The translational response of the human mdm2 gene in HEK293T cells exposed to rapamycin: a role for the 5′-UTRs

Polysomal messenger RNA (mRNA) populations change rapidly in response to alterations in the physiological status of the cell. For this reason, translational regulation, mediated principally at the level of initiation, plays a key role in the maintenance of cellular homeostasis. In an earlier translational profiling study, we followed the impact of rapamycin on polysome re-seeding. Despite the overall negative effect on transcript recruitment, we nonetheless observed that some mRNAs were significantly less affected. Consequently, their relative polysomal occupancy increased in the rapamycin-treated cells. The behaviour of one of these genes, mdm2, has been further analysed. Despite the absence of internal ribosome entry site activity we demonstrate, using a dual reporter assay, that both the reported mdm2 5′-UTRs confer resistance to rapamycin relative to the 5′-UTR of β-actin. This relative resistance is responsive to the downstream targets mTORC1 but did not respond to changes in the La protein, a reported factor acting positively on MDM2 translational expression. Furthermore, extended exposure to rapamycin in the presence of serum increased the steady-state level of the endogenous MDM2 protein. However, this response was effectively reversed when serum levels were reduced. Taken globally, these studies suggest that experimental conditions can dramatically modulate the expressional output during rapamycin exposur

Alternatively spliced isoforms of the human elk-1 mRNA within the 5′ UTR: implications for ELK-1 expression

The expression of cellular proteins that play central roles in the regulation of cell growth and differentiation is frequently tightly controlled at the level of translation initiation. In this article, we provide evidence that the ETS domain transcription factor ELK-1 forms part of this class of genes. Its mRNA 5′ UTR is composed of a complexed mosaic of elements, including uAUGs, uORFs and RNA structure, that interplay to modulate ribosomal access to the ELK-1 AUG start codon. Superimposed upon this is the generation of two different 5′ UTRs via alternative splicing. The two spliced isoforms show altered cellular and tissue distributions and behave differently in polysomal recruitment assays in the presence of the drug rapamycin. We propose that repression is therefore the sum of a series of interplaying negative elements within the 5′ UTRs, a situation which may reflect the need for tight translational control of ELK-1 in different tissues and under changing physiological condition

The translational response of the human mdm2 gene in HEK293T cells exposed to rapamycin: a role for the 5′-UTRs

Polysomal messenger RNA (mRNA) populations change rapidly in response to alterations in the physiological status of the cell. For this reason, translational regulation, mediated principally at the level of initiation, plays a key role in the maintenance of cellular homeostasis. In an earlier translational profiling study, we followed the impact of rapamycin on polysome re-seeding. Despite the overall negative effect on transcript recruitment, we nonetheless observed that some mRNAs were significantly less affected. Consequently, their relative polysomal occupancy increased in the rapamycin-treated cells. The behaviour of one of these genes, mdm2, has been further analysed. Despite the absence of internal ribosome entry site activity we demonstrate, using a dual reporter assay, that both the reported mdm2 5′-UTRs confer resistance to rapamycin relative to the 5′-UTR of β-actin. This relative resistance is responsive to the downstream targets mTORC1 but did not respond to changes in the La protein, a reported factor acting positively on MDM2 translational expression. Furthermore, extended exposure to rapamycin in the presence of serum increased the steady-state level of the endogenous MDM2 protein. However, this response was effectively reversed when serum levels were reduced. Taken globally, these studies suggest that experimental conditions can dramatically modulate the expressional output during rapamycin exposure

An approach to analyse the specific impact of rapamycin on mRNA-ribosome association

