Nestin is a neuroepithelial target gene of thyroid transcription factor-1, a homeoprotein required for forebrain organogenesis.

Thyroid transcription factor-1 (TTF-1, also known as NKX2.1 and T/EBP), a transcription factor belonging to the NKX-2 family of homeodomain-containing genes, plays an essential role in the organogenesis of the thyroid gland, lung, and ventral forebrain. Nestin is an intermediate filament protein strongly expressed in multipotential neuroepithelial stem cells and rapidly down-regulated during postnatal life. Here we show that stable fibroblastic clones expressing TTF-1 acquire a phenotype reminiscent of neuroepithelial cells in culture and up-regulate the endogenous nestin gene. TTF-1 transactivates in HeLa and NIH3T3 cells a reporter gene driven by a central nervous system-specific enhancer element from the second intron of the rat nestin gene, where it recognizes a DNA-binding site (NestBS) whose sequence resembles a nuclear hormone/cAMP-responsive element very different from canonical TTF-1 binding sites. Nuclear extracts from the head of mouse embryos form a retarded complex with NestBS of the same mobility of the extracts obtained from TTF1-expressing clones, which is either abolished or supershifted in the presence of two different antibodies recognizing the TTF-1 protein. Thus, the neuroepithelial marker nestin is a direct central nervous system-specific target gene of TTF-1, leading to the hypothesis that it might be the effector through which TTF-1 plays its role in the organogenesis of the forebrain.

A potential role for the OTX2 homeoprotein in creating early 'highways' for axon extension in the rostral brain.

Brain pattern formation starts with a subdivision of the neuroepithelium through site-specific expression of regulatory genes and, subsequently, the boundaries between presumptive neuromeres may provide a scaffold for early formation of axon tracts. In the mouse forebrain, the transcription factor OTX2 is strongly expressed at several such boundaries. Combining dye tracing and staining for OTX2 protein, we show that a number of early fibre tracts develop within stripes of OTX2 expression. To analyse a putative influence of OTX2 on the expression of molecules involved in neurite growth, we generated several clones of NIH3T3 cells stably expressing OTX2 protein at varying levels. As shown by immunoblotting, Otx2 transfection affects the expression of a variety of cell and substratum adhesion molecules, rendering the cells a favourable substratum in neurite outgrowth assays. Among the molecules upregulated with increasing levels of OTX2 are NCAM, tenascin-C and DSD-1-PG, which also in situ colocalize with zones of OTX2 expression at boundaries. These data suggest that Otx2 might be involved in defining local substrata for axon extension in the forebrain.

Regulatory interactions between the human HOXB1, HOXB2, and HOXB3 proteins and the upstream sequence of the Otx2 gene in embryonal carcinoma cells.

Vertebrate Hox and Otx genes encode homeodomain-containing transcription factors thought to transduce positional information along the body axis in the segmental portion of the trunk and in the rostral brain, respectively. Moreover, Hox and Otx2 genes show a complementary spatial regulation during embryogenesis. In this report, we show that a 1821-base pair (bp) upstream DNA fragment of the Otx2 gene is positively regulated by co-transfection with expression vectors for the human HOXB1, HOXB2, and HOXB3 proteins in an embryonal carcinoma cell line (NT2/D1) and that a shorter fragment of only 534 bp is able to drive this regulation. We also identified the HOXB1, HOXB2, and HOXB3 DNA-binding region on the 534-bp Otx2 genomic fragment using nuclear extracts from Hox-transfected COS cells and 12.5 days postcoitum mouse embryos or HOXB3 homeodomain-containing bacterial extracts. HOXB1, HOXB3, and nuclear extracts from 12.5 days postcoitum mouse embryos bind to a sequence containing two palindromic TAATTA sites, which bear four copies of the ATTA core sequence, a common feature of most HOM-C/HOX binding sites. HOXB2 protected an adjacent site containing a direct repeat of an ACTT sequence, quite divergent from the ATTA consensus. The region bound by the three homeoproteins is strikingly conserved through evolution and necessary (at least for HOXB1 and HOXB3) to mediate the up-regulation of the Otx2 transcription. Taken together, our data support the hypothesis that anteriorly expressed Hox genes might play a role in the refinement of the Otx2 early expression boundaries in vivo.

Sequence-specific DNA recognition by the thyroid transcription factor-1 homeodomain.

The molecular basis for the DNA binding specificity of the thyroid transcription factor 1 homeodomain (TTF-1HD) has been investigated. Methylation and ethylation interference experiments show that the TTF-1HD alone recapitulates the DNA binding properties of the entire protein. Studies carried out with mutant derivatives of TTF-1HD indicate a precise correspondence of some of its amino acid residues with specific bases in its binding site, allowing a crude orientation of the TTF-1HD within the protein-DNA complex. TTF-1HD shows an overall geometry of interaction with DNA similar to that previously observed for Antennapedia class HDs, even though the binding specificities of these two types of HDs are distinct. We demonstrate that the crucial difference between the binding sites of Antennapedia class and TTF-1 HDs is in the motifs 5'-TAAT-3', recognized by Antennapedia, and 5'-CAAG-3', preferentially bound by TTF-1. Furthermore, the binding of wild type and mutants TTF-1 HD to oligonucleotides containing either 5'-TAAT-3' or 5'-CAAG-3' indicate that only in the presence of the latter motif the Gln50 in TTF-1 HD is utilized for DNA recognition. Since the Gln at position 50 is an essential determinant for DNA binding specificity for several other HDs that bind to 5'-TAAT-3' containing sequences, we suggest that utilization by different HDs of key residues may depend on the sequence context and probably follows a precise hierarchy of contacts.

The thyroid transcription factor-1 gene is a candidate target for regulation by Hox proteins.

