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The Journal of Neuroscience, October 15, 1999, 19(20):8818-8829
Identification of a cis-Acting Dendritic Targeting
Element in MAP2 mRNAs
Arne
Blichenberg1,
Birgit
Schwanke1,
Monika
Rehbein1,
Craig C.
Garner2,
Dietmar
Richter1, and
Stefan
Kindler1
1 Institute for Cell Biochemistry and Clinical
Neurobiology, University of Hamburg, D-20246 Hamburg, Germany, and
2 Department of Neurobiology, University of Alabama at
Birmingham, South Birmingham, AL 35213-0021
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ABSTRACT |
In neurons, a limited number of mRNAs have been identified in
dendritic processes, whereas other transcripts are restricted to the
cell soma. Here we have investigated the molecular mechanisms underlying extrasomatic localization of mRNAs encoding
microtubule-associated protein 2 (MAP2) in primary neuronal cultures.
Vectors expressing recombinant mRNAs were introduced into hippocampal
and sympathetic neurons using DNA transfection and microinjection
protocols, respectively. Chimeric mRNAs containing the entire 3'
untranslated region of MAP2 transcripts fused to a nondendritic
reporter mRNA are detected in dendrites. In contrast, RNAs containing
MAP2 coding and 5' untranslated regions or tubulin sequences are
restricted to the cell soma. Moreover, 640 nucleotides from the MAP2 3'
untranslated region (UTR) are both sufficient and essential for
extrasomatic localization of chimeric mRNAs in hippocampal and
sympathetic neurons. Thus, a cis-acting dendritic
targeting element that is effective in two distinct neuronal cell types
is contained in the 3' UTR of MAP2 transcripts. The observation of RNA
granules in dendrites implies that extrasomatic transcripts seem to
assemble into multimolecular complexes that may function as transport units.
Key words:
dendritic targeting element; RNA localization into
dendrites; subcellular transport; extrasomatic protein synthesis; neuronal cytoskeleton/microtubule-associated protein; primary cultures
of neurons; microinjection; transfection
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INTRODUCTION |
Neurons possess distinct cellular
compartments that are highly diverse with respect to their protein
repertoire. Most likely a differential molecular composition of
dendritic microdomains and postsynaptic structures is not only
attributable to selective protein sorting but also reflects local
synthesis of specific proteins (Steward, 1994 , 1997; Kindler et al.,
1997; Kuhl and Skehel, 1998; Tiedge et al., 1999). This hypothesis
first arose with the ultrastructural detection of polyribosomes in
dendritic shafts at the base of dendritic spines (Steward and Levy,
1982; Steward and Reeves, 1988) and was subsequently supported by the identification of distinct mRNAs in dendrites. Dendritic mRNAs encode,
among other proteins, the microtubule-associated protein 2 (MAP2)
(Garner et al., 1988; Bruckenstein et al., 1990; Kleiman et al., 1990),
the  subunit of the
Ca2+/calmodulin-dependent protein kinase
II (-CaMKII) (Burgin et al., 1990), the product of an
activity-regulated gene (arg3.1) (Link et al., 1995), also described as
activity-regulated cytoskeleton-associated protein, arc (Lyford et al.,
1995), the neuropeptides vasopressin and oxytocin (Mohr et al., 1995),
the inositol 1,4,5-triphosphate receptor type 1 (Furuichi et al.,
1993), neurogranin (Landry et al., 1994), amino acid receptors
(Miyashiro et al., 1994), the cAMP response element binding protein
(CREB) (Crino et al., 1998), and dendrin (Herb et al., 1997). The
noncoding RNA BC1 (Tiedge et al., 1991), ribosomal RNAs (Kleiman et
al., 1993), and tRNAs (Tiedge and Brosius, 1996) are also present in
dendrites. Dendritic tran-scripts were detected in synaptosome
preparations (Chicurel et al., 1993; Rao and Steward, 1993), and
isolated dendrites are capable of protein synthesis (Torre and Steward,
1992; Crino and Eberwine, 1996). Moreover, specific forms of synaptic
plasticity in the rat hippocampus seem to depend on translation in
dendrites (Kang and Schuman, 1996). These findings imply that
extrasomatic protein synthesis influences the protein composition in
dendritic compartments and contributes to modulations of synaptic
function (for review, see Steward, 1994, 1997; Kindler et al., 1997;
Kuhl and Skehel, 1998; Tiedge et al., 1999).
Modulation of extrasomatic protein composition and synaptic
transmission seems to partially rely on dendritic targeting of selected
transcripts and their regulated decentralized translation. This idea is
supported by the observation that arc/arg3.1 mRNA and protein
specifically accumulate in dendritic layers in which synapses have
previously been stimulated (Steward et al., 1998). However, the
molecular mechanisms directing selective mRNA targeting to dendrites
and local protein synthesis are poorly understood. In other cell
systems, such as Drosophila embryos and Xenopus oocytes, regulated interactions between mRNA signal sequences and
trans-acting factors govern cytoplasmic transport and
site-specific translation of various transcripts (St. Johnston, 1995).
Our aim was to functionally characterize cis-acting
dendritic targeting sequences in MAP2 mRNAs. This was accomplished by
the expression of chimeric transcripts containing various MAP2 mRNA
fragments in two primary neuronal cell systems and an analysis of their subcellular distribution. A 640 nucleotide element contained in the 3'
untranslated region (3' UTR) of MAP2 transcripts was found to be both
sufficient and essential to mediate efficient dendritic mRNA
localization in two different neuronal cell types.
