Subnucleolar location of fibrillarin and NopA64 in Lepidium sativum root meristematic cells is changed in altered gravity

Summary. Fibrillarin and the plant nucleolin homolog NopA64 are two important nucleolar proteins involved in pre-rRNA processing. In order to determine the effects of the altered gravity environment on the nucleolus, we have investigated the location of fibrillarin and NopA64 in nucleolar subcomponents of cress (Lepidium sativum L.) root meristematic cells grown under clinorotation, which reproduces an important feature of microgravity, namely, the absence of the orienting action of a gravity vector, and compared it to the location in control cells grown in normal 1 g conditions. Prior to these experiments, we report here the characterization of cress fibrillarin as a 41 kDa protein which can be isolated from meristematic cells in three nuclear fractions, namely, the soluble ribonucleoprotein fraction, the chromatin fraction, and the nuclear-matrix fraction. Furthermore, as reported for other species, the location of both fibrillarin and NopA64 in the cress cell nucleolus was in zones known to contain complex ribonucleoprotein particles involved in early pre-rRNA processing, i.e., processomes. Under altered gravity, a decrease in the quantity of both fibrillarin and NopA64 compared to controls was observed in the transition zone between fibrillar centers and the dense fibrillar component, as well as in the bulk of the dense fibrillar component. These data suggest that altered (reduced) gravity results in a lowered level of functional activity in the nucleolus. Correspondence and reprints: Centro de Investigaciones Biológicas, Consejo Superior de Investigaciones Cientificas, Ramiro de Maeztu 9, 28040 Madrid, Spain.     

Effect of changes in gravity on the quantity and localization of fibrillarin in the nucleolus of cress root meristem

For the first time, in altered gravity, with antifibrillarin antibodies and immunogold microscopy fibrillarin that is one of the most important proteins of rRNA processing was localized. The quantitative study of the density of gold particles in the nuclelous, under clinorotation both the transition zone FC-DFC and the dense fibrillar component were less labeled as compared to the control. Obtained data allow us to suppose the lowering of the rRNA processing level in the nucleoli under the influence of altered gravity.     

Inactivation of the yeast Sen1 protein affects the localization of nucleolar proteins

A mutation in the Saccharomyces cerevisiae SEN1 gene causes accumulation of end-matured, intron-containing pre-tRNAs. Cells containing the thermosensitive sen1-1 mutation exhibit reduced tRNA splicing endonuclease activity. However, Sen1p is not the catalytic subunit of this enzyme. We have used Sen1p-specific antibodies for cell fractionation studies and immunofluorescent microscopy and determined that Sentp is a low abundance protein of about 239 kDa. It localizes to the nucleus with a granular distribution. We verified that a region in SEN1 containing a putative nuclear localization signal sequence (NLS) is necessary for nuclear targeting. Furthermore, we found that inactivation of Sen1p by temperature shift of a strain carrying sen1-1 leads to mislocalization of two nucleolar proteins, Nopt and Ssb1 Possible mechanisms are discussed for several related nuclear functions of Sen1p, including tRNA splicing and the maintenance of a normal crescent-shaped nucleolus.     

N-糖链加工影响里氏木霉形态发生并提高木质纤维素降解能力

[背景] 烟曲霉α-1,2-甘露糖苷酶MsdS在高尔基体中将N-糖链Man₈GlcNAc₂加工为成熟分泌糖蛋白的糖型Man₆GlcNAc₂,有研究表明MsdS与烟曲霉的形态发生、细胞壁合成及蛋白质分泌密切相关;与烟曲霉不同的是,里氏木霉的成熟分泌糖蛋白上的N-糖链结构为Man₈GlcNAc₂,细胞却能正常生长,说明丝状真菌N-糖链的加工具有物种特异性,但其生物学意义不明。[目的] 为研究N-糖链加工对里氏木霉细胞生长及蛋白质分泌的影响,本研究将烟曲霉MsdS转入里氏木霉中以改变其成熟分泌糖蛋白的糖型。[方法] 构建带有烟曲霉msdS基因的重组质粒并转入里氏木霉中,获得msdS表达菌株Tr-MsdS,分析Tr-MsdS菌株的生长表型、N-糖组、蛋白质分泌途径和纤维素酶活性的变化。[结果] 在里氏木霉msdS表达菌株Tr-MsdS中,分泌糖蛋白的主要糖型由出发株的Man₈GlcNAc₂转变为Man₆GlcNAc₂,细胞壁组分发生变化,但细胞壁完整性未受影响;与出发株相比,Tr-MsdS菌株产孢、出芽及分枝增多;另外,MsdS的表达还影响蛋白质分泌,在50℃时降解纤维素和β-葡聚糖的能力分别提高9.9%和32.2%。[结论] 研究结果表明,N-糖链的加工可影响里氏木霉蛋白质,尤其是纤维素酶的分泌,干扰N-糖链加工可能是提高里氏木酶纤维素酶产量的新策略。     

