The 10 S BC-1 ribonucleoprotein particle contains identifier sequence-binding proteins that interact with an array of GCAAG/CTTGC motifs between split promoter sequences for RNA polymerase III

Local Gene Expression in Axons and Nerve Endings: The Glia-Neuron Unit

Neurons have complex and often extensively elongated processes. This unique cell morphology raises the problem of how remote neuronal territories are replenished with proteins. For a long time, axonal and presynaptic proteins were thought to be exclusively synthesized in the cell body, which delivered them to peripheral sites by axoplasmic transport. Despite this early belief, protein has been shown to be synthesized in axons and nerve terminals, substantially alleviating the trophic burden of the perikaryon. This observation raised the question of the cellular origin of the peripheral RNAs involved in protein synthesis. The synthesis of these RNAs was initially attributed to the neuron soma almost by default. However, experimental data and theoretical considerations support the alternative view that axonal and presynaptic RNAs are also transcribed in the flanking glial cells and transferred to the axon domain of mature neurons. Altogether, these data suggest that axons and nerve terminals are served by a distinct gene expression system largely independent of the neuron cell body. Such a local system would allow the neuron periphery to respond promptly to environmental stimuli. This view has the theoretical merit of extending to axons and nerve terminals the marginalized concept of a glial supply of RNA (and protein) to the neuron cell body. Most long-term plastic changes requiring de novo gene expression occur in these domains, notably in presynaptic endings, despite their intrinsic lack of transcriptional capacity. This review enlightens novel perspectives on the biology and pathobiology of the neuron by critically reviewing these issues.

Caldendrin but not calmodulin binds to light chain 3 of MAP1A/B: an association with the microtubule cytoskeleton highlighting exclusive binding partners for neuronal Ca(2+)-sensor proteins

Caldendrin is a neuronal Ca(2+)-sensor protein (NCS), which represents the closest homologue of calmodulin (CaM) in nerve cells. It is tightly associated with the somato-dendritic cytoskeleton of neurons and highly enriched in the postsynaptic cytomatrix. Here, we report that caldendrin specifically associates with the microtubule cytoskeleton via an interaction with light chain 3 (LC3), a microtubule component with sequence homology to the GABAA receptor-associated protein (GABARAP), which is, like LC3, probably involved in cellular transport processes. Interestingly, two binding sites exist in LC3 for caldendrin from which only one exhibits a strict Ca(2+)-dependency for the interaction to take place but both require the presence of the first two EF-hands of caldendrin. CaM, however, is not capable of binding to LC3 at both sites despite its high degree of primary structure similarity with caldendrin. Computer modelling suggests that this might be explained by an altered distribution of surface charges at the first two EF-hands rendering each molecule, in principle, specific for a discrete set of binding partners. These findings provide molecular evidence that NCS can transduce signals to a specific target interaction irrespective of Ca(2+)-concentrations and CaM-levels.

Non-coding ribonucleic acids--a class of their own?

Non-coding ribonucleic acids (RNAs) do not contain a peptide-encoding open reading frame and are therefore not translated into proteins. They are expressed in all phyla, and in eukaryotic cells they are found in the nucleus, cytoplasm, and mitochondria. Non-coding RNAs either can exert structural functions, as do transfer and ribosomal RNAs, or they can regulate gene expression. Non-coding RNAs with regulatory functions differ in size ranging from a few nucleotides to over 100 kb and have diverse cell- or development-specific functions. Some of the non-coding RNAs associate with human diseases. This chapter summarizes the current knowledge about regulatory non-coding RNAs.

The single-stranded DNA- and RNA-binding proteins pur alpha and pur beta link BC1 RNA to microtubules through binding to the dendrite-targeting RNA motifs

Neural BC1 RNA is distributed in neuronal dendrites as RNA-protein complexes (BC1 RNPs) containing Translin. In this study, we demonstrated that the single-stranded DNA- and RNA-binding protein pur alpha and its isoform, pur beta, which have been implicated in control of DNA replication and transcription, linked BC1 RNA to microtubules (MTs). The binding site was within the 5' proximal region of BC1 RNA containing putative dendrite-targeting RNA motifs rich in G and U residues, suggesting that in the cytoplasm of neurons, these nuclear factors are involved in the BC1 RNA transport along dendritic MTs. The pur proteins were not components of BC1 RNP but appeared to associate with MTs in brain cells. Therefore, it is suggested that they may transiently interact with the RNP during transport. In this respect, the interaction of pur proteins with BC1 RNA could be regulated by the Translin present within the RNP, because the binding mode of these two classes of proteins (pur proteins and Translin) to the dendrite-targeting RNA motifs was mutually exclusive. As the motifs are well conserved in microtubule-associated protein 2a/b mRNA as well, the pur proteins may also play a role(s) in the dendritic transport of a subset of mRNAs.

