Increase of Cu,Zn-superoxide dismutase activity during differentiation of human K562 cells involves activation by copper of a constantly expressed copper-deficient protein.

Cu,Zn-superoxide dismutase activity, expressed on the basis of cell number, increased by 50% during sodium butyrate-induced differentiation of human K562 erythroleukemia cells. The increased enzyme activity was found to be concomitant with constant Cu,Zn-superoxide dismutase mRNA and immunoreactive protein levels and was accompanied by a rise in intracellular copper and glutathione. Incubation of K562 cell homogenates with copper caused an increase of Cu,Zn-superoxide dismutase activity which reached the levels observed after differentiation in the presence of sodium butyrate. The same treatment led to no significant activity increase in homogenates derived from differentiated cells. Externally added ceruloplasmin increased both intracellular copper levels and Cu,Zn-superoxide dismutase activity in undifferentiated cells to a level comparable with that observed after induction of differentiation. Both increments were abolished by depletion of cell glutathione. Cu,Zn-superoxide dismutase purified from control cells had both a lower kcat and a lower copper content than the enzyme purified from differentiated cells. From these data we conclude that: 1) Cu,Zn-superoxide dismutase is present in K562 cells also under the form of a less active copper-deficient enzyme, 2) the extent of enzyme activation is regulated post-translationally by differential delivery of copper as a function of differentiation stage, and 3) glutathione is likely to play a role in delivering copper to the copper-deficient protein in intact K562 cells.     

CPEB degradation during Xenopus oocyte maturation requires a PEST domain and the 26S proteasome

Cytoplasmic poly(A) elongation is widely utilized during the early development of many organisms as a mechanism for translational activation. Targeting of mRNAs for this mechanism requires the presence of a U-rich element, the cytoplasmic polyadenylation element (CPE), and its binding protein, CPEB. Blocking cytoplasmic polyadenylation by interfering with the CPE or CPEB prevents the translational activation of mRNAs that are crucial for oocyte maturation. The CPE sequence and CPEB are also important for translational repression of mRNAs stored in the Xenopus oocyte during oogenesis. To understand the contribution of protein metabolism to these two roles for CPEB, we have examined the mechanisms influencing the expression of CPEB during oogenesis and oocyte maturation. Through a comparison of CPEB mRNA levels, protein synthesis, and accumulation, we find that CPEB is synthesized during oogenesis and stockpiled in the oocyte. Minimal synthesis of CPEB, <3.6%, occurs during oocyte maturation. In late oocyte maturation, 75% of CPEB is degraded coincident with germinal vesicle breakdown. Using proteasome and ubiquitination inhibitors, we demonstrate that CPEB degradation occurs via the proteasome pathway, most likely through ubiquitin-conjugated intermediates. In addition, we demonstrate that degradation requires a 14 amino acid PEST domain.     

Multiple mechanisms collaborate to repress nanos translation in the Drosophila ovary and embryo

Translational control of gene expression is essential for development in organisms that rely on maternal mRNAs. In Drosophila, translation of maternal nanos (nos) mRNA must be restricted to the posterior of the early embryo for proper patterning of the anterior-posterior axis. Spatial control of nos translation is coordinated through the localization of a small subset of nos mRNA to the posterior pole late in oogenesis, activation of this localized mRNA, and repression of the remaining unlocalized nos mRNA throughout the bulk cytoplasm. Translational repression is mediated by the interaction of a cis-acting element in the nos 3' untranslated region with two proteins, Glorund (Glo) and Smaug (Smg), that function in the oocyte and embryo, respectively. The mechanism of Glo-dependent repression is unknown. Previous work suggests that Smg represses translation initiation but this model is not easily reconciled with evidence for polysome association of repressed nos mRNA. Using an in vitro translation system, we have decoupled translational repression of nos imposed during oogenesis from repression during embryogenesis. Our results suggest that both Glo and Smg regulate translation initiation, but by different mechanisms. Furthermore, we show that, during late oogenesis, nos translation is also repressed post-initiation and provide evidence that Glo mediates this event. This post-initiation block is maintained into embryogenesis during the transition to Smg-dependent regulation. We propose that the use of multiple modes of repression ensures inactivation of nos RNA that is translated at earlier stages of oogenesis and maintenance of this inactivate state throughout late oogenesis into embryogenesis.     

