Inhibition of protein synthesis alters the subcellular distribution of mRNA in neurons but does not prevent dendritic transport of RNA

Impaired dynamic interaction of axonal endoplasmic reticulum and ribosomes contributes to defective stimulus-response in spinal muscular atrophy

Background

Axonal degeneration and defects in neuromuscular neurotransmission represent a pathological hallmark in spinal muscular atrophy (SMA) and other forms of motoneuron disease. These pathological changes do not only base on altered axonal and presynaptic architecture, but also on alterations in dynamic movements of organelles and subcellular structures that are not necessarily reflected by static histopathological changes. The dynamic interplay between the axonal endoplasmic reticulum (ER) and ribosomes is essential for stimulus-induced local translation in motor axons and presynaptic terminals. However, it remains enigmatic whether the ER and ribosome crosstalk is impaired in the presynaptic compartment of motoneurons with Smn (survival of motor neuron) deficiency that could contribute to axonopathy and presynaptic dysfunction in SMA.

Methods

Using super-resolution microscopy, proximity ligation assay (PLA) and live imaging of cultured motoneurons from a mouse model of SMA, we investigated the dynamics of the axonal ER and ribosome distribution and activation.

Results

We observed that the dynamic remodeling of ER was impaired in axon terminals of Smn-deficient motoneurons. In addition, in axon terminals of Smn-deficient motoneurons, ribosomes failed to respond to the brain-derived neurotrophic factor stimulation, and did not undergo rapid association with the axonal ER in response to extracellular stimuli.

Conclusions

These findings implicate impaired dynamic interplay between the ribosomes and ER in axon terminals of motoneurons as a contributor to the pathophysiology of SMA and possibly also other motoneuron diseases.

Supplementary Information

The online version contains supplementary material available at 10.1186/s40035-022-00304-2.

Pathological missorting of endogenous MAPT/Tau in neurons caused by failure of protein degradation systems

Missorting of MAPT/Tau represents one of the early signs of neurodegeneration in Alzheimer disease. The triggers for this are still a matter of debate. Here we investigated the sorting mechanisms of endogenous MAPT in mature primary neurons using microfluidic chambers (MFCs) where cell compartments can be observed separately. Blocking protein degradation pathways with proteasomal or autophagy inhibitors dramatically increased the missorting of MAPT in dendrites on the neuritic side, suggesting that degradation of MAPT in dendrites is a major determinant for the physiological axonal distribution of MAPT. Such missorted dendritic MAPT differed in its phosphorylation pattern from axonal MAPT. By contrast, enhancing autophagy or proteasomal pathways strongly reduced MAPT missorting, thereby confirming the role of protein degradation pathways in the polar distribution of MAPT. Dendritic missorting of MAPT by blocking protein degradation resulted in the loss of spines but not in overall cell toxicity. Inhibition of local protein synthesis in dendrites eliminated the missorting of MAPT, indicating that the accumulation of dendritic MAPT is locally generated. In support of this, a substantial fraction of Mapt/Tau mRNA was detected in dendrites. Taken together, our results indicate that the autophagy and proteasomal pathways play important roles in fine-tuning dendritic MAPT levels and thereby prevent synaptic toxicity caused by MAPT accumulation. Abbreviations Ani: anisomycin; Baf: bafilomycin A₁; BSA: bovine serum albumin; cAMP: cyclic adenosine monophosphate; CHX: cycloheximide; DMSO: dimethyl sulfoxide; DIV: days in vitro; Epo: epoxomicin; E18: embryonic day 18; FISH: fluorescence in situ hybridization; IgG: immunoglobulin; kDa: kilodalton; Lac: lactacystin; LDH: lactate dehydrogenase; MFC: microfluidic chambers; MAPs: microtubule-associated proteins; MAPT/Tau: microtubule-associated protein tau; PVDF: polyvinylidene difluoride; PBS: phosphate-buffered saline; PRKA: protein kinase AMP-activated; RD150: round device 150; RT: room temperature; SDS: sodium dodecyl sulfate; SEM: standard error of the mean; Wor: wortmannin.

