Post-Transcriptional Regulation of the GAP-43 Gene by Specific Sequences in the 3' Untranslated Region of the mRNA

PeproTech - Your Source for Neuroscience Research Reagents

QUICK SEARCH:

[advanced]

	Author:		Keyword(s):
Year:		Vol:		Page:

HOME | SEARCH | ARCHIVE | SUBSCRIBE | CONTACT | HELP

This Article

Abstract

Full Text (PDF)

Submit an eLetter

Alert me when this article is cited

Alert me when eLetters are posted

Alert me if a correction is posted

Citation Map

Services

Email this article to a friend

Similar articles in this journal

Similar articles in ISI Web of Science

Similar articles in PubMed

Alert me to new issues of the journal

Download to citation manager

Citing Articles

Citing Articles via HighWire

Citing Articles via ISI Web of Science (55)

Citing Articles via Google Scholar

Google Scholar

Articles by Tsai, K.-C.

Articles by Perrone-Bizzozero, N. I.

Search for Related Content

PubMed

PubMed Citation

Articles by Tsai, K.-C.

Articles by Perrone-Bizzozero, N. I.

Previous Article  |  Next Article

Volume 17, Number 6, Issue of March 15, 1997 pp. 1950-1958
Copyright ©1997 Society for Neuroscience

Post-Transcriptional Regulation of the GAP-43 Gene by Specific Sequences in the 3 $'$ Untranslated Region of the mRNA

Kao-Chung Tsai¹, Victor V. Cansino¹, Douglas T. Kohn¹, Rachael L. Neve², and Nora I. Perrone-Bizzozero¹
¹ Departments of Biochemistry and Neuroscience and Cancer Center, University of New Mexico School of Medicine, Albuquerque, New Mexico 87131, and ² McLean Hospital, Departments of Psychiatry and Genetics, Harvard Medical School, Boston, Massachusetts 02115

ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
FOOTNOTES
REFERENCES

ABSTRACT

We have shown previously that GAP-43 gene expression during neuronal differentiation is controlled by selective changes inmRNA stability. This process was found to depend on highly conservedsequences in the 3 $'$ untranslated region (3 $'$ UTR) of the mRNA.To map the sequences in the GAP-43 3 $'$ UTR that mediate this post-transcriptionalevent, we generated specific 3 $'$ UTR deletion mutants and chimeraswith the $beta$ -globin gene and measured their half-lives in transfectedPC12 cells. Our results indicate that there are two distinct instability-conferringelements localized at the 5 $'$ and 3 $'$ ends of the GAP-43 3 $'$ UTR.Of these destabilizing elements, only the one at the 3 $'$ end isrequired for the stabilization of the mRNA in response to treatmentwith the phorbol ester TPA. This 3 $'$ UTR element consists of highlyconserved uridine-rich sequences and contains specific recognitionsites for two neural-specific GAP-43 mRNA-binding proteins. Analysisof the levels of mRNA and protein derived from various 3 $'$ UTRdeletion mutants indicated that all mutants were translated effectivelyand that differences in gene expression in response to TPA wereattributable to changes in GAP-43 mRNA stability. In addition,the phorbol ester was found to affect the binding of specificRNA-binding proteins to the 3 $'$ UTR of the GAP-43 mRNA. Given that,like the GAP-43 mRNA, its degradation machinery and the GAP-43mRNA-binding proteins are expressed primarily in neural cells,we propose that these factors may be involved in the post-transcriptionalregulation of GAP-43 gene expression during neuronal differentiation.
Key words: GAP-43; post-transcriptional regulation; gene expression; neuronal differentiation; mRNA stability; RNA-binding proteins; PC12 cells

INTRODUCTION

The growth-associated protein GAP-43 is expressed in neurons primarily during the development and regeneration of neural connections(for review, see Benowitz and Routtenberg, 1987; Skene, 1989).After synaptogenesis, GAP-43 expression declines sharply in mostneuronal populations except for those in specific associationareas in the neocortex and limbic system (Benowitz et al., 1988;Neve et al., 1988). GAP-43 is known to participate both in mechanismsof axonal pathfinding during neural development and in the regulationof neurotransmitter release and synaptic plasticity in maturesynapses (Dekker et al., 1989; Aigner and Caroni, 1993; Ivinset al., 1993; Meberg et al., 1995; Strittmatter et al., 1995).Given the important biological properties of this protein, itis of great interest to define the mechanisms that control thedevelopmental pattern and regional variations in GAP-43 gene expression.Findings by several laboratories clearly indicate that neuralspecificity in the expression of this gene is controlled by elementsin the promoter region (Nevidi et al., 1992; Verhaagen et al.,1993; Starr et al., 1994; Vanselow et al., 1994). A second levelof control of GAP-43 gene expression is mediated by post-transcriptionalmechanisms (Federoff et al., 1988; Perrone-Bizzozero et al., 1991,1993). The induction of the GAP-43 mRNA during brain developmentand nerve regeneration does not correlate well with its rate oftranscription (Perrone-Bizzozero et al., 1991). Furthermore, inundifferentiated PC12 cells, the gene is transcribed constitutively,although the steady-state levels of the GAP-43 mRNA are very low.The apparent discrepancy between the rates of synthesis and theaccumulation of the GAP-43 mRNA in PC12 cells was found to beattributable to the intrinsic instability of the mRNA. In contrast,when cells are induced to differentiate in response to NGF, theGAP-43 mRNA is stabilized selectively via protein kinase C-dependentmechanisms (Perrone-Bizzozero et al., 1993). These results areconsistent with the idea that changes in mRNA stability play acrucial role in the control of GAP-43 gene expression.

To define the molecular basis for the control of GAP-43 mRNA stability, we began to examine the cis- and trans-acting factorsinvolved in this process. We found that the GAP-43 3 $'$ UTR is highlyconserved and contains major determinants for mRNA instability(Kohn et al., 1996a). Unlike such determinants in other post-transcriptionallyregulated mRNAs (Shaw and Kamen, 1986; Shyu et al., 1991), thesesequences do not contain AUUUA motifs but exhibit multiple U-richstretches. We recently have shown that these U-rich regions containrecognition sites for three brain-specific RNA-binding proteins(Kohn et al., 1996a). The finding that their binding activityand the levels of the GAP-43 mRNA are correlated spatially andtemporally further suggests that these proteins may be involvedin the post-transcriptional regulation of GAP-43 gene expression(Kohn et al., 1996a).

In this study we sought to investigate the specific elements in the 3 $'$ UTR of the GAP-43 mRNA that contribute to its post-transcriptionalregulation. Analysis of the half-life of several 3 $'$ UTR deletionmutants and chimeras with the $beta$ -globin gene revealed that a U-richelement in the 3 $'$ end of the GAP-43 3 $'$ UTR controls both the intrinsicinstability of the mRNA in undifferentiated PC12 cells and thespecific stabilization of the mRNA in response to phorbol estertreatment. This region also contains recognition sites for twobrain-specific GAP-43 mRNA-binding proteins. Our results suggestthat RNA protein interactions between these proteins and theircognate sequences in the GAP-43 3 $'$ UTR may contribute to the controlof GAP-43 gene expression during neuronal differentiation.

