EAST interacts with Megator and localizes to the putative spindle matrix during mitosis in Drosophila

We have used immunocytochemistry to demonstrate that the EAST protein in Drosophila, which forms an expandable nuclear endoskeleton at interphase, redistributes during mitosis to colocalize with the spindle matrix proteins, Megator and Skeletor. EAST and Megator also colocalize to the intranuclear space surrounding the chromosomes at interphase. EAST is a novel protein that does not have any previously characterized motifs or functional domains. However, we show by immunoprecipitation experiments that EAST is likely to molecularly interact with Megator which has a large NH2-terminal coiled-coil domain with the capacity for self assembly. On the basis of these findings, we propose that Megator and EAST interact to form a nuclear endoskeleton and as well are important components of the putative spindle matrix complex during mitosis.     

Immunoelectron microscope localization of Mr 90000 heat shock protein and Mr 70000 heat shock cognate protein in the salivary glands of Chironomus thummi

The Mr 90000 heat shock protein (hsp 90) and one of the Mr 70000 heat shock cognate proteins (hsc 70) were localized by immunoelectron microscopy in salavary gland cells of normal and heat-shocked larvae of Chironomus thummi using polyclonal antibodies raised against Drosophila proteins. Immunoblotting after separation of proteins by gel electrophoresis shows that these antibodies cross-react with the corresponding proteins of Chironomus. Hsp 90 was localized both in the cytoplasm and in the nucleus, where it is associated with intrachromosomal and extrachromosomal ribonucleoprotein (RNP) fibrils, as well as with the peripheral region of compact chromatin. After heat shock the concentration of hsp 90 increases in the nucleus. This increase is prevented by actinomycin D administration during the heat shock. Hsp 90 is associated with the chromatin of puffs repressed by heat shock and with the RNP fibrils of actively transcribing heat shock puffs. Hsc 70 is mainly found in RNP fibrils and in the periphery of compact chromatin. During heat shock the concentration of hsc 70 decreases in the cytoplasm while it becomes more abundant in association with chromatin and intrachromosomal and extrachromosomal RNP fibrils. These results suggest a translocation of the existing protein from the cytoplasm toward the nucleus. They are supported by observations of the effect of heat shock carried out in the presence of actinomycin D.by D.P. Bazett-Jones     

Nuclear localization and the heat shock proteins

The highly conserved heat shock proteins (HSP) belong to a subset of cellular proteins that localize to the nucleus. HSPs are atypical nuclear proteins in that they localize to the nucleus selectively, rather than invariably. Nuclear localization of HSPs is associated with cell stress and cell growth. This aspect of HSPs is highly conserved with nuclear localization occurring in response to a wide variety of cell stresses. Nuclear localization is likely important for at least some of the heat shock proteins’ protective functions; little is known about the function of the heat shock proteins in the nucleus. Nuclear localization is signalled by the presence of a basic nuclear localization sequence (NLS) within a protein. Though most is known about HSP 72’s nuclear localization, the NLS(s) has not been definitively identified for any of the heat shock proteins. Likely more is involved than presence of a NLS; since the heat shock proteins only localize to the nucleus under selective conditions, nuclear localization must be regulated. HSPs also function as chaperons of nuclear transport, facilitating the movement of other macromolecules across the nuclear membrane. The mechanisms involved in chaperoning of proteins by HSPs into the nucleus are still being identified.     

Nuclear heat shock protein 72 as a negative regulator of oxidative stress (hydrogen peroxide)-induced HMGB1 cytoplasmic translocation and release

In response to inflammatory stimuli (e.g., endotoxin, proinflammatory cytokines) or oxidative stress, macrophages actively release a ubiquitous nuclear protein, high-mobility group box 1 (HMGB1), to sustain an inflammatory response to infection or injury. In this study, we demonstrated mild heat shock (e.g., 42.5 degrees C, 1 h), or enhanced expression of heat shock protein (Hsp) 72 (by gene transfection) similarly rendered macrophages resistant to oxidative stress-induced HMGB1 cytoplasmic translocation and release. In response to oxidative stress, cytoplasmic Hsp72 translocated to the nucleus, where it interacted with nuclear proteins including HMGB1. Genetic deletion of the nuclear localization sequence (NLS) or the peptide binding domain (PBD) from Hsp72 abolished oxidative stress-induced nuclear translocation of Hsp72-DeltaNLS (but not Hsp72-DeltaPBD), and prevented oxidative stress-induced Hsp72-DeltaPBD-HMGB1 interaction in the nucleus. Furthermore, impairment of Hsp72-DeltaNLS nuclear translocation, or Hsp72-DeltaPBD-HMGB1 interaction in the nucleus, abrogated Hsp72-mediated suppression of HMGB1 cytoplasmic translocation and release. Taken together, these experimental data support a novel role for nuclear Hsp72 as a negative regulator of oxidative stress-induced HMGB1 cytoplasmic translocation and release.     

