A pseudogene is a gene copy that does not produce a functional, full-length protein. The human genome is estimated to contain up to 20,000 pseudogenes. Although much effort has been devoted to understanding the function of pseudogenes, their biological roles remain largely unknown. Here we report the role of an expressed pseudogene-regulation of messenger-RNA stability-in a transgene-insertion mouse mutant exhibiting polycystic kidneys and bone deformity. The transgene was integrated into the vicinity of the expressing pseudogene of Makorin1, called Makorin1-p1. This insertion reduced transcription of Makorin1-p1, resulting in destabilization of Makorin1 mRNA in trans by way of a cis-acting RNA decay element within the 5' region of Makorin1 that is homologous between Makorin1 and Makorin1-p1. Either Makorin1 or Makorin1-p1 transgenes could rescue these phenotypes. Our findings demonstrate a specific regulatory role of an expressed pseudogene, and point to the functional significance of non-coding RNAs.
NDEL1 Phosphorylation by Aurora-A Kinase Is Essential for Centrosomal Maturation, Separation, and TACC3 Recruitment
NDEL1 is a binding partner of LIS1 that participates in the regulation of cytoplasmic dynein function and microtubule organization during mitotic cell division and neuronal migration. NDEL1 preferentially localizes to the centrosome and is a likely target for cell cycle-activated kinases, including CDK1. In particular, NDEL1 phosphorylation by CDK1 facilitates katanin p60 recruitment to the centrosome and triggers microtubule remodeling. Here, we show that Aurora-A phosphorylates NDEL1 at Ser251 at the beginning of mitotic entry. Interestingly, NDEL1 phosphorylated by Aurora-A was rapidly downregulated thereafter by ubiquitination-mediated protein degradation. In addition, NDEL1 is required for centrosome targeting of TACC3 through the interaction with TACC3. The expression of Aurora-A phosphorylation-mimetic mutants of NDEL1 efficiently rescued the defects of centrosomal maturation and separation which are characteristic of Aurora-A-depleted cells. Our findings suggest that Aurora-A-mediated phosphorylation of NDEL1 is essential for centrosomal separation and centrosomal maturation and for mitotic entry.
Stimulated by maturation-inducing hormone secreted from follicle cells surrounding the oocytes, fully-grown oocytes mature and become fertilisable. During maturation, immature oocytes resume meiosis arrested at the first prophase and proceed to the first or second metaphase at which they are naturally inseminated. Paying special attention to general and species-specific aspects, we summarise the mechanisms regulating the initial phase of oocyte maturation, from the reception of hormonal signals on the oocyte surface to activation of the maturationpromoting factor in the cytoplasm, in amphibians, fishes, mammals and marine invertebrates. INTRODUCfION TO OOCYTE MATURATIONThe life of multicellular organisms begins at fertilisation, the union of germ cells (the egg and the spermatozoon). The production and maturation of germ cells and their fusion are indispensable for the maintenance of a species beyond the limited longevity of individuals. Oocytes are produced in ovaries by the entry of mitotically proliferating oogonia into meiosis. Oocytes stop their meiotic cell cycle at the first prophase, during which they grow by the accumulation of substances necessary for early embryonic development (vitellogenesis). In many species, fullygrown postvitellogenic oocytes arrested at the first meiotic prophase are immature, and they are unable to be fertilised until they mature. The oocytes that have been induced to mature resume meiosis from the first prophase and proceed to the first or second metaphase, at which time, in many invertebrates and vertebrates, they are inseminated (1). During the course of maturation, oocytes undergo drastic morphological changes associated with progression of the meiotic cell cycle, among which breakdown of the oocyte nuclear envelope (germinal vesicle breakdown, GVBD) occurring at the prophase/metaphase transition is frequently regarded as a hallmark of the progress of maturation, although it does not necessarily mean the completion of maturation (Figure 1).Oocyte maturation is induced by sequential actions of three substances (2): gonadotropic hormone (GTH; or gonad-stimulating substance in starfish, GSS), maturation-inducing hormone (MIH; or maturationinducing substance, MIS) and maturation-promoting factor (MPF) (Figure 2). Two species of GTH, a luteinizing hormone (LH) and a follicle-stimulating hormone (FSH), are secreted from the pituitary gland in vertebrates. Both LH and FSH consist of two glycoproteinous subunits, a and ~ subunits; the former is also a component of the thyroid-stimulating hormone (ISH) and the latter characterises each hormone. FSH is responsible for oocyte growth, and LH triggers oocyte maturation by stimulating follicle cells surrounding the 115 oocytes to produce MIH. MIH in vertebrates is a steroid derivative and interacts with a membrane-bound receptor on the oocyte surface, and subsequent signal transduction from the surface to the cytoplasm is probably intermediated by GfP-binding proteins (Gproteins). The MIH signal finally results in the formation and activa...
