Role of a neuronal small non-messenger RNA: behavioural alterations in BC1 RNA-deleted mice.

BC1 RNA is a small non-messenger RNA common in dendritic microdomains of neurons in rodents. In order to investigate its possible role in learning and behaviour, we compared controls and knockout mice from three independent founder lines established from separate embryonic stem cells. Mutant mice were healthy with normal brain morphology and appeared to have no neurological deficits. A series of tests for exploration and spatial memory was carried out in three different laboratories. The tests were chosen as to ensure that different aspects of spatial memory and exploration could be separated and that possible effects of confounding variables could be minimised. Exploration was studied in a barrier test, in an open-field test, and in an elevated plus-maze test. Spatial memory was investigated in a Barnes maze and in a Morris water maze (memory for a single location), in a multiple T-maze and in a complex alley maze (route learning), and in a radial maze (working memory). In addition to these laboratory tasks, exploratory behaviour and spatial memory were assessed under semi-naturalistic conditions in a large outdoor pen. The combined results indicate that BC1 RNA-deficient animals show behavioural changes best interpreted in terms of reduced exploration and increased anxiety. In contrast, spatial memory was not affected. In the outdoor pen, the survival rates of BC1-depleted mice were lower than in controls. Thus, we conclude that the neuron-specific non-messenger BC1 RNA contributes to the aptive modulation of behaviour.

Molecular kinesis in cellular function and plasticity.

Intracellular transport and localization of cellular components are essential for the functional organization and plasticity of eukaryotic cells. Although the elucidation of protein transport mechanisms has made impressive progress in recent years, intracellular transport of RNA remains less well understood. The National Academy of Sciences Colloquium on Molecular Kinesis in Cellular Function and Plasticity therefore was devised as an interdisciplinary platform for participants to discuss intracellular molecular transport from a variety of different perspectives. Topics covered at the meeting included RNA metabolism and transport, mechanisms of protein synthesis and localization, the formation of complex interactive protein ensembles, and the relevance of such mechanisms for activity-dependent regulation and synaptic plasticity in neurons. It was the overall objective of the colloquium to generate momentum and cohesion for the emerging research field of molecular kinesis.

Neuronal BC1 RNA: co-expression with growth-associated protein-43 messenger RNA.

Brain-specific cytoplasmic RNA 1 (BC1-RNA), a non-coding RNA polymerase III transcript, is a neuronal RNA that is specifically targeted to dendritic domains. It is co-localized with components of the dendritic protein synthetic machinery, and it has been suggested to operate in the regulation of local translation-related processes in postsynaptic microdomains, thus subserving long-term synaptic plasticity in neurons. To probe the relevance of BC1 expression in neuronal plasticity, we have analyzed the expression pattern of BC1 RNA in the rat nervous system. We found that BC1 RNA is expressed by a specific subset of neurons (but not by non-neuronal cells) in the central and peripheral nervous system of the adult rat. The BC1 labeling pattern indicates that the subcellular location of the RNA is typically postsynaptic which, depending on cell type, manifests itself in a predominantly somatic, somatodendritic, or dendritic location. Our results further show that BC1-expressing neurons typically co-express the messenger RNA for growth-associated protein-43 (GAP-43). Such co-expression was observed in diverse brain areas, including the olfactory bulb, neocortex, and hippocampus, among others. While BC1 RNA was in many neuronal cell types detectable in distal dendritic domains, GAP-43 messenger RNA was typically more restricted to neuronal perikarya. In the mature nervous system, expression of GAP-43 has been described as an intrinsic determinant of predominantly presynaptic plasticity, while BC1 RNA has been implicated in postsynaptic plasticity. Co-expression of both RNAs, as reported here, thus identifies a distinct subset of neurons in the rat nervous system that exhibits both types of plasticity.

Long-term maintenance of mature hippocampal slices in vitro.

