ENC-1: A Novel Mammalian Kelch-Related Gene Specifically Expressed in the Nervous System Encodes an Actin-Binding Protein

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Volume 17, Number 9, Issue of May 1, 1997 pp. 3038-3051
Copyright ©1997 Society for Neuroscience

ENC-1: A Novel Mammalian Kelch-Related Gene Specifically Expressed in the Nervous System Encodes an Actin-Binding Protein

Maria-Clemencia Hernandez¹, Pedro J. Andres-Barquin¹, Salvador Martinez³, Alexandro Bulfone², John L.R. Rubenstein², and Mark A. Israel¹
¹ Preuss Laboratory of Molecular Neuro-Oncology and Department of Neurological Surgery and ² Nina Ireland Laboratory for Developmental Neurobiology and Department of Psychiatry, University of California, San Francisco, California 94143, and ³ Department of Anatomy, Faculty of Medicine, University of Murcia, 30100 Murcia, Spain

ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
FOOTNOTES
REFERENCES

ABSTRACT

We have identified and characterized a novel murine gene, Ectoderm-Neural Cortex-1 (ENC-1), that is an early and highly specificmarker of neural induction in vertebrates. ENC-1, which encodesa kelch family related protein, is expressed during early gastrulationin the prospective neuroectodermal region of the epiblast andlater in development throughout the nervous system (NS). ENC-1expression is highly dynamic and, after neurulation, preferentiallydefines prospective cortical areas. The only apparent expressionof ENC-1 outside the NS is restricted to the rostral-most somitomereof the presomitic mesoderm, at the times corresponding to theepithelialization that precedes somite formation. Cellular expressionof epitope-tagged ENC-1 shows extensive co-localization of ENC-1with the actin cytoskeleton, and immunoprecipitation studies demonstratea physical association between ENC-1 and actin. ENC-1 functionsas an actin-binding protein that may be important in the organizationof the actin cytoskeleton during neural fate specification anddevelopment of the NS.
Key words: ENC-1; kelch repeats; epiblast; nervous system; actin; neuron

INTRODUCTION

The complexity of the nervous system (NS) presents major challenges for understanding how its neural components are formedand organized. Only a few molecular markers are available to monitorthe earliest events of NS development. Among the earliest markersidentified in vertebrates are homeobox genes Otx-2 (Simeone etal., 1992, 1993), XlHbox 6 (Wright et al., 1990), Nkx-2.1 andNkx-2.2 (Shimamura et al., 1995), and XlPOU 2 (Witta et al., 1995);the basic helix-loop-helix gene XASH-3 (Zimmerman et al., 1993;Turner and Weintraub, 1994); the cell adhesion molecule N-CAM(Kintner and Melton, 1987); class II $beta$ -tubulin (Richter et al.,1988; Oschwald et al., 1991); and the carbohydrate epitope L5(Roberts et al., 1991). As development proceeds, an increasingnumber of genes are expressed in restricted domains of the neuraltube. These expression domains define the following two typesof boundaries: (1) transverse boundaries perpendicular to thelongitudinal axis that segregate transverse or neuromeric domainsand (2) longitudinal boundaries parallel to the longitudinal axissegregating longitudinal domains extending through multiple transversedomains. In embryonic hindbrain and forebrain, the expressionpattern of a large number of candidate regulatory genes, includinghomeobox genes, suggests a neuromeric organization (Bulfone etal., 1993; Puelles and Rubenstein, 1993; Rubenstein et al., 1994,Shimamura et al., 1995). Similarly, genes marking areas of regionalspecification in the cortex have been identified (Bulfone et al.,1995), although little is known of the mechanism regulating suchregionalization.

Most genes defining early events or domains of CNS development are transcription factors, the expression of which is temporallyand spatially restricted. This is compatible with data indicatingthat NS development involves a combination of signaling by solublecytokines, cell-cell interactions, and interactions with the extracellularmatrix that regulate gene expression in a lineage-specific manner(for review, see Simpson, 1995; Calof, 1995). Other observationssuggest that changes in cell shape leading to reorganization ofthe cytoskeleton alters gene expression, possibly by interactingwith nuclear matrix or by activating and facilitating the transportof regulatory factors to the nucleus (Ben-Ze'ev, 1991; Li et al.,1994; Rosette and Karin, 1995; Weitzer et al., 1995).