The BRCT domain of mammalian Pes1 is crucial for nucleolar localization and rRNA processing

The nucleolar protein Pes1 interacts with Bop1 and WDR12 in a stable complex (PeBoW-complex) and its expression is tightly associated with cell proliferation. The yeast homologue Nop7p (Yph1p) functions in both, rRNA processing and cell cycle progression. The presence of a BRCT-domain (BRCA1 C-terminal) within Pes1 is quite unique for an rRNA processing factor, as this domain is normally found in factors involved in DNA-damage or repair pathways. Thus, the function of the BRCT-domain in Pes1 remains elusive. We established a conditional siRNA-based knock-down-knock-in system and analysed a panel of Pes1 truncation mutants for their functionality in ribosome synthesis in the absence of endogenous Pes1. Deletion of the BRCT-domain or single point mutations of highly conserved residues caused diffuse nucleoplasmic distribution and failure to replace endogenous Pes1 in rRNA processing. Further, the BRCT-mutants of Pes1 were less stable and not incorporated into the PeBoW-complex. Hence, the integrity of the BRCT-domain of Pes1 is crucial for nucleolar localization and its function in rRNA processing.     

Altered nuclear transport and the most selfish of genes.

The Segregation Distorter System in Drosophila is one of the best-known and genetically characterized systems of meiotic drive. A recent paper by Kusano et al. (2001) provides a key molecular insight into the molecular mechanism by which one chromosome can ensure the destruction of its partner.     

DDM1 binds Arabidopsis methyl-CpG binding domain proteins and affects their subnuclear localization

Methyl-CpG binding domain (MBD) proteins in Arabidopsis thaliana bind in vitro methylated CpG sites. Here, we aimed to characterize the binding properties of AtMBDs to chromatin in Arabidopsis nuclei. By expressing in wild-type cells AtMBDs fused to green fluorescent protein (GFP), we showed that AtMBD7 was evenly distributed at all chromocenters, whereas AtMBD5 and 6 showed preference for two perinucleolar chromocenters adjacent to nucleolar organizing regions. AtMBD2, previously shown to be incapable of binding in vitro-methylated CpG, was dispersed within the nucleus, excluding chromocenters and the nucleolus. Recruitment of AtMBD5, 6, and 7 to chromocenters was disrupted in ddm1 and met1 mutant cells, where a significant reduction in cytosine methylation occurs. In these mutant cells, however, AtMBD2 accumulated at chromocenters. No effect on localization was observed in the chromomethylase3 mutant showing reduced CpNpG methylation or in kyp-2 displaying a reduction in Lys 9 histone H3 methylation. Transient expression of DDM1 fused to GFP showed that DDM1 shares common sites with AtMBD proteins. Glutathione S-transferase pull-down assays demonstrated that AtMBDs bind DDM1; the MBD motif was sufficient for this interaction. Our results suggest that the subnuclear localization of AtMBD is not solely dependent on CpG methylation; DDM1 may facilitate localization of AtMBDs at specific nuclear domains.     

A plastome mutation affects processing of both chloroplast and nuclear DNA-encoded plastid proteins

Summary A bovine tRNA gene cluster has been characterized and the sequences of four tDNAs determined. Two of the tDNAs could encode tRNA^Ser _IGA, one tDNA^Ser _UGA, and the fourth tRNA^Gln _CUG. The three serine tDNAs representing the UCN codon isoacceptor family are almost identical. However, the sequence of the tDNA^Ser _TGA differs from a previously sequenced bovine tDNA^Ser _TGA at 12 positions (ca. 14%). This finding suggests that in the bovine genome, two subfamilies of genes might encode tRNA^Ser _UGA. It also raises the possibility that new genes for a specific UCN isoacceptor might arise from the genes of a different isoacceptor, and could explain previously observed differences between species in the anticodons of coevolving pairs of tRNAs^Ser _UCN. The gene cluster also contains complete and partial copies, and fragments, of the BCS (bovine consensus sequence) SINE (short interspersed nuclear element) family, six examples of which were sequenced. Some of these elements occur in close proximity to two of the serine tDNAs.     