<p>Abstract</p> <p>Background</p> <p>Recent work, using both cell culture model systems and tumour derived cell lines, suggests that the differential recruitment into polysomes of mRNA populations may be sufficient to initiate and maintain tumour formation. Consequently, a major effort is underway to use high density microarray profiles to establish molecular fingerprints for cells exposed to defined drug regimes. The aim of these pharmacogenomic approaches is to provide new information on how drugs can impact on the translational read-out within a defined cellular background.</p> <p>Methods</p> <p>We describe an approach that permits the analysis of de-novo mRNA-ribosome association in-vivo during short drug exposures. It combines hypertonic shock, polysome fractionation and high-throughput analysis to provide a molecular phenotype of translationally responsive transcripts. Compared to previous translational profiling studies, the procedure offers increased specificity due to the elimination of the drugs secondary effects (e.g. on the transcriptional read-out). For this pilot "proof-of-principle" assay we selected the drug rapamycin because of its extensively studied impact on translation initiation.</p> <p>Results</p> <p>High throughput analysis on both the light and heavy polysomal fractions has identified mRNAs whose re-recruitment onto free ribosomes responded to short exposure to the drug rapamycin. The results of the microarray have been confirmed using real-time RT-PCR. The selective down-regulation of TOP transcripts is also consistent with previous translational profiling studies using this drug.</p> <p>Conclusion</p> <p>The technical advance outlined in this manuscript offers the possibility of new insights into mRNA features that impact on translation initiation and provides a molecular fingerprint for transcript-ribosome association in any cell type and in the presence of a range of drugs of interest. Such molecular phenotypes defined pre-clinically may ultimately impact on the evaluation of a particular drug in a living cell.</p

Alternatively spliced isoforms of the human elk-1 mRNA within the 5′ UTR: implications for ELK-1 expression

The expression of cellular proteins that play central roles in the regulation of cell growth and differentiation is frequently tightly controlled at the level of translation initiation. In this article, we provide evidence that the ETS domain transcription factor ELK-1 forms part of this class of genes. Its mRNA 5′ UTR is composed of a complexed mosaic of elements, including uAUGs, uORFs and RNA structure, that interplay to modulate ribosomal access to the ELK-1 AUG start codon. Superimposed upon this is the generation of two different 5′ UTRs via alternative splicing. The two spliced isoforms show altered cellular and tissue distributions and behave differently in polysomal recruitment assays in the presence of the drug rapamycin. We propose that repression is therefore the sum of a series of interplaying negative elements within the 5′ UTRs, a situation which may reflect the need for tight translational control of ELK-1 in different tissues and under changing physiological conditions

elk-1 mRNA within the 5 0 UTR: implications for ELK-1 expression

The expression of cellular proteins that play central roles in the regulation of cell growth and differentiation is frequently tightly controlled at the level of translation initiation. In this article, we provide evidence that the ETS domain transcription factor ELK-1 forms part of this class of genes. Its mRNA 5 0 UTR is composed of a complexed mosaic of elements, including uAUGs, uORFs and RNA structure, that interplay to modulate ribosomal access to the ELK-1 AUG start codon. Superimposed upon this is the generation of two different 5 0 UTRs via alternative splicing. The two spliced isoforms show altered cellular and tissue distributions and behave differently in polysomal recruitment assays in the presence of the drug rapamycin. We propose that repression is therefore the sum of a series of interplaying negative elements within the 5 0 UTRs, a situation which may reflect the need for tight translational control of ELK-1 in different tissues and under changing physiological conditions

Computational KIR copy number discovery reveals interaction between inhibitory receptor burden and survival.

Natural killer (NK) cells have increasingly become a target of interest for immunotherapies. NK cells express killer immunoglobulin-like receptors (KIRs), which play a vital role in immune response to tumors by detecting cellular abnormalities. The genomic region encoding the 16 KIR genes displays high polymorphic variability in human populations, making it difficult to resolve individual genotypes based on next generation sequencing data. As a result, the impact of polymorphic KIR variation on cancer phenotypes has been understudied. Currently, labor-intensive, experimental techniques are used to determine an individual's KIR gene copy number profile. Here, we develop an algorithm to determine the germline copy number of KIR genes from whole exome sequencing data and apply it to a cohort of nearly 5000 cancer patients. We use a k-mer based approach to capture sequences unique to specific genes, count their occurrences in the set of reads derived from an individual and compare the individual's k-mer distribution to that of the population. Copy number results demonstrate high concordance with population copy number expectations. Our method reveals that the burden of inhibitory KIR genes is associated with survival in two tumor types, highlighting the potential importance of KIR variation in understanding tumor development and response to immunotherapy