Cultures of primary neurons or thin brain slices are typically prepared from immature animals. We introduce a method to prepare hippocampal slice cultures from mature rats aged 20-30 days. Mature slice cultures retain hippocampal cytoarchitecture and synaptic connections up to 3 months in vitro. Spontaneous epileptiform activity is rarely observed suggesting long-term retention of normal neuronal excitability and of excitatory and inhibitory synaptic networks. Picrotoxin, a GABAergic Cl(-) channel antagonist, induced characteristic interictal-like bursts that originated in the CA3 region, but not in the CA1 region. These data suggest that mature slice cultures displayed long-term retention of GABAergic inhibitory synapses that effectively suppressed synchronized burst activity via recurrent excitatory synapses of CA3 pyramidal cells. Mature slice cultures lack the reactive synaptogenesis, spontaneous epileptiform activity, and short life span that limit the use of slice cultures isolated from immature rats. Mature slice cultures are anticipated to be a useful addition for the in vitro study of normal and pathological hippocampal function.

Activity-dependent regulation of dendritic BC1 RNA in hippocampal neurons in culture.

Several neuronal RNAs have been identified in dendrites, and it has been suggested that the dendritic location of these RNAs may be relevant to the spatiotemporal regulation of mosaic postsynaptic protein repertoires through transsynaptic activity. Such regulation would require that dendritic RNAs themselves, or at least some of them, be subject to physiological control. We have therefore examined the functional regulation of somatodendritic expression levels of dendritic BC1 RNA in hippocampal neurons in culture. BC1 RNA, an RNA polymerase III transcript that is a component of a ribonucleoprotein particle, became first detectable in somatodendritic domains of developing hippocampal neurons at times of initial synapse formation. BC1 RNA was identified only in such neurons that had established synapses on cell bodies and/or developing dendritic arbors. When synaptic contact formation was initiated later in low-density cultures, BC1 expression was coordinately delayed. Inhibition of neuronal activity in hippocampal neurons resulted in a substantial but reversible reduction of somatodendritic BC1 expression. We conclude that expression of BC1 RNA in somatic and dendritic domains of hippocampal neurons is regulated in development, and is dependent upon neuronal activity. These results establish (for the first time to our knowledge) that an RNA polymerase III transcript can be subject to control through physiological activity in nerve cells.

RNA transport in dendrites: a cis-acting targeting element is contained within neuronal BC1 RNA.

In nerve cells, a select group of RNAs has been localized to dendritic domains. Here we have examined dendritic RNA transport in sympathetic neurons in primary culture, using a microinjection protocol with neuronal BC1 RNA and with BC1-derived sequence segments. After cytoplasmic microinjection, full-length BC1 RNA was selectively transported to dendrites; in contrast, control RNAs such as nuclear RNAs and random-sequence irrelevant RNAs remained restricted to cytoplasmic areas proximal to the injection sites. Chimeric RNAs were constructed that contained the full-length BC1 sequence inserted upstream or downstream of the coding regions of nondendritic mRNAs. After microinjection, such chimeric RNAs were specifically targeted to dendrites; microinjected corresponding nonchimeric mRNAs were not. Dendritic transport of BC1 RNA was rapid: the average dendritic delivery rate within the first hour after microinjection was 242 +/- 25 microm/hr. Whereas a 5'-BC1 segment of 62 nucleotides was transported to dendrites to extents and at levels similar to full-length BC1 RNA, a 3'-BC1 segment of 60 nucleotides did not exit injected somata to any significant degree. A cis-acting dendritic targeting element is thus contained in the 5' part of neuronal BC1 RNA. These results demonstrate that mechanisms exist in neurons for fast and specific transport of selected RNAs to dendrites.

Expression of dendritic BC200 RNA, component of a 11.4S ribonucleoprotein particle, is conserved in humans and simians.