Single-molecule imaging of translational output from individual RNA granules in neurons

Dendritic RNAs are localized and translated in RNA granules. Here we use single-molecule imaging to count the number of RNA molecules in each granule and to record translation output from each granule using Venus fluorescent protein as a reporter. For RNAs encoding activity-regulated cytoskeletal-associated protein (ARC) or fragile X mental retardation protein (FMRP), translation events are spatially clustered near individual granules, and translational output from individual granules is either sporadic or bursty. The probability of bursty translation is greater for Venus-FMRP RNA than for Venus-ARC RNA and is increased in Fmr1-knockout neurons compared to wild-type neurons. Dihydroxyphenylglycine (DHPG) increases the rate of sporadic translation and decreases bursty translation for Venus-FMRP and Venus-ARC RNAs. Single-molecule imaging of translation in individual granules provides new insight into molecular, spatial, and temporal regulation of translation in granules.

Requirement for protein synthesis at developing synapses

Activity and protein synthesis act cooperatively to generate persistent changes in synaptic responses. This forms the basis for enduring memory in adults. Activity also shapes neural circuits developmentally, but whether protein synthesis plays a congruent function in this process is poorly understood. Here, we show that brief periods of global or local protein synthesis inhibition decrease the synaptic vesicles available for fusion and increase synapse elimination. Ca(2+)/calmodulin-dependent protein kinase II (CaMKII) is a critical target; its levels are controlled by rapid turnover, and blocking its activity or knocking it down recapitulates the effects of protein synthesis inhibition. Mature presynaptic terminals show decreased sensitivity to protein synthesis inhibition, and resistance coincides with a developmental switch in regulation from CaMKII to PKA (protein kinase A). These findings demonstrate a novel mechanism regulating presynaptic activity and synapse elimination during development, and suggest that protein translation acts coordinately with activity to selectively stabilize appropriate synaptic interactions.

Region-directed phototransfection reveals the functional significance of a dendritically synthesized transcription factor

Multiple nuclear transcription factors including E-26-like protein 1 (Elk-1) have been found in neuronal dendrites, yet the functional significance of such localization has not yet been explained. Here we use a focal transfection procedure, 'phototransfection', to introduce Elk1 mRNA into specific regions of live, intact primary rat neurons. Introduction and translation of Elk1 mRNA in dendrites produced cell death, whereas introduction and translation of Elk1 mRNA in cell bodies did not produce cell death. Elk-1 translated in dendrites was transported to the nucleus, and cell death depended upon transcription, supporting the dendritic imprinting hypothesis and highlighting the importance of the dendritic environment on protein function. Our demonstration of the utility of phototransfection for spatially controlled introduction of mRNAs opens the broader opportunity to use this method to introduce selected quantities of small molecules into discrete regions of live cells to assess their biological functions.

GAP-43 mRNA in growth cones is associated with HuD and ribosomes

The neuron-specific ELAV/Hu family member, HuD, interacts with and stabilizes GAP-43 mRNA in developing neurons, and leads to increased levels of GAP-43 protein. As GAP-43 protein is enriched in growth cones, it is of interest to determine if HuD and GAP-43 mRNA are associated in developing growth cones. HuD granules in growth cones are found in the central domain that is rich in microtubules and ribosomes, in the peripheral domain with its actin network, and in filopodia. This distribution of HuD granules in growth cones is dependent on actin filaments but not on microtubules. GAP-43 mRNA is localized in granules found in both the central and peripheral domains, but not in filopodia. Ribosomes were extensively colocalized with HuD and GAP-43 mRNA granules in the central domain, consistent with a role in the control of GAP-43 mRNA stability in the growth cone. Together, these results demonstrate that many of the components necessary for GAP-43 mRNA translation/stabilization are present within growth cones.