Structure in the amphibian germinal vesicle

The germinal vesicle (GV) of Xenopus laevis is an enormous nucleus that contains 18 giant lampbrush chromosomes and thousands of inclusions. The inclusions are primarily of three types: approximately 1500 extrachromosomal nucleoli, 50-100 Cajal bodies, and several thousand B-snurposomes, which correspond to speckles or interchromatin granule clusters in other nuclei. The large size and abundance of the GV organelles, as well as the ease with which they can be studied both in vivo and in vitro, make the GV an ideal object for analysis of nuclear structure and function.     

Protein ligands mediate the CRM1-dependent export of HuR in response to heat shock

AU-rich elements (AREs) located in the 3' UTRs of the messenger RNAs (mRNAs) of many mammalian early response genes promote rapid mRNA turnover. HuR, an RRM-containing RNA-binding protein, specifically interacts with AREs, stabilizing these mRNAs. HuR is primarily nucleoplasmic, but shuttles between the nucleus and the cytoplasm via a domain called HNS located between RRM2 and RRM3. We recently showed that HuR interacts with two protein ligands, pp32 and APRIL, which are also shuttling proteins, but rely on NES domains recognized by CRM1 for export. Here we show that heat shock induces increased association of HuR with pp32 and APRIL through protein-protein interactions and that these ligands partially colocalize with HuR in cytoplasmic foci. HuR associations with the hnRNP complex also increase, but through RNA links. CRM1 coimmunoprecipitates with HuR only after heat shock, and nuclear export of HuR becomes sensitive to leptomycin B, an inhibitor of CRM1. Export after heat shock requires the same domains of HuR (HNS and RRM3) that are essential for binding pp32 and APRIL. In situ hybridization and coimmunoprecipitation experiments show that LMB treatment blocks both hsp70 mRNA nuclear export and its cytoplasmic interaction with HuR after heat shock. Together, our results argue that upon heat shock, HuR switches its export pathway to that of its ligands pp32 and APRIL, which involves the nuclear export factor CRM1. HuR and its ligands may be instrumental in the nuclear export of heat-shock mRNAs.     

Karyosphere in oogenesis]

The purpose of this review is to draw attention to the peculiar phenomenon during gametogenesis: the formation of the karyosphere. This phenomenon is characterized by concentration of all chromosomes in the limited area of the nucleus and may be considered as alternative of the genome in the state of lumpbrush chromosomes. The formation of the karyosphere is a widely spread phenomenon during oogenesis of different animal classes. The karyosphere can be developed during different stages of oogenesis in different organisms; but as a rule the chromosomes of diploten stage of meiosis take part in its formation. As to functional identity of the karyosphere in different species, special investigations are to be done, but contemporary knowledge of the karyosphere formation reveals some common feature:1) in the karyosphere the chromosomes are in a relatively spiral state as demonstrated by the positive Feulgen reaction; 2) there is a low level of RNA synthesis or the absence of it in the karyosphere; 3) during the karyosphere formation the nucleus is enriched by the acid proteins and a lot of protein granules and structures appearing in a close contact with the karysphere. The more typical examples of the karyosphere formation can be observed in the insect oocytes belonging to the nutrimentary type of oogenesis. In the oocytes of some animals the peculiar protein substances are formed around the chromosome knot and appear as a fibrillar zone. Such karyosphere appears to be a kind of capsule inside the nucleus. The capsules are developed as a result of complex interaction between the main nuclear structures; chromosomes, nucleoli, and nuclear membrane as it is manifested by the analysis of some recent ultrastructural date obtained in some insect and amphibian oocytes. The function of the karyosphere capsule and the role of the nuclear structure (sinaptonemal complex, extrachromosomal DNA, and nuclear membrane) in formation of the capsule, are discussed as well as the ultrastructural and cytochemical similarity between the karyosphere capsule of oocytes and nuclear bodies of somatic cells.     

Use of peptide tagging to detect proteins expressed from cloned genes: deletion mapping functional domains of Drosophila hsp 70.

We have developed a technique which allows specific detection of proteins expressed from cloned genes. The method involves fusion of an oligonucleotide coding for part of the neuropeptide substance P to the 3' end of the gene; the protein can then be detected with a monoclonal antibody that recognises this peptide. We have used this method to determine the properties of deletion mutants of the major Drosophila heat shock protein, hsp70, expressed in monkey COS cells. The results suggest that this protein has two distinct domains. Both are capable of accumulating in the nucleus of unstressed cells, but only the more highly conserved N-terminal domain is able to bind to nucleoli following a heat shock. This implies that nucleolar binding and nuclear migration are distinct properties of the protein, and suggests that the former may be of functional importance. In addition, we observed a novel effect of heat shock on cellular metabolism: protein fragments that are normally rapidly degraded are stabilized. The effect persists for several hours after the heat shock, but does not require expression of heat shock proteins. Together with previously published data, these results suggest an intimate relationship between protein degradation and the heat shock response.     

