Avian erythroleukemia: a model for corepressor function in cancer.

Transcriptional regulation at the level of chromatin plays crucial roles during eukaryotic development and differentiation. A plethora of studies revealed that the acetylation status of histones is controlled by multi-protein complexes containing (de)acetylase activities. In the current model, histone deacetylases and acetyltransferases are recruited to chromatin by DNA-bound repressors and activators, respectively. Shifting the balance between deacetylation, i.e. repressive chromatin and acetylation, i.e. active chromatin can lead to aberrant gene transcription and cancer. In human acute promyelocytic leukemia (APL) and avian erythroleukemia (AEL), chromosomal translocations and/or mutations in nuclear hormone receptors, RARalpha [NR1B1] and TRalpha [NR1A1], yielded oncoproteins that deregulate transcription and alter chromatin structure. The oncogenic receptors are locked in their 'off' mode thereby constitutively repressing transcription of genes that are critical for differentiation of hematopoietic cells. AEL involves an oncogenic version of the chicken TRalpha, v-ErbA. Apart from repression by v-ErbA via recruitment of corepressor complexes, other repressors and corepressors appear to be involved in repression of v-ErbA target genes, such as carbonic anhydrase II (CAII). Reactivation of repressed genes in APL and AEL by chromatin modifying agents such as inhibitors of histone deacetylase or of methylation provides new therapeutic strategies in the treatment of acute myeloid leukemia.

Dual role for transcription factor AP-2 in the regulation of the major fetal promoter P3 of the gene for human insulin-like growth factor II.

The human insulin-like growth factor II (IGF-II) gene contains four promoters that are differentially active during cell growth and development. Promoter 3 (P3) is the most active promoter in fetal and non-hepatic adult tissues. In addition to its expression during development, P3 is also the major promoter in many tumour tissues and IGF-II-expressing cell lines. Here we show that AP-2 has a dual function in P3 regulation in vivo as well as in vitro. In cells expressing low levels of endogenous AP-2, AP-2 overexpression activates P3, whereas P3 promoter activity is inhibited in cells containing abundant AP-2. Four potential AP-2-binding sites were identified in footprinting studies with recombinant AP-2. One of these AP-2-binding sites is located within the previously identified element P3-4 that contains two adjacent binding sites for IGF-II promoter-binding proteins IPBP3 and IPBP4/5. By applying binding competition assays and mutational analysis it is shown that AP-2 interferes with IPBP3 binding and transactivation in vivo as well as in vitro. Furthermore, AP-2 can bind additional elements in the proximal P3 promoter that also contribute to AP-2-mediated transactivation as shown by transient transfection assays. From these results we conclude that AP-2 is an important regulator in vivo and in vitro of IGF-II P3 activity.

Identification of a key regulatory element for the basal activity of the human insulin-like growth factor II gene promoter P3.

Transcription of the human insulin-like growth factor II (IGF-II) gene is under the control of four promoters (P1-P4) that are differentially active during growth and development. Promoter 3 (P3) is the most active promoter during fetal development as well as in most adult tissues. P3 is also the most active promoter in tumour tissues and cell lines expressing IGF-II. Transient transfections of HeLa and Hep3B cells with truncated promoter constructs revealed that the region between -289 and -183 relative to the transcription start site supports basal promoter activity in both cell lines. Footprint experiments showed that the region between positions -192 and -172 (P3-4) is the only element bound by nuclear proteins. P3-4 is bound by five proteins, of which three proteins (proteins 3, 4 and 5) bind specifically and are expressed at the same levels in HeLa and Hep3B cells. Electrophoretic mobility shift assays and differential footprint experiments revealed the presence of two protein-binding regions within the P3-4 element. Proteins 4 and 5 bind box A (-193 to -188), whereas box B (-183 to -172) is bound by protein 3. From transcription experiments in vitro it can be concluded that Box A is essential for P3 activity. Box A is part of a region 11 dG residues long and is protected by proteins 4 and 5 that bind a contiguous set of six dG residues. DNA-binding of proteins 4 and 5 to box A requires the presence of Zn2+ ions. Thus structural and functional analysis reveals that the P3-4 element is a key regulatory element of P3 that contains two separate binding sites for proteins essential for the basal activity of IGF-II P3.