MATERIALS AND METHODS
Cell culture and transfection studies As in previous studies, mRNA stability assays were performed in the GAP-43-deficient cell clone PC12-N36 (Kohn et al., 1996a).This line does not express detectable levels of the GAP-43 mRNAor protein (Perrone-Bizzozero et al., 1994). PC12-N36 cells weretransfected with GAP-43 cDNAs in the expression vector pMEP4 (Invitrogen,San Diego, CA) by electroporation. Briefly, cells were resuspendedin 1× HeBS buffer (137 mM NaCl, 5 mM KCl, 0.7 mM Na₂HPO₄, 6 mMdextrose, and 20 mM HEPES, pH 7.05) containing 20 µg of recombinantplasmid DNA and 380 µg of salmon testis DNA as carrier. The cellsuspension was electroporated under 250 V and 960 µF in a GenePulser apparatus (Bio-Rad, Richmond, CA). Then cells were platedin complete medium for 24 hr, and the selection was initiatedwith 100 µg/ml hygromycin-B for 2 weeks, followed by 150 µg/mlthereafter. Once cells were selected, they were used for mRNAdecay experiments as described below. To compare the variationsof mRNA stability in different cell lines, we also transfectedconstructs into the human neuroblastoma cell line SH-SY5Y andthe monkey kidney cell line COS-7. SH-SY5Y and COS-7 cells werecultured in Eagle's minimal essential medium. The complete mediumincluded 10% fetal calf serum, 2 mM L-glutamine, 75 U/ml penicillin,and 75 µg/ml streptomycin.
Plasmid preparation Deletion mutants and point mutations. To investigate the sequences in the 3 $'$ UTR that regulate GAP-43 mRNA stability, we generatedseveral 3 $'$ UTR deletion mutants and chimeras with a rat full-lengthGAP-43 cDNA clone (GA11B; Neve et al., 1987). BstYI digestionof this clone created three fragments $---$ A, C, and B (in 5 $'$ to 3 $'$ orientation). Fragment A contains the GAP-43 5 $'$ UTR coding regionand 62 bases of the 3 $'$ UTR downstream of the stop codon. C contains114 base pairs (bp) of the 3 $'$ UTR downstream of A and is followedby B (225 bp) (see Fig. 1). These fragments were ligated to createthe A, AC, and AB constructs in pGEM3Z (Promega, Madison, WI)and subsequently were digested with EcoRI/BamHI and cloned intothe PvuII site of pMEP4. The $Delta$ 3 $'$ UTR construct was prepared fromthe GA11B GAP-43 cDNA by deleting its 3 $'$ UTR at the NspI site.Re-ligation of this plasmid created a new stop codon 12 basesdownstream of the NspI site. The construct D40 was made by deleting21 bp 5 $'$ and 19 bp 3 $'$ of the stop codon in the GAP-43 cDNA. TheU3 construct was created by PCR-mediated site-directed mutagenesis(Neve and Neve, 1995), in which five U residues were replacedby A residues in three A/GUUUG/C stretches within the B fragment(⁹³⁹AUUUGUUUC to AUAUGUAUC, ⁹⁶⁵GUUUUUG to GUUAUUG and ¹⁰⁰⁰GUUUUUUG to GUAUAUUG; see Fig. 1). D40 and U3 werecloned into the SpeI/SalI sites of pBluescript II SK⁺ (pBSKII⁺; Stratagene, La Jolla, CA), digested with XbaI and XhoI, andcloned into the NheI/XhoI sites in pMEP4. The construct containingthe coding region of rabbit $beta$ -globin gene was prepared from pRSV-globin(Gorman et al., 1983) by digestion with HindIII and BglII. Thisfragment then was cloned into pMEP4.
Fig. 1. Schematic representation of the wild-type GAP-43 cDNA and of several 3 $'$ UTR deletion mutants and chimeras. A, The restrictionmap shown in the wild-type construct (WT) corresponds to the full-lengthrat GAP-43 cDNA (GA11B; Neve et al., 1987) that was used to generatethe various constructs. Segments represent the different fragmentscreated by restriction enzyme digestion. Chimeras were generatedby a combination of these fragments with the $beta$ -globin coding region.B, Sequence of the GAP-43 3 $'$ untranslated region (3 $'$ UTR) of theGAP-43 cDNA. The sequences in the B region are indicated in italics,and the three regions in U3, including five point mutations, areunderlined.
[View Larger Version of this Image (54K GIF file)]

Chimeras. Several chimeras of the rat GAP-43 3 $'$ UTR and the $beta$ -globin gene were prepared. The C1 chimera contains the codingregion of rabbit $beta$ -globin and the 3 $'$ UTR of GAP-43. Trans-PCR(Neve and Neve, 1995) was used to delete the GAP-43 coding regionand introduce HindIII/BglII sites between the 5 $'$ and 3 $'$ UTRs.The coding region of $beta$ -globin (from pRSV-globin) was ligated tothe HindIII/BglII site, after which the C1 chimera was releasedfrom pBSKII⁺ and cloned into XhoI/NheI-digested pMEP4. In addition, two chimericconstructs were prepared by linking the rabbit $beta$ -globin codingregion with either the B fragment (globin-B), or the C fragment(globin-C), of GAP-43 3 $'$ UTR. To generate these chimeras, we excisedthe GAP-43 3 $'$ UTR from the C1 chimera in pBSKII⁺ by digestion with BglII andClaI. Then the B and C fragments werecloned into the BglII/ClaI sites of this construct to create globin-Bor globin-C in pBSKII⁺. These chimeric cDNAs were excised out and cloned into the XhoI/NheIsites of pMEP4 as described above. The C2 chimera contained thecoding region of GAP-43 flanked by the $beta$ -globin 5 $'$ and 3 $'$ UTRsfrom pSP64T (a gift from Dr. D. A. Melton, Harvard University,Cambridge, MA; Krieg and Melton, 1984). The plasmid was digestedwith BglII to separate the $beta$ -globin 5 $'$ and 3 $'$ UTRs, after whichthe coding region of GAP-43 was inserted into the BglII site.The resulting construct then was digested with HindIII/BamHI andcloned into the same restriction sites of the expression vectorpMEP4.
mRNA stability analysis Studies on the stability of the various mRNAs were performed as described by Kohn et al. (1996a). Once cultures reached 75-85%confluency, cells were induced for 16 hr in the presence of 5µM CdCl₂. Exposure to this metal ion causes an 8- to 10-fold activationof the human metallothionein-II_A promoter in the pMEP4 vector(Richards et al., 1984). After induction, cadmium was washed out,and cells were collected at various time points. In some studies,cultures were treated with various agents, including 12-O-tetradecanoylphorbol-13-acetate(TPA; 160 nM), polymyxin B (2000 U/ml), and nerve growth factor(NGF; 100 ng/ml). Samples containing 15 µg of cytosolic RNA wereprocessed for Northern blot analysis as described by Perrone-Bizzozeroet al. (1993). Blots were probed with labeled cDNAs for GAP-43, $beta$ -globin (Gorman et al., 1983), or glyceraldehyde-3-phosphatedehydrogenase (G3PD). The intensity of the mRNA band was determinedby densitometry with the FotoAnalyst system (Fotodyne, New Berlin,WI) within the linear range of response. Optical densities ofthe GAP-43 bands were corrected by those of G3PD. As we have shownpreviously (Perrone-Bizzozero et al., 1993), the decay of theGAP-43 mRNA follows an exponential function, M_o = M_te^t (in which $lambda$ = ln2/T_1/2). The half-life (T_1/2) of the variousGAP-43 transcripts was calculated from the plot of relative mRNAlevels versus time of decay by using linear regression analysis.
Western blot analysis Western blots were used to verify that the mRNAs derived from the various GAP-43 3 $'$ UTR deletion mutants were translated effectivelyinto GAP-43 protein. For these studies, total RNA and proteinwere extracted from permanently transfected PC12-N36 with theTri reagent (Sigma, St. Louis, MO), and samples were processedfor Northern and Western blot analysis. Aliquots containing 50µg of protein were separated on 10% polyacrylamide gels and electrotransferredonto polyvinylidene fluoride membranes. GAP-43 levels were detectedby a polyclonal antibody to rat GAP-43 as previously described(Sower et al., 1995).
In vitro RNA-binding studies Analyses of the interactions between brain cytosolic proteins and different subregions of the GAP-43 3 $'$ UTR were performedas described by Kohn et al. (1996a). Briefly, the GAP-43 3 $'$ UTRand the B fragment were subcloned into pGEM3Z and used to generate³²P-labeled sense RNA by in vitro transcription with SP6 and T7RNA polymerases. In vitro RNA-binding studies were performed with0.5 ng of labeled RNA (5 × 10⁴ cpm) and 50 µg of brain cytosolic protein (S100 fraction). RNAprotein complexes were cross-linked by irradiation for 30 minat 4°C at 4 cm from a UV lamp (Sylvania G30T8, 254 nm). UV cross-linkedcomplexes were digested with RNase A, and labeled proteins wereanalyzed by 10% polyacrylamide gel electrophoresis and autoradiography.In some experiments, protein extracts were prepared from controland TPA-induced PC12 cells and used in RNA-binding assays as indicatedabove.

