Functional analysis of adenovirus protein IX identifies domains involved in capsid stability, transcriptional activity, and nuclear reorganization.

The product of adenovirus (Ad) type 5 gene IX (pIX) is known to actively participate in the stability of the viral icosahedron, acting as a capsid cement. We have previously demonstrated that pIX is also a transcriptional activator of several viral and cellular TATA-containing promoters, likely contributing to the transactivation of the Ad expression program. By extensive mutagenesis, we have now delineated the functional domains involved in each of the pIX properties: residues 22 to 26 of the highly conserved N-terminal domain are crucial for incorporation of the protein into the virion; specific residues of the C-terminal leucine repeat are responsible for pIX interactions with itself and possibly other proteins, a property that is critical for pIX transcriptional activity. We also show that pIX takes part in the virus-induced nuclear reorganization of late infected cells: the protein induces, most likely through self-assembly, the formation of specific nuclear structures which appear as dispersed nuclear globules by immunofluorescence staining and as clear amorphous spherical inclusions by electron microscopy. The integrity of the leucine repeat appears to be essential for the formation and nuclear retention of these inclusions. Together, our results demonstrate the multifunctional nature of pIX and provide new insights into Ad biology.

The cell-surface-expressed nucleolin is associated with the actin cytoskeleton.

Nucleolin is a RNA- and protein-binding multifunctional protein. Mainly characterized as a nucleolar protein, nucleolin is continuously expressed on the surface of different types of cells along with its intracellular pool within the nucleus and cytoplasm. By confocal and electron microscopy using specific antibodies against nucleolin, we show that cytoplasmic nucleolin is found in small vesicles that appear to translocate nucleolin to the cell surface. Translocation of nucleolin is markedly reduced at low temperature or in serum-free medium, whereas conventional inhibitors of intracellular glycoprotein transport have no effect. Thus, translocation of nucleolin is the consequence of an active transport by a pathway which is independent of the endoplasmic reticulum-Golgi complex. The cell-surface-expressed nucleolin becomes clustered at the external side of the plasma membrane when cross-linked by the nucleolin-specific monoclonal antibody mAb D3. This clustering, occurring at 20 degrees C and in a well-organized pattern, is dependent on the existence of an intact actin cytoskeleton. At 37 degrees C, mAb D3 becomes internalized, thus illustrating that surface nucleolin can mediate intracellular import of specific ligands. Our results point out that nucleolin should also be considered a component of the cell surface where it could be functional as a cell surface receptor for various ligands reported before.

DNA replication progresses on the periphery of nuclear aggregates formed by the BCL6 transcription factor.

The BCL6 proto-oncogene, frequently alterated in non-Hodgkin lymphoma, encodes a POZ/zinc finger protein that localizes into discrete nuclear subdomains. Upon prolonged BCL6 overexpression in cells bearing an inducible BCL6 allele (UTA-L cells), these subdomains apparently coincide with sites of DNA synthesis. Here, we explore the relationship between BCL6 and replication by both electron and confocal laser scanning microscopy. First, by electron microscope analyses, we found that endogenous BCL6 is associated with replication foci. Moreover, we show that a relatively low expression level of BCL6 reached after a brief induction in UTA-L cells is sufficient to observe its targeting to mid, late, and at least certain early replication foci visualized by a pulse-labeling with bromodeoxyuridine (BrdU). In addition, when UTA-L cells are simultaneously induced for BCL6 expression and exposed to BrdU for a few hours just after the release from a block in mitosis, a nuclear diffuse BCL6 staining indicates cells in G(1), while cells in S show a more punctate nuclear BCL6 distribution associated with replication foci. Finally, ultrastructural analyses in UTA-L cells exposed to BrdU for various times reveal that replication progresses just around, but not within, BCL6 subdomains. Thus, nascent DNA is localized near, but not colocalized with, BCL6 subdomains, suggesting that they play an architectural role influencing positioning and/or assembly of replication foci. Together with its previously function as transcription repressor recruiting a histone deacetylase complex, BCL6 may therefore contribute to link nuclear organization, replication, and chromatin-mediated regulation.