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MATERIALS AND METHODS |
Construction of eukaryotic expression vectors. The
basic vector pNE expresses a nuclear location signal (NLS)/enhanced
green fluorescent protein (EGFP) fusion protein driven by the  -actin promoter from chicken. It was derived from the plasmid act-16 (Fregien and Davidson, 1986) provided with additional cloning sites and
the GFP cDNA sequence (pact-hCGFP; courtesy of A. Matus, Friedrich
Miescher Institute, Basel, Switzerland). The
NcoI-NotI fragment was replaced by the
corresponding EGFP cDNA fragment from pEGFP-N1 (Clontech Laboratories,
Palo Alto, CA). A sequence encoding an NLS (MGPKKKRKVGS) was introduced
at the NcoI site upstream of the EGFP coding region using
two oligonucleotides (5'-CATGGGGCCCAAGAAGAAACGCAAAGTGGGAAG-3' and
5'-CATGCTTCCCACTTTGCGTTTCTTCTTGGGCCC-3').
Vectors that express EGFP-encoding mRNAs fused to parts of MAP2 mRNAs
contain the following cDNA sequences (GenBank/EMBL Data Bank accession
numbers U30937, X51842, and U30938): pNEc (nucleotides 60-5549,
X51842); pNEcu (198-367, U30937; 60-5552, X51842; 4-176,
U30938); pNEu (5383-5552, X51842; 4-3720, U30938);
pNEu 2436-3071 (5383-5552, X51842; 4-2435 and 3072-3720, U30938); the numbers in
pNEu181-1963, pNEu1586-3274,
pNEu2804-3728,
pNEu1586-2435, pNEu2432-3274,
pNEu2432-2807,
pNEu2804-3274, pNEu2432-3071,
pNEu2632-3274, and
pNEu2632-3071 refer to the 5' and 3' ends of the
inserted MAP2 cDNA fragments, respectively, with nucleotide numbering
according to the 3' UTR sequence (U30938); -tubulin vector pNEtub
(GenBank/EMBL Data Bank accession number V01227): nucleotides
1-1617.
Preparation and transfection of primary hippocampal
neurons. Cultures of hippocampal neurons were prepared from
embryonic day 21 (E21) rat embryos as described (Goslin and Banker,
1991). Briefly, cells were grown at a density of 400 cells/mm2 on 18 mm
poly-L-lysine (Sigma-Aldrich Chemie, Deisenhofen,
Germany)-coated glass coverslips face down above a confluent layer of
glial cells in serum-free medium with N2 supplements (Goslin and
Banker, 1991) at 37°C and 5% CO2. One day
after plating, the cells were transfected. Thirty minutes before
transfection, the coverslips were transferred into fresh N2 medium
containing 1% (v/v) fetal calf serum (FCS) with cells facing up.
Fifteen micrograms of pUC19 carrier DNA prepared over two CsCl
gradients (Sambrook et al., 1989) and 5 µg of vector DNA (purified
over affinity columns; Qiagen, Hilden, Germany) were mixed in a final
volume of 100 µl in 0.25 M CaCl2. One hundred microliters of 2 × BBS (50 mM BES, 280 mM NaCl, 1.5 mM
Na2HPO4, pH 6.96) were
slowly added while air was continuously blown into the solution with a
Pasteur pipette. Twenty minutes later, the mixture was distributed
dropwise onto the cells (100 µl per coverslip) while the dish was
gently swirled. After 6 hr at 37°C, 5% CO2,
cells were washed twice with HBSS (Gibco BRL/Life Technologies,
Eggenstein, Germany) buffered with 10 mM HEPES, pH 7.4, and
placed back onto the glial cells. After 14-18 d, neurons were analyzed
by in situ hybridization or immunocytochemistry. Transfection rates, as judged by the amount of cells exhibiting a
positive in situ hybridization signal, were typically
between 0.1 and 0.5%.
Preparation and microinjection of primary sympathetic
neurons. Primary cultures of superior cervical ganglia (SCG)
neurons were generated from E21 rat embryos as described by Higgins et al. (1991). Cells were seeded on poly-D-lysine
(Sigma-Aldrich Chemie) and laminin (Gibco BRL/Life Technologies)-coated
coverslips at a density of 5-10 cells/mm2
in serum-free medium. Three days after plating, dendritic growth was
induced by supplementing the medium with matrigel (75 µg/ml; Roche
Diagnostics, Heidelberg, Germany). Non-neuronal cell proliferation was
discouraged by adding cytosine -D-arabinofuranoside (2 µM; Sigma-Aldrich Chemie). After 14-21 d in culture,
differentiated neurons were injected with vector DNA at a concentration
of 200 ng/µl using the Eppendorf microinjector 5242 (Eppendorf,
Hamburg, Germany). Cells were placed into Leibovitz L-15 medium (Gibco BRL/Life Technologies) and viewed with an Axiovert 135 microscope (Zeiss, Oberkochen, Germany) at 400× magnification. During the injection of nuclei with Femto-tips (Eppendorf), the pressure was
constantly kept at about 100 hPa. The injection time was restricted to
1 hr per coverslip. Afterward the cells were incubated for 4 hr at
37°C, 5% CO2 in normal SCG cell culture
medium, fixed, and analyzed by in situ hybridization or immunocytochemistry.
