The distribution of two hnRNP-associated proteins defined by a monoclonal antibody is altered in heat-shocked HeLa cells

Reversible protein aggregation as cytoprotective mechanism against heat stress

Temperature fluctuation is one of the most frequent threats to which organisms are exposed in nature. The activation of gene expression programs that trigger the transcription of heat stress-protective genes is the main cellular response to resist high temperatures. In addition, reversible accumulation and compartmentalization of thermosensitive proteins in high-order molecular assemblies are emerging as critical mechanisms to ensure cellular protection upon heat stress. Here, we summarize representative examples of membrane-less intracellular bodies formed upon heat stress in yeasts and human cells and highlight how protein aggregation can be turned into a cytoprotective mechanism.

Proteomic analysis of protein phosphorylations in heat shock response and thermotolerance

Heat shock (HS) induces a wide variety of biological processes, including inhibition of protein synthesis, elevated expression of heat shock proteins, induction of thermotolerance, and apoptotic cell death in a dose-dependent manner. We compared phosphorylated proteins in heat-shocked and thermotolerant cells using proteome analysis. After HS treatment of control RIF-1 and their thermotolerant derivatives, TR-RIF-1 cells, cellular proteins were separated by two-dimensional gel electrophoresis and the phosphorylated proteins were detected with the anti-phosphotyrosine antibodies. We found that 93 proteins showed significant changes in phosphorylation between control and thermotolerant cells as a function of recovery time after HS; we identified 81 of these proteins with peptide mass fingerprinting using MALDI-TOF MS after in-gel trypsin digestion. These phosphorylated proteins exhibit various cellular functions, including chaperones, ion channels, signaling molecules, in transcription and translation processes, in amino acid biosynthesis, oxidoreduction, energy metabolism, and cell motility or structure, suggesting that HS turns on the various signaling pathways by activating protein-tyrosine kinases (PTKs). Of these, 20 proteins were previously identified phosphorylated proteins and 64 were newly identified. These proteins can be grouped into three families: 1) proteins highly phosphorylated in TR-RIF-1 cells at basal level and phosphorylated more significantly by HS in RIF-1 than TR-RIF-1; 2) proteins highly phosphorylated in control RIF-1 cells at basal level and phosphorylated more easily by HS in TR-RIF-1 than in RIF-1 cells; and 3) proteins with a similar basal phosphorylation level in both RIF-1 and TR-RIF-1 cells and responding to HS similarly in both cells. Most of the phosphorylated proteins are presumably involved in HS signaling in different ways, with the first and second families of proteins influencing thermotolerance. The possible tyrosine phosphorylation sites, the possible PTKs phosphorylating these proteins, and the proteins binding to these phosphorylated sites were predicted by the Netphos, ScanProsite, and Scansite programs. These results suggest that HS can activate various PTKs and HS responses can be regulated by phosphorylations of proteins having various functions.

Spatiotemporal regulation of hnRNP M and 2H9 gene expression during mouse embryonic development

Using the HeLa cell model along with an in vitro splicing system, we have previously shown that hnRNP M and 2H9 are involved in the pre-mRNA splicing process and most interestingly also in heat shock-induced transient splicing arrest by transiently leaving the hnRNP complexes. Due to this unique regulatory function in a mechanism that turns splicing on and off, these two hnRNPs appear as important proteins for controlling gene expression. Here we investigated by in situ hybridization and immunohistochemical staining techniques the expression level of specific mRNA and protein during mouse embryonic development. HnRNP M and 2H9 are found to be expressed at all examined stages (6.5-18.5 days post-coïtum), in a differential manner, and at various levels depending on tissues, cell types and also embryonic stages; fairly high levels of both hnRNPs are always observed in the central nervous system. Furthermore, levels of colocalizing protein and transcript are not always present in the same proportion, thus suggesting a post-transcriptional regulation of hnRNP M and 2H9 gene expression. The complex spatiotemporal variations we observed might well anticipate a role for these two hnRNPs also in modulating splicing, thereby influencing gene expression and further many physiological processes.