Isolation and characterization of an equine foamy virus.

Foamy viruses (FVs) are complex retroviruses which have been isolated from different animal species including nonhuman primates, cattle, and cats. Here, we report the isolation and characterization of a new FV isolated from blood samples of horses. Similar to other FVs, the equine foamy virus (EFV) exhibits a highly characteristic ultrastructure and induces syncytium formation and subsequent cell lysis on a large number of cell lines. Molecular cloning of EFV reveals that the general organization is that of other known FVs, whereas sequence similarity with its bovine FV counterpart is only 40%. Interestingly, EFV buds exclusively from the plasma membrane and not from the endoplasmic reticulum (ER), as previously shown for other FVs. The absence of the ER retrieval dilysine motif in EFV Env is likely responsible for this unexpected sorting pathway.

An anchorage nuclear structure for telomeric DNA repeats in HeLa cells.

Using either a biotinylated peptide nucleic acid (PNA) oligomer or a digoxigenin-labeled double-stranded DNA probe, we determined the distribution of the telomeric DNA repeats in HeLa cells by in-situ hybridization at the ultrastructural level. The telomeric DNA was found at the periphery of previously unrecognized roundish nuclear structures, distributed throughout the nucleoplasm. The levels of association of the telomeric DNA with these structures was investigated by exposure of cells to a detergent-containing hypotonic solution which only preserves tightly linked components. The telomeric DNA repeats stayed associated with their anchorage structures following spreading apart of nucleoproteins. Because changes in cellular DNA topology are associated with the intranuclear development of herpes simplex virus type 1 (HSV-1) and adenovirus type 5 (Ad5) in HeLa cells, we examined the distribution of telomeric DNA when cellular DNA is pushed toward the nuclear border. The circular telomeric complexes were morphologically unmodified; however, as a result of the partition of cellular and viral DNA in two concentric compartments, they migrated towards the nuclear border, along with the compressed cellular chromatin. Taken together, our results exemplify the unique organization of the telomeric DNA, which is coiled around a central core of a diameter of 120 nm and can therefore be clearly distinguished from the bulk of the cellular chromatin.

Deletion of the fiber gene induces the storage of hexon and penton base proteins in PML/Sp100-containing inclusions during adenovirus infection.

The present study has documented changes in the in situ distribution of viral DNA and capsid proteins in 293 cells infected with fiber gene-deleted adenoviruses. It shows that infection results in the intense production of progeny viruses which appear morphologically intact although they are devoid of fiber-coding sequence in their genome and hence of fiber protein in their capsid. The data confirm, therefore, that fiber protein is not essential for the assembly of progeny viruses. The main contribution of our observations concerns specific intranuclear structures induced by infection with either wild-type or fiber gene-deleted viruses. These clear amorphous inclusions contain two cellular proteins, PML and Sp100, which in non-infected cells co-localize to a special type of nuclear bodies. PML and Sp100 nuclear bodies appear to directly modulate or to be altered in a wide variety of situations including viral infections, cell death and transformation. In cells infected with fiber gene-deleted viruses, the clear amorphous inclusions now accumulate non-used hexon and penton base proteins, whereas the absence of fiber protein prevents the assembly of capsid proteins in crystallin arrays. Taken together, the data suggest that the clear amorphous inclusions may correspond to storage sites of structural and regulatory proteins. Consequently, these virus-induced structures may promote the productive cycle of adenoviruses by regulating the amount of over-produced viral proteins and the shutoff of the host cell metabolism.

Release of viruses and viral DNA from nucleus to cytoplasm of HeLa cells at late stages of productive adenovirus infection as revealed by electron microscope in situ hybridization.