Identification of signal sequences determining the specific nucleolar localization of fibrillarin in HeLa cells

Fibrillarin is one of the major nucleolar proteins and is involved in pre-rRNA maturation. Its three main regions are a glycine and arginine-rich (GAR) domain, an RNA-binding domain, and an alpha-helical region, which presumably has a methyltransferase activity. Yet the roles of these regions in nucleolus-specific localization of fibrillarin are still unclear. To elucidate this issue, a series of plasmids was constructed to express human fibrillarin mutants fused with the green fluorescent protein. Localization of the chimeric proteins was studied in interphase and mitotic HeLa cells after single transfection with the plasmids. Deletion or a mutation of any domain proved to alter the specific fibrillarin location coinciding with sites of pre-rRNA synthesis. The GAR domain and the first spacer together were sufficient for fibrillarin migration into the nucleolus. Fibrillarin mutants located within the interphase nucleolus did not differ in mitotic location from the wild-type fibrillarin.     

The localization of FGFR3 mutations causing thanatophoric dysplasia type I differentially affects phosphorylation, processing and ubiquitylation of the receptor

Recurrent missense fibroblast growth factor receptor 3 (FGFR3) mutations have been ascribed to skeletal dysplasias of variable severity including the lethal neonatal thanatophoric dysplasia types I (TDI) and II (TDII). To elucidate the role of activating mutations causing TDI on receptor trafficking and endocytosis, a series of four mutants located in different domains of the receptor were generated and transiently expressed. The putatively elongated X807R receptor was identified as three isoforms. The fully glycosylated mature isoform was constitutively but mildly phosphorylated. Similarly, mutations affecting the extracellular domain (R248C and Y373C) induced moderate constitutive receptor phosphorylation. By contrast, the K650M mutation affecting the tyrosine kinase 2 (TK2) domain produced heavy phosphorylation of the nonglycosylated and mannose-rich isoforms that impaired receptor trafficking through the Golgi network. This resulted in defective expression of the mature isoform at the cell surface. Normal processing was rescued by tyrosine kinase inhibitor treatment. Internalization of the R248C and Y373C mutant receptors, which form stable disulfide-bonded dimers at the cell surface was less efficient than the wild-type, whereas ubiquitylation was markedly increased but apparently independent of the E3 ubiquitin-ligase casitas B-lineage lymphoma (c-Cbl). Constitutive phosphorylation of c-Cbl by the K650M mutant appeared to be related to the intracellular retention of the receptor. Therefore, although mutation K650M affecting the TK2 domain induces defective targeting of the overphosphorylated receptor, a different mechanism characterized by receptor retention at the plasma membrane, excessive ubiquitylation and reduced degradation results from mutations that affect the extracellular domain and the stop codon.     

Altered gravity affects ventral root activity during fictive swimming and the static vestibuloocular reflex in young tadpoles (Xenopus laevis)

During early periods of life, modifications of the gravitational environment affect the development of sensory, neuronal and motor systems. The vestibular system exerts significant effects on motor networks that control eye and body posture as well as swimming. The objective of the present study was to study whether altered gravity (AG) affects vestibuloocular and spinal motor systems in a correlated manner. During the French Soyuz taxi flight Andromède to the International Space Station ISS (launch: October 21, 2001; landing: October 31, 2001) Xenopus laevis embryos were exposed for 10 days to microgravity (microg). In addition, a similar experiment with 3g-hypergravity (3g) was performed in the laboratory. At onset of AG, embryos had reached developmental stages 24 to 27. After exposure to AG, each tadpole was tested for its roll-induced vestibuloocular reflex (rVOR) and 3 hours later it was tested for the neuronal activity recorded from the ventral roots (VR) during fictive swimming. During the post-AG recording periods tadpoles had reached developmental stages 45 to 47. It was observed that microgravity affected VR activity during fictive swimming and rVOR. In particular, VR activity changes included a significant decrease of the rostrocaudal delay and a significant increase of episode duration. The rVOR-amplitude was transiently depressed. Hypergravity was less effective on the locomotor pattern; occurring effects on fictive swimming were the opposite of microg effects. As after microgravity, the rVOR was depressed after 3g-exposure. All modifications of the rVOR and VR-activity recovered to normal levels within 4 to 7 days after termination of AG. Significant correlations between the rVOR amplitude and VR activity of respective tadpoles during the recording period have been observed in both tadpoles with or without AG experience. The data are consistent with the assumptions that during this period of life which is characterized by a progressive development of vestibuloocular and vestibulospinal projections (i) microgravity retards the development of VR activity while hypergravity weakly accelerates it; (ii) that microgravity retards the rVOR development while hypergravity caused a sensitization, and that (iii) AG-induced changes of VR activity during fictive swimming have a vestibular origin.     