Staufen recruitment into stress granules does not affect early mRNA transport in oligodendrocytes

Staufen is a conserved double-stranded RNA-binding protein required for mRNA localization in Drosophila oocytes and embryos. The mammalian homologues Staufen 1 and Staufen 2 have been implicated in dendritic RNA targeting in neurons. Here we show that in rodent oligodendrocytes, these two proteins are present in two independent sets of RNA granules located at the distal myelinating processes. A third kind of RNA granules lacks Staufen and contains major myelin mRNAs. Myelin Staufen granules associate with microfilaments and microtubules, and their subcellular distribution is affected by polysome-disrupting drugs. Under oxidative stress, both Staufen 1 and Staufen 2 are recruited into stress granules (SGs), which are stress-induced organelles containing transiently silenced messengers. Staufen SGs contain the poly(A)-binding protein (PABP), the RNA-binding proteins HuR and TIAR, and small but not large ribosomal subunits. Staufen recruitment into perinuclear SGs is paralleled by a similar change in the overall localization of polyadenylated RNA. Under the same conditions, the distribution of recently transcribed and exported mRNAs is not affected. Our results indicate that Staufen 1 and Staufen 2 are novel and ubiquitous SG components and suggest that Staufen RNPs are involved in repositioning of most polysomal mRNAs, but not of recently synthesized transcripts, during the stress response.

Protein synthesis is necessary for dendritic spine proliferation in adult brain slices

Dendritic spines, small protrusions from dendritic shafts, receive most of the excitatory synapses in cortical regions. Spines are highly plastic structures that can be rapidly produced or lost in response to a wide array of internal and external stimuli, and they proliferate in acute slice preparations [J. Neurosci. 19 (1999) 2876]. The goal of the present study was to determine if protein synthesis is necessary for this spine proliferation. We found that the addition of protein synthesis inhibitors to acute slices (in which spines otherwise proliferate) blocked new spine growth. Furthermore, a population of longer spines was observed after 2 h but these did not develop during protein synthesis blockade. These data suggest that protein synthesis is necessary for new spine growth in acute brain slice preparations and support literature suggesting that newly produced spines develop from filopodia-like protrusions.

Molecular determinants and physiological relevance of extrasomatic RNA localization in neurons

Specific sorting of mRNA molecules to subcellular microdomains is an evolutionarily conserved mechanism by which the polarized nature of eukayotic cells may be established and maintained. The molecular composition of the RNA localization machinery is complex. Sequence motifs within RNA molecules to be transported, called cis-acting elements, and proteins, referred to as trans-acting factors, are essential components. Transport of the resulting ribonucleoprotein complexes to distinct cytoplasmic regions occurs along the cytoskeletal network. The pathway is observed in organisms as diverse as yeast and human and it plays a critical role in development and cell differentiation. Moreover, RNA localization takes place in differentiated cell types including neurons. There is ample evidence to suggest that sorting of defined mRNA species to the neurites of nerve cells and on-site translation has an impact on various aspects of nerve cell biology.

Protein synthesis in the dendrite

In neurons, many proteins that are involved in the transduction of synaptic activity and the expression of neural plasticity are specifically localized at synapses. How these proteins are targeted is not clearly understood. One mechanism is synaptic protein synthesis. According to this idea, messenger RNA (mRNA) translation from the polyribosomes that are observed at the synaptic regions provides a local source of synaptic proteins. Although an increasing number of mRNA species has been detected in the dendrite, information about the synaptic synthesis of specific proteins in a physiological context is still limited. The physiological function of synaptic synthesis of specific proteins in synaptogenesis and neural plasticity expression remains to be shown. Experiments aimed at understanding the mechanisms and functions f synaptic protein synthesis might provide important information about the molecular nature of neural plasticity.

Targeting of mRNAs within the glial cell cytoplasm: how to hide the message along the journey

The subcellular targeting of mRNAs encoding myelin proteins to the oligodendrocyte processes is an accepted fact in myelin formation. How these messengers are kept silent during their movement to the subcellular domain where they are turned on remains a mystery. This review focuses on aspects of mRNA targeting and speculates on possible molecular mechanisms for the translational control of myelin-located mRNAs.