Considerable progress has been made over the past 10 years towards a full understanding of the functional significance of the structural changes resulting from the production of adenoviruses in permissive cells. Similarly, the host-virus interactions which are involved in viral replication and gene expression as well as in RNA nuclear export have been investigated. Post-embedding nonisotopic in situ hybridization has been proven to be a powerful tool for the study of nucleic acids in infected cells provided that controlled elimination of artifacts by appropriate treatments was undertaken. Adenovirus infected cells present two biological characteristics which could lead to false positive or negative results. First, they contain large amounts of single-stranded portions of viral DNA which are revealed with viral RNA molecules. Second, DNA-binding proteins are present which hide some nucleic acid sequences. By using a DNA probe and appropriate variations in the experimental protocol, it is possible to reveal specifically different kinds of targets, simultaneously single-stranded DNA (ssDNA) and double-stranded DNA (dsDNA), or only ssDNA, or only dsDNA, or only RNA. By using two probes labeled with different haptens, biotine and digoxigenin, it is possible to detect concomitantly two nucleic acid targets and, therefore, to study their relationships. In order to gain insight into the changes in the nucleus before cell lysis and to improve our knowledge on the series of steps leading to the release of adenoviruses from the nucleus, examination of cells at 41 h post-infection and identification of structures containing adenoviral nucleic acids were undertaken. In addition to the ultrastructural changes and precise distribution of cellular DNA and viral nucleic acid molecules already described in cells up to 24 h post-infection (for a review, see Puvion E, Puvion-Dutilleul F (1996) Exp Cell Res 229, 217-225), new results were obtained. Routine observation revealed the presence of: i) viruses in the cytoplasm, some being located next to nuclear pores; ii) abnormally large portions of the nuclear envelope devoid of underlying condensed chromatin; iii) proliferation of either the inner nuclear membrane only or both membranes of the nuclear envelope; and iv) electron-opaque grains in the nuclear compartment involved in viral genome transcription, and also in the clusters of interchromatin granules known to contain mature viral messenger RNA (Bridge E et al (1996) J Cell Biol 135, 303-314). In situ hybridization revealed the presence of: i) dsDNA in the cytoplasmic viruses indicating that they were mature viruses; ii) free viral dsDNA and ssDNA molecules in the cytoplasm whereas host DNA remained confined at the nuclear border; and iii) viral RNA in the newly-described electron-opaque grains we call, therefore, viral-RNA containing grains. Immunodetection of bromodeoxyuridine (BrdU) incorporated into DNA in pulse and pulse-chase experiments allowed us to ascertain that cells at 41 h post-infection were truly living cells and that at least part of the newly-synthesized viral DNA migrated from the nucleus to the cytoplasm. Taken together, the data suggest that modifications of the nuclear matrix, cytoskeleton, and nucleo-cytoplasmic interactions might occur near the termination of adenovirus infection inducing the progressive release of viruses, vial dsDNA and ssDNA molecules in the cytoplasm. In addition, the observation of a new structural support for the intranuclear viral RNA in the clusters of interchromatin granules emphasizes the role of these cellular structures in the intranuclear trafficking of messenger RNA leading to the regulation of its nuclear export.

Pilot ultrastructural evaluation of human preauricular skin before and after high-energy pulsed carbon dioxide laser treatment.

BACKGROUND: Carbon dioxide laser resurfacing has recently come into favor for the treatment of photodamaged skin. While the clinical and histologic effects of high-energy short-pulse carbon dioxide lasers on human skin have been investigated, the ultrastructural effects of these lasers have not been documented. Our objective was to study the ultrastructural effects of a high-energy pulsed carbon dioxide laser on photodamaged human skin. OBSERVATIONS: Before laser surgery, the ultrastructural changes characteristic of photodamaged skin were evident. Immediately after treatment, there was extensive coagulation necrosis of the epidermis and papillary dermis. Thirty days after treatment, there was no evidence of intercellular or intracellular edema, and ordered differentiation of the epidermal keratinocytes, with a loss of keratinocyte dysplasia, was seen. Increased numbers of desmosomes and tonofibrils were noted. New deposition of collagen was present in the papillary dermis. The ultrastructural findings seen at 90 days after treatment were similar to those seen at 30 days, apart from increased organization of collagen fibers in the papillary dermis. CONCLUSIONS: Treatment with the high-energy pulsed carbon dioxide laser appears to reverse the epidermal and dermal changes of photoaging on an ultrastructural level. These changes appear morphologically to be consistent with previously described clinical and histologic changes following laser resurfacing.