Double immunolocalization of major nucleolar proteins, fibrillarin and B23, in dividing mammalian cultured cells.

Using specific autoimmune sera to the nucleolar protein fibrillarin and monoclonal antibodies to B23/nucleophosmin, we localized early and late nucleolar rRNA-processing factors in cycling human HeLa and pig PK cells. It was shown that, at the electron microscopic level, fibrillarin was located over the nucleolar fibrillar compartment, but was absent in the fibrillar centres. During mitosis, fibrillarin was located within the same domains as B23, namely, the cytoplasm, the perichromosomal layer, prenucleolar bodies, and the nucleolar cytoplasmic derivatives, but the kinetics of the two proteins during mitosis was essentially different. Thus, fibrillarin dissociated from the nucleolar remnant at prophase of mitosis or following actinomycin D treatments after B23, but was found to be more prominent within the perichromosomal layer at metaphase, and earlier migrated to the reassembled nucleoli at telophase. In contrast to B23, fibrillarin was found to be resistant to the treatment with 2 M NaCl.     

Proteasome-dependent processing of nuclear proteins is correlated with their subnuclear localization

Although proteasomes are abundant in the nucleoplasm little is known of proteasome-dependent proteolysis within the nucleus. Thus, we monitored the subcellular distribution of nuclear proteins in correlation with proteasomes. The proteasomal pathway clears away endogenous proteins, regulates numerous cellular processes, and delivers immunocompetent peptides to the antigen presenting machinery. Confocal laser scanning microscopy revealed that histones, splicing factor SC35, spliceosomal components, such as U1-70k or SmB/B('), and PML partially colocalize with 20S proteasomes in nucleoplasmic substructures, whereas the centromeric and nucleolar proteins topoisomerase I, fibrillarin, and UBF did not overlap with proteasomes. The specific inhibition of proteasomal processing with lactacystin induced accumulation of histone protein H2A, SC35, spliceosomal components, and PML, suggesting that these proteins are normally degraded by proteasomes. In contrast, concentrations of centromeric proteins CENP-B and -C and nucleolar proteins remained constant during inhibition of proteasomes. Quantification of fluorescence intensities corroborated that nuclear proteins which colocalize with proteasomes are degraded by proteasome-dependent proteolysis within the nucleoplasm. These data provide evidence that the proteasome proteolytic pathway is involved in processing of nuclear components, and thus may play an important role in the regulation of nuclear structure and function.     

Cell surface localization and processing of the ComG proteins, required for DNA binding during transformation of Bacillus subtilis

The comG operon of Bacillus subtilis encodes seven proteins essential for the binding of transforming DNA to the competent cell surface. We have explored the processing of the ComG proteins and the cellular localization of six of them. All of the proteins were found to be membrane associated. The four proteins with N-terminal sequence motifs typical of type 4 prepilins (ComGC, GD, GE and GG) are processed by a pathway that requires the product of comC , also an essential competence gene. The unprocessed forms of ComGC and GD behave like integral membrane proteins. Pre-ComGG differs from pre-ComGC and pre-ComGD, in that it is accessible to proteolysis only from the cytoplasmic face of the membrane and at least a portion of it behaves like a peripheral membrane protein. The mature forms of these proteins are translocated to the outer face of the membrane and are liberated when peptidoglycan is hydrolysed by lysozyme or mutanolysin. ComGG exists in part as a disulphide-cross-linked homodimer in vivo . ComGC was found to possess an intramolecular disulphide bond. The previously identified homodimer form of this protein is not stabilized by disulphide bond formation. ComGF behaves as an integral membrane protein, while ComGA, a putative ATPase, is located on the inner face of the membrane as a peripheral membrane protein. Possible roles of the ComG proteins in DNA binding to the competent cell surface are discussed in the light of these and other results.     