Primate BC200 RNA, a brain-specific small cytoplasmic RNA, is one of the few known cell type specific non-messenger RNAs. It originated from a monomeric Alu short interspersed repetitive element (SINE) in primates. In situ hybridization using rhesus monkey (Macaca mulatta) brain sections reveals a similar cellular and sub-cellular distribution as in human brain. In addition to confirming its dendritic location, the distribution in an old world monkey indicates a discrete regional and subcellular location of BC200 RNA. We also report that BC200 RNA exists as a ribonucleoprotein (RNP) particle in vivo. In sucrose gradients, the BC200 particle has a sedimentation constant of about 11.4 S, significantly more than the corresponding 200 nucleotide long naked RNA (approximately 7.6 S).

Expression of neural BC1 RNA: induction in murine tumours.

BC1 RNA is a small cytoplasmic RNA polymerase III transcript that is expressed in the rodent nervous system. The RNA is selectively expressed in neurons where it is located in somatodendritic domains. BC1 RNA is not normally detectable in non-neuronal somatic cells; it is however expressed in germ cells and in cultured immortal cell lines of various non-neural origins. We therefore sought to establish whether the neuron-specific regulation of BC1 expression is altered in non-neural tumour cells. Oncogen and chemical carcinogen induced mouse tumours were analysed for the presence of BC1 RNA, using Northern transfer and in situ hybridisation. Here we report that BC1 RNA is selectively expressed in tumour cells, but not in corresponding normal tissues. These results indicate that neural-specific regulation of BC1 expression is lacking in murine tumour cells of non-neural origin.

Expression of neural BC200 RNA in human tumours.

BC200 RNA is a 200-nucleotide-long non-messenger RNA that is selectively expressed in the primate nervous system, where it has been identified in somatodendritic domains of a subset of neurons. BC200 RNA is not normally expressed in non-neuronal somatic cells; it has been shown, however, to be expressed in germ cells and in cultured immortal cell lines of various non-neural origins. In order to investigate whether the neuron-specific expression of BC200 RNA is also deregulated during tumourigenesis in non-neural human tissues, 80 different tumour specimens, representing 19 different tumour types, were screened for the presence of the RNA. BC200 RNA was expressed in carcinomas of the breast, cervix, oesophagus, lung, ovary, parotid, and tongue, but not in corresponding normal tissues. BC200 RNA was not detectable in bladder, colon, kidney, or liver carcinoma tissues examined in this study. These results demonstrate that BC200 expression is deregulated under certain neoplastic conditions. The expression of BC200 RNA in non-neural tumours may indicate a functional interrelationship with induction and/or progression of such tumours.

Translational machinery in dendrites of hippocampal neurons in culture.

In neurons, several mRNAs are selectively delivered to dendritic domains where they are presumably translated by local protein synthetic machinery. Although electron microscopy has identified polyribosomes in dendrites, in particular in postsynaptic dendritic compartments, the functional composition of the local protein synthetic apparatus and the scope of its translational capacity have not been analyzed. To ascertain the translational competence of dendrites, we have probed hippocampal neurons in primary culture for various integral and associated factors of the translational apparatus. We report here that dendrites of such neurons are equipped with a spectrum of translational machinery components, including ribosomes, tRNAs, initiation and elongation factors, and elements of the cotranslational signal recognition mechanism. These components are differentially and nonuniformly distributed in dendritic arbors. Their dendritic location illustrates the soma-independent potential of dendrites to synthesize selected proteins in local domains.

Identification and characterization of BC1 RNP particles.

Rodent brain-specific small cytoplasmic BC1 RNA is an unusual RNA in several respects. It is an RNA polymerase III transcript expressed specifically in neurons, with regional and developmental regulation. Moreover, it is one of a few RNAs actively transported into dendrites. Three findings indicate that BC1 RNA exists as a ribonucleoprotein complex in vivo. First, the buoyant density of fractions containing BC1 RNA from brain extract on CsCI and Cs2SO4 gradients is 1.45 g/ml and 1.55 g/ml, respectively; this is consistent with the density of RNA-protein complexes. Second, in sucrose gradients, the BC1 particle has a larger S value (8.7S) than naked RNA (6.1S). Third, BC1 RNA from brain extracts migrates with retarded mobility compared to naked BC1 RNA during agarose gel electrophoresis. Additionally, in comparison to the signal recognition particle (SRP), the BC1 RNP is more heat resistant and less Mg(2+)-dependent. The buoyant density of the BC1 RNP suggests the presence of protein(s) with a total mass of about 138kD.