RESULTS

The main determinants of GAP-43 mRNA instability are localized in the 3 $'$ UTR
We previously showed that the GAP-43 3 $'$ UTR is highly conserved in evolution and that this region seems to control mRNA turnovervia its specific interactions with three brain-specific RNA-bindingproteins (Kohn et al., 1996a). To characterize the role of specificsequences within the GAP-43 3 $'$ UTR in mRNA stability, we generateda series of 3 $'$ UTR deletion mutants and chimeras of the GAP-43and $beta$ -globin cDNAs in the expression vector pMEP4 (Fig. 1). Thestability of these constructs was tested in transfected PC12-N36cells (Perrone-Bizzozero et al., 1994). This GAP-43-deficientPC12 cell line enables the determination of the stability of transfectedGAP-43 transcripts without the interference of the endogenousmRNA (Kohn et al., 1996a). Northern blots from representativemRNA decay studies are shown in Figures 2A and 3. The use of aninducible promoter allows for the determination of mRNA turnoverwithout disturbing the intracellular environment with transcriptioninhibitors (Chen et al., 1995; Kohn et al., 1996a). Although themetallothionein promoter exhibits a small level of basal activity(control lanes, Figs. 2, 3, 4), on stimulation with cadmium thereis an 8- to 10-fold increase in the rate of transcription andmRNA accumulation (time 0 lanes, Figs. 2, 3, 4). After cadmiuminduction, mRNA decay rates are examined in the absence of themetal ion. Under these conditions the transfected full-lengthGAP-43 mRNA decayed with a half-life of 5 hr (WT, Fig. 2B andTable 1), consistent with the stability of the endogenous mRNA(Perrone-Bizzozero et al., 1993). On deletion of the 3 $'$ UTR, thehalf-life of the mRNA increased threefold ( $Delta$ 3 $'$ UTR mutant, Fig.2), indicating that this region contains the main determinantsfor mRNA instability. The destabilizing effect of these sequenceswas confirmed by addition of the GAP-43 3 $'$ UTR to the $beta$ -globinmRNA. The globin mRNA is very stable, with reported half-lifevalues ranging from 17 to >50 hr (Aviv et al., 1976; Volloch andHousman, 1981). However, ligation of the GAP-43 3 $'$ UTR to the $beta$ -globin coding region (C1 construct, Fig. 2) made this otherwisestable mRNA become unstable, with a half-life of ~5 hr similarto the half-life of wild-type GAP-43 mRNA (Table 1). Finally,the opposite effect was observed on ligation of the 3 $'$ UTR ofglobin to the GAP-43 coding sequence (C2 chimera). Although deletionof the 3 $'$ UTR ( $Delta$ 3 $'$ UTR) significantly increased the stabilityof the GAP-43 mRNA, the half-life of the mRNA became even longer(T_1/2 = 19 hr) when the GAP-43 coding region was linked to the3 $'$ UTR of $beta$ -globin (Fig. 2, Table 1).
Fig. 2. Role of the GAP-43 3 $'$ UTR on mRNA stability. PC12-N36 cells were transfected with a rat full-length GAP-43 cDNA construct(WT), a deletion mutant without the 3 $'$ UTR ( $Delta$ 3 $'$ UTR), or chimeraswith the $beta$ -globin cDNA (C1 and C2; see Fig. 1). Cells were incubatedwith cadmium to induce high levels of transfected mRNAs. For mRNAdecay studies, RNAs were isolated from cells harvested at thetime points indicated after removal of cadmium. Control lanes(Co) show the basal levels of the transfected mRNA in the absenceof the metal. A, Northern blots from representative mRNA decayexperiments: analysis was performed with 15 µg of cytosolic RNA.The same membrane was probed for GAP-43 first and then reprobedfor G3PD. B, mRNA decay curves. GAP-43 mRNA levels were determinedby densitometry, corrected by those of G3PD, and expressed relativeto those before the decay phase (time 0).
[View Larger Version of this Image (36K GIF file)]

Fig. 3. Analysis of the stability of the different GAP-43 3 $'$ UTR deletion mutants and chimeras with the $beta$ -globin cDNA in transfectedcells. PC12-N36 cells were transfected with various constructsin the expression vector pMEP4, and mRNA decay studies were performedas indicated in Figure 2. Northern blots show the rate of decayof different GAP-43 3 $'$ UTR deletion mutants and chimeras. Blotswere probed with either GAP-43 (A) or $beta$ -globin (B) cDNAs and reprobedwith G3PD to control for RNA loading. The structure of each constructis shown in Figure 1.
[View Larger Version of this Image (77K GIF file)]

Fig. 4. Effect of three U-rich regions in GAP-43 3 $'$ UTR and the region surrounding the stop codon on GAP-43 mRNA stability. A, Northernblots show the decays of the wild-type and mutant U3 and D40 constructs.B, mRNA decay curves indicate that neither the five U by A replacementsin U3 nor the deletion of 40 nt in D40 has any effect in the rateof decay of the mRNA.
[View Larger Version of this Image (32K GIF file)]

Table 1. Half-lives of the GAP-43 mRNA and various 3 $'$ UTR mutants and chimeras

Construct Mean ± SD p value

WT 4.99 ± 0.42 (n = 9)

A. 3 $'$ UTR mutants

$Delta$ 3 $'$ UTR 14.58 ± 1.97 (n = 6) p < 0.001^*

A 8.50 ± 1.01 (n = 5) p < 0.02^*

AC 9.55 ± 0.38 (n = 5) p < 0.01^*

AB 6.55 ± 0.81 (n = 8) NS

D40 4.44 ± 0.61 (n = 5) NS

U3 5.77 ± 0.53 (n = 5) NS

B. Chimeras

Globin 10.50 ± 1.51 (n = 13)

C1 5.53 ± 0.52 (n = 10) p < 0.01^**

C2 19.35 ± 4.14 (n = 5) p < 0.01^*

Globin-C 14.60 ± 2.08 (n = 4) p < 0.05^**

Globin-B 5.93 ± 1.50 (n = 7) p < 0.01^**

^* p values relative to WT; ^** p values relative to globin. NS, Nonsignificant.