Ultrastructural localization of interferon-inducible double-stranded RNA-activated enzymes in human cells.

The protein kinase PKR and the 2',5'-oligoadenylate (2-5A) synthetase are two interferon-induced and double-stranded RNA-activated enzymes which are implicated in the mechanism of action of interferon. Their distribution was undertaken here at the ultrastructural level by the immunogold procedure, following the use of specific monoclonal antibodies directed against PKR and 69- and 100-kDa forms of the 2-5A synthetase. These enzymes were detected as a pool of nonaggregated proteins scattered throughout the cell and as aggregates often associated with electron-dense doughnut-like structures showing a similar aspect whatever their subcellular localization: the cytoplasm, the nuclear envelope, and the nucleus. In general, the 2-5A synthetases were present in much more lower amounts than the PKR, probably due to the difficulty of detecting traces of proteins by electron microscopy. To circumvent this, we used a human lymphoblastoid cell line overexpressing the 69-kDa form of the 2-5A synthetase. In such cells, the synthetase was then clearly observed in both the cytoplasm and the nucleus; isolated or small clusters of gold particles were numerous in the cell mainly over the RNP fibrils of the interchromatin space, nucleolus, and ribosomes. Interestingly, gold particles were also found to be associated with the membranes of nuclear envelope and rough endoplasmic reticulum probably due to the myristilated motif of this form of 2-5A synthetase. Finally, intensely labeled electron-opaque dots sometimes associated with the nuclear pore complexes were present in the nucleus and in the cytoplasm of cells which might suggest their transport from the nucleus to the cytoplasm or reciprocally through the nuclear pore complexes. These observations indicate the wider distribution of the dsRNA-activated enzymes in the cell, thus pointing out their potential implication in as yet undetermined physiological function(s) necessary for various cellular metabolic reactions.

Nuclear targeting of incoming human foamy virus Gag proteins involves a centriolar step.

The pathways used in the transport of retroviral genomes to the nucleus are poorly identified. Analyzing the intracellular localization of incoming foamy viruses, we have found that the Gag antigens and the viral genome accumulate in a distinct perinuclear domain identified as the centrosome. Colchicine treatment completely abolished pericentriolar targeting of human foamy virus (HFV) proteins, suggesting a role for microtubules in the transport of the incoming viral proteins to the centrioles. Finally, we demonstrate that, similarly to human immunodeficiency virus DNA, HFV DNA can enter the nucleus of G1/S-phase-arrested cells, although no viral gene expression can be observed. Recent observations have demonstrated that foamy viruses have several features not shared by other retroviruses. The intracellular route of the incoming Gag antigens may constitute a new specificity of this class of viruses.

Ultrastructure of the nucleus in relation to transcription and splicing: roles of perichromatin fibrils and interchromatin granules.

In the present article we summarize our results concerning the in situ ultrastructural organization of the nuclear steps of mRNA production using several cellular models including normal noninfected cells, herpes simplex virus type 1 and adenovirus type 5 infected cells, and transiently transfected cells. We confirm that perichromatin fibrils are the in situ morphological expression of nascent transcripts and the main support of splicing. Special emphasis is devoted to the clusters of interchromatin granules which seem to be involved in several central functions including accumulations of snRNP components as well as sorting and/or regulation of export of different RNA species.

LYSP100-associated nuclear domains (LANDs): description of a new class of subnuclear structures and their relationship to PML nuclear bodies.

