Iron regulates the stability of the mRNA encoding the transferrin receptor (TfR). When iron is scarce, iron regulatory proteins (IRPs) stabilize TfR mRNA by binding to the 3-untranslated region. High levels of iron induce degradation of TfR mRNA; the translation inhibitor cycloheximide prevents this. To distinguish between cotranslational mRNA decay and a trans effect of translation inhibitors, we designed a reporter system exploiting the properties of the selectable marker gene thymidine kinase (TK). The 3-untranslated region of human transferrin receptor, which contains all elements necessary for iron-dependent regulation of mRNA stability, was fused to the TK cDNA. In stably transfected mouse fibroblasts, the expression of the reporter gene was perfectly regulated by iron. Introduction of stop codons in the TK coding sequence or insertion of stable stem-loop structures in the leader sequence did not affect on the iron-dependent regulation of the reporter mRNA. This implies that global translation inhibitors stabilize TfR mRNA in trans. Cycloheximide prevented the destabilization of TfR mRNA only in the presence of active IRPs. Inhibition of IRP inactivation by cycloheximide or by the specific proteasome inhibitor MG132 correlated with the stabilization of TfR mRNA. These observations suggest that inhibition of translation by cycloheximide interferes with the rate-limiting step of iron-induced TfR mRNA decay in a transacting mechanism by blocking IRP inactivation.
The expression of the salvage pathway enzyme thymidine kinase (TK) is very low in resting mammalian cells, but increases dramatically when growth-stimulated cells enter S phase. The 30-fold rise in TK mRNA levels in response to growth factors is due to a well-characterized transcriptional activation and less defined post-transcriptional mechanisms. A minigene containing the murine TK promoter and the TK cDNA showed a 3-fold increase in TK mRNA levels after growth induction in stably transfected mouse TK-deficient L fibroblasts. Introduction of the first three TK introns resulted in a 10-fold regulation of TK expression which was predominantly due to repressed TK mRNA levels in serum-deprived cells. Removal of intron 3 from this construct or replacement of the TK promoter by a constitutive SV40 promoter led to a reduced, but still significant increase in TK mRNA levels during the onset of proliferation. These results indicate that both the TK promoter and specific TK introns contribute independently to the growth-dependent regulation of TK mRNA expression. To examine the regulatory mechanisms in more detail we analyzed TK transcription rates and steady-state levels of nuclear transcripts from an SV40 promoter-driven minigene that contains introns 2 and 3 of the TK gene. Using a set of single-stranded probes we detected TK-specific antisense transcription that was up-regulated in resting cells. Similarly, antisense transcription of the endogenous TK gene in Swiss 3T3 cells rose during serum deprivation while sense transcription was regulated in the opposite way. Luciferase reporter assays revealed the presence of a putative antisense promoter in intron 3 of the murine TK gene. These results suggest a negative role for intron-dependent antisense transcription in the regulation of TK mRNA expression in mouse fibroblasts.
BackgroundAurora-A is a bona-fide oncogene whose expression is associated with genomic instability and malignant transformation. In several types of cancer, gene amplification and/or increased protein levels of Aurora-A are a common feature.ResultsIn this report, we describe that inhibition of cell proliferation is the main effect observed after transient overexpression of Aurora-A in primary human cells. In addition to the known cell cycle block at the G2/M transition, Aurora-A overexpressing cells fail to overcome the restriction point at the G1/S transition due to diminished RB phosphorylation caused by reduced Cyclin D1 expression. Consequently, overexpression of Cyclin D1 protein is able to override the Aurora-A mediated G1 block. The Aurora-A mediated cell cycle arrest in G2 is not influenced by Cyclin D1 and as a consequence cells accumulate in G2. Upon deactivation of p53 part of the cells evade this premitotic arrest to become aneuploid.ConclusionOur studies describe that an increase of Aurora-A expression levels on its own has a tumor suppressing function, but in combination with the appropriate altered intracellular setting it might exert its oncogenic potential. The presented data indicate that deactivation of the tumor suppressor RB is one of the requirements for overriding a cell cycle checkpoint triggered by increased Aurora-A levels.
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