Two cis-acting elements in the 3 $'$ UTR regulate GAP-43 mRNA instability
Having demonstrated the destabilizing effect of the whole GAP-43 3 $'$ UTR, we sought to map the instability determinants byusing a series of 3 $'$ UTR deletion mutants and chimeras with the $beta$ -globin gene. Initial studies involved the analysis of differentfragments derived from the GAP-43 3 $'$ UTR (Fig. 1). Combinationsof these fragments (A, AB, and AC) were cloned into the expressionvector pMEP4, and the stability of the corresponding mRNAs wastested in transfected PC12-N36 cells. Among these constructs,A was found to decay with a half-life of 8.5 hr (Fig. 3A, Table1), which was significantly shorter than that of the mRNA lackingits 3 $'$ UTR ( $Delta$ 3 $'$ UTR construct) but longer than that of the full-lengthmRNA (WT). Addition of the C fragment to the 3 $'$ end of A did notchange the half-life significantly (T_1/2 = 9.5 hr, Table 1).In contrast, addition of the B fragment shortened the half-lifeof the resulting AB mRNA to a level comparable to that of thewild-type GAP-43 mRNA (T_1/2 = 6.5 hr, Table 1). These resultsindicate that there are at least two cis-acting instability-conferringelements within the GAP-43 3 $'$ UTR. One element is ~60 nucleotides(nt) long and is localized at the 5 $'$ end of the GAP-43 3 $'$ UTR(A fragment). The other determinant is 250 nt long and residesat the terminal 3 $'$ end of the 3 $'$ UTR (B fragment). It also isworth noting that fragment C contains a single AUUUA motif adjacentto a poly(A) stretch. Unlike other AU motifs (Shaw and Kamen,1986), this element is not present in a U-rich region and doesnot confer instability to the GAP-43 mRNA.

To investigate further the destabilizing effect of the B fragment, we created a chimeric construct by linking the B fragmentto the $beta$ -globin coding region; this was designated globin-B (Fig.3B). To control for specificity, we also ligated the C fragmentto the $beta$ -globin coding region (globin-C). Addition of the B fragmentto the $beta$ -globin coding region significantly decreased the stabilityof the globin transcript (T_1/2 = 6 hr, Table 1), confirming therole of this region as a destabilizing element in the GAP-43 mRNA.In contrast, the globin-C mRNA showed a slightly longer half-life(T_1/2 = 14.5 hr) than that of the $beta$ -globin coding region (T_1/2= 10.5 hr), suggesting that the C fragment has a stabilizing,rather than destabilizing, effect on the mRNA.

Recent studies indicate that the function of certain instability-conferring elements in the 3 $'$ UTRs depends on the presenceof stretches of three or more adjacent U residues within them(Chen et al., 1995; Zubiaga et al., 1995). Given that the destabilizingB fragment contains several U-rich stretches and that these motifsare highly conserved (Kohn et al., 1996a), subsequent studiesexamined the role of these motifs in GAP-43 mRNA stability. FiveU residues within three U-rich stretches in the B fragment weremutated to A by site-directed mutagenesis to generate the U3 mutant(Fig. 1). When tested in mRNA decay studies, the U3 mRNA showeda half-life of ~6 hr, similar to that of the wild-type GAP-43mRNA (Fig. 4). Thus, although the three A/GUUUG/C motifs withinthe B fragment were reasonable candidates to mediate the destabilizingeffect of this region, mutations in these elements did not affectthe half-life of the mRNA. These results are in agreement witha recent finding that similar point mutations in GUUUUUG motifsin the c-jun mRNA do not affect mRNA stability (Peng et al., 1996)and suggest that other regions within the B fragment mediate thiseffect.

It has been shown that the stop codon and its flanking sequences may affect the half-life of mRNA (Belgrader et al., 1994).To test whether these sequences contribute to the instabilityof the A region, we generated the D40 mutant. This construct containeda deletion of 21 nucleotides upstream and 19 downstream of thestop codon, resulting in the net loss of 40 nucleotides withinthe A region (Fig. 1). The half-life of the D40 construct wassimilar to that of the wild-type mRNA in transfected PC12-N36cells (T_1/2 = 4.5 hr, Table 1), suggesting that this region doesnot contribute to the intrinsic instability of the GAP-43 mRNAin undifferentiated PC12 cells. These results are in contrastwith a recent study in which the region surrounding the stop codonin the GAP-43 mRNA was found to control GAP-43 mRNA stabilityin NGF-induced PC12 cells [Nishizawa and Okamoto (1994); see Discussion].

In summary, the results of our initial characterization of the determinants of GAP-43 mRNA stability indicated that the maininstability determinants are localized in the 3 $'$ UTR. As shownin Figure 5 and Table 1, the presence or absence of these elementsresults in a threefold variation in the half-life of the GAP-43mRNA. These GAP-43 3 $'$ UTR sequences were also equally effectivewhen they were linked to the $beta$ -globin coding sequence, suggestingthat their function is independent of the particular coding regionto which they are attached. On the basis of these findings, wepropose that the A and B regions of the GAP-43 3 $'$ UTR containthe main determinants for the instability of the mRNA in undifferentiatedPC12 cells.
Fig. 5. Analysis of the stability of the wild-type GAP-43 mRNA and several 3 $'$ UTR mutants in PC12-N36 cells. mRNA decay assays wereperformed in stably transfected PC12-N36 cells, as described inFigure 2. The relative levels of the GAP-43 mRNA at differentdecay times were calculated by densitometric analysis of Northernblots and were corrected by the levels of G3PD in the same sample.The plot shows representative decay curves for the wild-type GAP-43mRNA (WT), the AC, AB, and A mutants, and the Globin-B and Globin-Cchimeras.
[View Larger Version of this Image (26K GIF file)]

Role of 3 $'$ UTR sequences in the TPA-mediated stabilization of the GAP-43 mRNA
We showed previously that NGF and the phorbol ester TPA induce GAP-43 gene expression in PC12 cells by causing selective changesin the stability of the mRNA (Perrone-Bizzozero et al., 1991,1993). To begin to identify the specific mRNA sequences mediatingthis response, we tested the effect of TPA on the induction andstability of the full-length GAP-43 mRNA in transfected PC12-N36cells. As shown in Figure 6A, both TPA and NGF caused the inductionof the transfected GAP-43 mRNA, with the phorbol ester showinga more robust induction. Thus, as shown for the endogenous GAP-43mRNA, the transfected mRNA exhibits a more rapid and powerfulinduction with TPA than with NGF, although both agents use thesame signal transduction pathway to elicit this response (Perrone-Bizzozeroet al., 1993). With regard to the mechanism of this induction,we found that the half-life of the transfected mRNA was prolongedthreefold by the phorbol ester (Fig. 6B) and was decreased significantlyby the protein kinase C inhibitor polymyxin B (Fig. 6A). Additionof the transcription inhibitor DRB did not affect the responseto TPA, but in agreement with previous studies (Perrone-Bizzozeroet al., 1991; Chen et al., 1995), DRB was found to increase thehalf-life of the mRNA in control cells. Thus, the transfectedGAP-43 mRNA was found to behave similarly to the endogenous mRNAin that it was stabilized by PKC activators and transcriptioninhibitors and destabilized by PKC inhibitors (Perrone-Bizzozeroet al., 1991, 1993).
Fig. 6. TPA causes the induction and stability of the GAP-43 mRNA in transfected PC12-N36 cells. A, Northern blots demonstrate thelevels of induction and stability of the transfected wild-typeGAP-43 mRNA in PC12-N36 cells. For the induction phase, cellswere treated for 16 hr in the presence of NGF (NGF; 100 ng/ml),TPA (TPA; 160 nM), or CdCl₂ (Cd; 5 µM). For the decay phase, aftercadmium induction, cells were washed out of the metal ion andincubated for 6 hr in the presence (+DRB) or absence of DRB (60µM) and TPA (160 nM) or polymyxin B (PB; 2000 U/ml). B, Cellswere induced for 16 hr with either Cd²⁺ (filled squares) or TPA and Cd²⁺ (open squares), and mRNA decay assays were performed in the presenceor absence of 160 nM TPA. The relative half-lives of the mRNAwere calculated as described in Materials and Methods.
[View Larger Version of this Image (34K GIF file)]

