In vivo phosphorylation of Drosophila melanogaster nuclear lamins during both interphase and mitosis

To study phosphorylation of D. melanogaster nuclear lamins in vivo, we used Kc tissue culture cells. Kc cells contain products of both lamin genes, the lamin Dm0 gene encoding constitutive polypeptides expressed in almost all cell types and the developmentally regulated lamin C gene. We grew Kc cells in low phosphate medium and labelled them with (32P(H3PO4. To obtain mitotic cells we used vinblastine to arrest cells in metaphase. Cells were collected, washed, lysed and resultant extracts fractionated in the presence of protein phosphatase inhibitors. D. melanogaster proteins were then denatured by boiling in SDS plus DTT, followed by immunoaffinity chromatography and SDS-PAGE purification. As anticipated, we found that a CNBr fragment derived from the N-terminal part of lamin Dm0-derivatives (amino acid residues 2-158; fragment A) was phosphorylated during both interphase and mitosis. Interphase but not mitotic phosphorylation was found on an internal CNBr fragment (derived from the end of the central rod domain and the first part of the C-terminal lamin tail; amino acid residues 385-548; fragment D). Interphase only phosphorylation was also detected on another CNBr fragment derived from the extreme C-terminal portion of lamin Dm0-derivatives (amino acid residues 549-622; fragment E). To supplement these data, we used 2-D tryptic peptide mapping followed by phosphorImager analysis. We routinely detected at least seven 'spots' derived from interphase lamins but only a single mitotic lamin phosphopeptide.     

Microtubule-associated nuclear envelope proteins in interphase and mitosis

The LINC (linker of nucleoskeleton and cytoskeleton) complex forms a transcisternal bridge across the NE (nuclear envelope) that connects the cytoskeleton with the nuclear interior. This enables some proteins of the NE to communicate with the centrosome and the microtubule cytoskeleton. The position of the centrosome relative to the NE is of vital importance for many cell functions, such as cell migration and division, and centrosomal dislocation is a frequent phenotype in laminopathic disorders. Also in mitosis, a small group of transmembrane NE proteins associate with microtubules when they concentrate in a specific membrane domain associated with the mitotic spindle. The present review discusses structural and functional aspects of microtubule association with NE proteins and how this association may be maintained over the cell cycle.     

Phosphorylation of the nuclear lamins during interphase and mitosis

The nuclear lamina is a polymeric protein assembly that is proposed to function as an architectural framework for the nuclear envelope. Previous work suggested that phosphorylation of the major polypeptides of the lamina (the "lamins") may induce disassembly of this structure during mitosis. To further investigate the possible involvement of phosphorylation in regulation of lamina structure, we characterized lamin phosphorylation occurring in mammalian tissue culture cells during interphase and mitosis. Phosphorylation occurs continuously throughout all interphase periods (coordinately with nuclear envelope growth), and takes place mainly on the assembled lamina. When the lamina is disassembled during cell division, the lamins are modified with approximately 1-2 molecules of associated phosphate. This level of mitotic phosphorylation is 4-7-fold higher than the average interphase level. Lamin phosphate occurs predominantly as phosphoserine, and is distributed over numerous tryptic peptides, many of which are modified during both interphase and mitotic periods. Significantly, phosphorylation is the only detectable charge-altering postsynthetic modification of the lamins that occurs specifically during mitosis. The results of this study support the notion that phosphorylation is important for regulation of interphase and mitotic lamina structure.     

Dual functions of Nicotiana benthamiana Rae1 in interphase and mitosis

Rae1 performs multiple functions in animal systems, acting in interphase as an mRNA export factor and during mitosis as a mitotic checkpoint and spindle assembly regulator. In this study we characterized multiple functions of Rae1 in plants. Virus-induced gene silencing of Nicotiana benthamiana Rae1 , NbRae1 , which encodes a protein with four WD40 repeats, resulted in growth arrest and abnormal leaf development. NbRae1 was mainly associated with the nuclear envelope during interphase, and NbRae1 deficiency caused accumulation of poly(A) RNA in the nuclei of leaf cells, suggesting defective mRNA export. In the shoot apex, depletion of NbRae1 led to reduced mitotic activities, accompanied by reduced cyclin-dependent kinase (CDK) activity and decreased expression of cyclin B1, CDKB1-1, and histones H3 and H4. The secondary growth of stem vasculature was also inhibited, indicating reduced cambial activities. Differentiated leaf cells of NbRae1 -silenced plants exhibited elevated ploidy levels. Immunolabeling in BY-2 cells showed that NbRae1 protein localized to mitotic microtubules and the cell plate-forming zone during mitosis, and recombinant NbRae1 directly bound to microtubules in vitro . Inhibition of NbRae1 expression in BY-2 cells using a β-estradiol-inducible RNAi system resulted in severe defects in spindle organization and chromosome alignment and segregation, which correlated with delays in cell cycle progression. Together, these results suggest that NbRae1 plays a dual role in mRNA export in interphase and in spindle assembly in mitosis.     

