Post-transcriptional control of CCAAT/enhancer-binding protein beta (C/EBPbeta) expression: formation of a nuclear HuR-C/EBPbeta mRNA complex determines the amount of message reaching the cytosol

In 3T3-L1 cells, HuR is constitutively expressed and prior to induction of differentiation localized predominantly to the nucleus. Within minutes of induction of differentiation, nuclear HuR binds to its target ligand mRNAs, and the complexes appear to move to the cytosol. One ligand mRNA is the CCAAT/enhancer-binding protein beta (C/EBPbeta) message. To examine the function and importance of the HuR-C/EBPbeta interaction, retroviral expression constructs were created in which the HuR binding site was altered by deletion (betadel) or deletion and substitution (betad/s). Expression of these constructs in murine embryonic fibroblasts resulted in significant adipose conversion relative to those cells expressing wild type C/EBPbeta. C/EBPbeta protein content was increased markedly in both betadel and betad/s, which correlated with the acquisition of the adipocyte phenotype. Analysis of the betad/s cell line demonstrated a robust expression of C/EBPalpha coincident with peroxisome proliferator-activated receptor gamma expression. Total C/EBPbeta mRNA accumulation indicated no difference between cells harboring either the wild type C/EBPbeta cDNA or betad/s construct. However, cytosolic C/EBPbeta mRNA in the cells expressing the betad/s construct was maintained at levels between 2- and 7-fold greater than in the cells expressing the wild type construct. Alteration in mRNA half-life was not responsible for the increased accumulation. Mechanistically, these data suggest that HuR binding results in nuclear retention of the C/EBPbeta mRNA and is consistent with HuR control, at least in part, of mRNA processing.     

An early event in adipogenesis, the nuclear selection of the CCAAT enhancer-binding protein {beta} (C/EBP{beta}) mRNA by HuR and its translocation to the cytosol

HuR is a ligand for nuclear mRNAs containing adenylate-uridylate-rich elements in the 3'-untranslated region. Once bound to the mRNA, HuR is recognized by adapter proteins that then facilitate nuclear export of the complex. In the cytosol, HuR is thought to function to control stability and translation of its ligand message. In the 3T3-L1 cells HuR is constitutively expressed and localized predominantly to the nucleus in the preadipocytes. However, within 30 min of exposure to the differentiation stimulus the HuR content in the cytosol increases, consistent with HuR regulating the availability of relevant mRNAs for translation. Using in vitro RNA gel shifts, we have demonstrated that the CCAAT enhancer-binding protein beta (C/EBPbeta) message is a ligand for HuR. Within 2 h of initiation of the differentiation process, HuR complexes containing C/EBPbeta mRNA could be isolated from the cytosolic compartment. Importantly, the process appears to be highly selective, as cyclin D1, which contains a putative HuR binding site and is expressed on the same time frame as C/EBPbeta, was not found in the immunoprecipitated messenger ribonucleoprotein complexes. The proximity of this event to adipogenic stimuli and the importance of C/EBPbeta to the differentiation process have led us to hypothesize a role for HuR in the regulation of the onset of adipogenesis. In support of this hypothesis, small interfering RNA suppression of HuR protein content resulted in an inhibition of C/EBPbeta protein expression and an attenuation of the differentiation process.     

Individual optimization: Mechanisms shaping the optimal reaction norm

In general, optimal reaction norms in heterogeneous populations can be obtained only by iterative numerical procedures (McNamara, 1991; Kawecki and Stearns, 1993). We consider two particular, but biologically plausible and analytically tractable cases of individual optimization to gain insight into the mechanisms which shape the optimal reaction norm of fecundity in relation to an environmental variable or an individual trait. In the first case, we assume that the quality of the environment (e.g. food abundance) or the quality of the individual (e.g. body size) is fixed during its entire life; it may also be a heritable individual trait. In the second case, individual quality is assumed to change randomly such that the probability distribution of quality in the next year is the same for the parent and for her offspring. For these two cases, we obtain analytical expressions for the shape of the optimal reaction norm, which are heuristically interpretable in terms of underlying selective mechanisms. It is shown that better quality may reduce the optimal fecundity. This outcome is particularly likely if better quality increases a fecundity-independent factor of parental survival in a long-lived species with fixed quality. This revised version was published online in July 2006 with corrections to the Cover Date.