The PML gene is fused to the retinoic acid receptor alpha (RAR alpha) gene in t(15;17) acute promyelocytic leukemia (APL), creating a PML-RAR alpha fusion oncoprotein. The PML gene product has been localized to subnuclear dot-like structures variously termed PODs, ND10s, Kr bodies, or PML nuclear bodies (PML NBs). The present study describes the cloning of a lymphoid-restricted gene, LYSP100, that is homologous to another protein that localizes to PML NBs, SP100. In addition to SP100 homology regions, one LYSP100 cDNA isoform contains a bromodomain and a PHD/TTC domain, which are present in a variety of transcriptional regulatory proteins. By immunofluorescence, LYSP100 was localized to nuclear dots that were surprisingly largely nonoverlapping with PML NBs. However, a minority of LYSP100 nuclear dots exactly colocalized with PML and SP100. We term the LYSP100 structures "LANDs," for LYSP100-associated nuclear domains. Although LYSP100 is expressed only in lymphoid cells, LANDs could be visualized in HeLa cells by transfection of a LYSP100 cDNA. Immunoelectron microscopy revealed LANDs to be globular, electron-dense structures morphologically distinct from the annular structures characteristic of PML NBs. LANDs were most often found in the nucleoplasm, but were also found at the nuclear membrane and in the cytoplasm, suggesting that these structures may traffic between the cytoplasm and the nucleus. By double-immunogold labeling of PML and LYSP100, some LANDs were shown to contain both PML and LYSP100. Thus, PML is localized to a second subnuclear domain that is morphologically and biochemically distinct from PML NBs.

Nucleoplasmic and nucleolar distribution of the adenovirus IVa2 gene product.

Sequence elements (DE) located downstream of the adenovirus major late promoter start site have previously been shown to be essential for the activation of this promoter after the onset of viral DNA replication. Two proteins (DEF-A and DEF-B) bind to these elements in a late-phase-dependent manner and contribute to this activation. DEF-B corresponds to a dimer of the adenovirus IVa2 gene product (pIVa2, 449 residues), while DEF-A is a heteromeric protein also comprising pIVa2. As revealed by specific immunofluorescence staining of infected cells, pIVa2 is targeted to the nucleus, where it distributes to both nucleoplasmic and nucleolar structures. We have identified the pIVa2 nuclear localization signal (NLS) as a basic peptide element at the C terminus of the protein (residues 432 to 449). An element essential for nucleolar localization (NuLS) has been mapped in the N-terminal part of pIVa2 (between residues 50 and 136). While NuLS activity is dependent upon an intact NLS, we show that both NLS and NuLS functions are independent of specific DNA-binding activity. As visualized by immunoelectron microscopy, pIVa2 is detected in the nucleoplasm at the level of the fibrillogranular network which is active in viral transcription. More surprisingly, pIVa2 accumulates within electron-dense amorphous inclusions found both in the nucleoplasm and in the nucleolus. Altogether, these results suggest that, besides controlling major late promoter transcription, pIVa2 serves additional, as yet unknown functions.

The osmium ammine-SO2 staining method for studying the in situ configuration of viral genomes in ultrathin sections of DNA virus infected cells.

The Feulgen-like osmium ammine-SO2 method developed by Cogliati and Gautier (CR Acad Sci Ser D 1973, 276, 3041-3044) stains the DNA at the ultrastructural level. Compared to several other techniques for detecting DNA, this method remains the only one revealing the configuration of the DNA molecules within the cell whatever their compactness. In the present article we summarize the results we obtained with the osmium ammine method in the study of the fate of viral genomes along the infectious cycles in several DNA virus infected cells including adenovirus, herpes simplex virus, simian virus 40 and poxvirus. The results are discussed in relation to the replicative and transcribing activities of viral DNA.

Sequestration of PML and Sp100 proteins in an intranuclear viral structure during herpes simplex virus type 1 infection.

We investigated the intranuclear distribution of PML and Sp100 in HeLa cells at the ultrastructural level and examined their relocalization in response to herpes simplex virus type 1 (HSV-1) infection. In the absence of infection, we observed that both are components, not only of nuclear bodies, but also of interchromatin granule-associated zones, which suggests a potential role for PML and Sp100 in splicing events. Prolonged HSV-1 infection induced dramatic changes in nuclear organization which consisted of the morphological disappearance of some nuclear structures (nuclear bodies, interchromatin granule-associated zones, coiled bodies) and of the development of a centrally located electron-translucent viral region which pushed the cellular clusters of interchromatin granules to the nuclear border. Concomitantly, dense bodies, concentric arrays of reduplicated inner nuclear membrane, and translucent patches containing a few viral capsids occurred at the nuclear border. PML and Sp100 were exclusively detected over the finely granular material of the viral translucent patches which also contains small amounts of p80-coilin and U1 and U2 snRNAs. An antiserum raised against capsid proteins intensely labeled the viral translucent patches at the level of their finely granular material and enclosed viral capsids. Our data, therefore, suggest that these viral structures, in addition to being the site of accumulation of viral capsid proteins and, possibly, a capsidworks, are also a site of sequestration of cell factors including PML and Sp100. Viral capsid proteins could interfere with and inactivate PML and Sp100 and be implicated in the shutoff of host cell metabolism induced by HSV-1 infection.