In situ hybridization analysis. The
KpnI-XbaI EGFP cDNA fragment from pEGFP-N1
(Clontech Laboratories) was subcloned into pBluescript-SKII( )
(Stratagene, Heidelberg, Germany). The resulting plasmid pBS-EGFP was
linearized with SmaI to transcribe a digoxigenin-labeled antisense EGFP RNA probe with T3 RNA polymerase according to the manufacturer's description (Roche Diagnostics, Mannheim, Germany). For in situ hybridization, cells were briefly washed with
PBS (5 mM
NaH2PO4, 5 mM
Na2HPO4, 2.7 mM KCl, 137 mM NaCl, pH
7.4) containing 4% (w/v) sucrose and fixed for 15 min in 4% (w/v)
paraformaldehyde, 2 mM
MgCl2, 5 mM EGTA, and 4%
(w/v) sucrose in PBS at room temperature, followed by washing in PBS
containing 4% (w/v) sucrose (three times, 5 min each). Subsequently,
coverslips were irradiated in a UV cross-linker (Stratagene) set to 120 mJ. Cells were permeabilized for 3 min in PBS containing 0.1%
(v/v) Triton X-100 and washed three times for five min each in PBS
containing 2 mM MgCl2.
Air-dried neurons were prehybridized for 2 hr at 50°C in 50% (v/v)
deionized formamide, 5 × SSC, 5 × Denhardt's solution,
0.2% (w/v) SDS, 50 µg/ml heparin, 100 µg/ml poly(A) homopolymer,
250 µg/ml denatured herring sperm DNA, and 250 µg/ml yeast tRNA.
Hybridization was performed overnight at 50°C in the same solution
but included ~500 ng/ml of the in vitro synthesized
digoxigenin-labeled riboprobe. Coverslips were washed twice in 1 × SSC and 0.1% (w/v) SDS at room temperature for 5 min each, and then
in 0.2 × SSC, 0.1% (w/v) SDS at 65°C (twice, 10 min each). The
hybridized probe was detected immunocytochemically using a sheep
anti-digoxigenin antibody coupled to alkaline phosphate (Roche
Diagnostics) and nitro blue tetrazolium and 5-bromo-4-chloro-3-indolyl
phosphate as a substrate according to the protocol provided by the
manufacturer. Cells were photographed on a Leitz Aristoplan microscope
(Ernst Leitz Wetzlar, Wetzlar, Germany). To evaluate the maximal
dendritic transport length of mRNA granules, pictures taken with a
video camera were analyzed using the NIH image software (developed at
National Institutes of Health, Bethesda, MD, and available on the
Internet at http://rsb.info.nih.gov/nih-image/). For each transfected
neuron the distance between the cell body and the distal-most dendritic
signal was measured using the program's segmented line tool.
Immunofluorescence microscopy of primary neuronal
cultures. Hippocampal and sympathetic neurons were prepared and
grown on coverslips as described above, washed in a physiological salt solution [0.9% (w/v) NaCl, 100 mM sodium phosphate
buffer, pH 7.4], fixed with 4% paraformaldehyde in high-salt PBS (450 mM NaCl, 20 mM sodium phosphate buffer, pH 7.4)
at room temperature for 15 min, and blocked with 5% (v/v) FCS in
high-salt PBS for 30 min. For immunofluorescence microscopy, coverslips
were incubated overnight with monoclonal antibodies against MAP2 (1:200
dilution; Chemicon International, Temecula, CA), tau (1:200 dilution;
Roche Diagnostics) or EGFP (1:500 dilution; Clontech Laboratories) at 4°C in 2% (v/v) FCS in high-salt PBS. After three washes in
high-salt PBS, coverslips were incubated overnight at 4°C with goat
anti-mouse IgG antibodies conjugated with either fluorescein, Cy3, or
Cy2 (Jackson ImmunoResearch Laboratories, West Grove, PA). Secondary antibodies were diluted 1:100 in 2% (v/v) FCS in high-salt PBS. After
three washes in high-salt PBS, cells were mounted and photographed as
described above, or a Zeiss laser-scanning microscope (Zeiss) was used.
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RESULTS |
Polar differentiation of cultured sympathetic and
hippocampal neurons
For the characterization of molecular determinants involved in
dendritic mRNA targeting, primary neurons derived from embryonic rat
hippocampi and superior cervical ganglia were grown in culture. Phase-contrast micrographs presented in Figure
1A,B
show that the given cell culture conditions promote a polar
differentiation of both sympathetic and hippocampal neurons as well as
the formation of an extended network of processes. Visualization of a
recombinant EGFP in individual neurons indicates that hippocampal cells
form a slightly more complex neurite network than sympathetic neurons (Fig. 1C,D). The nature of these cell processes
was further determined by immunocytochemical staining of cultures with
antibodies against the dendritic and axonal marker proteins MAP2 and
tau, respectively. MAP2 antibodies lead to a weak staining of neuronal
cell bodies and a strong labeling of several tapered, often
brancheddendrites per cell (Fig.
1E,F). In contrast, tau
antibodies stain a very dense meshwork of thin and long axonal
processes often running in bundles (Fig.
1G,H). Thus, both sympathetic and
hippocampal neurons develop dendrites and axons that can be reliably
distinguished on the basis of morphological and immunocytochemical
criteria. This feature and the fact that in cell culture both neuronal
cell types have been shown to localize endogenous MAP2 transcripts to
dendrites (Bruckenstein et al., 1990; Kleiman et al., 1990) make these
cell systems well suited for functional studies on the molecular
components underlying dendritic mRNA targeting.