Reverse transcriptase: mediator of genomic plasticity.

Reverse transcription has been an important mediator of genomic change. This influence dates back more than three billion years, when the RNA genome was converted into the DNA genome. While the current cellular role(s) of reverse transcriptase are not yet completely understood, it has become clear over the last few years that this enzyme is still responsible for generating significant genomic change and that its activities are one of the driving forces of evolution. Reverse transcriptase generates, for example, extra gene copies (retrogenes), using as a template mature messenger RNAs. Such retrogenes do not always end up as nonfunctional pseudogenes but form, after reinsertion into the genome, new unions with resident promoter elements that may alter the gene's temporal and/or spatial expression levels. More frequently, reverse transcriptase produces copies of nonmessenger RNAs, such as small nuclear or cytoplasmic RNAs. Extremely high copy numbers can be generated by this process. The resulting reinserted DNA copies are therefore referred to as short interspersed repetitive elements (SINEs). SINEs have long been considered selfish DNA, littering the genome via exponential propagation but not contributing to the host's fitness. Many SINEs, however, can give rise to novel genes encoding small RNAs, and are the migrant carriers of numerous control elements and sequence motifs that can equip resident genes with novel regulatory elements [Brosius J. and Gould S.J., Proc Natl Acad Sci USA 89, 10706-10710, 1992]. Retrosequences, such as SINEs and portions of retroelements (e.g., long terminal repeats, LTRs), are capable of donating sequence motifs for nucleosome positioning, DNA methylation, transcriptional enhancers and silencers, poly(A) addition sequences, determinants of RNA stability or transport, splice sites, and even amino acid codons for incorporation into open reading frames as novel protein domains. Retroposition can therefore be considered as a major pacemaker for evolution (including speciation). Retroposons, with their unique properties and actions, form the molecular basis of important evolutionary concepts, such as exaptation [Gould S.J. and Vrba E., Paleobiology 8, 4-15, 1982] and punctuated equilibrium [Elredge N. and Gould S.J. in Schopf T.J.M. (ed). Models in Paleobiology. Freeman, Cooper, San Francisco, 1972, pp. 82-115].

Transport of BC1 RNA in hypothalamo-neurohypophyseal axons.

Ample evidence indicates that in nerve cells, several individual proteins are locally synthesized in postsynaptic domains in dendrites. By contrast, axonal terminals, at least in mammals, are generally thought to lack protein synthetic capacity. However, axonal nerve endings of the hypothalamo-neurohypophyseal tract have recently been shown to contain mRNAs encoding vasopressin, oxytocin, dynorphin, and neurofilament. In this report, we identify BC1 RNA, a small RNA polymerase III transcript that is specifically expressed in neurons, in hypothalamo-neurohypophyseal axons. BC1 RNA has previously been shown to be located in somatic and dendritic domains of various types of neurons in the rat nervous system. Here we present evidence to show that BC 1 RNA, like several neuropeptide mRNAs, is axonally transported from magnocellular hypothalamic neurons to neurosecretory nerve endings in the posterior pituitary. BC1 RNA, which has been reported to be a component of a ribonucleoprotein particle, is thus colocalized with dendritic mRNAs in dendritic domains and with axonal mRNAs in axonal domains, respectively. Such colocalization is indicative of functional interactions of BC1 RNA with those mRNAs that are targeted to extrasomatic domains of nerve cells.

Primary structure, neural-specific expression, and dendritic location of human BC200 RNA.