The hnRNP 2H9 gene, which is involved in the splicing reaction, is a multiply spliced gene

The hnRNP 2H9 gene products are involved in the splicing process and participate in early heat shock-induced splicing arrest. By combining low/high stringency hybridisation, database search, Northern and Western blotting it is shown that the gene is alternatively spliced into at least six transcripts: hnRNPs 2H9, 2H9A, 2H9B, 2H9C, 2H9D and 2H9E predicting proteins containing 346, 331, 297, 215, 145 and 139 amino acids, respectively. The hnRNP 2H9A cDNA sequence was used to obtain a genomic BAC clone and the structure of the hnRNP 2H9 gene was revealed by sequencing two subclones together spanning about 6.7 kb. The six transcripts are processed from at least 10, 10, 8, 7, 5 and 4 exons, respectively, with all intron/exon junctions obeying the 'GT-AG' rule. The hnRNP 2H9 and 2H9A proteins contain two RNA recognition motifs of the quasi-RRM type found in the two C-terminal qRRMs of the hnRNPs H, H' and F proteins. The hnRNP 2H9B protein has a partially deleted N-terminal qRRM, which is completely deleted in hnRNP 2H9C. hnRNPs 2H9D and 2H9E contain only one slightly modified C-terminal qRRM. Furthermore, the six proteins vary in their auxiliary domains outside the qRRMs. Western blotting indicates that the alternatively spliced transcripts give rise to different sets and levels of proteins expressed among various human cells and tissues. Due to their great structural variations the different proteins may thus possess different functions in the splicing reaction.

Disruption of LT-antigen/p53 complex by heat treatment correlates with inhibition of DNA synthesis during transforming infection with SV40

Transforming infection of Go/G1-arrested primary mouse kidney cell cultures with simian virus 40 (SV40) induces cells to re-enter the S-phase of the cell cycle. In Go-arrested cells, no p53 is detected, whereas in cells induced to proliferate by infection, a gradual accumulation of p53 complexed to SV40 large T-antigen is observed in the nucleus. Heat treatment of actively proliferating SV40-infected cells leads to inhibition of DNA synthesis and growth arrest. To determine the fate of p53 after heat treatment, proliferating infected cells were exposed to mild heat (42.5°C) for increasing lengths of time. The results presented here show that after ninety minutes of treatment, the arrest of DNA synthesis by heat correlates with the disruption of the p53/LT-antigen complex. Longer treatments induce, in addition, a reduction in the solubility of p53, which was recovered tightly associated with the nuclear fraction. This contrasted with large T-antigen, whose solubility remained unaffected by heat treatment. Although the total amount of p53 in the nucleus remained constant, as shown by immunoblot analyses, p53 was no longer detectable after immunoprecipitation or by immunofluorescent staining techniques. These results suggest that heat treatment had either induced conformational changes in its antigenic sites, or had sequestered the sites through aggregation or binding to insoluble nuclear components.Key words: p53, heat shock, LT-antigen/p53 complex, S-phase.

Immunocytochemical detection of structural and regulatory proteins in rat adrenal nuclear matrix

The nuclear matrix is a specific cell structure consisting of a residual nucleoskeleton that extends from the nucleoli to the nuclear envelope. The nuclear matrix of steroidogenic cells was isolated previously from a purified nuclear fraction. We present here an in situ extraction method, modified Lutz's method, for rat glandular adrenal cell nuclear matrix. This residual organelle was characterized and studied using immunocytochemical methods. The adrenal glands were removed, the cells prepared in suspension and deposited by cytospin onto Poly-L-lysine glass slides. The nuclear matrix was extracted with Nonidet P-40, DNase I and high and low ionic strength buffers. Structural proteins, nuclear lamins, coilin and fibrillarin were detected immunocytochemically. The adrenal fasciculata cells were easily identified by this method because of their large nuclei and abundant lipid droplets in the cytoplasm. After immunocytochemical detection by antibodies against lamins A and C, a marked brown layer at the periphery of the nucleus was observed. The intensity of the staining was lower using the antibody against nuclear lamin B. Immunocytochemical detection of the protein coilin revealed punctuated stained areas, 2-6 per nucleus, that probably correspond to the coiled bodies. The protein fibrillarin was detected at the nucleolus and coiled bodies. Our technique is simple, reveals well preserved adrenal nuclear matrices, and may be a useful method for immunocytochemical analysis and in situ hybridization.