To map the cis-acting elements that contribute to the response to TPA, we evaluated GAP-43 mRNA and protein levels in PC12-N36cells transfected with the 3 $'$ UTR deletion mutants A, AC, andAB (Fig. 7A,B). Comparison of cadmium-induced and basal levelsof expression of these constructs indicated that, first, all ofthe constructs produced mRNAs that were translated adequatelyinto GAP-43 protein and, second, the accumulation of GAP-43 proteinparalleled that of the mRNA of each construct and responded asexpected to cadmium stimulation. Analysis of the levels of GAP-43protein and mRNA in the presence of TPA revealed that the phorbolester caused a threefold induction in GAP-43 expression in cellstransfected with the AB construct. In contrast, phorbol estertreatment had no effect on the expression of the A construct,whereas it decreased the expression of the AC mRNA (Fig. 7C).These effects are not likely to be exerted at the level of translation,because both GAP-43 mRNA and protein levels were affected similarlyby TPA. Comparison of the response of the A, AC, and AB mutantsto phorbol ester treatment indicates clearly that the specificelements responsible for the TPA-mediated stabilization of theGAP-43 mRNA are contained within the B fragment.
Fig. 7. Effect of TPA on GAP-43 mRNA and protein levels in PC12-N36 cells transfected with different 3 $'$ UTR mutants. A, B, Northern(A) and Western (B) blots show GAP-43 mRNA and protein levelsin permanently transfected control cells (Co) or in cells inducedfor 16 hr with cadmium (Cd) or phorbol ester (TPA), as describedin Figure 6. The levels of G3PD in Northern blots and tubulinin Western blots are presented as controls for gel loading. C,Relative induction of the GAP-43 mRNA and protein in TPA-treatedPC12-N36 cells. The levels of induction of each construct representthe mean of at least three independent experiments.
[View Larger Version of this Image (50K GIF file)]

Trans-acting factors for the control of GAP-43 mRNA stability
Like transcriptional regulation, the control of mRNA stability is thought to involve both cis- and trans-acting factors (Malteret al., 1989; Brewer, 1991). We previously identified potentialtrans-acting factors affecting GAP-43 mRNA stability (Kohn etal., 1996a). These are three developmentally regulated RNA-bindingproteins that interact with highly conserved polypyrimidine-richsequences in the GAP-43 3 $'$ UTR. Because both the GAP-43 mRNA andthese RNA-binding proteins are selectively localized to the nervoussystem (Kohn et al., 1996a), we hypothesized that the factorscontrolling GAP-43 mRNA stability are neuronal-specific. To testthis idea, we compared the stability of the mRNA in neuronal andnon-neuronal cells (Fig. 8). When transfected into PC12 cells,the GAP-43 mRNA exhibited a significantly faster turnover rate(T_1/2 = 5 hr) than it did when transfected into non-neuronal COS-7cells (T_1/2 = 13 hr, Fig. 8). A similar increase in mRNA stabilitywas observed when the AB and AC mutants were transfected intoCOS-7 cells (data not shown). Analysis of the stability of theGAP-43 mRNA in another neural cell line, the human neuroblastomaSH-5ySy, indicated that the mRNA decayed with a half-life similarto that observed in PC12 cells (Perrone-Bizzozero et al., 1994).Because the GAP-43 mRNA binding proteins are expressed selectivelyin brain and neural cell cultures (Kohn et al., 1996a) (see alsoFig. 9 below), our results are consistent with the idea that prolongedhalf-life of the GAP-43 mRNA in non-neural COS-7 cells may beattributable to the absence of one or more of the neuronal-specificGAP-43 mRNA-binding proteins.
Fig. 8. Comparative analysis of the half-life of the GAP-43 mRNA in COS-7 cells. Northern blots show the decay of the transfectedwild-type GAP-43 mRNA in PC12-N36 cells and non-neural COS-7 cells.The half-life of the mRNA was found to be ~2.5-fold shorter inthe neural lines than in COS-7 cells.
[View Larger Version of this Image (33K GIF file)]

Fig. 9. Detection of GAP-43 mRNA-binding proteins by UV cross-linking experiments. A, ³²P-labeled RNAs containing the entire GAP-43 3 $'$ UTR (GAP/3 $'$ ) orthe B region (GAP/B) were synthesized in vitro, as described byKohn et al. (1996a). RNAs (0.5 ng, 5 × 10⁴ cpm) were incubated with 50 µg of brain S100 protein for 10 minat 4°C. To test for binding specificity, we incubated reactionsin the presence or absence of a 100-fold excess of the correspondingcold competitor RNA (GAP/3 $'$ or GAP/B). After UV irradiation, RNAprotein complexes were analyzed in 10% polyacrylamide gels. B,RNA-binding reactions were performed with ³²P-labeled GAP/3 $'$ RNA and cytosolic extracts derived from controlPC12 cells (Co) or cells induced for 16 hr with 160 nM TPA (+TPA).Gels were exposed to film for 3-7 d at $-$ 80°C.
[View Larger Version of this Image (38K GIF file)]

Given that the B region mediates the increased stability of the GAP-43 mRNA in the presence of TPA, RNA-binding proteins interactingwith these sequences are potential candidates for trans-actingfactors involved in this process. Thus, subsequent experimentsexamined the interactions of sequences in the B fragment or theentire GAP-43 3 $'$ UTR with brain cytosolic proteins (Fig. 9). Ofthe three major GAP-43 mRNA-binding proteins in brain extracts,the 90 and 45 kDa proteins were found to interact preferentiallywith the B fragment. Competition experiments revealed that, althoughthe B fragment did not show a direct interaction with the 65 kDaRNA-binding protein, an excess of this region was as effectiveas the entire GAP-43 3 $'$ UTR in competing for the formation ofall three RNA protein complexes (Fig. 9A). In contrast to the65 kDa protein, the 45 and 90 kDa proteins display a preferentialaffinity for poly(U) while showing no significant binding to poly(C)(Kohn et al., 1996a). Therefore, our results suggest that U-richsequences within the B region participate in these RNA proteininteractions.

To begin to examine the role of these proteins in the stabilization of the GAP-43 mRNA in response to TPA, we performed RNA-bindingassays with extracts derived from control and TPA-treated PC12cells. As shown in Figure 9B, TPA altered the pattern of RNA proteininteractions by decreasing the binding of a 60 kDa species andincreasing the binding of those of 40, 45, and 65 kDa to the GAP-433 $'$ UTR. These results suggests that regulated RNA protein interactionsbetween these proteins and specific U-rich sequences in the 3 $'$ UTR may contribute to the control of GAP-43 mRNA stability duringneuronal differentiation.