We have identified and characterized a novel gene, the expression of which is highly specific for neural tissue. ENC-1, namedfor its expression pattern in ctoderm and eural ortex, is expressedearly during embryogenesis in the prospective neuroectodermalregion of the epiblast and continues to be expressed during developmentthroughout the NS. Analysis of ENC-1 indicates that it is a homologof kelch, a Drosophila gene essential for oogenesis (Xue and Cooley,1993). Members of the kelch family have been identified in severalspecies and are important for cytoskeletal organization and function(Varkey et al., 1995; Way et al., 1995b). ENC-1 is the only memberof this family expressed in the NS and encodes a cytoplasmic proteinthat interacts with the actin cytoskeleton. Based on ENC-1's patternof expression, primary structure, subcellular localization, andin vivo interaction with actin, we propose that ENC-1 functionsas an actin-binding protein important for organization of thecytoskeleton during neural fate specification and developmentof the NS.

MATERIALS AND METHODS
Cloning and sequence analysis of ENC-1 cDNA. Total RNA was isolated from embryonic day 17 (E17), postnatal day 1, and adultmouse brains by the guanidinium-CsCl method (Ausubel et al., 1994).Total RNA (5 µg) was used for the synthesis of cDNA (SuperScriptpreamplification system, Life Technologies, Gaithersburg, MD)that served as a template for a PCR amplification using primersspecific for Id molecules. A cDNA fragment of 732 bp was amplifiedwith the oligonucleotide 5 $'$ -AAGGAGCTGGTGCCCACC-3 $'$ , then clonedinto the PCRII (Invitrogen, San Diego, CA) plasmid (clone p2x)and its DNA sequence determined. To obtain a full-length ENC-1cDNA clone corresponding to the mRNA recognized by p2x DNA, wescreened a previously described mouse brain cDNA library (Porteuset al., 1992) using standard colony hybridization procedures (Sambrooket al., 1989). Several positive clones were identified and analyzed.Both strands of the longest cDNA (clone p10.2x) were sequencedas double-stranded plasmids with synthetic primers by the dideoxy-nucleotidechain termination method using the Sequenase enzyme (United StatesBiochemicals, Cleveland, Ohio) and [ $alpha$ -³⁵S]dATP (Amersham, Arlington Heights, IL). A XbaI fragment of 598bp corresponding to the 5 $'$ end of ENC-1 cDNA was subcloned inthe M13mp19 RF vector (Boehringer Mannheim, Indianapolis, IN)to facilitate sequencing, because this region is rich in guanineand cytosine nucleotides. Sequence analyses were performed usingthe Wisconsin Genetics Computer Group Sequence Analysis SoftwarePackage.

Northern blot analysis. Northern blot analysis was performed as described previously in Ausubel et al. (1994). A blot containing1 µg of poly A⁺ RNA isolated from a variety of tissues of adult mice (Clontech,Palo Alto, CA) was hybridized to a ³²P-radiolabeled DNA probe prepared by random primed (Amersham)DNA synthesis using clone p2x (732 bp fragment of a coding regionof ENC-1 cDNA). Blots were subsequently hybridized with a $beta$ -actincDNA probe used as an RNA loading and transfer control.

Construction of tagged ENC-1. Epitope-tagged ENC-1 was prepared by introduction of a DNA sequence encoding an 11 amino acidpeptide (MASMTGGQQMG) corresponding to the major capsid proteinof T7 (Tsai et al., 1992) at the initiation codon of ENC-1. A54 bp oligonucleotide encoding the 11 amino acids of the T7 epitopeand amino acids 2-8 of ENC-1 was synthesized as the upstream primerand 5 $'$ -CCTGCCTTCCTAATGTAGAGC-3 $'$ as the downstream primer locatedat the 3 $'$ end of the ENC-1 coding region. Clone p10.2x servedas a template to amplify the coding region of ENC-1 fused to theDNA encoding the T7 epitope at the 5 $'$ end by PCR. The expected1800 bp PCR fragment was cloned into the PCR3 eukaryotic expressionplasmid (T/A cloning kit, Invitrogen). DNA sequence of this insertwas determined and found to be unchanged.

In vitro transcription and translation of ENC-1. To prepare ENC-1 and T7tagENC-1 proteins, SalI-linearized DNA from plasmidp10.2x and EcoRI-linearized DNA from plasmid pT7tagENC-1 wereused as templates in in vitro transcription reactions (Stratagene,La Jolla, CA) and in vitro translation using [³⁵S]methionine (Amersham) and a rabbit reticulocyte translationkit, as recommended by the supplier (Promega, Madison, WI). Theprotein products were boiled in SDS loading buffer, separatedon SDS-PAGE, and visualized by autoradiography.

