Borna disease virus persistent infection activates mitogen-activated protein kinase and blocks neuronal differentiation of PC12 cells.

Persistence of Borna disease virus (BDV) in the central nervous system causes damage to specific neuronal populations. BDV is noncytopathic, and the mechanisms underlying neuronal pathology are not well understood. One hypothesis is that infection affects the response of neurons to factors that are crucial for their proliferation, differentiation, or survival. To test this hypothesis, we analyzed the response of PC12 cells persistently infected with BDV to the neurotrophin nerve growth factor (NGF). PC12 is a neural crest-derived cell line that exhibits features of neuronal differentiation in response to NGF. We report that persistence of BDV led to a progressive change of phenotype of PC12 cells and blocked neurite outgrowth in response to NGF. Infection down-regulated the expression of synaptophysin and growth-associated protein-43, two molecules involved in neuronal plasticity, as well as the expression of the chromaffin-specific gene tyrosine hydroxylase. We showed that the block in response to NGF was due in part to the down-regulation of NGF receptors. Moreover, although BDV caused constitutive activation of the ERK1/2 pathway, activated ERKs were not translocated to the nucleus efficiently. These observations may account for the absence of neuronal differentiation of persistently infected PC12 cells treated with NGF.

Light induces chromatin modification in cells of the mammalian circadian clock.

The mammalian circadian clock resides in neurons of the hypothalamic suprachiasmatic nucleus (SCN). Light entrains phase resetting of the clock using the retino-hypothalamic tract, via release of glutamate. Nighttime light exposure causes rapid, transient induction of clock and immediate-early genes implicated in phase-shifting the pacemaker. Here we show that a nighttime light pulse caused phosphorylation of Ser10 in histone H3's tail, in SCN clock cells. The effect of light was specific, and the kinetics of H3 phosphorylation were characteristic of the early response, paralleling c-fos and Per1 induction. Using fos-lacZ transgenic mice, we found that H3 phosphorylation and Fos induction occurRed in the same SCN neurons. Systemic treatment with the GABAB receptor agonist baclofen prevented light-induced c-fos and Per1 expression and H3 phosphorylation, indicating that one signaling pathway governs both events. Our results suggest that dynamic chromatin remodeling in the SCN occurs in response to a physiological stimulus in vivo.

A clockwork organ.

The vertebrate circadian clock was thought to be highly localized to specific anatomical structures: the mammalian suprachiasmatic nucleus (SCN), and the retina and pineal gland in lower vertebrates. However, recent findings in the zebrafish, rat and in cultured cells have suggested that the vertebrate circadian timing system may in fact be highly distributed, with most if not all cells containing a clock. Our understanding of the clock mechanism has progressed extensively through the use of mutant screening and forward genetic approaches. The first vertebrate clock gene was identified only a few years ago in the mouse by such an approach. More recently, using a syntenic comparative genetic approach, the molecular basis of the the tau mutation in the hamster was determined. The tau gene in the hamster appears to encode casein kinase 1 epsilon, a protein previously shown to be important for PER protein turnover in the Drosophila circadian system. A number of additional clock genes have now been described. These proteins appear to play central roles in the transcription-translation negative feedback loop responsible for clock function. Post-translational modification, protein dimerization and nuclear transport all appear to be essential features of how clocks are thought to tick.

La protein has a positive effect on the translation of TOP mRNAs in vivo.

In vertebrates, the mRNAs encoding ribosomal proteins, as well as other proteins implicated in translation, are characterized by a 5'-untranslated region (5'-UTR), including a stretch of pyrimidines at the 5'-end. The 5'-terminal oligopyrimidine (5'-TOP) sequence, which is involved in the growth-dependent translational regulation characteristic of this class of genes (so-called TOP genes), has been shown to specifically bind the La protein in vitro, suggesting that La might be implicated in translational regulation in vivo. In order to substantiate this hypothesis, we have examined the effect of La on TOP mRNA translational control in both stable and transient transfection experiments. In particular we have constructed and analyzed three stably transfected Xenopus cell lines inducible for overexpression of wild-type La or of putative dominant negative mutated forms. Moreover, La-expressing plasmids have been transiently co-transfected together with a plasmid expressing a reporter TOP mRNA in a human cell line. Our results suggest that in vivo La protein plays a positive role in the translation of TOP mRNA. They also suggest that the function of La is to counteract translational repression exerted by a negative factor, possibly cellular nucleic acid binding protein (CNBP), which has been previously shown to bind the 5'-UTR downstream from the 5'-TOP sequence.