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.

Ribosome association contributes to restricting mRNAs to the cell body of hippocampal neurons

In neurons, mRNAs are differentially sorted to axons, dendrites, and the cell body. Recently, regions of certain mRNAs have been identified that target those mRNAs for translocation to the processes. However, the mechanism by which many, if not most mRNAs are retained in the cell body is not understood. Total inhibition of translation, by puromycin or cycloheximide, results in the mislocalization of cell body mRNAs to dendrites. We have examined the effect of translational inhibitors on the localization of ferritin mRNA, the translation of which can also be inhibited specifically by reducing iron levels. Using nonisotopic in situ hybridization, ferritin mRNA is found restricted to the cell body of cultured rat hippocampal neurons. Following treatment with either puromycin or cycloheximide, it migrates into dendrites. Control experiments reveal that the drugs affect neither the viability of the neuronal cultures, nor the steady-state level of ferritin mRNA. When transcription and protein synthesis are inhibited simultaneously, ferritin mRNA is found in the dendrites of puromycin, but not of cycloheximide-treated neurons. However, the localization of ferritin mRNA is unaffected by changes in iron concentration that regulate its translation rate specifically. We propose a model whereby cell body-restricted mRNAs are maintained in that location by association with ribosomes and with another cell component, which traps mRNAs when they are freed of ribosome association. The release of all mRNA species, as happens after total protein synthesis inhibition, floods the system and allows cell body mRNAs to diffuse into dendrites. In contrast, the partial release of the single ferritin mRNA species does not saturate the trapping system and the mRNA is retained in the cell body.

Making sense of the multiple MAP-2 transcripts and their role in the neuron

Microtubule-associated protein-2 (MAP-2) is a family of heat-stable, phosphoproteins expressed predominantly in the cell body and dendrites of neurons. Three major MAP-2 isoforms, (MAP-2a, MAP-2b, MAP-2c) are differentially expressed during the development of the nervous system and have an important role in microtubule dynamics. Several MAP-2 cDNA clones that correspond to the major MAP-2 transcripts and additional, novel MAP-2 transcripts expressed in the CNS and PNS have been characterized. The transcripts result from the alternative splicing of a single MAP-2 gene consisting of 20 exons. Studies are now being directed toward understanding the role of the multiple MAP-2 forms that contain novel exons in the nervous system. The expression, localization, and possible functions of the newly identified spliced forms are the focus of this review.

Differential intracellular sorting of immediate early gene mRNAs depends on signals in the mRNA sequence

This study characterizes the differential targeting of recently synthesized immediate early gene (IEG) mRNAs to neuronal cell bodies versus dendrites and tests the hypothesis that this targeting is based on signals in the encoded proteins. A single electroconvulsive seizure induces the expression of a number of IEG mRNAs in granule cells of the dentate gyrus. Most of these IEG mRNAs remain in the cell body, including two that are characterized in the present study (the mRNAs for NGFI-A and COX-2). In contrast, the mRNA for Arc moved rapidly into dendrites at an apparent rate of approximately 300 micron/hr. Inhibiting protein synthesis with cycloheximide did not disrupt the differential mRNA sorting, demonstrating that the differential targeting of mRNAs is not dependent on translation.

Differential intracellular sorting of immediate early gene mRNAs depends on signals in the mRNA sequence

This study characterizes the differential targeting of recently synthesized immediate early gene (IEG) mRNAs to neuronal cell bodies versus dendrites and tests the hypothesis that this targeting is based on signals in the encoded proteins. A single electroconvulsive seizure induces the expression of a number of IEG mRNAs in granule cells of the dentate gyrus. Most of these IEG mRNAs remain in the cell body, including two that are characterized in the present study (the mRNAs for NGFI-A and COX-2). In contrast, the mRNA for Arc moved rapidly into dendrites at an apparent rate of approximately 300 micron/hr. Inhibiting protein synthesis with cycloheximide did not disrupt the differential mRNA sorting, demonstrating that the differential targeting of mRNAs is not dependent on translation.