Cell culture, transfection, and immunofluorescence. National Institutes of Health (NIH) 3T3 cells and Daoy cells were obtainedfrom the American Type Culture Collection (Rockville, MD) (catalog#ATCC CRL 1658 and #ATCC HTB 186, respectively). SNB40 cells werekindly provided by Dr. R. Youle, NIH, Bethesda, MD. NIH 3T3 cellswere cultured in high-glucose DMEM containing 100 µg/ml penicillinG, 100 µg/ml streptomycin, and 5% FBS (all from Life Technologies)and maintained in a humidified 5% CO₂/95% air incubator at 37°C.A transient transfection protocol modified from that describedby Felgner and Ringold (1989) was used to examine ENC-1 expression.Briefly, cells were grown to 70-80% confluence in a two-well tissueculture chamber slide (Nunc, InterMed, Naperville, IL) and washedonce with calcium- and magnesium-free PBS (CM-PBS) and once withOptiMEM medium (Life Technologies). A lipofectin-DNA mixture containing2 µg of pT7tagENC-1 DNA or pCR3 DNA and 3 µg of lipofectin (LifeTechnologies) diluted in 1 ml of OptiMEM was then added to eachwell. After incubation at 37°C for 6-7 hr, the medium was replacedwith 1 ml of culture medium containing 10% FBS. The cells wereexamined between 12 and 48 hr after transfection. Medulloblastomacell lines Daoy and SNB40 were cultured in Eagle's Minimal EssentialMedium with Earle's BSS supplemented with nonessential amino acids,1 mM sodium pyruvate, 100 µg/ml penicillin G, 100 µg/ml streptomycin,and 10% FBS (all from Life Technologies). The cultures were maintainedin a humidified 5% CO₂/95% air incubator at 37°C. Stable transfectionswere performed in cells grown to 70-80% confluence in 35 mm tissueculture plates by adding a lipofectin-DNA mixture containing 8µg of pT7tagENC-1 DNA or pCR3 DNA and 10 µg of lipofectin dilutedin 2 ml of OptiMEM. After incubation at 37°C for 6-12 hr, thetransfection medium was replaced with 2 ml of culture medium,and cells were incubated for an additional 48 hr. Cells were thendivided between two 100 mm tissue culture plates and selectedfor 3 weeks in culture medium containing 500 µg/ml G418 (Geneticin,Life Technologies). Four pools of transfectant clones were obtainedand subsequently maintained in presence of G418.

For immunofluorescence, the transfected cells were fixed in 4% paraformaldehyde in CM-PBS for 10 min at room temperature.Cells were permeabilized, and nonspecific binding was blockedby incubating the cells for 15 min at room temperature in CM-PBS-Tween(CM-PBS/0.1% Tween 20) containing 0.05% Nonidet P-40, 10% goatserum, and 3% BSA. The same solution without Nonidet P-40 wasused for the following incubations with antibodies. Initially,an incubation with mouse T7tag monoclonal antibody (1:300 dilution)(Novagen, Madison, WI) was performed at room temperature for 1hr. After washing in PBS, cells were incubated for 1 hr at roomtemperature with a 1:50 dilution of FITC-conjugated goat anti-mouseIgG (Boehringer Mannheim). To visualize the F-actin cytoskeleton,cells were washed and incubated further for 40 min with TRITC-labeledphalloidin (Sigma, St. Louis, MO) at a final concentration of0.2 µg/ml in PBS. Cells were finally washed and mounted, and preparationswere examined and photographed using a Zeiss Axioplan epifluorescencemicroscope (Zeiss, Oberkochen, Germany).

Immunoblot analysis and immunoprecipitation. Transfected cell lines were lysed in EBC buffer (50 mM Tris-HCl, pH 8.0, 120mM NaCl, 0.5% Nonidet P-40, 1 mM EDTA) containing 10 µg/ml aprotininand leupeptin and 1 mM PMSF (Sigma). The protein concentrationof the lysates was quantitated by the Bradford protein assay (Bio-Rad,Hercules, CA), and 100 µg of total protein was resolved by SDS-PAGEusing standard methods. The proteins were then transferred tonitrocellulose membranes by electroblotting and processed forimmunodetection. Nitrocellulose membranes were incubated for 3hr at room temperature in TBS-Tween (50 mM Tris, pH 7.6, 1.5%NaCl, 0.1% Tween 20) containing 6% nonfat milk (dilution buffer)and overnight at 4°C with the T7tag monoclonal antibody diluted1:10,000 in dilution buffer. Then the membranes were rinsed briefly,washed three times for 5 min each in TBS-Tween, and incubatedfor 1 hr at room temperature with the secondary antibody (peroxidase-labeledgoat anti-mouse IgG, Life Technologies) diluted 1:15,000 in dilutionbuffer. Finally, the membranes were washed in TBS-Tween for 1hr at room temperature and the labeled bands visualized with anECL detection system (Amersham).