DISCUSSION
Differences in the rates of degradation of messenger RNAs play a significant role in the control of gene expression in eukaryoticcells (for review, see Sachs, 1993; Beelman and Parker, 1995).Within the nervous system, mRNA stability mechanisms are knownto regulate the expression of a number of important neuronal proteinssuch as growth-associated proteins (e.g., GAP-43; Perrone-Bizzozeroet al., 1991, 1993), cytoskeletal elements (e.g., neurofilamentproteins; Schwartz et al., 1995), neurotransmitter biosyntheticenzymes and receptors (Haddock et al., 1989; Czyzyk-Krzeska etal., 1994), and the amyloid precursor protein (Zaidi and Malter,1994). After the discovery of the post-transcriptional controlof the GAP-43 gene, the 3 $'$ UTR of the mRNA was proposed to mediatethis regulatory mechanism. First, the GAP-43 3 $'$ UTR is highlyconserved across different species, from human to goldfish, witha level of conservation that matches or exceeds that of the codingregion (Perrone-Bizzozero et al., 1991; Kohn et al., 1996a). Second,these sequences contain putative instability-conferring sequencesthat resemble AU-rich elements described in other mRNAs with afast turnover (Chen et al., 1995; Peng et al., 1996). Third, theGAP-43 3 $'$ UTR contains recognition sites for the binding of specificbrain cytosolic proteins (Kohn et al., 1996a). Like the GAP-43mRNA, these proteins are regulated developmentally and localizedto the nervous system, suggesting that they may participate inthe post-transcriptional regulation of the GAP-43 gene. In thisstudy we present direct evidence that elements in the 3 $'$ UTR ofGAP-43 mRNA are involved in the control of mRNA stability. Ondeletion of the 3 $'$ UTR ( $Delta$ 3 $'$ UTR), the resulting GAP-43 mRNA wasfound to be three times more stable than the wild-type mRNA. Notonly did deletion of these sequences have a stabilizing effecton the GAP-43 mRNA, but also addition of the GAP-43 3 $'$ UTR tothe $beta$ -globin coding region destabilized this normally stable mRNA.Conversely, the 3 $'$ UTR of $beta$ -globin was found to stabilize theGAP-43 coding region (C2 chimera) even beyond the level observedfor the $Delta$ 3 $'$ UTR construct. Thus, analyses of the stability ofdeletion mutants and chimeras indicate clearly that the intrinsicinstability of the GAP-43 mRNA in PC12 cells is attributable tosequences localized in its highly conserved 3 $'$ UTR.

With regard to the precise mechanisms that control differential mRNA turnover, recent evidence indicates that this processis extremely complex and that multiple cis- and trans-acting factorsare involved. In addition, several studies have revealed thata number of variables need to be considered in the interpretationof mRNA stability data, including the effect of translation onmRNA turnover (Savant-Bhonsale and Cleveland, 1992; Nishizawaand Okamoto, 1994; Chen et al., 1995). For example, minor changesin mRNA sequence, because of the introduction of point mutationsor specific deletions, may affect mRNA stability indirectly viaa perturbation of the RNA secondary structure that leads to changesin translation efficiency (Weiss and Liebhaber, 1994). In viewof this potential problem, we examined the ability of different3 $'$ UTR deletion mutants used in this study to generate GAP-43protein in transfected cells and found that all of them were translatedeffectively. Thus, these results suggest that differences in thestability of the various transcripts are not the result of translationaleffects. Furthermore, because translation imposes a series ofstructural requirements on mRNA molecules, our results suggestthat the differences in mRNA decay rates observed here are notlikely to be attributable to major alterations in the overallstructure of the mRNA but rather to specific changes within limitedregions in the 3 $'$ UTR. Finally, comparison of the structural andfunctional properties of specific subregions of the GAP-43 3 $'$ UTR reveals that the overall length of the 3 $'$ UTR or the locationof specific elements relative to the stop codon does not havea direct effect in mRNA stability. As shown in Figure 1 and Table1, it is the presence of specific regions in the 3 $'$ UTR, ratherthan their size and specific location, that determines the half-lifeof the GAP-43 mRNA.

Using deletion mutation analysis, we identified two different instability-conferring sequences in the 3 $'$ UTR of the GAP-43mRNA. One is a 60 nt region at the 5 $'$ end of the 3 $'$ UTR. Removalof this element increases the half-life of the mRNA twofold. Althoughthis element contributes to the intrinsic instability of the mRNAin undifferentiated PC12 cells, it is not sufficient to stabilizethe mRNA in response to phorbol ester treatment. These resultsare in contrast with a recent report in which this region wasfound to mediate the stabilization of the mRNA in response toNGF (Nishizawa and Okamoto, 1994). Although the reasons for thisdiscrepancy are unclear, it should be noted that there are majordifferences in the transfection protocols and cell lines usedin that study and in the use of transcription inhibitors for thedetermination of mRNA turnover rates. The other determinant ofGAP-43 mRNA stability identified in our study is localized ina 250 nt U-rich region in the 3 $'$ end of the GAP-43 3 $'$ UTR. Notonly did deletion of this element result in the stabilizationof the mRNA, but also addition of these sequences to the codingregion of $beta$ -globin significantly decreased the half-life of thechimeric transcript. Although this element contains several highlyconserved U-rich stretches (A/GUUUG/C), replacement of the middleU with A in three of the U-rich stretches did not change the half-lifeof the transcripts, suggesting that additional sequences in thisregion may contribute to its destabilizing effect. In fact, werecently have found a 25 nt U-rich region downstream of thesemotifs that contains a recognition site for a neuronal-specificelav-like RNA-binding protein [Chung et al. (1997); also see below].

Phorbol esters such as 12-O-tetradecanoyl-phorbol-12-acetate (TPA) are known to exert a highly pleiotropic response in a varietyof cell types both in vivo and in vitro (Nishizuka, 1986). Severallines of evidence indicate that phorbol esters can mimic manyof the responses of neural cells to growth factors, such as theinduction in GAP-43 expression and neurite outgrowth by NGF (Montzet al., 1985; Perrone-Bizzozero et al., 1993). There is also evidencethat TPA can affect gene expression regulation at the post-transcriptionallevel by causing specific changes in mRNA stability (Iwai et al.,1991; Saceda et al., 1991; Perrone-Bizzozero et al., 1993). Inthis study we investigated the possibility that the TPA-inducedstabilization of the GAP-43 mRNA (Perrone-Bizzozero et al., 1993)could be mediated via specific sequences within the GAP-43 3 $'$ UTR. We found that the 250 nt B region in the GAP-43 3 $'$ UTR containsan element that confers responsiveness to TPA; the mRNA containingthis region was unstable in uninduced cells and stabilized inthe presence of TPA. This increase in GAP-43 mRNA stability resultedin an enhanced expression of GAP-43 protein in the cells. Thus,the B region in the GAP-43 3 $'$ UTR can mimic major regulatory featuresof the entire GAP-43 mRNA.

To characterize further the mechanisms by which sequences in the B region exert this effect, we examined their interactionwith specific RNA-binding proteins. Of the three GAP-43 mRNA-bindingproteins identified in brain cytosolic extract, those that havethe highest specificities for poly(U) RNA (Kohn et al., 1996a)were found to bind this 250 nt U-rich region. One is a 90 kDamolecular weight RNA-binding protein, the activity of which isdependent on protein phosphorylation (Kohn et al., 1996a). Theother is a 45 kDa protein that recently was identified as a memberof the elav family of neuronal-specific RNA-binding proteins (Robinowet al., 1988; Szabo et al., 1991; Kim and Baker, 1993; King etal., 1994). These proteins are involved in the development ofthe nervous system and are thought to regulate specific gene expressionvia post-transcriptional mechanisms (King et al., 1994; Chunget al., 1996). Analysis of RNA protein interactions indicatedthat there is an increased binding of the low molecular weightGAP-43 mRNA-binding proteins in TPA-induced PC12 cells. In contrast,we found decreased binding of a 60 kDa neural-specific protein.These results suggest that these GAP-43 mRNA-binding proteinsmay function as trans-acting factors for the post-transcriptionalregulation of GAP-43 gene expression. In fact, this elav-likeprotein is enriched in brain polysomes, the same subcellular fractionthat contains the GAP-43 mRNA degradation machinery (Kohn et al.,1996b), further suggesting a role of this factor in mRNA turnover.Characterizing the function and regulation of these RNA-bindingproteins will help clarify not only the fundamental basis forthe control of GAP-43 mRNA stability but also the role of thispost-transcriptional mechanism in the expression of this and otherimportant neural-specific genes during neuronal differentiation.