Another way to move chromosomes

A typical way of moving chromosomes is exemplified by mitotic segregation, in which the centromere is directly captured by spindle microtubules. In this study, we highlight another way of moving chromosomes remotely from outside the nucleus, which involves SUN and KASH domain nuclear envelope proteins. SUN and KASH domain protein families are known to connect the nucleus to cytoskeletal networks and play a role in migration and positioning of the nucleus. Recent studies in the fission yeast Schizossacharomyces pombe demonstrated an additional role for the SUN–KASH protein complex in chromosome movements. During meiotic prophase, telomeres are moved to rearrange chromosomes within the nucleus. The SUN–KASH protein complex located in the nuclear envelope is involved in this process. Telomeres are connected to the SUN protein on the nucleoplasmic side, and the dynein motor complex binds to the KASH protein on the cytoplasmic side. Telomeres are then moved along the nuclear envelope using cytoplasmic microtubules. These findings illustrate a general mechanism for transmitting a cytoskeletal driving force to chromosomes across the nuclear envelope. Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users. Note added in proof Recently, a related article on C. elegans SUN protein has been published: Penkner A, Tang L, Novatchkova M, Ladurner M, Fridkin A, Gruenbaum Y, Schweizer D, Loidl J, Jantsch V (2007) The nuclear envelope protein Matefin/Sun-1 is required for homologous pairing in C. elegans meiosis. Dev Cell 12:873–885     

Localization of the chromatin-remodeling protein ATRX in the oocyte nucleus of some insects

A comparative study of nuclear distribution of the chromatin-remodeling protein ATRX in the oocytes of three species of insects in which the oocyte nucleus at the diplotene stage differs in structure, has been carried out using fluorescent and immunoelectron microscopy. In tóhe oocyte nucleus of the tenebrionid beetles, Tribolium castaneum and Tenebrio molitor, ATRX preferably associates with the karyosphere (karyosome) that represents a result of concentration of the condensed chromosomes in a limited volume of the nucleus. In the oocyte nucleus of the house cricket, Acheta domesticus, in which a karyosphere does not form, the protein ATRX is distributed in the entire nuclear volume in association with the chromatin. The fact of ATRX presence in the extrachromosomal structures of the insect oocyte nucleus, the karyosphere capsule and specific nuclear bodies, is documented for the first time.     

Cellular stresses induce the nuclear accumulation of importin alpha and cause a conventional nuclear import block

We report here that importin alpha accumulates reversibly in the nucleus in response to cellular stresses including UV irradiation, oxidative stress, and heat shock. The nuclear accumulation of importin alpha appears to be triggered by a collapse in the Ran gradient, resulting in the suppression of the nuclear export of importin alpha. In addition, nuclear retention and the importin beta/Ran-independent import of importin alpha also facilitate its rapid nuclear accumulation. The findings herein show that the classical nuclear import pathway is down-regulated via the removal of importin alpha from the cytoplasm in response to stress. Moreover, whereas the nuclear accumulation of heat shock cognate 70 is more sensitive to heat shock than the other stresses, importin alpha is able to accumulate in the nucleus at all the stress conditions tested. These findings suggest that the stress-induced nuclear accumulation of importin alpha can be involved in a common physiological response to various stress conditions.     

Hikeshi, a nuclear import carrier for Hsp70s, protects cells from heat shock-induced nuclear damage

During heat shock stress, importin β family-mediated nucleocytoplasmic trafficking is downregulated, whereas nuclear import of the molecular chaperone Hsp70s is upregulated. Here, we identify a nuclear import pathway that operates during heat shock stress and is mediated by an evolutionarily conserved protein named "Hikeshi," which does not belong to the importin β family. Hikeshi binds to FG-Nups and translocates through nuclear pores on its own, showing characteristic features of nuclear transport carriers. In reconstituted transport, Hikeshi supports the nuclear import of the ATP form of Hsp70s, but not the ADP form, indicating the importance of the Hsp70 ATPase cycle in the import cycle. In living cells, depletion of Hikeshi inhibits heat shock-induced nuclear import of Hsp70s, reduces cell viability after heat shock stress, and significantly delays the attenuation and reversion of multiple heat shock-induced nuclear phenotypes. Nuclear Hsp70s rescue the effect of Hikeshi depletion at least in part. Thus, Hsp70s counteract heat shock-induced damage by acting inside of the nucleus.