To immunoprecipitate actin and actin-associated proteins from stably transfected Daoy cells, 85% confluent cultures in 150mm dishes were lysed at 4°C in 1.5 ml of EBC buffer containing10 µg/ml aprotinin and leupeptin and 1 mM PMSF. Lysates were clarifiedby centrifugation, and the supernatants were gently agitated at4°C for 3 hr with an affinity-purified rabbit anti-actin antibody(Sigma) or with normal rabbit Igs (Dako, Carpinteria, CA). Thiswas followed by the addition of 60 µl of protein A-Sepharose beads(Life Technologies) and incubation further for 1 hr. Immunoprecipitateswere then collected by centrifugation, washed five times withEBC buffer at 4°C, and denatured in SDS loading buffer for electrophoresis.Samples were separated on 10% SDS-PAGE and transferred to nitrocellulosemembranes. The membranes were treated as above with T7tag monoclonalantibody.

In situ hybridization. ENC-1 expression was detected in tissue sections from whole mouse embryos and fetuses, as well as inpostnatal brains using radioactive in situ RNA hybridization (Bulfoneet al., 1993). A radiolabeled antisense ENC-1 riboprobe was transcribedfrom the 732 bp cDNA clone p2x. In situ hybridization to wholemouse embryos (E8.0-E10.5) and whole embryonic brains (E11.5 andE12.5) was performed using nonradioactive probes according tothe methods of Conlon and Rossant (1992) and Shimamura et al.(1994), with modifications described in Bulfone et al. (1995).For these experiments, the antisense ENC-1 riboprobe was synthesizedusing a digoxigenin RNA labeling kit (Boehringer Mannheim) andDNA from the clone p10.2x. The hybridized probe was detected byanti-digoxigenin antibody using an alkaline phosphatase reaction.As a control, radioactive and nonradioactive riboprobes of Tbr-1and Pax6 genes were used in adjacent sections and in whole mouseembryos at the same stage of development in parallel, simultaneousexperiments. These probes detected the previously reported Tbr-1and Pax6 patterns of expression (data not shown).

RESULTS

Molecular cloning of ENC-1
To better understand mammalian NS development, we sought to identify novel genes, the expression for which was limited tothe NS. For this purpose, we used PCR amplification of cDNA preparedfrom mRNA of mouse brain at different stages of development. Thesereactions were primed with oligonucleotides designed to reflectconserved regions of transcription factors likely to be importantin NS development. Without additional characterization, we thenscreened the reaction products for differential expression inthe developing NS. Among the reaction products of an RT-PCR amplificationdesigned to identify Id family members (Benezra et al., 1990)in mRNA isolated from the brain of a 1-d-old mouse, we isolateda cDNA fragment of 732 bp. This fragment was used as a probe inNorthern blot analysis of poly(A⁺) RNA from adult mouse tissues. This Northern blot analysis revealedabundant transcripts in the brain, but expression was not apparentin any other mouse tissue examined (Fig. 1). Overexposure of theautoradiogram revealed a very weak signal in testis tissue (datanot shown). Abundant transcripts were also detected in total RNAisolated from brains of E17 and postnatal day 1 mice (data notshown). The transcript we detected is ~4.5 kb. The 732 bp fragmentwas cloned in the PCRII vector (clone p2x) and then used to screena mouse brain cDNA library (Porteus et al., 1992). We analyzedtwo of several cDNA clones obtained, p7.2x and p10.2x, which hada size of ~1.9 and 2.4 kb, respectively.
Fig. 1. Northern blot analysis of ENC-1 mRNA in mouse tissues. ENC-1 transcript distribution in adult mouse tissues shows high levelsof tissue-specific ENC-1 expression in the brain. Positions ofmolecular size markers are indicated on the left. Bottom panel, $beta$ -Actin cDNA hybridization as an RNA loading and transfer control.
[View Larger Version of this Image (44K GIF file)]

Sequence analysis of ENC-1
Figure 2 presents the nucleotide sequence of the ENC-1 cDNA clone p10.2x and the predicted amino acid sequence of the polypeptideit encodes. This cDNA clone of 2390 bp is a partial representationof the 4.5 kb mRNA (see above), but it contains a long open readingframe (ORF) of 1767 bp. A stop codon is found 9 nt upstream ofthe ATG that marks the 5 $'$ end of the longest ORF of this cDNAclone; therefore, we assume that this is the initial methionineof the translational product. The predicted protein has 589 aminoacids and a calculated molecular weight of 66,043 Da. We performedin vitro transcription-translation assays using both p7.2x andp10.2x DNA as a template and detected a protein of ~67 kDa inagreement with the predicted molecular weight (see Fig. 4A) (datanot shown).
Fig. 2. Nucleotide and deduced amino acid sequence of the mouse ENC-1 cDNA (GenBank accession number U65079[GenBank]). The nucleotidesequence of the 2390 bp cDNA (clone p10.2x) is shown in the toplines, and its predicted amino acid sequence is shown below thecDNA sequence in single-letter code. Numbers on the right referto the last nucleotide or last amino acid in each correspondingline. The ORF extends from nucleotide 1 to 1767 and encodes aprotein of 589 amino acids. The terminator codon is indicatedby an asterisk in the protein sequence.
[View Larger Version of this Image (64K GIF file)]