The most important stages of the mechanism of action in vivo of carcinogen diethylnitrosoamine and its effect on the synthesis of RNA,proteins, DNA,and deoxyribonucleotides

The mechanisms of nitric oxide (NO) generation from exogenous and endogenous sources, induced by the addition of the carcinogen diethylnitrosoamine (DENA) to rat organism have been studied. Within 15 h after the addition of DENA, the carcinogen itself acts as an exogenous NO donor. The products of protein degradation (the process induced by DENA) act as endogenous donors of NO. It was shown that the generation of NO from DENA leads to deep hemic and tissue hypoxia and induces the inactivation of oxygen-dependent enzymes, including ribonucleotide reductase, and the inhibition of ATP synthesis. Under these conditions, the protein synthesis and as a consequence the synthesis of deoxyribonucleotides and DNA are strongly suppressed; i.e., DENA produces the effect similar to the action of the antibiotic cycloheximide, an inhibitor of translation. The administration of cycloheximide to the animal organism also led to the appearance of a considerable amount of NO in the blood. It is assumed that NO initiates (on the administration of the carcinogen) or at least enhances (on the administration of cycloheximide) the blockage of the synthesis of the protein, deoxyribonucleotides, and DNA. In response to the disturbance of protein synthesis, the complex of enzymes is activated that accomplish the utilization of the degradation products of proteins, including the inducible form of NO synthase.     

Subcellular localization of cytoplasmic lattice-associated proteins is dependent upon fixation and processing procedures

We and others have recently demonstrated by immuno-EM and mutation analysis that two oocyte-restricted maternal effect genes, PADI6 and MATER, localize, in part, to the oocyte cytoplasmic lattices (CPLs). During these ongoing studies, however, we found that the localization of these factors by confocal immunofluorescence (IF) analysis can vary dramatically depending upon how the oocytes and embryos are processed, with the localization pattern sometimes appearing more uniformly cytoplasmic while at other times appearing to be primarily cortical. We set out to better understand this differential staining pattern by testing a range of IF protocol parameters, changing mainly time and temperature conditions of the primary antibody solution incubation, as well as fixation methods. We found by confocal IF whole mount analysis that PADI6 and MATER localization in germinal vesicle stage oocytes is mainly cytoplasmic when the oocytes are fixed and then incubated with primary antibodies at room temperature for 1 hour, while the localization of these factors is largely limited to the cortex when the oocytes are fixed and incubated in primary antibody at 4 °C overnight. We then probed sections of fixed/embedded ovaries and isolated two-cell embryos with specific antibodies and found that, under these conditions, PADI6 and MATER were again primarily cytoplasmically localized, although the staining for these factors is slightly more cortical at the two-cell stage. Taken together, our results suggest that the localization of CPL-associated proteins by confocal IF is particularly affected by processing conditions. Further, based on our current observations, it appears that PADI6 and MATER are primarily distributed throughout the cytoplasm as opposed to the oocyte subcortex.     

Dynamic localization and interaction with other Bacillus subtilis actin-like proteins are important for the function of MreB

Bacterial actin-like proteins play a key role in cell morphology and in chromosome segregation. Many bacteria, like Bacillus subtilis, contain three genes encoding actin-like proteins, called mreB, mbl and mreBH in B. subtilis. We show that MreB and Mbl colocalize extensively within live cells, and that all three B. subtilis actin paralogues interact with each other underneath the cell membrane. A mutation in the phosphate 2 motif of MreB had a dominant negative effect on cell morphology and on chromosome segregation. Expression of this mutant allele of MreB interfered with the dynamic localization of Mbl. These experiments show that the interaction between MreB and Mbl has physiological significance. An mreB deletion strain can grow under special media conditions, however, depletion of Mbl in this mutant background abolished growth, indicating that actin paralogues can partially complement each other. The membrane protein MreC was found to interact with Mbl, but not with MreB, revealing a clear distinction between the function of the two paralogues. The phosphate 2 mutant MreB protein allowed for filament formation of mutant or wild-type MreB, but abolished the dynamic reorganization of the filaments. The latter mutation led to a strong reduction, but not complete loss, of function of MreB, both in terms of chromosome segregation and of cell morphology. Our work shows that that the dynamic localization of MreB is essential for the proper activity of the actin-like protein and that the interactions between MreB paralogues have important physiological significance.