Histone H1 of Trypanosoma cruzi is concentrated in the nucleolus region and disperses upon phosphorylation during progression to mitosis

Phosphorylation of histone H1 is intimately related to the cell cycle progression in higher eukaryotes, reaching maximum levels during mitosis. We have previously shown that in the flagellated protozoan Trypanosoma cruzi, which does not condense chromatin during mitosis, histone H1 is phosphorylated at a single cyclin-dependent kinase site. By using an antibody that recognizes specifically the phosphorylated T. cruzi histone H1 site, we have now confirmed that T. cruzi histone H1 is also phosphorylated in a cell cycle-dependent manner. Differently from core histones, the bulk of nonphosphorylated histone H1 in G(1) and S phases of the cell cycle is concentrated in the central regions of the nucleus, which contains the nucleolus and less densely packed chromatin. When cells pass G(2), histone H1 becomes phosphorylated and starts to diffuse. At the onset of mitosis, histone H1 phosphorylation is maximal and found in the entire nuclear space. As permeabilized parasites preferentially lose phosphorylated histone H1, we conclude that this modification promotes its release from less condensed and nucleolar chromatin after G(2).     

Immunocytochemical localization of casein kinase II during interphase and mitosis

We have developed specific antibodies to synthetic peptide antigens that react with the individual subunits of casein kinase II (CKII). Using these antibodies, we studied the localization of CKII in asynchronous HeLa cells by immunofluorescence and immunoelectron microscopy. Further studies were done on HeLa cells arrested at the G1/S transition by hydroxyurea treatment. Our results indicate that the CKII alpha and beta subunits are localized in the cytoplasm during interphase and are distributed throughout the cell during mitosis. Further electron microscopic investigation revealed that CKII alpha subunit is associated with spindle fibers during metaphase and anaphase. In contrast, the CKII alpha' subunit is localized in the nucleus during G1 and in the cytoplasm during S. Taken together, our results suggest that CKII may play significant roles in cell division control by shifting its localization between the cytoplasm and nucleus.     

Architecture of the Trypanosoma brucei nucleus during interphase and mitosis

The structural basis of mitosis, spindle organisation and chromosome segregation, in the unicellular parasite Trypanosoma brucei is poorly understood. Here, using immunocytochemistry, fluorescent in situ hybridisation and electron microscopy, we provide a detailed analysis of mitosis in this parasite. We describe the organisation of the mitotic spindle during different stages of mitosis, the complex ultrastructure of kinetochores and the identification of a potential spindle-organising centre in the mitotic nucleus. We investigate the dynamics of chromosome segregation using telomeric and chromosome-specific probes. We also discuss the problems involved in chromosome segregation in the light of the fact that the T. brucei karyotype has 22 chromosomes in the apparent presence of only eight ultrastructurally defined kinetochores. Received: 9 August 1999; in revised form: 15 October 1999 / Accepted: 10 November 1999     

Serine phosphorylation of focal adhesion kinase in interphase and mitosis: a possible role in modulating binding to p130(Cas)

Focal adhesion kinase (FAK) is an important regulator of integrin signaling in adherent cells and accordingly its activity is significantly modulated during mitosis when cells detach from the extracellular matrix. During mitosis, FAK becomes heavily phosphorylated on serine residues concomitant with its inactivation and dephosphorylation on tyrosine. Little is known about the regulation of FAK activity by serine phosphorylation. In this report, we characterize two novel sites of serine phosphorylation within the C-terminal domain of FAK. Phosphorylation-specific antibodies directed to these sites and against two previously characterized sites of serine phosphorylation were used to study the regulated phosphorylation of FAK in unsynchronized and mitotic cells. Among the four major phosphorylation sites, designated pS1-pS4, phosphorylation of pS1 (Ser722) is unchanged in unsynchronized and mitotic cells. In contrast, pS3 and pS4 (Ser843 and Ser910) exhibit increased phosphorylation during mitosis. In vitro peptide binding experiments provide evidence that phosphorylation of pS1 (Ser722) may play a role in modulating FAK binding to the SH3 domain of the adapter protein p130(Cas).     