Fig. 4. In vivo association between ENC-1 and actin, and cellular localization of ENC-1. A, In vitro synthesis of ³⁵S-radiolabeled full-length ENC-1 from ENC-1 and T7-tagged ENC-1expression vectors. Autoradiogram of SDS-PAGE resolved ENC-1 andT7-tagged ENC-1 proteins after synthesis by in vitro transcription-translationassays. Luciferase was used as a control. Positions of the molecularmass markers in kilodaltons are shown at left. B, Stable expressionof T7-tagged ENC-1 in Daoy and SNB40 cell lines. Immunoblot analysiswith T7tag monoclonal antibody was performed from stably transfectedDaoy and SNB40 cell lines with T7-tagged ENC-1 expression vectorand corresponding vector control. Positions of the molecular massmarkers in kilodaltons are shown at left. C, In vivo associationbetween ENC-1 and actin. Lysates from Daoy cells stably transfectedwith T7-tagged ENC-1 were immunoprecipitated with a polyclonalantibody against actin or with normal rabbit Igs. Immunoprecipitateswere then analyzed by immunoblotting with T7 tag monoclonal antibody.The T7-tagged ENC-1 (67 kDa) was present in the anti-actin immunoprecitate,but not in the control (arrow). Cross-reactivity with rabbit heavy-chainIgG is indicated by an asterisk. Normal rabbit Igs were used inan excess concentration in relation to the affinity-purified anti-actinantibody, which accounts for a stronger signal of the heavy-chainIgG in the control immunoprecipitate. Positions of the molecularmass markers in kilodaltons are shown at left. D, Co-localizationof ENC-1 with the actin cytoskeleton. T7-tagged ENC-1 was stablyexpressed in Daoy cells and localized by immunofluorescence witha mouse T7tag monoclonal antibody followed by FITC-conjugatedgoat anti-mouse Ig (b, d). In the same cells, actin filamentswere visualized with TRITC-labeled phalloidin (a, c). Cells fixedafter a 30 min treatment with cytochalasin D to disrupt actinfilaments were also examined (c, d). Photomicrographs were takenfrom the same field using filters for rhodamine (left) and fluorescein(right). Magnification 630×.
[View Larger Version of this Image (62K GIF file)]

Searches for homology in protein databases revealed that ENC-1 shares a significant degree of homology (28% overall identityand 50% overall similarity) with the 76.5 kDa kelch protein, acomponent of ring canals in Drosophila egg chambers (Fig. 3A,B)(ORF1) (Xue and Cooley, 1993). Sequence analysis of ENC-1 alsoindicated the presence of a 50 amino acid stretch consecutivelyrepeated six times in the C-terminal half of the protein (Fig.3B, shaded boxes). This tandemly repeated motif was first identifiedin the kelch protein and subsequently defined a family of proteinscontaining highly similar repeats (Chang-Yeh et al., 1991; Xueand Cooley, 1993; Bork and Doolittle, 1994). Other members ofthis family that share significant sequence identity with ENC-1are calicin, a major basic protein of the mammalian sperm headcytoskeleton (von Bülow et al., 1995); SPE-26, a Caenorhabditiselegans protein expressed throughout the testis in both spermatogonialcells and spermatides (Varkey et al., 1995); $alpha$ -scruin, an actin-bundlingprotein found in the acrosomal process of Limulus polyhemus sperm(Way et al., 1995b); $beta$ -scruin, a homolog of $alpha$ -scruin that is localizedto the acrosomal vesicle of Limulus sperm (Way et al., 1995a);and MIPP, a protein encoded by a intracisternal A-particle-promotedplacenta-expressed gene (Chang-Yeh et al., 1991). Additional proteinsequences that contain this repeated motif include several ORFsof the poxvirus family such as A55R, C2L, F15, and F3L of vacciniavirus (Goebel et al., 1990); C4L and C13L of swinepox virus (Massunget al., 1993); and P65 of entromelia virus (Senkevich et al.,1993).
Fig. 3. Amino acid comparison of ENC-1 with kelch-related proteins. A, Alignment of ENC-1 and two homologous proteins, kelch and SPE-26,generated by the Wisconsin Genetics Computer Group Sequence AnalysisSoftware Package modules PILE UP and PRETTYBOX. The arrows abovethe aligned sequences denote a region of homology (BTB/POZ domain)present in ENC-1, kelch, and a number of zinc finger proteins.The arrowhead indicates the start position of the first repeat,based on structural analysis of the repeat motif (kelch motif)by Bork and Doolittle (1994). The double asterisks indicate thedouble-glycine motif found in all kelch repeats. B, Schematicrepresentation of proteins that share homology to ENC-1. The homologybetween the proteins is represented by thicker parts of linesrepresenting each sequence. The shaded boxes represent the repeatedsegments of ~50 amino acids (kelch motif). The number and locationof repeats were based strictly on the presence of two adjacentglycine residues. The hatched box represents the BTB/POZ domain.Z represents the zinc finger regions in the BCL-6 protein. Proteinlength in amino acids and percentages of amino acid identity andsimilarity are shown on the right.
[View Larger Version of this Image (75K GIF file)]