Cloning of human 2H9 heterogeneous nuclear ribonucleoproteins. Relation with splicing and early heat shock-induced splicing arrest

Using antibody 2H9 from our heterogeneous nuclear ribonucleoproteins (anti-hnRNP) monoclonal antibody library, we previously showed in HeLa cells that a 35-37-kDa protein doublet switches from the hnRNP complexes to the nuclear matrix following a 10-min heat shock at 45 degrees C (1 Lutz, Y., Jacob, M., and Fuchs, J. P. (1988) Exp. Cell Res. 175, 109-124). cDNA cloning and sequencing revealed an hnRNP protein (2H9) which is a new member of the hnRNP F, H/H' family. Protein 2H9 displays two consensus sequence-type RNA binding domains (CS-RBD) showing 80-90% homology with two of the three CS-RBDs of hnRNP F and H/H'. Another common feature is the presence of two glycine/tyrosine-rich auxiliary domains located at the C terminus and between the two CS-RBDs. At the functional level we show that specific anti-2H9 peptide antibodies can directly inhibit an in vitro splicing system. Moreover, the 2H9 protein doublet is no more present in nuclear extracts from such briefly stressed cells, which interestingly correlates with the inability of these extracts to catalyze in vitro splicing reactions. Taken together, our data suggest that these proteins are involved in the splicing process and also participate in early heat shock-induced splicing arrest by transiently leaving the hnRNP complexes. These 2H9 proteins, which are encoded by a single gene located on human chromosome 10, were also found to be associated with nuclear bodies in situ.

The human hnRNP-M proteins: structure and relation with early heat shock-induced splicing arrest and chromosome mapping

With anti-hnRNP monoclonal antibody 6D12 we previously showed in HeLa cells that as early as 10 min after the onset of a heat shock at 45 degrees C, a 72.5-74 kDa antigen doublet leaves the hnRNPs and strongly associates with the nuclear matrix, the effect being reversed after a 6 h recovery at 37 degrees C. cDNA cloning and sequencing enabled us to identify these antigens as hnRNP-M proteins and further to show that the correct sequence differs by an 11 amino acid stretch from the originally published sequence. We also show that monoclonal antibodies raised against synthetic hnRNP-M peptides can directly inhibit in vitro splicing. Furthermore, stressing cells at 45 degrees C for 10 min is sufficient to abolish the splicing capacity of subsequently prepared nuclear extracts which, interestingly, do not contain the hnRNP-M proteins any more. Taken together, our data suggest that these proteins are involved in splicing as well as in early stress-induced splicing arrest. Further in situ hybridization assays located the hnRNP-M encoding gene on human chromosome 19.

Properties of the adenovirus IVa2 gene product, an effector of late-phase-dependent activation of the major late promoter

The adenovirus major late promoter is strongly activated after the onset of viral DNA replication. Sequence elements located downstream of the major later promoter start site have previously been shown to be essential for this activation. Two proteins (DEF-A and DEF-B) bind to these elements in a late-phase-dependent manner. DEF-B has been identified as the product of adenovirus intermediate gene IVa2 (pIVa2) (C. Tribouley, P. Lutz, A. Staub, and C. Kedinger, J. Virol. 68:4450-4457, 1994). Here we show that pIVa2, while monomeric in solution, binds to its recognition sequence as a dimer and that two 20-residue amphipathic alpha helices play an essential role in this DNA-binding activity. Attempts to purify DEF-A have failed, but its chromatographic behavior, together with its immunological properties, established that pIVa2 is also a component of this heteromeric protein. In addition, the time course of pIVa2 synthesis during infection correlated with simultaneous detection of the binding of both DEF-A and DEF-B complexes to the downstream elements. Finally, as revealed by immunomicroscopy, pIVa2 is targeted to the nucleus, where it distributes to restricted locations in the nucleoplasm, as well as to the nucleoli. Altogether, these results demonstrate that pIVa2 plays a critical role in the transition from the early to the late phase of the lytic cycle. Furthermore, pIVa2 may serve additional functions yet to be uncovered, as suggested by its presence within the cell nucleolus.