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Figure 1.
Polar morphology and protein compartmentalization
in primary neurons. Phase-contrast (A, B) and
fluorescent (C-H) micrographs of cultured
sympathetic (A, C, E, G) and hippocampal neurons
(B, D, F, H) after 2 weeks in culture.
Phase-contrast images shown in A and B
reveal an elaborated neuronal network present in both primary cell
cultures. C, D, Neurons were
microinjected and transfected, respectively, with pNE vector DNA
leading to the expression of EGFP. The recombinant protein was either
directly visualized by autofluorescence (D) or
detected through immunocytochemistry with an anti-EGFP antibody and a
Cy2-coupled secondary antibody (C).
E-H, Neurons immunostained with mouse
monoclonal antibodies against the cytoskeletal proteins MAP2 (E,
F) and tau (G, H) and secondary
goat anti-mouse antibodies coupled to Cy3. Neuronal somata and
dendrites are intensely stained with anti-MAP2 antibodies (E,
F). Dendrites taper over their length and often form
secondary branches. In hippocampal cultures, dendrites are longer
relative to the cell body diameter and branch more frequently than
processes of sympathetic neurons. G, H,
Anti-tau antibodies primarily label the finely meshed axonal network
consisting of thin processes that course in and out of the field of
view. Processes often assemble to thicker axon bundles.
A-D represent scanned prints of pictures taken
with a conventional Leitz fluorescent microscope. Micrographs shown in
E-H were captured with a laser-scanning microscope.
Scale bars, 50 µm.
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cis-acting sequences direct dendritic targeting
of MAP2 mRNAs
Observations on mRNA localization in various non-neuronal cell
systems indicate that localized transcripts typically carry cis-acting transport signals that interact with
trans-acting proteins to mediate cytoplasmic mRNA targeting.
Matus and colleagues (Marsden et al., 1996) have suggested an
alternative mechanism in which a translational complex is localized by
virtue of a targeting signal encoded on the nascent protein leading to
passive co-transport of the corresponding transcripts. To investigate
whether MAP2 mRNA localization to dendrites depends on targeting
signals contained in transcripts or polypeptides, we have introduced
vectors into primary neurons that lead to the expression of chimeric
mRNAs and proteins. In the basic vector pNE, the avian -actin
promoter initiates transcription of mRNAs encoding an EGFP variant
carrying an N-terminal NLS. Previous experiments have shown that
somatically injected EGFP transcripts and -tubulin mRNAs transcribed
from eukaryotic expression vectors remain restricted to the somata of
sympathetic neurons (Muslimov et al., 1997; Prakash et al., 1997). To
investigate whether individual MAP2 mRNA or protein segments are
capable of imparting extrasomatic localization competence on an
exogenous reporter mRNA, different cDNA fragments corresponding to
coding and noncoding regions of MAP2 mRNAs were inserted next to the
EGFP cDNA in the vector pNE (Fig. 2). As
a control, the cDNA of the entire -tubulin transcript was inserted
downstream of the EGFP sequence. The subcellular localization of
chimeric mRNAs expressed from these vectors was monitored by in
situ hybridization with a digoxygenin-labeled antisense EGFP RNA.
Thus, all recombinant transcripts are detected with the same
sensitivity level and distinguished from endogenous MAP2 mRNAs. In
hybridization experiments with a sense EGFP probe, no significant
signals were observed (see Fig.
4I,J).
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Figure 2.
Schematic representation of the expression
and detection of recombinant transcripts in primary neurons to identify
cis-acting dendritic targeting signals in MAP2 mRNAs.
Different MAP2 cDNA fragments are inserted adjacent to the EGFP cDNA in
vector pNE. From pNEc a MAP2/EGFP fusion protein encoding mRNA is
transcribed, whereas in pNEcu and pNEu MAP2 sequences are inserted
downstream of the EGFP stop codon. Subcellular localization of chimeric
transcripts in primary neurons is determined by nonradioactive
in situ hybridizations with a digoxygenin-labeled RNA
probe complementary to EGFP sequences. ActP,
-actin promoter; EGFP, enhanced green fluorescent
protein; polyA, polyadenylation signal.
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In SCG cultures, vectors were microinjected into the nuclei of fully
differentiated neurons. The subcellular localization of reporter mRNAs
was monitored 4 hr after injection. In contrast, undifferentiated
hippocampal neurons were transfected with vector DNAs the day after
plating. Analysis of transcript distribution was performed ~2 weeks
after transfection. During this time neurons had developed axons,
dendrites, and synapses (Fig. 1).