Requirement of Rsk-2 for epidermal growth factor-activated phosphorylation of histone H3.

During the immediate-early response of mammalian cells to mitogens, histone H3 is rapidly and transiently phosphorylated by one or more unidentified kinases. Rsk-2, a member of the pp90rsk family of kinases implicated in growth control, was required for epidermal growth factor (EGF)-stimulated phosphorylation of H3. RSK-2 mutations in humans are linked to Coffin-Lowry syndrome (CLS). Fibroblasts derived from a CLS patient failed to exhibit EGF-stimulated phosphorylation of H3, although H3 was phosphorylated during mitosis. Introduction of the wild-type RSK-2 gene restored EGF-stimulated phosphorylation of H3 in CLS cells. In addition, disruption of the RSK-2 gene by homologous recombination in murine embryonic stem cells abolished EGF-stimulated phosphorylation of H3. H3 appears to be a direct or indirect target of Rsk-2, suggesting that chromatin remodeling might contribute to mitogen-activated protein kinase-regulated gene expression.

Small nucleolar RNAs and nucleolar proteins in Xenopus anucleolate embryos.

We investigated the presence and localization, in the cells of anucleolate mutant embryos of Xenopus laevis, of three representative small nucleolar RNAs (snoRNAs), U3, U15 and U17, and of two nucleolar proteins, nucleolin and fibrillarin. The levels of the three snoRNAs in the anucleolate mutant are the same as in normal embryos, in contrast to 5S RNA and ribosomal proteins. In situ hybridization showed that, in the absence of fully organized nucleoli, the three RNAs are diffusely distributed in the nucleus and partly associated with a number of small structures. Nucleolin and fibrillarin are also present in the anucleolate embryos as in normal embryos, although there is less nucleolin mRNA in the former. The two nucleolar proteins were localized by immunofluorescence microscopy. Fibrillarin, similar to its associated U3 and U15 snoRNAs, is diffusely distributed in the anucleolate nucleus and is partly associated with small structures, probably prenucleolar bodies and pseudonucleoli. Nucleolin also appears diffusely distributed in the nucleus with some spots of higher concentration, but with a different pattern with respect to fibrillarin.

Fugu intron oversize reveals the presence of U15 snoRNA coding sequences in some introns of the ribosomal protein S3 gene.

We present here the analysis of the genomic organization of the Fugu gene coding for ribosomal protein S3 and its intron encoded U15 RNA, and compare it with the homologous human and Xenopus genes. Only two of the six Fugu S3 gene introns do not contain the U15 sequence and are in fact shorter than 100 nucleotides, as most Fugu introns. The other four introns are somewhat longer and contain sequences homologous to U15 RNA; two of these represent functional copies, as shown by microinjections of Fugu transcripts into Xenopus oocytes, whereas the other two appear to be nonfunctional pseudocopies. Thus Fugu turns out to be ideal for the study of intron encoded snoRNAs, partly because of the reduced cloning and sequencing workload, and partly because the intron length per se can be an indication of the presence of a snoRNA coding sequence.

A functional role for some Fugu introns larger than the typical short ones: the example of the gene coding for ribosomal protein S7 and snoRNA U17.

The compact genome of Fugu rubripes, with its very small introns, appears to be particularly suitable to study intron-encoded functions. We have analyzed the Fugu gene for ribosomal protein S7 (formerly S8, see Note), whose Xenopus homolog contains in its introns the coding sequences for the small nucleolar RNA U17. Except for intron length, the organization of the Fugu S7 gene is very similar to that of the Xenopus counterpart. The total length of the Fugu S7 gene is 3930 bp, compared with 12691 bp for Xenopus. This length difference is uniquely due to smaller introns. Although short, the six introns are longer than the approximately 100 bp size of most Fugu introns, as they host U17 RNA coding sequences. While four of the six U17 sequences are 'canonical', the remaining two represent diverged U17 pseudocopies. In fact, microinjection in Xenopus oocytes of in vitro synthesized Fugu transcripts containing the 'canonical' U17f sequence results in efficient production of mature U17 RNA, while injection of a transcript containing the U17 psi b sequence does not.