Inhibition of axonal growth by brefeldin A in hippocampal neurons in culture

The outgrowth of neuronal processes involves a great increase in the surface area of the cell. The supply of membrane material necessarily must be coordinated with the demands for neurite growth. The selective growth of only one or two neurites at any given time during the development of polarity raises the possibility that the production of materials by the soma is limiting for growth (Dotti and Banker, 1987; Dotti et al., Goslin and Banker, 1990). To examine the role of the availability of membrane components during the development of polarity and axonal elongation, we treated neurons with brefeldin A, an antibiotic that disrupts the trafficking of vesicles from the Golgi complex to the plasma membrane. Treatment with brefeldin A (1 microg/ml) inhibited axonal growth within 0.5 hr; in unpolarized cells it prevented the formation of an axon. These results indicate that the availability of membrane components of Golgi-derived vesicles is required for axonal growth and hence the development of polarity. Inhibitors of protein and RNA synthesis also blocked axonal growth and the development of polarity, but over a much slower time course. This suggests that the full complement of proteins and mRNAs required for the initial development of polarity is present for several hours before polarity is actually established.

Inhibition of axonal growth by brefeldin A in hippocampal neurons in culture

The outgrowth of neuronal processes involves a great increase in the surface area of the cell. The supply of membrane material necessarily must be coordinated with the demands for neurite growth. The selective growth of only one or two neurites at any given time during the development of polarity raises the possibility that the production of materials by the soma is limiting for growth (Dotti and Banker, 1987; Dotti et al., Goslin and Banker, 1990). To examine the role of the availability of membrane components during the development of polarity and axonal elongation, we treated neurons with brefeldin A, an antibiotic that disrupts the trafficking of vesicles from the Golgi complex to the plasma membrane. Treatment with brefeldin A (1 microg/ml) inhibited axonal growth within 0.5 hr; in unpolarized cells it prevented the formation of an axon. These results indicate that the availability of membrane components of Golgi-derived vesicles is required for axonal growth and hence the development of polarity. Inhibitors of protein and RNA synthesis also blocked axonal growth and the development of polarity, but over a much slower time course. This suggests that the full complement of proteins and mRNAs required for the initial development of polarity is present for several hours before polarity is actually established.

Immature Human Megakaryocytes Produce Nuclear-Associated Acetylcholinesterase

Acetylcholinesterase (AChE) is expressed in murine megakaryocytes (MK), where its antisense inhibition suppresses differentiation, yet was never detected in human MK. Here, we report that AChE is produced in normal human bone marrow MK and in cell lines derived thereof. Reverse transcriptase-polymerase chain reaction (RT-PCR) amplification showed two ACHEmRNA forms in human megakaryoblastic DAMI cells. In situ hybridization demonstrated ACHEmRNA surrounding the nucleus of small DAMI cells and the nuclear lobes of large, polyploid cells. Differentiation induction with phorbol ester and exposure to recombinant human thrombopoietin suppressed both ACHEmRNA and AChE activity. The residual AChE in mature differentiated cells acquired higher stability and detergent-sensitivity as compared with AChE in small proliferating cells. AChE activity was primarily associated with nuclei of both DAMI cells and small (10 μm) primary proliferating human bone marrow MK identified with GPIIb/IIIa antibodies. This activity was significantly reduced in medium size MK (10 to 25 μm) and was almost undetectable in large MK (<25 μm), yet was twofold more abundant in some large MK from idiopathic thrombocytopenia purpura (ITP) patients with accelerated MK maturation. The loss of AChE activity at the transition from proliferating to differentiating MK highlights species-specific differences in its expression, suggesting a distinct role for AChE in human MK development.