Interestingly, despite these methodological differences, data obtained
with both cell systems are very similar. Control transcripts consisting
of the EGFP coding region fused to the entire -tubulin mRNA were
restricted to cell somata and proximal-most dendritic segments of
sympathetic (Fig. 3A) and
hippocampal neurons (Fig. 4A). This is consistent
with the observation that in both primary cultures endogenous
-tubulin transcripts are found only in neuronal cell bodies and the
basal parts of dendrites (Bruckenstein et al., 1990; Kleiman et al.,
1990). Next we examined two chimeric transcripts in which sequences
from the MAP2 coding region are fused to the EGFP mRNA. In the
first, the 5' UTR and the entire coding region of MAP2 transcripts are
located downstream of the EGFP sequence such that the MAP2 sequences
are not translated (vector pNEcu). These reporter mRNAs remained in the
cell soma (Figs. 3C, 4C). In the second, the MAP2
coding region is situated upstream and in frame with the EGFP sequence
(vector pNEc). These transcripts were also retained in the cell soma
(Figs. 3E, 4E). The ability of the latter
mRNAs to express a MAP2/EGFP fusion protein was confirmed by
transfecting the vector into HEK293 cells. As expected, an
autofluorescent protein decorated the microtubules of transfected cells
(data not shown). In contrast to the above results, reporter RNAs
carrying the entire MAP2 3' UTR downstream of the EGFP sequence were
found in dendrites of the majority of microinjected sympathetic and
transfected hippocampal neurons (vector pNEu) (Figs. 3G,
4G). The findings described above are summarized in Figure
5. Labeled cells were grouped into two
classes: (1) those exhibiting a "somatic" RNA distribution pattern
for which the in situ hybridization signal was restricted to
cell bodies and proximal-most sections of dendrites and (2) cells
showing "dendritic" localization of chimeric transcripts to parts
of at least one cell process that were farther away from the soma than one cell body diameter as measured from the base of the dendrite. On
the basis of these criteria, chimeric mRNAs containing the MAP2 3' UTR
were dendritically localized in ~60% of the evaluated sympathetic
and hippocampal neurons. In contrast, recombinant reporter transcripts
containing tubulin sequences or MAP2 5' untranslated and coding regions
almost exclusively exhibited a somatic distribution pattern (>96%).
In none of the microinjected or transfected cells were reporter
transcripts ever detected in axons. Taken together, these findings show
that MAP2 mRNAs are targeted selectively and specifically to dendrites
of sympathetic and hippocampal neurons. Dendritic localization of MAP2
transcripts is directed by cis-acting targeting elements
situated in the 3' UTR of the mRNAs and is not indirectly mediated
by an inherent dendritic targeting signal of the nascent MAP2
polypeptide chain.
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Figure 3.
In situ hybridization analysis of
the subcellular distribution of chimeric mRNAs in sympathetic neurons
after vector DNA injection into the nucleus. Bright-field (A, C,
E, G) and phase-contrast (B, D, F, H)
micrographs of cells injected with pNEtub (A, B), pNEcu
(C, D), pNEc (E, F), and pNEu
(G, H). In neurons shown in A-H,
reporter mRNAs were immunocytochemically detected using a
digoxigenin-labeled antisense EGFP probe and an alkaline
phosphatase-conjugated sheep anti-digoxigenin antibody. After the
addition of nitro blue tetrazolium and 5-bromo-4-chloro-3-indolyl
phosphate, a dark-colored reaction product was detectable. Chimeric
RNAs containing -tubulin sequences (A, B) or the MAP2
coding region (C, D, E, F) are restricted to cell
somata, whereas transcripts carrying the entire 3' UTR of MAP2 mRNAs
are found in dendrites (G, H). Images were
collected with a video camera connected to a Leitz microscope. Scale
bar, 50 µm.
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Figure 4.
Detection of chimeric transcripts in hippocampal
neurons after transfection with vector DNA. Bright-field (A, C,
E, G, I) and phase-contrast (B, D, F, H,
J) micrographs of neurons transfected with pNEtub
(A, B, I, J), pNEcu (C, D), pNEc
(E, F), and pNEu (G, H) are
shown. In A-H, neurons were hybridized
with a digoxigenin-labeled antisense EGFP probe. After incubation with
alkaline phosphatase-conjugated sheep anti-digoxigenin antibody, the
addition of nitro blue tetrazolium and 5-bromo-4-chloro-3-indolyl
phosphate resulted in a dark-colored reaction product in a small
fraction of the cells. Hybridization with a sense EGFP probe never
resulted in significant cell staining (I, J).
Recombinant transcripts with sequences of the MAP2 coding region
(C-F) or -tubulin mRNA (A, B)
are only detected in the cell soma. In contrast, chimeric mRNAs
possessing the entire 3' UTR of MAP2 transcripts are present in
dendrites (G, H). Cells were photographed with a
video camera attached to a Leitz microscope. Scale bar, 50 µm.
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Figure 5.
Subcellular distribution of chimeric transcripts
in sympathetic and hippocampal neurons. In the left
panel, the molecular structure of 9.6 kb MAP2 transcripts is
schematically indicated with black bars and
lines representing coding and noncoding regions,
respectively. Below, MAP2 sequences that are present in recombinant
mRNAs derived from the corresponding vectors are indicated as
heavy black bars. From pNEc, a MAP2/EGFP fusion protein
is synthesized (indicated by a black arrow), whereas the
MAP2 coding region in pNEcu transcripts is not translated into a
protein. The right panel lists the relative amount of
cells showing dendritic localization of chimeric transcripts in
sympathetic and hippocampal neurons and the total number of evaluated
cells per construct. In both types of transgenic primary neurons, only
recombinant mRNAs containing the MAP2 3' UTR are efficiently localized
to dendrites.
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The cis-acting dendritic targeting element resides in a
subregion of the 3' untranslated region
Because the 3' UTR of MAP2 mRNAs comprises ~3.74 kb (Kindler et
al., 1996), it seems likely that this region mediates additional functions besides transcript localization, such as RNA stability and
translation. To further delineate the cis-acting dendritic targeting element (DTE) in this region, we have expressed a number of
chimeric transcripts containing subfragments of the 3' UTR in both
sympathetic and hippocampal neurons. Data obtained with both primary
cell systems are summarized in Figure
6A.
