up a functional co-transfection assay in which fusion proteins composed of the DNA-binding domain of either TTF-1 or Pax8 fused to the repressive domain of the drosophila engrailed protein were used to competitively counteract the activity of endogenous TTF-1 or Pax8 factor in the differentiated thyroid cell line PCCl3. Contrary to the Thyroglobulin or Thyroid Peroxidase promoter, the known regulatory elements of the human ThOX/DUOX genes displayed no reduction in transcriptional activity when either TTF-1 or Pax8 competitor was produced in the cell, indicating that the presently characterized control elements of human ThOX/DUOX genes are not responsive to these thyroid-specific transcription factors.

Functional inactivation of thyroid transcription factor-1 in PCCl3 thyroid cells.

Thyroid transcription factor-1 (TTF-1) is a key regulator of thyroid development and function. In order to identify the genes whose expression depends on TTF-1 transcriptional activity within the thyrocyte we analyzed the consequence of the functional inactivation of this factor in PCCl3 cells. The expression of a fusion protein composed of the DNA binding domain of TTF-1 and of the strong repressive domain of the engrailed protein resulted in a dramatic loss of epithelial cell morphology and in proliferation arrest. These changes were reversed when the inhibition of endogenous TTF-1 was relieved. No change was observed when a similar fusion protein containing point mutations abolishing DNA binding activity was produced in the cells. Besides the expected down-regulation of expression of the main genes linked to the differentiated thyroid function, we observed a decreased expression of the transcription factors Hhex, Pax 8 and TTF-2 and of E-cadherin. By contrast, both ThOX-1 and DUOXA-1 genes were up-regulated, as well as the ones encoding vimentin and several proteins involved in cell cycle arrest. Our data thus extend the known roles of TTF-1 in thyroid development and in the expression of differentiated function in the adult organ to the control of epithelial morphology and of cell division in mature thyrocytes.

Expression of a transactivation-deficient form of thyroid transcription factor I decreases the activity of co-transfected thyroglobulin and thyroperoxidase promoters

Thyroid transcription factor I (TTF‐1) plays a critical role in thyroid organogenesis and in the control of expression of several thyroid‐specific genes, like those coding for thyroglobulin and thyroperoxidase. We have expressed the isolated DNA‐binding homeodomain of TTF‐1 in cultured thyroid cells by transient transfection. A specific reduction in the activity of cotransfected thyroglobulin and thyroperoxidase promoters was observed in the presence of the isolated TTF‐1 homeodomain, as compared to their activity measured in the presence of a mutated homeodomain unable to bind DNA. The activity of the SV40 early promoter, used as a control, was only marginally affected in these experiments. The transactivation‐deficient form of TTF‐1 described here may thus be used for investigating other cellular processes that are dependent on TTF‐1 transcriptional activity.

Isolation and functional characterization of the rat Thyroglobulin gene upstream enhancer region

We report here the isolation and functional characterization of the as yet undescribed rat Thyroglobulin gene upstream enhancer element.

The homopurine–homopyrimidine DNA sequence flanking the thyroglobulin gene does not behave as a transcriptional diode in living cells

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Identification of a short basic peptide motif able to drive copy-number dependent nuclear accumulation of a linked protein.

The repetitive [RTRG](6) peptide was fortuitously identified as a potent nuclear localization signal when linked to the green fluorescent reporter protein. Replacing the arginines by lysines, or the threonines by glycines, both resulted in a decreased nuclear targeting ability of the peptide within this context. By contrast, the sequence [RT](12) proved able to drive nuclear accumulation of the linked protein as efficiently as the starting peptide. Remarkably, [RTRG](n) peptides where n=2 to 6 showed a gradual, copy-number dependent, increase in their ability to target the green fluorescent protein to the cell nucleus. As a consequence, the nuclear to cytoplasmic concentration ratio of the linked protein within the cell could be adjusted to different values depending on the number of repeats used in the fusion. Our observation may open the way to the use of [RTRG](n) repeats of given lengths (n=2 to 6) for fixing the nuclear-cytoplasmic partition of shuttling protein domains in the course of their functional study.