Immature Human Megakaryocytes Produce Nuclear-Associated Acetylcholinesterase

Acetylcholinesterase (AChE) is expressed in murine megakaryocytes (MK), where its antisense inhibition suppresses differentiation, yet was never detected in human MK. Here, we report that AChE is produced in normal human bone marrow MK and in cell lines derived thereof. Reverse transcriptase-polymerase chain reaction (RT-PCR) amplification showed two ACHEmRNA forms in human megakaryoblastic DAMI cells. In situ hybridization demonstrated ACHEmRNA surrounding the nucleus of small DAMI cells and the nuclear lobes of large, polyploid cells. Differentiation induction with phorbol ester and exposure to recombinant human thrombopoietin suppressed both ACHEmRNA and AChE activity. The residual AChE in mature differentiated cells acquired higher stability and detergent-sensitivity as compared with AChE in small proliferating cells. AChE activity was primarily associated with nuclei of both DAMI cells and small (10 μm) primary proliferating human bone marrow MK identified with GPIIb/IIIa antibodies. This activity was significantly reduced in medium size MK (10 to 25 μm) and was almost undetectable in large MK (<25 μm), yet was twofold more abundant in some large MK from idiopathic thrombocytopenia purpura (ITP) patients with accelerated MK maturation. The loss of AChE activity at the transition from proliferating to differentiating MK highlights species-specific differences in its expression, suggesting a distinct role for AChE in human MK development.

Translocation of RNA granules in living neurons

Sorting of RNAs to specific subcellular loci occurs in diverse settings from fly oocytes to mammalian neurons. Using the membrane-permeable nucleic acid stain SYTO 14, we directly visualized the translocation of endogenous RNA in living cells. Labeled RNA was distributed nonrandomly as discrete granules in neuronal processes. The labeled granules colocalized with poly(A+) mRNA, with the 60S ribosomal subunit, and with elongation factor 1alpha, suggesting that granules represent a translational unit. A subset of labeled granules colocalized with beta-actin mRNA. Correlative light and electron microscopy indicated that the fluorescent granules corresponded to clusters of ribosomes at the ultrastructural level. Poststaining of sections with heavy metals confirmed the presence of ribosomes within these granules. In living neurons, a subpopulation of RNA granules was motile during the observation period. They moved at an average rate of 0.1 microm/sec. In young cultures their movements were exclusively anterograde, but after 7 d in culture, one-half of the motile granules moved in the retrograde direction. Granules in neurites were delocalized after treatment with microtubule-disrupting drugs. These results raise the possibility of a cellular trafficking system for the targeting of RNA in neurons.

Translocation of RNA granules in living neurons

Sorting of RNAs to specific subcellular loci occurs in diverse settings from fly oocytes to mammalian neurons. Using the membrane-permeable nucleic acid stain SYTO 14, we directly visualized the translocation of endogenous RNA in living cells. Labeled RNA was distributed nonrandomly as discrete granules in neuronal processes. The labeled granules colocalized with poly(A+) mRNA, with the 60S ribosomal subunit, and with elongation factor 1alpha, suggesting that granules represent a translational unit. A subset of labeled granules colocalized with beta-actin mRNA. Correlative light and electron microscopy indicated that the fluorescent granules corresponded to clusters of ribosomes at the ultrastructural level. Poststaining of sections with heavy metals confirmed the presence of ribosomes within these granules. In living neurons, a subpopulation of RNA granules was motile during the observation period. They moved at an average rate of 0.1 microm/sec. In young cultures their movements were exclusively anterograde, but after 7 d in culture, one-half of the motile granules moved in the retrograde direction. Granules in neurites were delocalized after treatment with microtubule-disrupting drugs. These results raise the possibility of a cellular trafficking system for the targeting of RNA in neurons.