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Figure 6.
A, Identification of a 640 nucleotide cis-acting DTE in the 3' UTR of MAP2
transcripts. In the left panel, regions of the MAP2 3'
UTR included in chimeric mRNAs transcribed from the corresponding
vectors are shown as heavy black bars. In the
right panel, the percentage of primary neurons
exhibiting dendritic mRNA localization patterns and the total number of
analyzed cells are shown. In parentheses, the total
number of analyzed coverslips/independent transfections of hippocampal
neurons are shown. Only chimeric transcripts containing a
640-nucleotide-long sequence highlighted in gray are
detected with high frequency in dendrites of sympathetic and
hippocampal neurons. Deletion of this targeting element omits dendritic
localization. B, Dendritic mRNA localization patterns of
several hybrid mRNAs. The histogram displays the relative amount of
cells that show their distal-most in situ staining in
the indicated ranges of distance from the soma. For each construct, 200 cells from two independent transfections of hippocampal neurons were
analyzed. In cells that exhibit a low frequency of dendritic mRNA
localization (pNEu2632-3071 and
pNEu2436-3071 transfected cells), recombinant
transcripts on average traveled less far into the cell processes than
in neurons with a high percentage of dendritic labeling (pNEu and
pNEu2432-3071).
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As a first step to further characterize the DTE, three overlapping mRNA
regions spanning most of the 3' UTR [Fig. 6A,
vectors pNEu181-1963, pNEu1586-3274,
pNEu2804-3728 (nucleotide numbering according to the
entire 3' UTR sequence)] were tested for their ability to mediate
dendritic localization of reporter transcripts. Interestingly, only
mRNAs containing nucleotides 1586-3274 were targeted into dendrites
with approximately the same frequency as transcripts possessing the
entire 3' UTR. In contrast, for mRNAs comprising nucleotides 181-1963
and 2804-3728 (pNEu181-1963 and
pNEu2804-3728), the relative amount of cells
showing dendritic mRNA targeting was dramatically decreased. Results
obtained with sympathetic and hippocampal neurons are similar, with a
slightly higher frequency of dendritic localization observed in
hippocampal cells (Fig. 6A). Thus, in MAP2
transcripts, essential signals for dendritic mRNA localization seem to
reside in the middle part of the 3' UTR (nucleotides 1586-3274). The relatively low, but in comparison to EGFP/-tubulin transcripts significantly higher, frequency of dendritic localization of mRNAs transcribed from vectors pNEu181-1963 and
pNEu2804-3728 (Fig. 6A) may
indicate that the corresponding subregions of the MAP2 3' UTR
contribute to transcript targeting, although to a minor extent.
To further outline DTE sequences, the targeting capacities of the 5'
and 3' parts of the RNA fragment spanning nucleotides 1586-3274 were
individually analyzed. Transcripts derived from pNEu2432-3274 were localized to dendrites with
high frequency, whereas mRNAs transcribed from
pNEu1586-2435 were predominantly restricted to
cell bodies of hippocampal and sympathetic neurons. When the
cis-active mRNA fragment spanning nucleotides 2432-3274 was
further divided into two halves (pNEu2432-2807
and pNEu2804-3274) or 200 nucleotide deletions
were made from either the 5' end (pNEu2632-3274) or from both ends (pNEu2632-3071), all four
resulting subfragments were unable to mediate significant dendritic
mRNA targeting. In contrast, deleting 200 nucleotides from the 3'
end (pNEu2432-3071) did not interfere with the
extrasomatic localization capacity of the resulting fragment (Figs.
6A,
7A,B,E,F).
Taken together, these data imply that a 640 nucleotide region
containing nucleotides 2432-3071 of the MAP2 3' UTR contains all
cis-acting signals sufficient for dendritic mRNA
localization. Further deletions from either the 5'
(pNEu2632-3071) or 3' end
(pNEu2432-2807) of this DTE dramatically
interferes with its extrasomatic targeting capacity, indicating that
the entire 640 nucleotide region is required to mediate transcript
localization into dendrites (Fig. 6A). The central
role of the DTE in dendritic mRNA targeting was further confirmed by
its deletion from the entire 3' UTR
(pNEu2436-3071). In contrast to
dendritically localized reporter transcripts containing the
entire 3' UTR (pNEu), mRNAs transcribed from
pNEu2436-3071 are primarily restricted to
cell somata (Figs. 6A, 7
C,D,G,H). Thus, a 640 nucleotide DTE situated in the 3' UTR of MAP2 mRNAs appears
to be sufficient and essential for their efficient localization into
dendrites of both sympathetic and hippocampal neurons. Cells expressing
pNEu2436-3071 transcripts exhibited a
slightly lower frequency of dendritic mRNA localization than neurons
that were transfected with the constructs
pNEu181-1963 and
pNEu1586-2435. This is a surprising observation
because all MAP2 mRNA sequences found in
pNEu181-1963 and
pNEu1586-2435 transcripts that may induce a
low-frequency dendritic localization are also present in
pNEu2436-3071 mRNAs. It is possible that the 640 nucleotide DTE deletion in pNEu2436-3071
transcripts induces a change in the secondary structure of the
remaining 3' UTR parts, thereby inhibiting a minor dendritic
localization capacity of these sequences.
View larger version (90K):
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[in a new window]
|
Figure 7.
