Elizabeth L. Murray

Common SNP in pre-miR-146a decreases mature miR expression and predisposes to papillary thyroid carcinoma

Although papillary thyroid carcinoma (PTC) displays strong heritability, no predisposing germ-line mutations have been found. We show that a common G/C polymorphism (rs2910164) within the pre-miR-146a sequence reduced the amount of pre- and mature miR-146a from the C allele 1.9- and 1.8-fold, respectively, compared with the G allele. This is matched by a similar decrease in the amount of each pre-miR generated from the corresponding pri-miR-146a in an in vitro processing reaction. The C allele also interfered with the binding of a nuclear factor to pre-miR-146a. The reduction in miR-146a led to less efficient inhibition of target genes involved in the Toll-like receptor and cytokine signaling pathway (TRAF6, IRAK1), and PTC1 (also known as CCDC6 or H4), a gene frequently rearranged with RET proto-oncogene in PTC. In an association study of 608 PTC patients and 901 controls, we found marked differences in genotype distribution of rs2910164 (P = 0.000002), the GC heterozygous state being associated with an increased risk of acquiring PTC (odds ratio = 1.62, P = 0.000007), and both homozygous states protective with odds ratio = 0.42 for the CC genotype (P = 0.003) and odds ratio = 0.69 for the GG genotype (P = 0.0006). Moreover, 4.7% of tumors had undergone somatic mutations of the SNP sequence. Thus, our data suggest that a common polymorphism in pre-miR-146a affects the miR expression, contributes to the genetic predisposition to PTC, and plays a role in the tumorigenesis through somatic mutation. Preliminary evidence suggests that these effects are mediated through target genes whose expression is affected by the SNP status.

A role for the eIF4E-binding protein 4E-T in P-body formation and mRNA decay

4E-transporter (4E-T) is one of several proteins that bind the mRNA 5′cap-binding protein, eukaryotic initiation factor 4E (eIF4E), through a conserved binding motif. We previously showed that 4E-T is a nucleocytoplasmic shuttling protein, which mediates the import of eIF4E into the nucleus. At steady state, 4E-T is predominantly cytoplasmic and is concentrated in bodies that conspicuously resemble the recently described processing bodies (P-bodies), which are believed to be sites of mRNA decay. In this paper, we demonstrate that 4E-T colocalizes with mRNA decapping factors in bona fide P-bodies. Moreover, 4E-T controls mRNA half-life, because its depletion from cells using short interfering RNA increases mRNA stability. The 4E-T binding partner, eIF4E, also is localized in P-bodies. 4E-T interaction with eIF4E represses translation, which is believed to be a prerequisite for targeting of mRNAs to P-bodies. Collectively, these data suggest that 4E-T interaction with eIF4E is a priming event in inducing messenger ribonucleoprotein rearrangement and transition from translation to decay.

Multiple regulators control expression of the Entner-Doudoroff aldolase (Eda) of Escherichia coli.

The Escherichia coli eda gene, which encodes the Entner-Doudoroff aldolase, is central to the catabolism of several sugar acids. Here, we show that Eda synthesis is induced by growth on gluconate, glucuronate, or methyl-beta-D-glucuronide; phosphate limitation; and carbon starvation. Transcription of eda initiates from three promoters, designated P1, P2, and P4, each of which is responsible for induction under different growth conditions. P1 controls eda induction on gluconate and is regulated by GntR. P2 controls eda induction on glucuronate and galacturonate and is regulated by KdgR. P4 is active under conditions of phosphate starvation and is directly controlled by PhoB. In addition, CsrA activates Eda synthesis, apparently by an indirect mechanism that may be involved in the modest changes in expression level that are associated with carbon starvation. The complex regulation of eda is discussed with respect to its several physiological roles, which apparently accommodate not only sugar acid catabolism but also detoxification of metabolites that could accumulate during starvation-induced stress.

A+U-Rich Instability Elements Differentially Activate 5′-3′ and 3′-5′ mRNA Decay

ABSTRACT The A+U-rich elements (or AREs) are cis-acting sequences that activate rapid mRNA decay, yet the overall polarity of this process is unknown. The current study describes an unbiased approach to this using the Invader RNA assay (Third Wave Technologies, Inc.) to quantify the decay of each of the three exons of human β-globin mRNA without added instability elements or with the AREs from c-fos or granulocyte-macrophage colony-stimulating factor (GM-CSF) mRNA in the 3′ untranslated region. Each of these genes under tetracycline operator control was stably transfected into cells, and β-globin mRNA was quantified with exon-specific probes following transcription termination. There was little overall evidence for polarity in stable mRNA decay. Adding the c-fos ARE activated rapid and simultaneous decay from both ends of the mRNA. In contrast, the GM-CSF ARE activated decay primarily from the mRNA 5′ end. These data were supported by reciprocal RNA interference knockdowns, and we present evidence that the 5′-3′ and 3′-5′ decay pathways are functionally linked.