Upstream flanking sequences and transcription of SINEs

SINEs, short interspersed repeated DNA elements, undergo amplification through retroposition and subsequent integration into a new location in the genome. Each new SINE insertion will be located in a new chromosomal environment, with different flanking sequences. Modulation of transcription by different flanking sequences may play an important role in determining which SINE elements are preferentially active in a genome. We evaluated the ability of upstream flanking sequences to regulate the transcription of three different SINEs (Alu, B2 and ID) by constructing chimeric constructs with known 5' flanking sequences of RNA polymerase III-transcribed genes. Upstream sequences from the 7SL RNA gene, U6 RNA gene, vault RNA gene, and BC1 gene increase transcription of Alu, B2 and BC1 in transient transfections of NIH3T3, HeLa, Neuro2a and C6 glioma cell lines. The 7SL sequence proved most efficient in increasing SINE transcription. The 7SL upstream fused to the BC1 RNA gene (an ID element) was used to create a transgenic mouse line. In contrast to the tissue-specific endogenous BC1 transcription, BC1 transgene transcripts were detected in all tissues tested. However, expression was much higher in those tissues that express the endogenous gene, demonstrating both transcriptional and post-transcriptional regulation. The BC1 RNA was detected in a similar ribonucleoprotein complex in the different tissues.

Identification of a negative regulatory DNA element for neuronal BC1 RNA expression by RNA polymerase III

BC1 RNA is a neuronal cell-specific RNA polymerase III (Pol III) transcript. The BC1 RNA gene has plural types of Pol III promoters, in addition to which an E-box sequence (E2 site) acts as a transcriptional activator, which is recognized by a brain-specific protein(s). Using an in vitro transcription system, we found that the upstream region of the BC1 RNA gene contained a sequence that interfered with the activity of the E-box element in a distance-independent manner. A tandem repeat within this sequence, which was weakly homologous with the neuron-restrictive silencer element (NRSE) found in the Pol II system, was recognized by a brain nuclear protein. Consistently, the transcriptional activity increased by deleting the tandem repeat sequence. We called this BC1 RNA-repressing element BCRE. The DNA-binding specificities of BCRE-binding protein differed from that of NRSE-binding protein (NRSF). A similar protein with an ability to bind to BCRE was also found in liver and kidney. Furthermore, the glutamate analog kainic acid increased the DNA-binding of both E2 site-binding protein and BCRE-binding protein, and then the levels of BC1 RNA also increased transiently. Our results suggested that both positive and negative regulatory elements contribute to neuronal BC1 RNA expression.

Protein synthesis in axons and terminals: significance for maintenance, plasticity and regulation of phenotype. With a critique of slow transport theory

This article focuses on local protein synthesis as a basis for maintaining axoplasmic mass, and expression of plasticity in axons and terminals. Recent evidence of discrete ribosomal domains, subjacent to the axolemma, which are distributed at intermittent intervals along axons, are described. Studies of locally synthesized proteins, and proteins encoded by RNA transcripts in axons indicate that the latter comprise constituents of the so-called slow transport rate groups. A comprehensive review and analysis of published data on synaptosomes and identified presynaptic terminals warrants the conclusion that a cytoribosomal machinery is present, and that protein synthesis could play a role in long-term changes of modifiable synapses. The concept that all axonal proteins are supplied by slow transport after synthesis in the perikaryon is challenged because the underlying assumptions of the model are discordant with known metabolic principles. The flawed slow transport model is supplanted by a metabolic model that is supported by evidence of local synthesis and turnover of proteins in axons. A comparison of the relative strengths of the two models shows that, unlike the local synthesis model, the slow transport model fails as a credible theoretical construct to account for axons and terminals as we know them. Evidence for a dynamic anatomy of axons is presented. It is proposed that a distributed "sprouting program," which governs local plasticity of axons, is regulated by environmental cues, and ultimately depends on local synthesis. In this respect, nerve regeneration is treated as a special case of the sprouting program. The term merotrophism is proposed to denote a class of phenomena, in which regional phenotype changes are regulated locally without specific involvement of the neuronal nucleus.