In situ hybridization analysis of
the subcellular distribution of chimeric mRNAs in sympathetic
(A-D) and hippocampal neurons
(E-H). Bright-field (A-C, E-G)
and phase-contrast (D, H) micrographs of cells
expressing recombinant transcripts from pNEu2432-3071
(A, B, E, F) and pNEu2436-3071
(C, D, G, H) are shown. The 640 nucleotide DTE in
the MAP2 3' UTR is sufficient to mediate extrasomatic mRNA localization
in both neuronal cell types (A, B, E, F). Higher
magnification images shown as insets depict the
particulate nature of the color-reaction product of the nonradioactive
in situ hybridization in dendrites
(arrows). Deletion of the DTE from the 3' UTR omits the
dendritic targeting capacity (C, D, G, H). Images
were captured either with a video camera (A-D)
or on conventional film (E-H). C
and G are bright-field images of areas shown as
phase-contrast micrographs in D and H,
respectively. Scale bars: A, C,
E, 50 µm; B,
F, G, 20 µm.
|
|
To compare the dendritic distribution patterns of recombinant
transcripts exhibiting a low versus high frequency of dendritic localization, we have measured the distance between the base of the
dendrite and the distal-most RNA granule in hippocampal neurons transfected with four different constructs. The data summarized in
Figure 6B indicate that recombinant transcripts that
lead to a low dendritic localization frequency
(pNEu2632-3071 and pNEu2436-3071 mRNAs) tend to migrate less far
into dendrites than transcripts inducing a high percentage of dendritic
labeling (pNEu and pNEu2432-3071). This finding
shows that the DTE determines not only the amount of cells exhibiting
extrasomatic mRNA localization but also the mean dendritic transport distance.
Several lines of evidence suggest that a specific secondary RNA
structure may serve as a localization signal in different cell systems
(Macdonald, 1990; Chartrand et al., 1999). The mfold program (Zuker,
1989) was used to predict an optimal secondary structure for the
DTE on the basis of free energy minimization (Fig.
8). The predicted structure consists of
two stem-loop clusters (nucleotides 2436-2524 and 2610-3000 of the 3'
UTR) that are connected via a long double-stranded region (nucleotides
2544-2609 and 3002-3067). Future experiments will be necessary to
identify elements within this structure that are essential for
dendritic RNA localization.
View larger version (16K):
[in this window]
[in a new window]
|
Figure 8.
Predicted secondary structure of the dendritic
targeting element in rat MAP2 mRNAs. The structure was determined using
the mfold program 2.3 developed by Zuker (1989) included in the
Wisconsin Package (Genetics Computer Group, Madison, WI). The free
energy of the structure shown is 160.7 kcal/mol.
|
|
Dendritic mRNA granules
Microinjection of fluorescently labeled transcripts in cultured
oligodendrocytes (Ainger et al., 1993) and labeling of endogenous RNAs
in cultured hippocampal neurons with a fluorescent dye (Knowles et al.,
1996) imply that transport of mRNAs into cell processes occurs in the
form of distinct multimolecular complexes. Here we show that the
in situ hybridization signal in cell bodies of transfected
and microinjected primary neurons mostly exhibits a uniform
distribution. In contrast, dendritic labeling typically appears in the
form of granules scattered along the length of cell processes of both
sympathetic (Fig. 7A,B) and
hippocampal neurons (Fig.
7E,F). The patchy in
situ hybridization signal observed in dendrites may reflect a
discontinuous nature of the extrasomatic mRNA delivery apparatus, with
distinct moving mRNA granules, or alternatively, with transcripts
preferentially docking to particular binding sites along dendritic shafts.
| |
DISCUSSION |
We have used two assay systems based on primary neurons in culture
to analyze the molecular components involved in dendritic targeting of
MAP2 mRNAs. Our results show that dendritic translocation is a
selective process that depends on MAP2 mRNA sequences. These cis-elements specifically mediate dendritic but not axonal
mRNA targeting. Control transcripts containing -tubulin and EGFP
sequences were seen to be almost exclusively restricted to somata. The
data presented here demonstrate that neurons possess mechanisms to specifically target selected mRNAs into dendritic processes.
Our observation that the coding region of MAP2 mRNAs does not impart
extrasomatic localization capacity on nondendritictranscripts shows
that MAP2 transcript targeting into dendrites is not mediated indirectly by an inherent dendritic targeting signal of the nascent MAP2 polypeptide chain as has been proposed by Marsden et al. (1996).
Similarly, Wallace et al. (1998) showed that an inhibition of protein
synthesis with cycloheximide does not disrupt dendritic localization of
arc/arg3.1 transcripts in the intact rat brain. Here we show that
chimeric mRNAs containing the entire 3' UTR of MAP2 transcripts
localize to dendrites with high efficiency. This finding indicates that
this subregion of MAP2 transcripts contains cis-acting
signals for extrasomatic mRNA targeting. This is consistent with the
observation that in transgenic mice that express MAP2c transcripts
missing the 3' noncoding region, recombinant mRNAs were found to be
restricted to hippocampal cell bodies (Marsden et al., 1996). Moreover,
most cis-acting targeting sequences that have so far been
identified on mRNAs that undergo cytoplasmic localization in
non-neuronal cell systems are situated in 3' noncoding regions (St.
Johnston, 1995; Bassell and Singer, 1997; Steward, 1997; Kuhl and
Skehel, 1998). Thus, in addition to regulating transcript stability and
translation, for example, 3' UTR sequences may direct the spatial
distribution of mRNAs in different cell types.