Vertebrate Hox homeobox genes are transcription factors which regulate antero-posterior axial identity in embryogenesis, presumably through activation and/or repression of downstream target genes. Some of these targets were reported to code for molecules involved in cell-cell interactions, whereas no relationship has yet been demonstrated between Hox genes and other transcription factors involved in determining and/or maintaining tissue specificity. The thyroid transcription factor-1 (TTF-1) is a homeodomain-containing protein required for expression of thyroid-specific genes. A 862 bp 5' genomic fragment of the rat TTF-1 gene, conferring thyroid-specific expression to a reporter gene, was sufficient to mediate transactivation by the human HOXB3 gene in co-transfection assay in both NIH3T3 or HeLa cells. HOXB3 is expressed in early mammalian embryogenesis in the anterior neuroectoderm, branchial arches and their derivatives, including the area of the thyroid primordia and thyroid gland. Transcription of the TTF-1 promoter is induced only by HOXB3, while its paralogous gene HOXD3 or other Hox genes expressed more posteriorly (HOXA4, HOXD4, HOXC5, HOXC6, HOXC8 and Hoxd-8) have no effect. Transactivation by HOXB3 is mediated by two binding sites containing an ATTA core located at -100 and +30 from the transcription start site. DNase I footprinting experiments show that the two sites bind HOXB3 protein synthesized in both Escherichia coli and eukaryotic cells, as well as nuclear factor(s) present in protein extracts obtained from mouse embryonic tissues which express group 3 Hox genes and TTF-1. Some of the DNA-protein complexes formed by the embryonic extracts are indistinguishable from those generated by HOXB3.(ABSTRACT TRUNCATED AT 250 WORDS)

The upstream region of the human homeobox gene HOX3D is a target for regulation by retinoic acid and HOX homeoproteins.

We studied the structure, regulation and expression of HOX3D, a human homeobox gene located in the HOX3 cluster on chromosome 12. HOX3D is developmentally regulated during embryogenesis and is activated by retinoic acid (RA) in cultured embryonal carcinoma (EC) cells. Transfection of HOX3D upstream genomic sequences linked to a reporter gene allowed the functional definition of its promoter, containing a canonical TATA element. This promoter directs the expression of the reporter gene in EC cells after induction with RA, and binds RA-induced nuclear factor(s) through a conserved palindromic sequence located approximately 100 bp upstream of the transcription start site. The HOX3D promoter is transactivated in both human and murine cells when cotransfected with vectors expressing the protein product of the upstream gene HOX3C and the paralogs of further upstream genes in the HOX4 cluster (i.e. HOX4D, HOX4C and the murine Hox 4.3). The HOX3D protein, and those encoded by the downstream gene HOX3E and its paralog HOX4B are instead inactive. HOX4C and HOX4D proteins synthesized in bacteria bind to the same conserved sequence located around position -120, as well as to the TATA box and immediately upstream and downstream nucleotides. These data provide evidence that cross-regulatory interactions between mammalian homeogenes take place in cultured cells, thus raising the possibility that a regulatory network may exist in vivo. The sequences on the HOX3D promoter involved in cross-regulation are different from those binding nuclear factors induced by RA.

Thyroid nuclear factor 1 (TTF-1) contains a homeodomain and displays a novel DNA binding specificity.

The cDNA for TTF-1, a thyroid nuclear factor that binds to the promoter of thyroid specific genes, has been cloned. The protein encoded by the cDNA shows binding properties indistinguishable from those of TTF-1 present in nuclear extracts of differentiated rat thyroid cells. The DNA binding domain of TTF-1 is a novel mammalian homeodomain that shows considerable sequence homology to the Drosophila NK-2 homeodomain. TTF-1 mRNA and corresponding binding activity are detected in thyroid and lung. The chromosomal localization of the TTF-1 gene has been determined in humans and mice and corresponds to chromosomes 14 and 12, respectively, demonstrating that the TTF-1 gene is not located within previously described clusters of homeobox-containing genes.

Heterogeneity of mRNA expression in Italian fucosidosis patients.

Genomic DNA and mRNA from six unrelated Italian patients affected with fucosidosis were analyzed using two probes (AF3 and AF11B) of partial length cDNA coding for the lysosomal enzyme alpha-L-fucosidase. DNA from patient 2, digested with EcoRI, showed a variant pattern of hybridization caused by the loss of an EcoRI site. The same patient showed a markedly decreased amount of mRNA on Northern blot hybridization. Among the remaining patients, who showed no variation at the DNA level, two apparently lacked mRNA for alpha-L-fucosidase whereas the other three showed a transcript similar in size and amount to that observed in controls. These data confirm the genetic heterogeneity of the molecular defects causing fucosidosis in Italy.

Regulation of IgM biosynthesis in human chronic lymphocytic leukemia. Normal and neoplastic B cells respond differently to TPA.

According to the pattern of IgM biosynthesis (membrane expression and secretion), human B cell chronic lymphocytic leukemias (B-CLLs) were subgrouped into four classes, namely: class I: membrane- secretion-; class II: membrane+ secretion-; class III: membrane+ secretion+; class IV: membrane- secretion+. Abundant membrane mu chain mRNA was present in cells from all cases, indicating that translational and/or post translational events were responsible for the absence of surface IgM in classes I and IV. Similarly, post translational events blocked IgM secretion in non secreting B-CLL cells. In B-CLLs from classes I, II and III, TPA induced IgM secretion by up-regulating secretory mu chain mRNA. By contrast, in normal B cells, TPA induced down-regulation of the secretory form of Ig mRNA, irrespective of the maturational stage of the cell. These observations indicate that IgM biosynthesis is modulated differently by TPA in normal and malignant B cells.