Structure and expression of ribosomal protein genes in Xenopus laevis.

In Xenopus laevis, as well as in other vertebrates, ribosomal proteins (r-proteins) are coded by a class of genes that share some organizational and structural features. One of these, also common to genes coding for other proteins involved in the translation apparatus synthesis and function, is the presence within their introns of sequences coding for small nucleolar RNAs. Another feature is the presence of common structures, mainly in the regions surrounding the 5' ends, involved in their coregulated expression. This is attained at various regulatory levels: transcriptional, posttranscriptional, and translational. Particular attention is given here to regulation at the translational level, which has been studied during Xenopus oogenesis and embryogenesis and also during nutritional changes of Xenopus cultured cells. This regulation, which responds to the cellular need for new ribosomes, operates by changing the fraction of rp-mRNA (ribosomal protein mRNA) engaged on polysomes. A typical 5' untranslated region characterizing all vertebrate rp-mRNAs analyzed to date is responsible for this translational behaviour: it is always short and starts with an 8-12 nucleotide polypyrimidine tract. This region binds in vitro some proteins that can represent putative trans-acting factors for this translational regulation.

Sequence of the cDNA and gene coding for ribosomal protein S1 of Xenopus laevis.

The cloning and complete sequencing of one of the two gene copies coding for ribosomal protein (r-protein) S1 in Xenopus laevis and of the corresponding cDNA are reported. The comparison of the sequence of this cDNA (S1b) with the other (S1a) previously reported, reveals that, while the two DNA sequences have diverged somewhat, the amino-acid sequences are mostly unchanged. The two gene copies are apparently expressed at comparable levels, since the two corresponding mRNAs are similary represented in oocyte poly(A) RNA. The S1b gene has a total length of about 12000 nt and is composed of seven exons and six introns. By primer extension, it has been determined that the transcription start point is located in a pyrimidine-rich tract, as observed for all r-protein genes of X. laevis and other vertebrates so far analyzed. A computer analysis of the S1 sequence has shown the presence of a 150-nt sequence repeated in introns 3, 5 and 6, which is homologous to the one reported in the first intron of mammalian r-protein S3 gene. Furthermore, a 130-nt sequence is tandemly repeated 2.5 times at each of the two sites near the beginning and near the end of the first intron.

Different forms of U15 snoRNA are encoded in the introns of the ribosomal protein S1 gene of Xenopus laevis.

Recent cloning and sequencing of one of the two Xenopus gene copies (S1b) coding for the ribosomal protein S1 has revealed that its introns III, V and VI carry a region of about 150 nt that shares an identity of 60%. We show here the presence in Xenopus oocytes and cultured cells of a 143-147 nt long RNA species encoded by these three repeated sequences on the same strand as the S1 mRNA and by at least one repeat present in the S1 a copy of the r-protein gene. We identify these RNAs as forms of the small nucleolar RNA U15 (U15 snoRNA) because of their sequence homology with an already described human U15 RNA encoded in the first intron of the human r-protein S3 gene, which is homologous to Xenopus S1. Comparison of the various Xenopus and human U15 RNA forms shows a very high conservation in some regions, but considerable divergence in others. In particular the most conserved sequences include two box C and two box D motifs, typical of most snoRNAs interacting with the nucleolar protein fibrillarin. Adjacent to the two D boxes there are two sequences, 9 and 10 nt in length, which are perfectly complementary to an evolutionary conserved sequence of the 28S rRNA. Modeling the possible secondary structure of Xenopus and human U15 RNAs reveals that, in spite of the noticeable sequence diversity, a high structural conservation in some cases may be maintained by compensatory mutations. We show also that the different Xenopus U15 RNA forms are expressed at comparable levels, localized in the nucleoli and produced by processing of the intronic sequences, as recently described for other snoRNAs.