FOOTNOTES

Received Oct. 31, 1996; revised Dec. 23, 1996; accepted Jan. 13, 1997.

This work was supported in part by National Institutes of Health (Grants NS30255 and HD24236), the American Paralysis Association(Grant PBI-9006), and dedicated Health Research Funds of the Universityof New Mexico School of Medicine. K-C. T. was supported by theTri-Service General Hospital, Taipei, Taiwan. We thank Dr. RichardBurry for his gift of the PC12-N36 cell line and Dr. D. A. Meltonfor supplying the pSP64T $beta$ -globin UTR vector used in these studies.

Correspondence should be addressed to Dr. Nora I. Perrone-Bizzozero, Department of Biochemistry, BMSB Room 249, Universityof New Mexico School of Medicine, Albuquerque, NM 87131-5221.

Dr. Tsai's present address: Department of Physical Medicine and Rehabilitation, Tri-Service General Hospital, Taipei, Taiwan,Republic of China.

Dr. Kohn's present address: School of Physical Therapy, Ohio University, 119 Convocation Center, Athens, OH 45701.

REFERENCES

Aigner L, Caroni P (1993) Depletion of 43 kDa growth-associated protein in primary sensory neurons leads to diminished formation and spreading of growth cones. J Cell Biol 123:417-429 . [Abstract/Free Full Text]
Aviv H, Voloch Z, Bastos R, Levy S (1976) Biosynthesis and stability of globin mRNA in cultured erythroleukemic friend cells. Cell 8:495-503 . [ISI][Medline]
Beelman CA, Parker R (1995) Degradation of mRNA in eukaryotes. Cell 81:179-183 . [ISI][Medline]
Belgrader P, Cheng J, Zhou X, Stephenson LS, Maquat LE (1994) Mammalian nonsense codons can be cis effectors of nuclear mRNA half-life. Mol Cell Biol 14:8219-8228 . [Abstract/Free Full Text]
Benowitz LI, Routtenberg A (1987) A membrane phosphoprotein associated with neural development, axonal regeneration, phospholipid metabolism, and synaptic plasticity. Trends Neurosci 10:527-532. [ISI]
Benowitz LI, Apostolides PJ, Perrone-Bizzozero NI, Finklestein SP, Zwiers H (1988) Anatomical distribution of the growth-associated protein GAP-43/B-50 in the adult rat brain. J Neurosci 8:339-352 . [Abstract]
Brewer G (1991) An A+ U-rich element RNA binding factor regulates c-myc mRNA stability in vitro. Mol Cell Biol 8:1697-1708.
Chen CYA, Xu N, Shyu AB (1995) mRNA decay mediated by two distinct AU-rich elements from c-fos and granulocyte-macrophage colony-stimulating factor transcripts: different deadenylation kinetics and uncoupling from translation. Mol Cell Biol 15:5777-5788. [Abstract]
Chung S, Jiang L, Cheng S, Furneaux H (1996) Purification and properties of HuD, a neuronal RNA-binding protein. J Biol Chem 271:11518-11524 . [Abstract/Free Full Text]
Chung S, Eckrich M, Perrone-Bizzozero NI, Kohn DT, Furneaux H (1997) Elav-like proteins bind to a conserved regulatory element in the 3 $'$ UTR of the GAP-43 mRNA. J Biol Chem, in press.
Czyzyk-Krzeska MF, Furnari BA, Lawson EE, Milhorn DE (1994) Hypoxia increases rate of transcription and stability of tyrosine hydroxylase mRNA in pheochromocytoma (PC12) cells. J Biol Chem 269:760-764 . [Abstract/Free Full Text]
Dekker LV, De Graan PNE, Oestriecher AB, Versteeg DHG, Gispen WH (1989) Inhibition of noradrenaline release by antibodies to B-50 (GAP-43). Nature 34:274-276.
Federoff HJ, Grabczyk E, Fishman MC (1988) Dual regulation of GAP-43 gene expression by nerve growth factor and glucocorticoids. J Biol Chem 263:19290-19295 . [Abstract/Free Full Text]
Gorman C, Padmanabhan R, Howard BH (1983) High efficiency DNA-mediated transformation of primate cells. Science 221:551-553 . [Abstract/Free Full Text]
Haddock JR, Wang H, Malbon CC (1989) Agonist-induced destabilization of the $beta$ -adrenergic receptor mRNA. J Biol Chem 264:19928-19933. [Abstract/Free Full Text]
Ivins KJ, Neve KA, Feller DJ, Fidel SA, Neve RL (1993) Antisense GAP-43 inhibits the evoked release of dopamine from PC12 cells. J Neurochem 60:626-633 . [ISI][Medline]
Iwai Y, Bickel M, Pluznik DH, Cohen RB (1991) Identification of sequences within the murine granulocyte-macrophage colony-stimulating factor mRNA 3 $'$ -untranslated region that mediate mRNA stabilization induced by mitogen treatment of EL-4 thymoma cells. J Biol Chem 266:17959-17965 . [Abstract/Free Full Text]
Kim YJ, Baker BS (1993) The Drosophila gene rbp9 encodes a protein that is a member of a conserved group of putative RNA binding proteins that are nervous system-specific in both flies and humans. J Neurosci 13:1045-1056 . [Abstract]
King PH, Levine TD, Fremeau RT, Keene JD (1994) Mammalian homologs of Drosophila ELAV localized to a neuronal subset can bind in vitro to the 3 $'$ UTR of mRNA encoding the Id transcriptional repressor. J Neurosci 14:1943-1952 . [Abstract]
Kohn DT, Tsai K-C, Cansino VV, Neve RL, Perrone-Bizzozero NI (1996a) Role of highly conserved pyrimidine-rich sequences in the 3 $'$ untranslated region of the GAP-43 mRNA in mRNA stability and RNA-protein interactions. Mol Brain Res 36:240-250 . [Medline]
Kohn DT, Tsai K-C, Cansino VV, Perrone-Bizzozero NI (1996b) Developmental regulation of GAP-43 mRNA stability in vitro. Soc Neurosci Abstr 22:1710.
Krieg PA, Melton DA (1984) Functional messenger RNAs are produced by SP6 in vitro transcription of cloned cDNAs. Nucleic Acids Res 12:7057-7070 . [Abstract/Free Full Text]
Malter JS (1989) Identification of an AUUUA-specific messenger RNA binding protein. Science 246:664-666 . [Abstract/Free Full Text]
Meberg PJ, Valcourt EG, Routtenberg A (1995) Protein F1/GAP-43 and PKC gene expression patterns in hippocampus are altered 1-2 hr after LTP. Mol Brain Res 34:343-346 . [Medline]
Montz HPM, Davis GE, Skaper SD, Manthorpe M, Varon S (1985) Tumor-promoting phorbol diester mimics two distinct neurotrophic factors. Dev Brain Res 23:150-154.
Neve RL, Neve KA (1995) Receptor expression in mammalian cells. In: Receptor Molecular Biology, Vol 25, Methods in Neurosciences (Sealfon SC, ed), pp 163-174. San Diego: Academic.
Neve RL, Perrone-Bizzozero NI, Finklestein S, Zwiers H, Bird E, Kurnit D, Benowitz LI (1987) The neuronal growth-associated protein GAP-43 (B-50, F1): specificity, developmental regulation, and regional expression of the human and rat genes. Mol Brain Res 2:177-183.