Differential distribution of single-stranded DNA, double-stranded DNA, and RNA in adenovirus-induced intranuclear regions of HeLa cells.

We investigated in great detail the fine spatial distribution of nucleic acids within adenovirus-infected HeLa cells by various immunogold labeling procedures. To detect DNA, we used the in situ terminal deoxynucleotidyl transferase-immunogold technique. In addition to the expected evident label over the condensed host chromatin and the structures containing viral double- and single-stranded DNA, label was consistently revealed over round fibrillar spots. By contrast, other virus-induced substructures, such as compact rings, crystalloids, clear amorphous inclusions, and electron-dense amorphous inclusions, displayed no significant label. Except for the viral single-stranded DNA accumulation sites, identical labeling pattern was obtained with the in situ nick-translation-immunogold method. We further labeled the sections with anti-RNA antibodies. Label was present not only over the cytoplasm and the intranuclear fibrillogranular network but also quite obviously over the compact rings and interchromatin granule clusters. None was seen over the other nuclear structures of infected cells, notably over the fibrillar spots. We suggest that these fibrillar spots might be involved in the formation of the viral, non-encapsidated, double-stranded DNA storage site.

Adenovirus infection induces rearrangements in the intranuclear distribution of the nuclear body-associated PML protein.

We have studied at the ultrastructural level the localization of PML protein in response to adenovirus infection in HeLa cells. In nuclei of noninfected cells or at the early stage of infection, PML accumulated at the border of nuclear bodies as previously described [Koken et al. (1994) EMBO J. 13, 1073-1083]. Interestingly, we demonstrate herein that PML is also a component of the interchromatin granule-associated zones, recently described structures containing U1 snRNP [Visa et al. (1993) Eur. J. Cell Biol. 60, 308-321], suggesting that PML protein might be involved in some steps of splicing events. However, as the infection progressed these two cellular PML-containing structures disappeared but significant amounts of PML accumulated within two virus-induced structures, essentially the clear amorphous inclusions, but also the protein crystals. Relocalization of this protein to virus-induced structures may reflect an inactivation of PML functions.

Immunocytochemistry, autoradiography, in situ hybridization, selective stains: complementary tools for ultrastructural study of structure-function relationships in the nucleus. Applications to adenovirus-infected cells.

A significant amount of new information on structure-function relationships in nuclei of adenovirus-infected cells has accumulated during the last decade as a result of the combined use of several new cytochemical techniques. Localization of viral DNA on ultrathin sections of infected cells has been investigated at the ultrastructural level by using specific DNA staining and immunocytochemistry with monoclonal anti-DNA antibodies. Both techniques, however, concomitantly visualize cellular and viral DNA. The specific stain for DNA reveals the configuration of the DNA molecules in the different nuclear substructures, whatever their synthetic activities. The immunodetection of DNA reveals that specific antibodies strongly bind to DNA of condensed host chromatin and to both encapsidated and nonencapsidated inactive viral genomes. However, the observation of an abnormally low level of labeling over the substructures in which synthetic activities of viral genomes are known to be intense demonstrates a serious limitation of this technique for the detection of active DNA. Postembedding in situ hybridization is the most useful method for identifying with certainty the structures containing defined nucleic acid sequences. By using a biotinylated viral DNA probe, in situ hybridization provides specific identification of structures containing either viral DNA or viral RNA molecules. In addition, with appropriate pretreatment of the sections, it is possible to reveal either all the viral DNA--that is, both double- and single-stranded DNA molecules (dsDNA, ssDNA)--or more specific species such as only ssDNA or only dsDNA molecules. The replicative and transcriptional activities of viral genomes are determined by high-resolution autoradiography. Autoradiography after a short pulse incorporation of appropriate radioactive precursors by infected cells reveals the sites of cellular and viral DNA replication or transcription. A short pulse followed by chase periods of different durations reveals the progressive migration of the cellular and viral synthesized products. The in situ distribution of the viral 72 kDa DNA-binding protein, a highly phosphorylated protein which protects the viral ssDNA, is revealed either by immunocytochemistry with specific antibodies or by the bismuth staining method which stains all highly phosphorylated proteins, including both cellular and viral proteins. The combined results of all these cytochemical procedures reveal the composition and functions of some of the structures induced by adenovirus infection. They demonstrate that viral genomes engaged in replication lead to the formation of the replicative foci in which two compartments rapidly develop, one of which results from the aggregation of single strands of viral DNA and their accompanying 72 kDa protein.(ABSTRACT TRUNCATED AT 400 WORDS)