Small nuclear U-ribonucleoproteins in Xenopus laevis development. Uncoupled accumulation of the protein and RNA components

The accumulation of protein and RNA components of small nuclear U-ribonucleoprotein particles is non-co-ordinate during oogenesis and early embryogenesis in Xenopus laevis. Northern blot hybridization of a cloned Xenopus U2-RNA gene to oocyte and embryo RNAs demonstrates that the amount of small nuclear U2-RNA per oocyte reaches a plateau early in oogenesis (at the start of yolk deposition); further accumulation is not observed in oogenesis, nor in embryogenesis until the late blastula stage. In contrast, we show by immunoblot analysis that the proteins that bind to small nuclear U-RNAs continue to be accumulated after vitellogenesis begins, reaching maximum amounts only at the end of oocyte development. No further accumulation of these proteins is seen during embryogenesis. The consequences of this non-co-ordinate synthesis of small nuclear RNA and small nuclear RNA-binding proteins are as follows: a 10- to 20-fold excess of the protein components of the small ribonucleoprotein particles over small nuclear RNA exists in large oocytes; the bulk of the protein is cytoplasmic, while the RNA is nuclear. Thus the excess protein in the cytoplasm is uncomplexed with RNA. The imbalance between protein and RNA is not corrected until the late blastula or early gastrula stages of embryogenesis, when a tenfold increase in the amount of small nuclear U2-RNA is detected. Thus the protein, but not the RNA, components of small nuclear U-ribonucleoprotein particles are stockpiled in oocytes for later use in embryonic development. During the course of these studies, we also found that there are tissue-specific differences in the Sm-antigenic proteins of X. laevis.     

Gene expression during mammalian oogenesis and early embryogenesis: quantification of three messenger RNAs abundant in fully grown mouse oocytes

Ribonuclease protection assays have been used to quantitatively assess changes in steady-state levels of specific mRNAs during oogenesis and early embryogenesis in mice. The mRNAs encode ZP3 (a glycoprotein that serves as a sperm receptor), LDH-B (heart-type lactate dehydrogenase), and MOM-1 (a protein of unknown function). MOM-1 and LDH-B are expressed in a variety of adult mouse tissues and midgestation embryos, whereas ZP3 expression is restricted completely to oocytes. All three mRNAs are expressed by growing mouse oocytes and accumulate to unusually high levels in fully grown oocytes as compared to somatic cells; 240,000, 200,000 and 74,000 copies mRNA per fully grown oocyte for ZP3, LDH-B and MOM-1, respectively. Steady-state levels of LDH-B and MOM-1 mRNA undergo a modest decline (approximately 20-40%) during ovulation when fully grown oocytes become unfertilized eggs and, in general, mirror the reported change in poly(A)+RNA levels during this period of development. On the other hand, the level of ZP3 mRNA declines dramatically (approximately 98%) during ovulation, from approximately 240,000 copies per oocyte to approximately 5000 copies per unfertilized egg, and ZP3 mRNA is undetectable in fertilized eggs (less than 1000 copies per fertilized egg). MOM-1 mRNA is expressed at relatively low levels in morulae (approximately 2000 copies per embryo) and blastocysts (approximately 5000 copies per embryo), whereas ZP3 mRNA remains undetectable (less than 1000 copies per embryo) at these stages of preimplantation development. These findings are discussed in the context of overall gene expression during oocyte growth, meiotic maturation and early embryogenesis in mice.     