Polysome-Bound Endonuclease PMR1 Is Targeted to Stress Granules via Stress-Specific Binding to TIA-1

ABSTRACT The generalized process of mRNA decay involves deadenylation followed by release from translating polysomes, decapping, and exonuclease decay of the mRNA body. In contrast the mRNA endonuclease PMR1 forms a selective complex with its translating substrate mRNA, where it initiates decay by cleaving within the mRNA body. In stressed cells the phosphorylation of the α subunit of eukaryotic initiation factor 2 causes translating mRNAs to accumulate with stalled 48S subunits in large subcellular structures termed stress granules (SGs), wherein mRNAs undergo sorting for reinitiation, storage, or decay. Given the unique relationship between translation and PMR1-mediated mRNA decay, we examined the impact of stress-induced dissociation of polysomes on this process. Arsenite stress disrupts the polysome binding of PMR1 and its substrate mRNA but has no impact on the critical tyrosine phosphorylation of PMR1, its association with substrate mRNA, or its association with the functional ∼680-kDa mRNP complex in which it normally resides on polysomes. We show that arsenite stress drives PMR1 into an RNase-resistant complex with TIA-1, and we identify a distinct domain in the N terminus of PMR1 that facilitates its interaction with TIA-1. Finally, we show that arsenite promotes the delayed association of PMR1 with SGs under conditions which cause tristetraprolin and butyrate response factor 1, proteins that facilitate exonucleolytic mRNA, to exit SGs.

Assays for determining poly(A) tail length and the polarity of mRNA decay in mammalian cells

This chapter describes several methods for measuring the length of the mRNA poly(A) tail and a novel method for measuring mRNA decay. Three methods for measuring the length of a poly(A) tail are presented: the poly(A) length assay, the ligation-mediated poly(A) test (LM-PAT), and the RNase H assay. The first two methods are PCR-based assays involving cDNA synthesis from an oligo(dT) primer. The third method involves removing the poly(A) tail from the mRNA of interest. A major obstacle to studying the enzymatic step of mammalian mRNA decay has been the inability to capture mRNA decay intermediates with structural impediments such as the poly(G) tract used in yeast. To overcome this, we combined a standard kinetic analysis of mRNA decay with a tetracycline repressor-controlled reporter with an Invader RNA assay. The Invader RNA assay is a simple, elegant assay for the quantification of mRNA. It is based on signal amplification, not target amplification, so it is less prone to artifacts than other methods for nucleic acid quantification. It is also very sensitive, able to detect attomolar levels of target mRNA. Finally, it requires only a short sequence for target recognition and quantitation. Therefore, it can be applied to determining the decay polarity of a mRNA by measuring the decay rates of different portions of that mRNA.

The cytoskeleton-associated Ena/VASP proteins are unanticipated partners of the PMR1 mRNA endonuclease

The PMR1 mRNA endonuclease catalyzes the selective decay of a limited number of mRNAs. It participates in multiple complexes, including one containing c-Src, its activating kinase, and one containing its substrate mRNA. This study used tandem affinity purification (TAP) chromatography to identify proteins in HeLa cell S100 associated with the mature 60-kDa form of Xenopus PMR1 (xPMR60). Unexpectedly, this identified a number of cytoskeleton-associated proteins, most notably the Ena family proteins mammalian Enabled (Mena) and vasodilator-stimulated phosphoprotein (VASP). These are regulators of actin dynamics that distribute throughout the cytoplasm and concentrate along the leading edge of the cell. xPMR60 interacts with Mena and VASP in vivo, overexpression of Mena has no impact on mRNA decay, and Mena and VASP are recovered together with xPMR60 in each of the major complexes of PMR1-mRNA decay. In a wound-healing experiment induced expression of active xPMR60 in stably transfected cells resulted in a twofold increase in cell motility compared with uninduced cells or cells expressing inactive xPMR60 degrees . Under these conditions xPMR60 colocalizes with VASP along one edge of the cell.

In Vivo and In Vitro Analysis of Poly(A) Length Effects on mRNA Translation

Regulating gene expression at the translational level controls a wide variety of biological events such as development, long-term memory, stress response, transport and storage of certain nutrients, and viral infection. Protein synthesis at steady-state level can be directly measured with Western blot or using an easy-to-detect reporter such as luciferase. However, these methods do not measure the association of mRNA with ribosomes, which is more meaningful in understanding the mechanism and dynamics of translation. This chapter describes the use of sucrose density gradients for analysis of polysome profiles. RNA or protein samples extracted from gradient fractions are commonly used for further analysis of their association with translating ribosomes. We also describe an in vitro translation system prepared from HeLa S3 cell cytoplasmic extract that shows dependency on the mRNA cap and length of the poly(A) length tail, both features of translation in vivo. This is particularly useful to study the cis- and trans-acting factors involved in translational control. Lastly, we describe a method for transfecting cells with an in vitro prepared RNA to study the impact of poly(A) length on translation. This approach is particularly useful for characterizing cis-acting elements that work in conjunction with poly(A) in regulating translation.