Phosphorylation of activation functions AF-1 and AF-2 of RAR alpha and RAR gamma is indispensable for differentiation of F9 cells upon retinoic acid and cAMP treatment

The role of RAR alpha 1 and RAR gamma 2 AF-1 and AF-2 activation functions and of their phosphorylation was investigated during RA-induced primitive and parietal differentiation of F9 cells. We found that: (i) primitive endodermal differentiation requires RAR gamma 2, whereas parietal endodermal differentiation requires both RAR gamma 2 and RAR alpha 1, and in all cases AF-1 and AF-2 must synergize; (ii) primitive endodermal differentiation requires the proline-directed kinase site of RAR gamma 2-AF-1, whereas parietal endodermal differentiation additionally requires that of RAR alpha 1-AF-1; (iii) the cAMP-induced parietal endodermal differentiation also requires the protein kinase A site of RAR alpha-AF-2, but not that of RAR gamma; and (iv) the AF-1-AF-2 synergism and AF-1 phosphorylation site requirements for RA-responsive gene induction are promoter context-dependent. Thus, AF-1 and AF-2 of distinct RARs exert specific cellular and molecular functions in a cell-autonomous system mimicking physiological situations, and their phosphorylation by kinases belonging to two main signalling pathways is required to enable RARs to transduce the RA signal during F9 cell differentiation.     

Matrix induced re-differentiation of cultured rat hepatocytes and changes of CCAAT/enhancer binding proteins

Rat hepatocytes de-differentiate and proliferate when cultured on collagen-coated dishes in a chemically defined Hepatocyte Growth Medium in the presence of hepatocyte growth factor and epidermal growth factor. The addition of biomatrix derived from Engelbreth-Holm-Swarm (EHS) mouse sarcoma stops this process and leads to re-differentiation of the cells. We monitored DNA binding activity and protein levels of CCAAT/Enhancer Binding Proteins (C/EBPs) during these events by electrophoretic mobility shift assays and western blot analysis. We used plasma protein gene expression as a marker for the proliferation and differentiation phases. During the initial proliferation phase the DNA binding activity of C/EBPs decreased about 5-10 fold, mainly due to reduction of C/EBP alpha protein to nearly undetectable levels. Addition of EHS-gel prevented the further loss of C/EBP alpha protein and established a new steady state level. Since C/EBP beta proteins were affected to a much lesser extent, the C/EBP alpha:C/EBP beta ratio was greater in the presence of EHS-gel. Transferrin, alpha 1-antitrypsin, and albumin mRNA expression increased substantially. Thus stabilized C/EBP alpha expression, an increased C/EBP alpha:C/EBP beta ratio, and increased expression of liver specific mRNAs all correlated with the transition of proliferative to differentiated cells.     

Mechanism of transformation by v-ErbA: substitution for steroid hormone receptor function in self renewal induction

V-ErbA, a mutated thyroid hormone receptor (TR) alpha cooperates with tyrosine kinase oncoproteins to induce fatal erythroleukemia in chicks. In vitro, v-ErbA employs a similar cooperation to induce sustained proliferation and arrest differentiation of committed erythroid progenitors. V-ErbA has been proposed to function as a dominant-negative c-ErbA/TR alpha, since it lacks an AF-2 transactivation domain and cannot be activated by hormone but retains the capacity to bind corepressors. However, v-ErbA fails to heterodimerize with the coreceptor RXR, exhibits an altered DNA binding specificity and fails to suppress the action of coexpressed TR alpha/c-ErbA in erythroblasts. In this paper, we identify a novel mechanism by which v-ErbA contributes to leukemogenesis. Recently, the glucocorticoid receptor (GR) was identified as a key regulator of proliferation and differentiation in normal erythroid progenitors. For this, the GR required to cooperate with endogenous receptor tyrosine kinases (c-Kit) and with the estrogen receptor (ER). Here, we demonstrate that v-ErbA can substitute for the ligand-activated GR and ER, inducing proliferation and arresting differentiation in the presence of specific GR and ER antagonists. Like the GR, v-ErbA required to cooperate with c-Kit for both proliferation induction and differentiation arrest, being devoid of biological activity in the absence of an active c-Kit. In self-renewing erythroblasts, v-ErbA not only repressed known v-ErbA target genes but also maintained high expression of c-myb. These biological activities of v-ErbA depended on distinct mutations in the DNA-binding domain. Additionally, v-ErbA acted as a partial, weak repressor of c-ErbA/TR alpha function in normal erythroblasts. It could be converted into a truly dominant-negative receptor by restoring its ability to heterodimerize with RXR.     

Induction of a subgroup of acute phase protein genes in mouse liver by hyperthermia

We have demonstrated that two members of the acute phase reactant family of positively regulated genes, alpha 1-acid glycoprotein (AGP-1 and AGP-2) and C-reactive protein (CRP) are induced by hyperthermia, while two others, the serum amyloid A (SAA) and alpha 1-antitrypsin (AT) genes, are not. Albumin (ALB), a negative acute phase reactant gene, is also induced by hyperthermia. The AGP-1, AGP-2, and CRP genes require glucocorticoids, but not IL-6, IL-1 beta or TNF alpha in response to hyperthermia. As with LPS, the C/EBP beta mRNA levels increased, while the C/EBP alpha mRNA levels decreased in response to LPS. In contrast to the LPS response, C/EBP delta was unchanged. Protein pool levels and DNA-binding activities of the 35 and 20 kDa C/EBP beta isoforms increase, whereas protein pool levels of the 42 kDa C/EBP alpha decrease and the 30kDa remained high. These studies suggest that the synthesis of specific C/EBP alpha and C/EBP beta isoforms is induced by hyperthermia, and that the regulation of the AGP-1 and AGP-2 genes during heat stress may involve one of these isoforms. The difference between the responses to hyperthermia and LPS is that the former, may not involve the participation of cytokines. Furthermore, since cis-acting heat shock elements (HSE) are located in the promoter regions of the ALB, CRP, and C/EBP beta genes, these regulatory sequences may be involved in the in vivo activation of these genes by hyperthermia.