Neve RL, Finch EA, Bird ED, Benowitz LI (1988) Growth-associated protein GAP-43 is expressed selectively in associative regions of the adult human brain. Proc Natl Acad Sci USA 85:3638-3642 . [Abstract/Free Full Text]
Nevidi E, Basi GS, Virag Akey I, Skene JHP (1992) A neural-specific GAP-43 core promoter located between unusual DNA elements that regulate its activity. J Neurosci 12:691-704. [Abstract]
Nishizawa K, Okamoto H (1994) Mutation analysis of the role for the carboxy-terminus encoding region in NGF-induced stabilization of GAP-43 mRNA. Biochem Biophys Res Commun 205:1380-1385 . [ISI][Medline]
Nishizuka K (1986) Studies and perspectives on protein kinase C. Science 246:664-666.
Peng SSY, Chen CCA, Shyu AB (1996) Functional characterization of a non-AUUUA AU-rich element from the c-jun proto-oncogene mRNA: evidence for a novel class of AU-rich elements. Mol Cell Biol 16:1490-1499. [Abstract]
Perrone-Bizzozero NI, Neve RL, Irwin N, Lewis SE, Fischer I, Benowitz LI (1991) Post-transcriptional regulation of GAP-43 mRNA levels during neuronal differentiation and nerve regeneration. Mol Cell Neurosci 2:402-409.
Perrone-Bizzozero NI, Cansino VV, Kohn DT (1993) Post-transcriptional regulation of GAP-43 gene expression in PC12 cells through PKC-dependent stabilization of the mRNA. J Cell Biol 120:1263-1270 . [Abstract/Free Full Text]
Perrone-Bizzozero NI, Tsai K-C, Cansino VV, Romero L, Burry RW (1994) Post-transcriptional control of GAP-43 mRNA in transfected cells. J Neurochem 62[Suppl]:S14C.
Richards RI, Heguy A, Karin M (1984) Structural and functional analysis of the human metallothionein-I_A gene: differential induction by metal ions and glucocorticoids. Cell 37:263-272 . [ISI][Medline]
Robinow S, Campos A, Yao K, White K (1988) The elav gene product of Drosophila, required in neurons, has three RNP consensus motifs. Science 42:1570-1572.
Saceda M, Knabbe C, Dickson RB, Lippman ME, Beonzert D, Lindsey RK, Gottardis MM, Martin MB (1991) Post-transcriptional destabilization of estrogen receptor mRNA in MCF-7 cells by 12-O-tetradecanoylphorbol-13-acetate. J Biol Chem 266:17809-17814 . [Abstract/Free Full Text]
Sachs AB (1993) Messenger RNA degradation in eukaryotes. Cell 74:413-421 . [ISI][Medline]
Savant-Bhonsale S, Cleveland DW (1992) Evidence for instability of mRNAs containing AUUUA motifs mediated through translation-dependent assembly of a >20S degradation complex. Genes Dev 6:1927-1939 . [Abstract/Free Full Text]
Schwartz ML, Bruce J, Shneidman PS, Schlaepfer WW (1995) Deletion of 3 $'$ -untranslated region alters the level of mRNA expression of a neurofilament light subunit transgene. J Biol Chem 270:26364-26369 . [Abstract/Free Full Text]
Shaw G, Kamen R (1986) A conserved AU sequence from the 3 $'$ untranslated region of GM-CSF mRNA mediates selective mRNA degradation. Cell 46:659-667 . [ISI][Medline]
Shyu AB, Belasco JG, Greenberg ME (1991) Two distinct destabilizing elements in the c-fos message trigger deadenylation as a first step in rapid mRNA decay. Genes Dev 5:221-231 . [Abstract/Free Full Text]
Skene JHP (1989) Axonal growth-associated proteins. Annu Rev Neurosci 12:127-156. [ISI][Medline]
Sower AC, Bird ED, Perrone-Bizzozero NI (1995) Increased levels of GAP-43 protein in schizophrenic brain tissues demonstrated by a novel immunodetection method. Mol Chem Neuropathol 24:1-11 . [ISI][Medline]
Starr RG, Lu B, Federoff HJ (1994) Functional characterization of the rat GAP-43 promotor. Brain Res 638:211-220 . [ISI][Medline]
Strittmatter SM, Fankhauser C, Huang PL, Mashimo H, Fishman MC (1995) Neuronal pathfinding is abnormal in mice lacking the neuronal growth cone protein GAP-43. Cell 80:445-452 . [ISI][Medline]
Szabo A, Dalmau J, Manley G, Rosenfeld M, Wonf E, Henson J, Posner JB, Furneaux HM (1991) Hud, a paraneoplastic encephalomyelitis antigen, contains RNA-binding domains and is homologous to elav and sex-lethal. Cell 67:325-333 . [ISI][Medline]
Vanselow J, Grabczyk E, Ping J, Baetscher M, Teng S, Fishman M (1994) GAP-43 transgenic mice: dispersed genomic sequences confer a GAP-43-like expression during development and regeneration. J Neurosci 14:499-510 . [Abstract]
Verhaagen J, Koster JG, Schrama LH, Eggen BJL, van der Neut R, Gispen WH, Destree OHJ (1993) The rat B-50 (GAP-43) promoter directs neural-preferred expression of a reporter gene in Xenopus laevis embryos. Neurosci Res Commun 13:83-90.
Volloch V, Housman D (1981) Stability of globin mRNA in terminally differentiating murine erythroleukemic cells. Cell 23:509-514 . [ISI][Medline]
Weiss IM, Liebhaber SA (1994) Erythroid specific determinants of $alpha$ -globin mRNA stability. Mol Cell Biol 14:8123-8132 . [Abstract/Free Full Text]
Zaidi SHE, Malter JS (1994) Amyloid precursor protein mRNA stability is controlled by a 29-base element in the 3 $'$ -untranslated region. J Biol Chem 269:24007-24013. [Abstract/Free Full Text]
Zubiaga A, Belasco J, Greenberg M (1995) The nonamer UUAUUUAUU is the key AU-rich sequence motif that mediates mRNA degradation. Mol Cell Biol 15:2219-2230 . [Abstract]

Copyright ©1997 Society for Neuroscience   0270-6474/1997/171950-09$05.00/0

This article has been cited by other articles:

D. Forest, R. Nishikawa, H. Kobayashi, A. Parton, C. J. Bayne, and D. W. Barnes
RNA expression in a cartilaginous fish cell line reveals ancient 3' noncoding regions highly conserved in vertebrates
PNAS, January 23, 2007; 104(4): 1224 - 1229.
[Abstract] [Full Text] [PDF]

R. W. Burry and C. L. Smith
HuD Distribution Changes in Response to Heat Shock but Not Neurotrophic Stimulation
J. Histochem. Cytochem., October 1, 2006; 54(10): 1129 - 1138.
[Abstract] [Full Text]

Volume 17, Number 6, Issue of March 15, 1997 pp. 1950-1958 Copyright ©1997 Society for Neuroscience

Post-Transcriptional Regulation of the GAP-43 Gene by Specific Sequences in the 3 Untranslated Region of the mRNA

Copyright ©1997 Society for Neuroscience 0270-6474/1997/171950-09$05.00/0

Volume 17, Number 6, Issue of March 15, 1997 pp. 1950-1958
Copyright ©1997 Society for Neuroscience

Post-Transcriptional Regulation of the GAP-43 Gene by Specific Sequences in the 3 $'$ Untranslated Region of the mRNA