Overexpression of poly(A) binding protein prevents maturation-specific deadenylation and translational inactivation in Xenopus oocytes.

Wormington, Michael; Searfoss, Anjanette M.; Hurney, Carol A.

doi:10.1002/j.1460-2075.1996.tb00424.x

Cited by 102 publications

(98 citation statements)

References 62 publications

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“…Thus, cytoplasmic polyadenylation is thought to exert its effects on translation largely by recruiting PABPs to the newly extended poly(A) tails. Consistent with a role of PABP in poly(A) tail mediated changes during oogenesis, overexpression of PABP1 in X. laevis oocytes blocks the maturation-induced deadenylation and translational inactivation of mRNAs that lack CPEs, as well as inhibiting the recruitment of some CPE-containing mRNAs onto polysomes (Wormington et al 1996). A role for PABP in oogenesis is also indicated by early meiotic defects in PAB-1-deficient C. elegans (Maciejowski et al 2005).…”

Section: Pabpssupporting

confidence: 52%

The DAZL and PABP families: RNA-binding proteins with interrelated roles in translational control in oocytes

Brook¹,

Smith²,

Gray³

2009

Reproduction

111

114

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Gametogenesis is a highly complex process that requires the exquisite temporal, spatial and amplitudinal regulation of gene expression at multiple levels. Translational regulation is important in a wide variety of cell types but may be even more prevalent in germ cells, where periods of transcriptional quiescence necessitate the use of post-transcriptional mechanisms to effect changes in gene expression. Consistent with this, studies in multiple animal models have revealed an essential role for mRNA translation in the establishment and maintenance of reproductive competence. While studies in humans are less advanced, emerging evidence suggests that translational regulation plays a similarly important role in human germ cells and fertility. This review highlights specific mechanisms of translational regulation that play critical roles in oogenesis by activating subsets of mRNAs. These mRNAs are activated in a strictly determined temporal manner via elements located within their 3 0 UTR, which serve as binding sites for trans-acting factors. While we concentrate on oogenesis, these regulatory events also play important roles during spermatogenesis. In particular, we focus on the deleted in azoospermia-like (DAZL) family of proteins, recently implicated in the translational control of specific mRNAs in germ cells; their relationship with the general translation initiation factor poly(A)-binding protein (PABP) and the process of cytoplasmic mRNA polyadenylation.

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Section: Pabpssupporting

confidence: 52%

The DAZL and PABP families: RNA-binding proteins with interrelated roles in translational control in oocytes

Brook¹,

Smith²,

Gray³

2009

Reproduction

111

114

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“…Overexpression of PABP leads to defects in cell division of the fission yeast Saccharomyces pombe (Tallada et al, 2002) and increases the translation termination efficiency in Saccharomyces cerevisiae (Cosson et al, 2002). Moreover, high PABP levels interfere with maturation-specific deadenylation and translational inactivation of maternal mRNAs in Xenopus oocytes (Wormington et al, 1996). In addition, elevated PABP levels have been detected in early stages of cancer supporting a link between cell growth and PABP levels (Verlaet et al, 2001).…”

Section: Discussionmentioning

confidence: 98%

Ataxin-2 Interacts with the DEAD/H-Box RNA Helicase DDX6 and Interferes with P-Bodies and Stress Granules