Alternative 5' splice site selection induced by heat shock

The mouse HSP47 gene consists of six exons separated by five introns. Three HSP47 cDNAs differing only in their 5' noncoding regions have been reported. One of these alternatively spliced mRNAs was detected only after heat shock, which caused an alternative 5' splice donor site selection. Other stress inducers, including an amino acid analog and sodium arsenite, had no effect on the alternative splicing. The alternatively spliced mRNA, which was 169 nucleotides longer in the 5' noncoding region compared to mRNA transcribed in non-heat shock conditions, was efficiently translated under heat shock conditions. This novel finding that alternative splicing is caused by artificial treatment like heat shock will provide a useful in vivo model for understanding the exon-intron recognition mechanism as well as heat shock-induced alterations in gene expression.

Alternative 5' splice site selection induced by heat shock

The mouse HSP47 gene consists of six exons separated by five introns. Three HSP47 cDNAs differing only in their 5' noncoding regions have been reported. One of these alternatively spliced mRNAs was detected only after heat shock, which caused an alternative 5' splice donor site selection. Other stress inducers, including an amino acid analog and sodium arsenite, had no effect on the alternative splicing. The alternatively spliced mRNA, which was 169 nucleotides longer in the 5' noncoding region compared to mRNA transcribed in non-heat shock conditions, was efficiently translated under heat shock conditions. This novel finding that alternative splicing is caused by artificial treatment like heat shock will provide a useful in vivo model for understanding the exon-intron recognition mechanism as well as heat shock-induced alterations in gene expression.

PMLRAR homodimers: distinct DNA binding properties and heteromeric interactions with RXR

Fusion proteins (named PMLRAR) between PML and the retinoic acid receptor alpha (RAR alpha) are generated as a result of the t(15;17) chromosomal translocation found in acute promyelocytic leukemia (APL). We show here that PMLRAR proteins exist in solution as stable homodimers whose formation is mediated by a presumptive coiled coil in the PML moiety. In contrast to RAR alpha, which requires heterodimerization with RXR for efficient DNA binding, PMLRAR homodimers can bind to target sequences in the absence of RXR, and the binding pattern of PMLRAR homodimeric complexes to directly repeated motif (DR) response elements with 1-5 bp spacers is different from that of RAR/RXR heterodimeric complexes. We show that the presence of RXR induces the formation of PMLRAR/RXR heteromeric complexes which bind to DNA via one RAR DNA binding domain (DBD) and one RXR DBD, like 'classical' RAR/RXR heterodimers. PMLRAR interaction with RXR occurs in solution and in transfected cultured Cos cells, and PMLRAR is able to sequester RXR efficiently in the cytoplasm, suggesting that dominant 'inactivation' of RXR may be a possible mechanism of action for PMLRAR. Accordingly, we show that PMLRAR can both prevent the binding of the vitamin D3 receptor (VDR) to a target sequence in vitro and inhibit vitamin D3-dependent activation of a VDR-responsive reporter gene in transfected cells. These results suggest that both the distinct DNA binding properties of PMLRAR homodimers and the sequestration of RXR by PMLRARs may contribute to the molecular mechanisms which underlie the pathogenesis of APL. We also report that RXR alpha transcripts are down-regulated by RA-treatment in promyelocytic cells.