Subcellular RNA compartmentalization

The phenomenon of mRNA sorting to defined subcellular domains is observed in diverse organisms such as yeast and man. It is now becoming increasingly clear that specific transport of mRNAs to extrasomal locations in nerve cells of the central and peripheral nervous system may play an important role in nerve cell development and synaptic plasticity. Although the majority of mRNAs that are expressed in a given neuron are confined to the cell somata, some transcript species are specifically delivered to dendrites and/or, albeit less frequently, to the axonal domain. The physiological role and the molecular mechanisms of mRNA compartmentalization is now being investigated extensively. Even though most of the fundamental aspects await to be fully characterized, a few interesting data are emerging. In particular, there are a number of different subcellular distribution patterns of different RNA species in a given neuronal cell type and RNA compartmentalization may differ depending on the electrical activity of nerve cells. Furthermore, RNA transport is different in neurons of different developmental stages. Considerable evidence is now accumulating that mRNA sorting, at least to dendrites and the initial axonal segment, enables local synthesis of key proteins that are detrimental for synaptic function, nerve cell development and the establishment and maintenance of nerve cell polarity. The molecular determinants specifying mRNA compartmentalization to defined microdomains of nerve cells are just beginning to be unravelled. Targeting appears to be determined by sequence elements residing in the mRNA molecule to which proteins bind in a manner to direct these transcripts along cytoskeletal components to their site of function where they may be anchored to await transcriptional activation upon demand.

A novel type of non-coding RNA expressed in the rat brain

We have characterized a novel type of non-coding RNA which consists of tandem repeats of similar sequences, approximately 0.9 kb in size. This RNA, termed Bsr (brain specific repetitive) RNA, is encoded at a single locus (6 q31-->q32) in the rat genome, where 100 to 150 copies of the 0.9 kb sequences are repeated in tandem. Bsr RNA is preferentially expressed in the rat central nervous system (CNS), especially in phylogenetically old structures, such as the pareo- and archicortex, amygdala, thalamus and hypothalamus. In the developing brains, Bsr RNA is expressed in the subsets of differentiating cells but not in proliferating cells. Despite the finding that Bsr RNA appears to be conserved only among the Rattus species, the specific expression pattern of Bsr RNA suggests that it might have some role in the rat CNS.

The dendritic translocation of translin protein in the form of BC1 RNA protein particles in developing rat hippocampal neurons in primary culture

Neural BC1 RNA is distributed in neuronal dendrites as ribonucleoprotein particles (RNP). Our previous studies indicated the presence of Translin in BC1 RNPs, which is a translational repressor and links a subset of mRNAs to microtubules. In this study, we confirmed that Translin associates with BC1 RNP and we used immunocytochemical methods to examine the subcellular distribution of Translin in developing hippocampal cells in primary cultures. Translin was detected in both the nuclei and cytoplasm of neurons, whereas in glial cells it was localized in the nuclei. Consistent with the reported developmental time course of BC1 RNA expression and dendritic delivery the translocation of Translin to the neuronal dendrites appeared to correlate with neuronal development and differentiation events such as the onset of synaptogenesis in culture. These observations suggest that BC1 RNP or Translin itself may be relevant to the dendritic translation of mRNAs in response to transsynaptic activity.

BC1 RNA protein particles in mouse brain contain two y-,h-element-binding proteins, translin and a 37 kDa protein

Neural BC1 RNA is distributed in dendrites in the form of ribonucleoprotein particles (RNP). Recently, Han et al. reported that testis-brain RNA-binding protein (the mouse homologue of Translin), known to be a translational repressor, links a subset of mRNAs to microtubules (MTs) through binding to their y-,h-sequence elements. We found that similar elements are also present in BC1 RNA. Therefore, it is possible that they also act as cis-elements, together with their transacting proteins, and control the transport of BC1 RNA along dendritic MTs. In this study, we demonstrated that two y-,h-element-binding proteins copurified with BC1 RNP. One was identified as mouse Translin and the other was a 37 kDa protein. This macromolecular assembly may constitute a transport particle for BC1 RNA. It is also possible that BC1 RNP or Translin itself may play a regulatory role(s) in the translation of mRNAs within dendrites.