The 3'-untranslated region of CaMKII alpha is a cis-acting signal for the localization and translation of mRNA in dendrites

Neuronal signaling requires that synaptic proteins be appropriately localized within the cell and regulated there. In mammalian neurons, polyribosomes are found not just in the cell body, but also in dendrites where they are concentrated within or beneath the dendritic spine. The alpha subunit of Ca(2+)-calmodulin-dependent protein kinase II (CaMKII alpha) is one of only five mRNAs known to be present within the dendrites, as well as in the soma of neurons. This targeted subcellular localization of the mRNA for CaMKII alpha provides a possible cell biological mechanism both for controlling the distribution of the cognate protein and for regulating independently the level of protein expression in individual dendritic spines. To characterize the cis-acting elements involved in the localization of dendritic mRNA we have produced two lines of transgenic mice in which the CaMKII alpha promoter is used to drive the expression of a lacZ transcript, which either contains or lacks the 3'-untranslated region of the CaMKII alpha gene. Although both lines of mice show expression in forebrain neurons that parallels the expression of the endogenous CaMKII alpha gene, only the lacZ transcripts bearing the 3'-untranslated region are localized to dendrites. The beta-galactosidase protein shows a variable level of expression along the dendritic shaft and within dendritic spines, which suggests that neurons can control the local biochemistry of the dendrite either through differential localization of the mRNA or variations in the translational efficiency at different sites along the dendrite.

Transgenic expression of embryonic MAP2 in adult mouse brain: implications for neuronal polarization

The major neuronal microtubule-associated protein MAP2 is selectively localized in dendrites, where its expression is under strong developmental regulation. To learn more about its potential effects on neuronal morphogenesis and its sorting within the neuronal cytoplasm, we have raised transgenic mice that express high levels of the embryonic form, MAP2c, in the adult brain. One transgenic line expressed higher levels of MAP2c than endogenous adult MAP2. This had no detectable effect on either the arrangement or morphology of neurons, suggesting that although MAP2c is necessary for neuronal morphogenesis it is not involved in its regulation. Like endogenous adult MAP2, transgenic MAP2c was present in dendrites but not axons, indicating that the signal responsible for its cytoplasmic sorting is contained within the 1.5 kb of its coding sequence. In situ hybridization with specific probes showed that transgenic MAP2c mRNA was limited to cell bodies. Thus, the dendritic localization of MAP2c protein cannot be the result of previous transport of its mRNA but must depend on a signal associated with the protein itself. Furthermore, because the amino acid sequence of MAP2c is present in all forms of MAP2, this signal is also contained within adult high-M(r) MAP2 protein. This raises the possibility that, rather than the conventional scheme of mRNA sorting preceding protein localization, the transport of adult MAP2 mRNA into dendrites could depend on it being part of a translation complex in which the targeting signal is on the nascent protein.

Transgenic expression of embryonic MAP2 in adult mouse brain: implications for neuronal polarization

The major neuronal microtubule-associated protein MAP2 is selectively localized in dendrites, where its expression is under strong developmental regulation. To learn more about its potential effects on neuronal morphogenesis and its sorting within the neuronal cytoplasm, we have raised transgenic mice that express high levels of the embryonic form, MAP2c, in the adult brain. One transgenic line expressed higher levels of MAP2c than endogenous adult MAP2. This had no detectable effect on either the arrangement or morphology of neurons, suggesting that although MAP2c is necessary for neuronal morphogenesis it is not involved in its regulation. Like endogenous adult MAP2, transgenic MAP2c was present in dendrites but not axons, indicating that the signal responsible for its cytoplasmic sorting is contained within the 1.5 kb of its coding sequence. In situ hybridization with specific probes showed that transgenic MAP2c mRNA was limited to cell bodies. Thus, the dendritic localization of MAP2c protein cannot be the result of previous transport of its mRNA but must depend on a signal associated with the protein itself. Furthermore, because the amino acid sequence of MAP2c is present in all forms of MAP2, this signal is also contained within adult high-M(r) MAP2 protein. This raises the possibility that, rather than the conventional scheme of mRNA sorting preceding protein localization, the transport of adult MAP2 mRNA into dendrites could depend on it being part of a translation complex in which the targeting signal is on the nascent protein.

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.