An additional domain of significant homology near the N terminus of ENC-1, kelch, calicin, and VA55 comprises ~120 amino acids(Fig. 3B, hatched box). This domain is homologous to a domainfound in several zinc finger proteins such as the mammalian BCL-6protein (Ye et al., 1993) (Fig. 3B) and proteins of Drosophilasuch as those encoded by tramtrack (TTK) (Harrison and Travers,1990) and Broad Complex (BR-C) (DiBello et al., 1991). This domainhas previously been named the BTB box (for Broad Complex, tramtrack,and bric à brac) (Godt et al., 1993) or POZ domain (for poxvirusesand zinc finger) (Bardwell and Treisman, 1994).

ENC-1 associates in vivo with actin and co-localizes with the actin cytoskeleton
To study the subcellular localization of ENC-1, we transfected Daoy and SNB40 cells, which normally express the ENC-1 gene,and NIH 3T3 cells, which do not express ENC-1 (data not shown),with an expression vector encoding a T7 epitope-tagged ENC-1 cDNA(pT7tag ENC-1). Before transfection, we confirmed by in vitrotranscription-translation assays that a protein of the predictedfull length was synthesized from this vector. As shown in Figure4A, the band corresponding to the T7-tagged ENC-1 fusion proteinmigrated in SDS-PAGE slightly slower than ENC-1, presumably asa result of the 11 amino acid insert at its N-terminal region.Using a T7tag monoclonal antibody, the T7-tagged ENC-1 fusionprotein was also detected by immunoblot analysis in cell extractsfrom stably transfected Daoy and SNB40 cells, but not from NIH3T3 cells (Fig. 4B) (data not shown).

The subcellular localization of the T7-tagged ENC-1 fusion protein in transiently or stably transfected Daoy, SNB40, and NIH3T3 cells was investigated by immunofluorescence. We used theT7tag monoclonal antibody followed by FITC-conjugated anti-mouseIg. We were unable to detect ENC-1 expression in NIH 3T3 cellsexcept when transiently transfected cells were examined 12-18hr after transfection. We noticed that fewer cells were labeledat 24 hr, and fewer yet at 48 hr. ENC-1-positive cells at 24-48hr showed obvious morphological evidence of cytotoxicity includingareas of detachment from the tissue culture surface and contractionof the cytoplasm (data not shown). We observed qualitatively similarexpression in the medulloblastoma cell lines SNB40 and Daoy. Inthe pools we studied, the level of expression was highest in celllines derived from Daoy. The staining in Daoy-positive cells wasdistributed throughout the cytoplasm and was particularly intensein the perinuclear area (Fig. 4D, b). Because kelch-related proteinsare known to be associated with actin filaments, we performeddual labeling with phalloidin, a fungal toxin specific for filamentousactin, and found extensive co-localization of ENC-1 with the actincytoskeleton (Fig. 4D, a,b). Co-localization of ENC-1 with actinwas maintained after treatment of the cells with cytochalasinD, an actin depolymerizing agent (Fig. 4D, c,d). These resultsstrongly suggested the possibility that ENC-1 might be associatedwith the actin filament network.

To address this question more critically, we sought to co-immunoprecipitate these proteins. Lysates from Daoy cells stablytransfected with T7-tagged ENC-1 were immunoprecipitated withan affinity-purified anti-actin antibody or with normal rabbitIgs as a control and then analyzed by immunoblotting with T7tagmonoclonal antibody. As shown in Figure 4C, the 67 kDa T7-taggedENC-1 was specifically detected by the anti-T7tag monoclonal antibodyin the actin immunoprecipitates, but it was absent in the immunoprecipitationfrom normal rabbit Igs. Although quantitation of the amount ofENC-1 associated with actin under physiological conditions awaitsthe availability of an antibody that recognizes ENC-1, these resultsdemonstrate a physical association between ENC-1 and actin inthese transfected cells.