Nonhoff

Ralser

Welzel

et al. 2007

MBoC

308

320

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Tight control of translation is fundamental for eukaryotic cells, and deregulation of proteins implicated contributes to numerous human diseases. The neurodegenerative disorder spinocerebellar ataxia type 2 is caused by a trinucleotide expansion in the SCA2 gene encoding a lengthened polyglutamine stretch in the gene product ataxin-2, which seems to be implicated in cellular RNA-processing pathways and translational regulation. Here, we substantiate a function of ataxin-2 in such pathways by demonstrating that ataxin-2 interacts with the DEAD/H-box RNA helicase DDX6, a component of P-bodies and stress granules, representing cellular structures of mRNA triage. We discovered that altered ataxin-2 levels interfere with the assembly of stress granules and cellular P-body structures. Moreover, ataxin-2 regulates the intracellular concentration of its interaction partner, the poly(A)-binding protein, another stress granule component and a key factor for translational control. Thus, our data imply that the cellular ataxin-2 concentration is important for the assembly of stress granules and P-bodies, which are main compartments for regulating and controlling mRNA degradation, stability, and translation. INTRODUCTIONAn essential step in the control of global gene expression in eukaryotes is the regulation of mRNA translation and degradation. Shortening of the poly(A) tail is the initial step to trigger mRNA for decay in two major mRNA degradation pathways in eukaryotic cells (Bernstein and Ross, 1989;Peltz et al., 1991;Decker and Parker, 1994;Beelman and Parker, 1995). In one pathway, the deadenylated mRNA is degraded by a cytoplasmic protein complex, the exosome, consisting of a number of exonucleases with 3Ј-5Ј activity (Butler, 2002). In the other pathway, shortening of the poly(A) tail leads to the removal of the cap structure of the mRNA by the decapping proteins DCP1 and DCP2 facilitating 5Ј-3Ј degradation of the mRNA through the exoribonuclease XRN1 (Beelman and Parker, 1995;Butler, 2002). These proteins colocalize in discrete cytoplasmic foci in mammalian cells, termed processing bodies or P-bodies (also known as DCP1-or GW182-bodies), indicating that mRNA decay is restricted to distinct cytoplasmic compartments in mammalian cells (van Dijk et al., 2002;Cougot et al., 2004). The human protein CCR4, which is involved in mRNA deadenylation, the decapping stimulating LSm proteins LSm1-7, the DEAD/Hbox RNA helicase DDX6 (also known as RCK/p54), GW182, and Ge-1 are components of P-bodies (Bouveret et al., 2000;Eystathioy et al., 2002;Ingelfinger et al., 2002; LykkeAndersen, 2002;Cougot et al., 2004;Yu et al., 2005). Moreover, the RNA-associated protein 55, hEDC3, Hedls as well as factors of the RISC complex localize to P-bodies in mammalian cells (Fenger-Gron et al., 2005;Liu et al., 2005;Sen and Blau, 2005;Yang et al., 2006). P-bodies represent dynamic structures that are in an equilibrium with polysomes and contain nontranslating mRNA . Remarkably, recent work demonstrated that mRNA molecules entering P-bodies can a...

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“…In Spisula embryogenesis, PABP is somehow masked in maturing oocytes and unable to bind polyadenylated RNA, revealing the existence of regulatory mechanisms operating on this class of proteins (de Melo Neto et al 2000). Accordingly, PABP overexpression prevented maturation-dependent deadenylation and translation inactivation of maternal transcripts but did not interfere with CPE-mediated polyadenylation (Wormington et al 1996). Since ePABP is replaced by increasing levels of PABP in later stages of development after zygotic gene activation (Voeltz et al 2001;Seli et al 2005), this programmed substitution of the universal translation effector is likely pivotal for guiding further specifi- (Mendez and Richter 2001), ePABP/PABP1 (Seli et al 2005), DAZL (Moore et al 2003;Collier et al 2005), and Pumilio (Wharton et al 1998) are shown.…”

Section: Translation Regulatory Cascades Genes and Development 141mentioning

confidence: 97%

“…The role of the polyadenylation process and resulting poly(A) tail in maternal mRNA gene expression is crucial, dictating either deadenylation or translation (Jackson and Standart 1990; Wormington et al 1996;Richter 1999). Interestingly, there is no decay of Xenopus messages following deadenylation through oocyte maturation or in the early stages of embryo development (until the mid-blastula transition), suggesting a reversible regulatory process that can shift mRNAs between repressed and translationally active states (Audic et al 1997;Voeltz and Steitz 1998).…”

Section: Poly(a)-dependent Translation Controlmentioning

confidence: 99%

Metazoan oocyte and early embryo development program: a progression through translation regulatory cascades

Vasudevan¹,

Seli²,

Steitz³

2006

Genes Dev.

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Overexpression of poly(A) binding protein prevents maturation-specific deadenylation and translational inactivation in Xenopus oocytes.

Cited by 102 publications

References 62 publications

The DAZL and PABP families: RNA-binding proteins with interrelated roles in translational control in oocytes

The DAZL and PABP families: RNA-binding proteins with interrelated roles in translational control in oocytes

Ataxin-2 Interacts with the DEAD/H-Box RNA Helicase DDX6 and Interferes with P-Bodies and Stress Granules

Metazoan oocyte and early embryo development program: a progression through translation regulatory cascades

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