Myelin basic protein mRNA localization and polypeptide targeting

Myelin basic proteins (MBPs), the major peripheral membrane proteins of central nervous system (CNS) myelin, are encoded by mRNAs that are selectively segregated to the myelinating processes of oligodendrocytes. In order to test whether the intracellular mechanisms responsible for MBP mRNA translocation are oligodendrocyte-specific, or alternatively, are present in other cell types and may therefore be more general, we have studied the localization of the 14 kD MBP mRNA and its encoded polypeptide (MBP14) in transiently transfected HeLa cells (a cervical carcinoma cell line) and in the rat pheochromocytoma cell line PC12. Unlike the situation in oligodendrocytes in situ, where MBP mRNAs are translocated and become "centrifugally" distributed, in both of the non-glial cells MBP mRNA was primarily detected in the perinuclear region. The MBP14 polypeptide was found associated with intracellular membranes, and not exclusively with the plasma membrane. Our results indicate that the inability of HeLa and PC12 cells to correctly target MBP mRNAs to the cell periphery leads to a failure to incorporate MBP polypeptides directly into the plasma membrane. Further, the data lend credence to the concept that MBP mRNA segregation appears to be a specific feature of myelin-forming cells which is required for the precise delivery of the encoded polypeptides to the forming myelin membrane.

RNAs radiate from gene to cytoplasm as revealed by fluorescence in situ hybridization

Genes for Epstein-Barr virus, human cytomegalovirus immediate early antigen and luciferase are abundantly transcribed in Namalwa, rat 9G and X1 cells, respectively. The EBV transcripts and HCMV-IE transcripts are extensively spliced, while in the luciferase transcript only a small intron sequence has to be spliced out. EBV transcripts are hardly localized in the cytoplasm while the luciferase and HCMV-IE transcripts are present in the cytoplasm and translated into proteins. We have correlated these characteristics with nuclear RNA distribution patterns as seen by fluorescence in situ hybridization. Transcripts of the HCMV-IE transcription unit were shown to be present in a main nuclear signal in the form of a track or elongated dot and as small nuclear RNA signals that radiate from this site towards the cytoplasm. A similar distribution pattern of small RNA signals was observed for transcripts of the luciferase gene, whereas the main nuclear signal was always observed as a dot and never as a track or elongated dot. In Namalwa cells, EBV transcripts were only present as track-like signals. The results suggest that when the extent for splicing is high, unspliced or partially spliced mRNAs begin to occupy elongated dot or track-like domains in the vicinity of the gene. When the extent of splicing is low, splicing is completed co-transcriptionally, leading to a bright dot-like signal. The presence of small nuclear spots in addition to the main signal correlates with cytoplasmic mRNA expression. The small spots most likely represent, therefore, mRNAs in transport to the cytoplasm.

Cytoplasmic chaperonin complexes enter neurites developing in vitro and differ in subunit composition within single cells

Chaperonins containing t-complex polypeptide-1 (CCT) are cytosolic molecular chaperone particles implicated especially in the biogenesis of cytoskeletal proteins by promoting the correct folding of the major ubiquitous cytoskeletal components, tubulin and actin. We have purified cytosolic chaperonins from the ND7/23 cell line, determined their subunit composition and examined changes in the intracellular locations of their components during differentiation of ND7/23 cells to a neuronal phenotype by using immunocytochemistry and immunoblots. Chaperonins containing the CCT alpha (TCP1) subunit enter neuritic processes and are particularly noticeable at the leading edge of growth cone-like structures where they co-localise with actin. Chaperonins containing three other components (CCT beta, epsilon and gamma), however, remain predominantly restricted to perikaryal cytoplasm. These findings suggest a heterogeneous population of chaperonin particles within single differentiated ND7/23 cells and this may reflect specialisation of chaperonin function in different cytoplasmic compartments of a neurone. Further, since ribosomes do not enter neurites while CCT alpha-containing chaperonins do, the latter may play roles, subsequent to translation, which influence cytoskeletal elaboration during neuritogenesis.