An E-box sequence acts as a transcriptional activator for BC1 RNA expression by RNA polymerase III in the brain

BC1 RNA is a small cytoplasmic RNA that is transcribed by RNA polymerase III (Pol III) in the rodent nervous system. In addition to essential intragenic promoter elements for Pol III, the BC1 RNA gene has five E-box sequences (CANNTG) in its 5' flanking region. Deletion analysis using an in vitro transcription system revealed that the region containing the E2 site (CAATTG) was necessary for effective transcription of BC1 RNA. A construct with point mutations within the E2 site showed reduced transcriptional activity. Furthermore, DNaseT I protection and gel retardation assays demonstrated that the E2 site was recognized specifically by a brain nuclear protein(s). These results suggest that the upstream E-box sequence and its binding protein may be involved in the regulation by Pol III of preferential BC1 RNA expression in the brain.

Mutational analysis reveals that an array of GCAAG/CTTGC motifs between sprit promoter sequences for RNA polymerase III is essential for neural BC1 RNA transcription

BC1 RNA is expressed from an identifier (ID) sequence by RNA polymerase III (Pol III) and occurs in neural cells as a ribonucleoprotein particle (BC1 RNP). On the BC1 RNA gene, between the Pol III promoter A and B boxes, there is a region which contains short inverted repeats, including three GCAAG/CTTGC motifs. We found that a nuclear protein binds specifically to this region and, using an in vitro transcription system, demonstrated that point mutations within these motifs markedly inhibit BC1 RNA transcription. These results suggest that the GCAAG/CTTGC motif region and its binding protein may play a role in the transcription of BC1 RNA. Moreover, we demonstrated that transcription is repressed by a concomitant molar excess of BC1 RNA and that the BC1 RNA transcribed by this system forms an RNP with nuclear protein(s), suggesting some interaction of BC1 RNA with transcription factor(s).

Molecular characterization of dendritically localized transcripts encoding MAP2

Transcripts encoding high molecular weight (Hwt) isoforms of microtubule-associated protein 2 (MAP2) have been localized in the dendritic compartment of neurons. In contrast, nearly all other neuronal messages, including transcripts encoding low molecular weight (Lwt) MAP2 isoforms, are restricted to cell somas. The mechanisms underlying the dendritic localization of Hwt-MAP2 transcripts are not known. In non-neuronal systems, mRNAs, are localized via signal sequences situated in their 3' untranslated regions (3' UTRs). In this study, we have localized the putative dendritic targeting element (DTE) in Hwt-MAP2 mRNAs by comparing the nucleotide sequences of the somatically localized 6 kb Lwt-MAP2 transcripts with the dendritcally localized 9 kb messages. Our analysis shows that both 6 kb and 9 kb transcripts have identical 3' - and 5'- UTRs, precluding the possibility that the DTE lies in these regions. Within the coding region a single segment that is unique to 9 kb Hwt MAP2 transcripts was identified. These findings suggest that the DTE lies within the 4 kb RNA segment that encodes the projection domain of Hwt-MAP2.

BC1 RNA and vasopressin mRNA in rat neurohypophysis: axonal compartmentalization and differential regulation during dehydration and rehydration

Brain cytoplasmic 1 (BC1) RNA is a small non-translated RNA polymerase III transcript. Because this RNA can be detected in the rat posterior pituitary with 35S in situ hybridization autoradiography, it has been hypothesized that this RNA might be transported in the axons of hypothalamo-neurohypophyseal neurons. In the present study, we aimed to determine the cellular localization of BC1 more precisely by using non-radioactive in situ hybridization of BC1 RNA at both the light and electron microscopic levels. Our studies revealed that BC1 RNA was indeed located intra-axonally. Furthermore, BC1 RNA was abundant within a subset of axonal swellings and/or terminals, and was also found in discrete cytoplasmic domains of undilated axonal segments. Using a semiquantitative in situ hybridization approach, we have measured and compared the changes in BC1 RNA and arginine vasopressin (AVP) mRNA during dehydration (chronic salt-loading) and rehydration. Chronic salt-loading significantly increased both BC1 RNA and AVP mRNA. The increase in BC1 RNA labelling (2.5-fold), however, was modest and somewhat less enduring than the increase in AVP mRNA labelling (13-fold). Upon rehydration, both the BC1 and vasopressin transcripts in the posterior pituitary rapidly returned to control values. In conclusion, like vasopressin mRNA, BC1 RNA is transported in axons of the hypothalamo-neurohypophyseal system where it aggregates in a subset of axonal swellings, and its axonal transport is similarly regulated. Therefore, we propose that BC1 RNA might be involved in the axonal targeting, docking and/or transport of AVP or other axonal mRNAs.