Nuclear envelope radiating microtubules in plant cells during interphase mitosis transition

Summary The microtubule distribution during the transition from interphase to the mitotic phase was examined at ultrastructural level in large highly vacuolated cells ofNautilocalyx lynchii and in small non-vacuolated cells ofPisum sativum. Both cell types contain, besides preprophase bands and perinuclear microtubules, also microtubules radiating from the nucleus into the transvacuolar cytoplasmic strands and cytoplasm respectively.This microtubule array appears to be nucleated by the cell's nuclear envelope (NE) or NE-surrounding cytoplasm.It is hypothesized that the microtubules radiating from the nucleusinitially play a role in the mobilization of the nucleus whilelater on a stabilized part of this array anchors the nucleus in the plane of cell division, and thus forms a cytoskeletal link between nucleus and division site.Our results are discussed in the light of previous work on cytoplasmic behaviour during interphase-mitosis transition in highly vacuolated plant cells.     

Localization of Nopp140 within mammalian cells during interphase and mitosis

We investigated distribution of the nucleolar phosphoprotein Nopp140 within mammalian cells, using immunofluorescence confocal microscopy and immunoelectron microscopy. During interphase, three-dimensional image reconstructions of confocal sections revealed that nucleolar labelling appeared as several tiny spheres organized in necklaces. Moreover, after an immunogold labelling procedure, gold particles were detected not only over the dense fibrillar component but also over the fibrillar centres of nucleoli in untreated and actinomycin D-treated cells. Labelling was also consistently present in Cajal bodies. After pulse-chase experiments with BrUTP, colocalization was more prominent after a 10- to 15-min chase than after a 5-min chase. During mitosis, confocal analysis indicated that Nopp140 organization was lost. The protein dispersed between and around the chromosomes in prophase. From prometaphase to telophase, it was also detected in numerous cytoplasmic nucleolus-derived foci. During telophase, it reappeared in the reforming nucleoli of daughter nuclei. This strongly suggests that Nopp140 could be a component implicated in the early steps of pre-rRNA processing.     

Histone tyrosine phosphorylation comes of age

Histones were discovered over a century ago and have since been found to be the most extensively posttranslationally modified proteins, although tyrosine phosphorylation of histones had remained elusive until recently. The year 2009 proved to be a landmark year for histone tyrosine (Y) phosphorylation as five research groups independently discovered this modification. Three groups describe phosphorylation of Y142 in the variant histone H2A.X, where it may be involved in the cellular decision making process to either undergo DNA repair or apoptosis in response to DNA damage. Further, one group suggests that phosphorylation of histone H3 on Y99 is crucial for its regulated proteolysis in yeast, while another found that Y41 phosphorylation modulates chromatin architecture and oncogenesis in mammalian cells. These pioneering studies provide the initial conceptual framework for further analyses of the diverse roles of tyrosine phosphorylation on different histones, with far reaching implications for human health and disease.

Erratum to: Singh R.K. and Gunjan A. Histone tyrosine phosphorylation comes of age. Epigenetics 2011; 6:153-60.     

Histone phosphorylation: how to proceed

Among all posttranslational modifications that occur on histone tails, phosphorylation is the one that establishes a direct link between chromatin remodeling and intracellular signaling pathways. Specific, conserved serine residues are present on the N-terminal tails of each histone. These are phosphoacceptor sites for a number of kinases, whose identification is essential to decipher the transduction routes leading to various physiological responses. In the case of histone H3, phosphorylation at the Ser10 residue may lead to either activated gene expression or chromatin condensation during mitosis. In addition, phosphorylation at specific sites may be coupled to other distinct modifications, such as acetylation and methylation, generating the so-called "histone code" which postulates that well defined combinatorial modifications at histone tails correspond to specific physiological responses. Here we describe a number of experimental methodologies that are essential for the study of histone phosphorylation. While chromatin immunoprecipitation is useful in recognizing gene targets, the in-gel kinase assay is a first, essential step in establishing the identity of the kinase(s) that operates in response to a specific signaling pathway. The subsequent use of in vitro kinase assays is helpful in validating the implication of a candidate kinase. These powerful approaches are important as identification of the signaling transduction routes leading to chromatin remodeling is critical to an understanding of all cellular processes.