Expression of ENC-1
To study the expression of ENC-1 during mouse development, we used in situ RNA hybridization to histological sections andwhole-mount preparations. ENC-1 expression was highly dynamicover the course of development but restricted almost exclusivelyto the NS. Expression was detected at the preneurulation stageof mouse embryos (E6.5) in the prospective neuroectodermal regionof the epiblast. In the neural plate (E8.0-E9.0), there was diffuseexpression. The highest levels of expression were observed inlateral areas, particularly in the neural ridge. Early neuraltube expression (E9.0-E10.5) was primarily localized to the alarplate. At later stages, ventral domains of ENC-1 expression appearedin the prosencephalon, rhombencephalon (RH), and spinal cord (SC).To describe ENC-1 expression, we used the terminology of the prosomericmodel (Bulfone et al., 1993; Puelles and Rubenstein, 1993; Rubensteinet al., 1994).

Early expression of ENC-1 (E6.5-E10.5)
ENC-1 expression was detected at E6.5 in the anterior and distal region of the egg cylinder. This is the ectodermal regionof the epiblast that later differentiates predominantly into neuroectodermalcells (Lawson et al., 1991; Quinlan et al., 1995) (Fig. 5a,b).No expression was detected in any extraembryonic tissue. At E8.0,ENC-1 expression was detected in ectodermal derivatives. The neuralplate was labeled rostrally in the lateral areas of the forebrainanlage and neural ridge (Fig. 5c). The cranial neural crest, whichis derived from the neural ridge (Couly and Le Douarin, 1987),was also labeled (Fig. 5d,h). We observed weak or no expressionin the anterior neural ridge (Fig. 5c); cranial neural crest doesnot form from this region (Osumi-Yamashita et al., 1994). Theprospective areas of the midbrain (MB) and rostral hindbrain,including the ventral neuroepithelial zones (Fig. 5c), expressedENC-1. Caudally, the expression was localized to the ectodermlateral to the primitive streak.
Fig. 5. ENC-1 expression at early stages of mouse development: E6.5-E10.5. a, b, Bright- and dark-field photomicrographs of the samesagittal section of an E6.5 mouse embryo after in situ hybridizationfor ENC-1 mRNA. The anterior (ant) and posterior (post) regionsof the embryo are indicated. a, Cresyl violet stain showing thelocalization of the epiblast. The insert is a schematic diagramshowing the fate map of the mouse epiblast during the early gastrulastage of development (based on the work of Lawson et al., 1991and Quinlan et al., 1995) and identifies the approximate locationswithin the epiblast of precursor cells for each of the germ layers:ectoderm (E), mesoderm (MES), and endoderm (EN). b, In situ RNAhybridization with a radiolabeled probe shows the expression ofENC-1 in the prospective neuroectodermal region of the epiblast.The asterisk indicates an artifact produced during the processof autoradiography. c, Dorsal (left) and lateral (right) viewsof E8.0 mouse embryos processed by nonradioactive whole-mountin situ RNA hybridization. ENC-1 expression is localized in neuroectodermalderivatives. d, Lateral view of an E9.0 mouse embryo processedby whole-mount in situ hybridization. The arrows show the expressionof the gene in the telencephalic vesicle (T), midbrain (MB), prorhombomereA (PRA), mandibular process (MD), and caudal neuropore (CN). Theopen arrows show the neural crest cells that are labeled in theirmigration pathway to the branchial arches and body segments. e,Dorsal view of the same embryo as in d showing the segmental expressionin the rostral RH, in coincidence with PRA. f, Whole-mount preparationof an E9.5 mouse embryo; g, h, sections of the same embryo. Theopen arrow in f and the large open arrow in h show the restrictedmesodermal ENC-1 expression to the rostral-most somitomere ofthe presomitic mesoderm. The arrow in g and the bidirectionalarrow in h show expression in PRA neuroepithelium. The dorsaltelencephalic neuroepithelium is also labeled in g. In h, thesmall open arrows show expression in migrating neural crest cells,and the large arrow shows the expression in the alar plate ofthe SC. i, Sagittal section showing the caudal paraxial mesodermof an E9.5 mouse embryo that was processed by whole-mount in situhybridization. The open arrow shows that ENC-1 is segmentallyexpressed in the paraxial mesoderm just before the somitic segmentationis morphologically recognized, but not in already-formed somites(S). j, Lateral view of two E10.5 mouse embryos processed by whole-mountin situ hybridization. k, l, Sagittal sections of the embryo shownin j, right. The thin arrow in j shows the boundary between midbrain(MB) and diencephalon (D). The asterisk indicates that some labelingis apparent in the prosencephalic basal plate. The open arrowsindicate the somitomeres that express ENC-1, which at this stageappears in the tail bud. The open arrow in k shows the prospectiveneuroepithelium of the HP. l, Photomicrograph showing the expressionof ENC-1 in cells of the dorsal root ganglia. For abbreviations,see Table 1. Scale bars: a, b, 30 µm; c, 150 µm; d, e, 280 µm;f, 300 µm; j, 320 µm. g-i are enlarged fivefold more than f; kand l are enlarged threefold more than j.
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Table 1. List of anatomical abbreviations