To date, a limited number of studies to functionally characterize
cis-acting targeting sequences in dendritic mRNAs have been performed. Data obtained with a microinjection assay comparable to what
we have used here indicate that regions involved in the localization of
vasopressin transcripts into dendrites are redundant encompassing
sequences of the coding region and potentially the 3' UTR (Prakash et
al., 1997). Conversely, using a transgenic approach, the 3' UTR of
-CaMKII mRNAs has been shown to impart extrasomatic translocation
competence on normally nondendritic -galactosidase transcripts
(Mayford et al., 1996). Subsequent studies to further delineate the
exact sequence elements involved in dendritic mRNA localization have
not yet been performed. Here we present a study to functionally
identify a cis-acting DTE. Our results indicate that 640 nucleotides from the 3' UTR of MAP2 mRNAs are sufficient to mediate
efficient dendritic localization of chimeric reporter transcripts. Most
of this region seems to be essential for correct subcellular mRNA
localization because further deletions from both ends of the element
disrupt the targeting capacity. Interestingly, the DTE in MAP2
transcripts does not share any striking similarity with the 3' UTR
sequence of -CaMKII mRNAs (A. Blichenberg, S. Kindler, and D. Richter, unpublished observations) or the DTEs of vasopressin
transcripts (Rehbein et al., 1986; Prakash et al., 1997). Although the
existence of rather short conserved sequence stretches that perform a
specific cellular function cannot be excluded, different mRNA species
may use slightly distinct molecular means to couple to a dendritic transport system. This idea is supported by the observation that MAP2
and -CaMKII mRNAs exhibit diverse subcellular distribution patterns
in dendrites. In hippocampal neurons in brain, the relative amount of
MAP2 transcripts seems to decrease from proximal to distal regions
(Garner et al., 1988), whereas -CaMKII mRNAs appear to be evenly
distributed throughout the dendritic arbor (Burgin et al., 1990).
Using microinjection of radioactively labeled RNAs into sympathetic
neurons, the extrasomatic targeting sequences in the short, noncoding
BC1 RNA have been restricted to its 5' part containing approximately 62 nucleotides (Muslimov et al., 1997). This is the shortest sequence
element described so far that is capable of mediating dendritic
targeting of chimeric RNAs. Interestingly, the MAP2 DTE does not
possess any obvious sequence similarity with this region. The extent of
structural conservation within DTEs may become clearer when additional
localization elements of other extrasomatic RNAs will be characterized
in the future. In this context it seems important to point out that the
sequence of a DTE per se is probably not the most important feature for dendritic RNA localization. In contrast, secondary and higher-order RNA
structures may represent more essential determinants for extrasomatic transcript localization (Macdonald, 1990; Chartrand et al., 1999). A
computer-based prediction indicates that the DTE in MAP2 mRNAs has the
ability to form a complex secondary structure. Specific secondary
structures of other RNA regions have indeed been shown to perform
critical roles in specifying RNA-protein interactions and thus
specific cellular functions (Draper, 1995; Ferrandon et al., 1997; Conn
and Draper, 1998).
The DTE of MAP2 mRNAs functions in two distinct neuronal cell types,
namely primary sympathetic and hippocampal neurons. This finding
implies that the dendritic mRNA transport machinery is identical in
different neuronal cell types. Small divergences in the results
obtained with both primary cell systems either may indicate minor
differences in the molecular system underlying dendritic mRNA
localization or may be related to differences in methodology, such as
the developmental time point of vector DNA introduction into neurons.
In both cultured sympathetic and hippocampal neurons, chimeric mRNAs
exhibit a granular pattern in dendrites. This is in accordance with
several other studies using primary neuronal cell culture systems. In
cortical neurons, Knowles et al. (1996) visualized individual moving
granules in neurites after fluorescent labeling of the entire RNA
population. In sympathetic neurons, chimeric transcripts containing
sequences of dendritically localized BC1 or vasopressin RNAs were
observed to assemble into clusters along dendritic shafts (Muslimov et
al., 1997; Prakash et al., 1997). The endogenous -actin mRNA was
found to assemble into complexes in growth cones of early
differentiating hippocampal neurons (Bassell et al., 1998). Moreover,
after microinjection into cultured oligodendrocytes, fluorescently
labeled myelin basic protein mRNA forms granules that undergo
anterograde movement into cell processes (Ainger et al., 1993). Taken
together these observations imply that in distinct neuronal and
non-neuronal cells, mRNA molecules are delivered to cytoplasmic
subregions in the form of multimolecular transport complexes.
| |
FOOTNOTES |
Received May 19, 1999; revised July 20, 1999; accepted Aug. 5, 1999.
This research was supported by the Deutsche Forschungsgemeinschaft
(Ri191-19-1, Ri192-21-5). This work forms part of a thesis (A.B.).
Correspondence should be addressed to Stefan Kindler, Institute for
Cell Biochemistry and Clinical Neurobiology, University of Hamburg,
D-20246 Hamburg, Germany.
| |
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C. J. Mee, E. C. G. Pym, K. G. Moffat, and R. A. Baines
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P. Macchi, I. Hemraj, B. Goetze, B. Grunewald, M. Mallardo, and M. A. Kiebler
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Y. De Diego Otero, L.-A. Severijnen, G. van Cappellen, M. Schrier, B. Oostra, and R. Willemsen
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E. Mohr, N. Prakash, K. Vieluf, C. Fuhrmann, F. Buck, and D. Richter
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TOP
ABSTRACT
INTRODUCTION