Production and characterization of monoclonal antibodies recognising defined regions of the human oestrogen receptor

Mouse monoclonal antibodies were raised against the N-terminal (amino acids 151-165) and the very C-terminal (amino acids 578-595) regions of the human oestrogen receptor (hER). These antibodies recognise the hER by enzyme-linked immunosorbent assay, immunocytochemistry, immunoblotting, immunoprecipitation and gel retardation assays. The presence of hER is used prognostically in human breast cancer. We have tested the reactivity of our monoclonal antibodies on breast cancer sections, comparing with the commonly used Abbott rat monoclonal antibody H222. These studies show that the two monoclonal antibodies described here are highly versatile and will be useful tools for in vivo and in vitro studies of hER function. Furthermore, we show that the corresponding epitopes can be used as molecular "tags" for heterologous proteins and offer a powerful means of purifying and/or characterizing over-produced fusion proteins containing these regions.

Structure, localization and transcriptional properties of two classes of retinoic acid receptor alpha fusion proteins in acute promyelocytic leukemia (APL): structural similarities with a new family of oncoproteins

Acute promyelocytic leukemia (APL) is due to a chromosomal t(15;17) translocation which involves a novel human gene, Myl, (also named PML) and the retinoic acid (RA) receptor alpha (RAR-alpha) gene. We report here the characterization of Myl and of the reciprocal MylRAR (PMLRAR) and RARMyl (RARPML) fusion transcripts which are found in two classes of APL patients. Myl displays similarities with a new family of proteins of which some members are fused to protooncogenes in the transforming proteins RFP-ret and T18. The speckled nuclear localization of Myl, as well as its sequence homology with the 52 kDa component of the RO/SSA ribonucleoprotein particle, suggest that Myl may be present in a ribonucleoprotein complex. In contrast to both Myl and RAR-alpha whose localization is essentially nuclear in the presence or absence of RA, MylRAR which is largely cytoplasmic in the absence of RA appears to be translocated to the nucleus in the presence of RA. Myl and MylRAR can associate in vitro and this association is mediated by a coiled coil in the Myl sequence. In vivo this association results in a colocalization of Myl and MylRAR which is identical to that of MylRAR alone. Studies of activation of transcription from the promoters of several RA target genes indicate that MylRARs have altered transcription activation properties when compared with RAR-alpha. Most notably, MylRAR represses markedly the activity of some RA target promoters in the absence of RA. Western blot analyses of patient samples show that MylRAR is expressed to a much higher level than wild type RAR-alpha originating from the normal allele. Taken together, these results suggest that MylRAR may interfere in a dominant manner with both Myl and RAR functions.

Retinoic acid receptor gamma: specific immunodetection and phosphorylation

Synthetic peptides corresponding to cDNA-deduced amino acid sequences unique to the human and mouse retinoic acid receptor gamma 1 (hRAR-gamma 1 and mRAR-gamma 1, respectively) were used to generate anti-RAR-gamma 1 antibodies. Four mAbs were selected, which were directed against peptides found in region A1 (Ab1 gamma (A1)), region F (Ab2 gamma (mF) and Ab4 gamma (hF)) and region D2 (Ab5 gamma (D2)). These antibodies specifically immunoprecipitated and recognized by Western blotting RAR-gamma 1 proteins in COS-1 cells transfected with expression vectors containing the RAR-gamma 1 cDNAs. They all reacted with both human and mouse RAR-gamma 1 proteins, except Ab4 gamma (hF) that was specific for hRAR-gamma 1. Rabbit polyclonal antibodies, directed against a peptide from the mRAR-gamma 1 F region were also obtained (RP gamma (mF)) and found to be specific for mouse RAR-gamma 1 protein. Furthermore, in gel retardation/shift assays the antibodies specifically retarded the migration of complexes obtained with a RA response element (RARE). Antibodies raised against regions D2 and F also recognized the RAR-gamma 2 isoform which differs from RAR-gamma 1 only in the A region. On the other hand, antibodies directed against the A1 region of RAR-gamma 1 (Ab1 gamma (A1)) only reacted with the RAR-gamma 1 protein. The antibodies characterized here allowed us to detect the presence of mRAR-gamma 1 and gamma 2 isoforms in mouse embryos and F9 embryonal carcinoma cells nuclear extracts. They were also used to demonstrate that the mRAR-gamma 1 protein can be phosphorylated and that the phosphorylation occurs mainly in the NH2-terminal A/B region.