Two hnRNP-associated proteins share common structural features with the adenoviral 72-kDa protein.

Using our anti-hnRNP monoclonal antibody library Y. Lutz, M. Jacob, and J.-P. Fuchs (1988) Exp. Cell Res., 175, 108-124; P. Mähl, Y. Lutz, E. Puvion, and J.-P. Fuchs, (1989) J. Cell Biol. 109, 1921-1935, we investigated by immunocytofluorescence the fate of a series of speckled-distributed nuclear antigens, after HeLa cells were infected with adenovirus type 2. Although the speckled pattern, which corresponds to the nucleoplasmic fibrillogranular network, including the interchromatin-granule clusters, was still observed during most of the infectious cycle, several antibodies also revealed additional, increasingly fluorescent virus-induced structures. In noninfected cells, two of these antibodies, termed 3F2 and 2A5, recognize two antigens of 33 and 31 kDa, respectively. Western blot analysis showed that this increasing amount of fluorescence observed in infected cells did not reflect an accumulation of the 33- and 31-kDa antigens, but is actually due to the fact that both antibodies also recognize the multifunctional adenovirus 72-kDa single-stranded DNA-binding protein (DBP). Immunoelectron microscopy analyses, including sequential double-labeling, indeed showed that this additional signal precisely colocalizes with the viral 72-kDa DBP, which essentially accumulates over the entire surface of the virus-induced single-stranded DNA accumulation sites. Taken together, our data show that two host-specific hnRNP-associated antigens share common epitopes with the viral 72-kDa DBP.

Anchorage of adenoviral RNAs to clusters of interchromatin granules.

Previous in situ hybridization experiments have revealed that clusters of interchromatin granules in adenovirus type 5 infected HeLa cells contain not only spliceosome components but also significant amounts of viral RNA and poly(A)+ RNA molecules whereas nonpolyadenylated viral RNA molecules are present within the still enigmatic viral compact rings. To determine the levels of association of the viral RNA molecules with cellular clusters of interchromatin granules and viral compact rings, we investigated the effects of a cell extraction technique on these structures. The spreading apart of the nucleoproteins by exposure of infected cells to a detergent-containing hypotonic solution, which exclusively preserves structurally linked components, resulted in the persistence within the clusters of interchromatin granules of U1 snRNA, U2 snRNA, viral RNA, and poly(A)+ RNA. These data clearly reveal that, in addition to the well-known strong binding of spliceosome components within the clusters of interchromatin granules, there also is an anchorage of viral RNA and messenger RNA molecules to these structures, which suggests functional relationships. Taken together, the data indicate that the clusters of interchromatin granules might be the sites of accumulation and retention of those cell and viral messenger RNA molecules that are transiently stored in the nucleus before their degradation or their transport to the cytoplasm. In addition, the firm binding of nonpolyadenylated viral RNA to the viral compact rings suggests a role for these structures in the transient storage of the nonused portions of the viral primary late transcripts.