Phosphatidylinositol 3-kinase (PI3K) is known to play critical roles in signal transduction processes related to a variety of cellular activities. In the present study, we investigated the role of PI3K during meiotic maturation in mouse oocytes using a specific inhibitor, LY294002. In follicle-stimulating hormone (FSH)-induced reversal of hypoxanthine-mediated meiotic arrest of cumulus oocyte complexes (COCs), LY294002 suppressed germinal vesicle breakdown (GVBD), first polar body (PB1) emission, and cumulus expansion. To examine the effect of LY294002, denuded oocytes (DOs) were cultured in medium containing follicular fluid meiosis-activating sterol (FF-MAS) since absence of gonadotropin receptors in oocytes has been reported and FSH did not stimulate meiotic maturation of DOs in the presence of hypoxanthine. In FF-MAS-induced maturation of DOs, LY294002 suppressed PB1emission, but not GVBD. In spontaneous gonadotropin-independent oocyte maturation, LY294002 had no effect on COCs and DOs. Akt/protein kinase B, a serine-threonine kinase, is a key downstream effector of the PI3K pathway. Therefore, we also examined the distribution of Akt during FSH-induced meiotic maturation. The distribution of Ser(473) phosphorylated Akt was similar to the localization of microtubules, while Thr(308) phosphorylated Akt was present in the pericentriolar materials (PCM) in metaphase I (MI) and II (MII) oocytes. LY294002 decreased the amount of Thr(308) phosphorylated Akt to very low to undetectable levels in MI and MII oocytes. Ser(473) phosphorylated Akt showed aberrant distribution and very low to undetectable levels of expression in LY294002-treated MI and MII oocytes, respectively. These results suggest that PI3K and Akt participate in mouse meiotic maturation.
We have earlier generated a mutant mouse in a course of making a transgenic line that exhibited interesting heterozygote phenotypes, which exhibited failure to thrive, severe bone deformities, and polycystic kidneys. This mutant mouse provided a clue to uncover a unique role of expressed pseudogenes. In this mutant the transgene was integrated into the vicinity of the expressing pseudogene of Makorin1 called Makorin1-p1. This insertion reduced transcription of the Makorin1-p1, resulting in destabilization of the Makorin1 mRNA in trans via a cis-acting RNA decay element within the 5' region of Makorin1 that is homologous between Makorin1 and Makorin1-p1. These findings demonstrate a novel and specific regulatory role of an expressed pseudogene as well as functional significance for noncoding RNAs. Next, we developed an original algorithm to determine how many pseudogenes are expressed. Based on our examination 2-3% of human processed pseudogenes are expressed using the most strict criteria. Interestingly, the mouse has a much smaller proportion of expressed pseudogenes (0.5-1%). Pseudogenes are functionally less constrained, and have accumulated more mutations than translated genes. If they have some functions in gene regulation, this property would allow more rapid functional diversification than protein-coding genes. In addition, some genetic phenomena that exhibit incomplete penetrance might be attributed to "mutation" or "variation" of pseudogenes.
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