Change in the expression of a nuclear matrix-associated protein is correlated with cellular transformation

We have identified a monoclonal antibody that recognizes a nuclear matrix-associated protein in NIH 3T3 cells. The immunofluorescence pattern consists predominantly of bright nuclear granule clusters distributed throughout the nucleoplasm, with the exclusion of nucleoli. It recognizes a protein of 190 kDa that is down-regulated to various degrees in a panel of single-oncogene-transformed NIH 3T3 cells. Its localization is similar, but not identical, to the spliceosomal speckles. p190 shows a coordinate expression during the growth cycle of nontransformed NIH 3T3 cells; it is synthesized at the highest level under growth arrest conditions. It is expressed in adult mouse brain and is also present in human IMR-90 fibroblasts.

Rapid effect of heat shock on two heterogeneous nuclear ribonucleoprotein-associated antigens in HeLa cells

During severe heat shock, which known to interrupt both splicing of RNA transcripts and nucleocytoplasmic transport, it is to be expected that the substructure of heterogeneous nuclear ribonucleoproteins (hnRNP) is altered in some way. Recently, we have shown that such a stress actually induces rapid alterations at the level of individual proteins (Lutz, Y., M. Jacob, and J.-P. Fuchs. 1988 Exp. Cell Res. 175:109-124). Here we report further investigations on two related 72.5-74-kD hnRNP proteins whose behavior is also rapidly modified by a heat shock at 45 degrees C, whereas no effect is observed at 42 degrees C. Using a monoclonal antibody, we show that in situ the antigens are available only when the cells are heat shocked at 45 degrees C. Subcellular fractionation shows that in normal cells the antigens are associated with the bulk of hnRNP (50-200S). During heat shock, whereas the overall characteristics of the bulk of preexisting hnRNP are unchanged, these antigens rapidly switch to a subpopulation of hnRNP with larger average size (50 to less than 300S) and increased stability. Structural analysis of the associated hnRNP in normal and stressed cells shows that in both cases the antigens are associated with the nuclear matrix subcomplex of hnRNP, which in situ is part of the internal nuclear matrix. Such hnRNP antigens, which are rapidly redistributed during a heat shock at the upper temperature range of the stress response, might well be involved in splicing and/or transport control.

Molecular organization of RNP complexes containing P11 antigen in heat-shocked and non-heat-shocked Drosophila cells

Immunofluorescence analysis of polytene chromosomes of Drosophila melanogaster using the monoclonal antibody P11 has shown that after heat-shock the 38-kDa P11 antigen almost exclusively localizes at heat-shock puff 93D where it is part of giant puff-specific RNP granules. The biochemical experiments reported here show that, independent of growth temperature, the P11 antigen is a component of nuclear 10S RNP particles. The P11-containing 10S snRNPs can be stabilized in CsCl with 20 mM Mg2+ and possess a buoyant density of rho = 1.4 g/cm3. Sucrose gradient analysis of nuclear RNP extracts of heat-shocked Schneider's S-3 tissue culture cells shows that, after a 37 degree C heat-shock, the 10S RNPs associate with large RNP complexes sedimenting at 170-220S. The change in distribution is a temperature-dependent process with intermediate forms at 29 degrees C and 33 degrees C. In thermotolerant cells this observed change in distribution is strongly reduced. DEAE-Sephacel column chromatography and sucrose gradient analysis of nuclear RNP, followed by Northern blot analysis using 93D-specific probes of the TaqI repeat and immunoblotting experiments, show that the P11-containing 10S snRNPs are distinct from the RNP complexes formed by the 93D transcripts, suggesting an indirect association after heat-shock. Our experiments demonstrate that, despite the fact that a 37 degrees C heat-shock does not affect the overall integrity of nuclear RNP, it imposes changes on the general organization and interaction of the nuclear RNP population, resulting in the formation of large nuclear RNP aggregates and complexes. Such changes may be important for the survival strategy of the cell and for hnRNA processing and storage events which are effected by heat-shock.