Primate BC200 RNA is a 200-nucleotide-long, nontranslatable RNA that is prevalently expressed in the nervous system. We have determined the primary structure of human BC200 RNA, using cDNA cloning and PCR techniques. BC200 RNA can be subdivided into three structural domains. The 5' region is homologous to Alu repetitive elements that are found in high copy numbers in primate genomes. The central part of BC200 RNA is characterized by a high percentage of A-residues, with a few interspersed other nucleotides. The 3' sequence is unique to BC200 RNA and shows no apparent similarity with known human DNA sequences. Sequence similarity with rodent BC1 RNA is limited to several short elements, and BC1/BC200 sequence comparisons indicate that the two genes have evolved via separate phylogenetic routes. Probes directed against the 3' unique part of BC200 RNA detected a single band corresponding to approximately 200 nucleotides on RNA blots. This band was identified only with RNA isolated from human brain, not with RNA from non-neural organs such as lung or kidney. In situ hybridization to selected areas of the human nervous system showed that BC200 RNA is expressed by a subpopulation of neurons that is analogous to the BC1 RNA-expressing subset of neurons in the corresponding areas of the rat nervous system. Moreover, like rat BC1 RNA, human BC200 RNA was localized to dendrite-rich neuropil areas, for example, in the inner plexiform layer of the retina. These results indicate that BC1 RNA and BC200 RNA, although of different evolutionary pedigree, may play analogous functional roles, in rodents and primates, respectively, in somatodendritic domains of nerve cells.

Murine BC1 RNA in dendritic fields of the retinal inner plexiform layer.

Rodent BC1 RNA is a non-messenger RNA polymerase III transcript that is almost exclusively expressed in nerve cells. BC1 RNA has been localised in somatic and dendritic domains of neurons, and its location has been interpreted to indicate a functional role in extrasomatic postsynaptic protein synthesis. In previous in situ hybridisation experiments, it has been demonstrated that in the retina most of the BC1 labelling signal was confined to the ganglion cell layer and the inner plexiform layer. Dendritic processes of several types of neurons form the neuritic plexus of the inner plexiform layer, and in order to determine the contribution of ganglion cells to the BC1 labelling signal, we eliminated this cell type by transecting the optic nerve unilaterally in newborn mice. Deletion of the ganglion cells resulted in a significant reduction although not a complete elimination of the BC1 signal in the inner plexiform layer. These data indicate that dendritic processes of both ganglion cells and amacrine cells contain BC1 RNA.

Immunoelectron microscopy of enzymes, multienzyme complexes, and selected other oligomeric proteins.

The collective term "immunoelectron microscopy" subsumes a number of techniques in which the biological material is decorated with specific antibodies, prior to being visualized in the electron microscope. In this article, we have reviewed literature on immunoelectron microscopy that focusses on the analysis of the molecular architecture of proteins, in particular of enzymes and of multienzyme complexes. Molecular immunoelectron microscopy has been remarkably successful with multi-subunit enzymes of complex quaternary structures, and in many cases the data have been the basis for the eventual development of detailed three-dimensional molecular models. The elucidation of subunit composition and juxtaposition of a given enzyme, an important accomplishment in itself, has in turn stimulated and guided discussions on the catalytic mechanism; illustrative examples include F1 ATPase and citrate lyase, among others. Here we have chosen a variety of enzymes, multienzyme complexes, and non-enzymatic proteins to demonstrate the versatility of immunoelectron microscopy, to illustrate methodological prerequisites and limitations, and to discuss significance and implications of individual immunoelectron microscopy studies.

The use of UV light as a cross-linking agent for cells and tissue sections in in situ hybridization.

UV cross-linking is introduced as a novel method to stabilize tissue on microscopic slides and to immobilize target molecules in biological material for in situ hybridization. UV illumination dramatically improves the stability of tissue sections and isolated cells on slides coated with gelatin/poly-lysine. Even during prolonged high-stringency washes, specimens remain firmly attached to the support layer. At the same time, the signal intensity is increased significantly whereas background levels remain as low as without UV illumination. These results indicate that while target RNAs and other molecules in the biological material are covalently cross-linked with their nearest neighbor molecules, tissues nonetheless remain penetrable, and target molecules remain accessible. We expect that this simple and efficient technique will find widespread applications in in situ hybridization methodology.