Concordance and interaction of guanine nucleotide dissociation inhibitor (RhoGDI) with RhoA in oogenesis and early development of the sea urchin

Rho GTPases are Ras-related GTPases that regulate a variety of cellular processes. In the sea urchin Strongylocentrotus purpuratus, RhoA in the oocyte associates with the membrane of the cortical granules and directs their movement from the cytoplasm to the cell cortex during maturation to an egg. RhoA also plays an important role regulating the Na(+) -H(+) exchanger activity, which determines the internal pH of the cell during the first minutes of embryogenesis. We investigated how this activity may be regulated by a guanine-nucleotide dissociation inhibitor (RhoGDI). The sequence of this RhoA regulatory protein was identified in the genome on the basis of its similarity to other RhoGDI species, especially for key segments in the formation of the isoprenyl-binding pocket and in interactions with the Rho GTPase. We examined the expression and the subcellular localization of RhoGDI during oogenesis and in different developmental stages. We found that RhoGDI mRNA levels were high in eggs and during cleavage divisions until blastula, when it disappeared, only to reappear in gastrula stage. RhoGDI localization overlaps the presence of RhoA during oogenesis and in embryonic development, reinforcing the regulatory premise of the interaction. By use of recombinant protein interactions in vitro, we also find that these two proteins selectively interact. These results support the hypothesis of a functional relationship in vivo and now enable mechanistic insight for the cellular and organelle rearrangements that occur during oogenesis and embryonic development.     

Two discrete modes of histone gene expression during oogenesis in Drosophila melanogaster

We have used in situ hybridization to ovarian tissue sections to study the pattern of histone gene expression during oogenesis in Drosophila melanogaster. Our studies suggest that there are two distinct phases of histone gene expression during oogenesis. In the first phase, which occurs during early to middle oogenesis (stages 5-10A), we observe a mosaic pattern of histone mRNA in the 15 nurse cells of the egg chamber: some cells have very high levels of mRNA, while others have little or no mRNA. Our analysis suggests that there is a cyclic accumulation and subsequent degradation of histone mRNA in the egg chamber and that very little histone mRNA is transported into the growing oocyte. Moreover, since the endomitotic replication cycles of the nurse cells are asynchronous during this period, the mosaic distribution of histone message would suggest that the expression of the histone genes in each nurse cell nucleus is probably coupled to DNA replication as in most somatic cells. The second phase begins at stage 10B. During this period, histone gene expression appears to be "induced" in all 15 nurse cells of the egg chamber, and instead of a mosaic pattern, high levels of histone mRNA are found in all cells. Unlike the earlier phase, this expression is apparently uncoupled from the endomitotic replication of the nurse cells (which are completed by the end of stage 10A). Moreover, much of the newly synthesized histone mRNA is transported from the nurse cells into the oocyte where it accumulates and is stored for use during early embryogenesis. Finally, we have also observed tightly clustered grains within nurse cell nuclei in non-denatured tissue sections. As was the case with cytoplasmic histone mRNA, there is a mosaic distribution of nuclear grains from stages 5 to 10A, while at stage 10B, virtually all nurse cell nuclei have grain clusters. These grain clusters appear to be due to the hybridization of nurse cell histone gene DNA to our probe, and are localized in specific regions of the nucleus.     

The translational repressor Cup associates with the adaptor protein Miranda and the mRNA carrier Staufen at multiple time-points during Drosophila oogenesis

In Drosophila melanogaster, Cup acts as a translational regulator during oocyte maturation and early embryogenesis. In this report, we show that Cup associates with Miranda, an adaptor protein involved in localization of specific mRNA complexes in both neuroblasts and oocytes. miranda and cup also interact genetically, since reducing miranda activity worsens the oogenesis defects associated with different cup mutant alleles. miranda mRNA is first detected within the cytoplasm of egg chambers during early oogenesis, coincidentally with very low levels of Miranda protein. We furthermore show that Cup interacts with Staufen, a protein involved in mRNA localization during oogenesis and nervous system development, and the two proteins co-localize within the posterior cytoplasm of late oocytes. Our results substantiate the idea that Cup is a multi-functional protein cooperating with different protein partners to direct egg chamber development at multiple time-points.     

中华鳖vasa基因克隆及在卵母细胞中的表达分析

研究利用中华鳖为研究模型进行爬行类生殖细胞发育分化成熟等生物学研究,克隆了中华鳖vasa基因的cDNA序列,全长3865 bp,包括5'端非编码区90 bp,3'端非编码区1699 bp,开放阅读框长2076 bp,共编码691个氨基酸。中华鳖Vasa氨基酸序列包含DEAD-box家族蛋白8个保守保守功能域,在N末端有4个RGG重复序列和2个GG富集区,与小鼠Vasa蛋白的同源性较高（72%）。荧光定量PCR的结果表明,中华鳖vasa mRNA主要精巢和卵巢中表达,其他体组织中均难检测到表达。卵巢冰冻切片原位杂交结果显示:中华鳖vasa mRNA在生殖细胞中特异表达;在卵子发生过程中的不同发育期卵母细胞中呈现动态的变化。即vasa mRNA在初级卵母细胞及生长期卵母细胞中表达最强,且均匀分布在细胞质中,随着卵母细胞的逐渐增大,信号逐渐减弱,直至在成熟的卵母细胞中几乎检测不到表达信号,说明vasa可能在中华鳖早期卵母细胞发育中起重要作用。同时,vasa基因可作为中华鳖生殖细胞分子标记物,根据其mRNA的表达水平来鉴别不同发育时期的卵母细胞。研究结果为进一步开展中华鳖胚胎生殖细胞发育及配子生成,特别是研究中华鳖,乃至爬行类原始生殖细胞（Primordial Germ Cells,PGCs）的起源、迁移、分化等研究奠定了基础。     

The Antiozonant Ethylenediurea Does Not Act via Superoxide Dismutase Induction in Bean

It has been proposed that the mode of action of ethylenediurea, a very effective antiozonant, is via an increase in the antioxidant enzyme superoxide dismutase (EH Lee, JH Bennett [1982] Plant Physiol 69: 1444-1449). Data presented here refute that hypothesis. No ethylenediurea-associated increases in Cu/Zn-superoxide dismutase or Mn-superoxide dismutase activity, nor in steady-state Cu/Zn-superoxide dismutase protein levels, were found in soluble extracts of bean (Phaseolus vulgaris L. cv Bush Blue Lake 290) leaves. However, the cytosolic Cu/Zn-superoxide dismutase increased as a result of ozone fumigation and subsequent injury. Also noted was a developmentally related difference between chloroplastic and cytosolic Cu/Zn-superoxide dismutase, the latter declining during maturation of the leaf.     

Temporal complexity within a translational control element in the nanos mRNA

Translational control of gene expression plays a fundamental role in the early development of many organisms. In Drosophila, selective translation of nanos mRNA localized to the germ plasm at the posterior of the embryo, together with translational repression of nanos in the bulk cytoplasm, is essential for development of the anteroposterior body pattern. We show that both components to spatial control of nanos translation initiate during oogenesis and that translational repression is initially independent of Smaug, an embryonic repressor of nanos. Repression during oogenesis and embryogenesis are mediated by distinct stem loops within the nanos 3' untranslated region; the Smaug-binding stem-loop acts strictly in the embryo, whereas a second stem-loop functions in the oocyte. Thus, independent regulatory modules with temporally distinct activities contribute to spatial regulation of nanos translation. We propose that nanos evolved to exploit two different stage-specific translational regulatory mechanisms.     

Developmental expression of fibrillarin and U3 snRNA in Xenopus laevis.

Fibrillarin is one of the protein components that together with U3 snRNA constitute the U3 snRNP, a small nuclear ribonucleoprotein particle involved in ribosomal RNA processing in eucaryotic cells. Using an antifibrillarin antiserum for protein detection and a fibrillarin cDNA and a synthetic oligonucleotide complementary to U3 snRNA as hybridization probes, the expression of these two components has been studied during Xenopus development. Fibrillarin mRNA is accumulated early in oogenesis, like many other messengers, and translated during oocyte growth. Fibrillarin protein is thus progressively accumulated throughout oogenesis to be assembled with U3 snRNA and used for ribosome production in the amplified nucleoli. After fertilization, the amount of U3 snRNA decreases while the maternally accumulated fibrillarin mRNA is maintained and utilized to produce more protein. After the mid-blastula transition, stored fibrillarin is assembled with newly synthesized U3 snRNA and becomes localized in the prenucleolar bodies and reforming nucleoli.