AP Alar plate MES Intra-embryonic mesoderm

BP Basal plate MGE Medial ganglionic eminence

CB Cerebellar plate ML Mantle layer

CN Caudal neuropore MX Maxillary process

CP Cortical plate NE Neuroepithelial zone

Cx Cortex OC Optic chiasma

CxA Cortical telencephalic anlage OP Optic eminence

D Diencephalon OS Optic stalk

DRG Dorsal root ganglion OV Optic vesicle

DT Dorsal thalamus P1-P6 Prosomeres 1-6

E Embryonic ectoderm POA Preoptic area

EC Ectoplacental cone PP Primordial plexiform layer

EMT Eminentia thalami PRA Prorhombomere A

EN Primitive endoderm PS Primitive streak region

ET Epithalamus PT Pretectal area

FB Forebrain R1-R8 Rhombomeres 1-8

HB Hindbrain RH Rhombencephalon

HP Hippocampus S Somite

Hy Hypothalamus SC Spinal cord

I Isthmus ST Striatum

IC Inferior colliculus SuC Superior colliculus

IF Isthmic fosa T Telencephalon

IN Infundibulum TF Trophoblast

LGE Lateral ganglionic eminence TG Trigeminal ganglion

M Mesoderm V Ventricle

MA Mammillary area VT Ventral thalamus

MB Midbrain YSC Yolk sac cavity

MD Mandibular process ZL Zona limitans

At E9.0 and E9.5, ENC-1 RNA expression was detected in the neuroepithelium of the caudal pole of the telencephalic vesicle(T) (Fig. 5d,f,g), the rostral RH [prorhombomere A (PRA)] (Fig.5d-h), and the alar plate of the SC (Fig. 5h). Mesenchymal cells(probably neural crest cells) in the head and body were also labeled(Fig. 5d,h). Caudally, ENC-1 was expressed in the margins of thecaudal neuropore (Fig. 5d).

In E10.5 mouse embryos, ENC-1 expression was observed in the T, where the cortical anlage showed more intense labeling thanthe basal ganglia anlage (Fig. 5j). The caudal diencephalon showedscattered cells expressing ENC-1 in ventral areas of the alarplate of prosomere 1 (P1). The mesencephalon (MB) showed a rostro-caudalgradient of expression that started at the mesencephalic-diencephalicboundary (Fig. 5j, arrows). ENC-1 was also expressed in the cerebellarplate and in dorsal areas of the RH and SC. Cells expressing ENC-1in the dorsal domains were primarily localized in the mantle layer(Fig. 5k). In addition, at this stage, weak expression of ENC-1appeared in the basal plate of P1 and P2 (Fig. 5j, asterisk).ENC-1 expression was also localized to the neural crest-derivedcells of the dorsal root ganglia (Fig. 5l).

Late embryonic expression of ENC-1 (E11.5-E16.5)
At E11.5, additional domains of expression, as well as those present at earlier stages, were observed. ENC-1 expression wasstrong in the cortical anlage of the T and in the medial ganglioniceminence (MGE) (Fig. 6a). A transverse zone of ENC-1 expressionbetween P1 and P2, in the region of the retroflexus tract (Fig.6a), was recognizable. In the basal plate of the prosencephalon,the expression extended from P1 to P4, where the mammillary region(MA) was more intensely labeled (Fig. 6a). More posteriorly, ENC-1was expressed in the cerebellar plate and in the alar plate ofRH and SC.
Fig. 6. Expression of ENC-1 in mouse CNS at late embryonic stages of development and adult brain. a-f, Isolated neural tube from anE11.5 mouse embryo processed by whole-mount in situ hybridization.a, Lateral view; e, dorsal view, after opening of the rhombencephalicroof; b-d, f, sagittal sections of the same embryo. The arrowin a indicates the mammillary region (MA). In b, the large arrowshows that the telencephalic expression of ENC-1 is localizedin the mantle layer of the cortex [primordial plexiform layer(PP)], and the short arrow shows that the unique ventricular expressionis localized in the anlage of the HP. The dashed line shows thelocation of the zona limitans (ZL). The asterisk in d shows theventricular expression in the diencephalic basal plate from therostral MB to the MA region. The bidirectional arrows show theposition of interneuromeric boundaries. The large arrows showthe basal plate of P3 and P4. The dotted line labels the positionof the zona limitans. g, Lateral view and h, ventricular viewafter midline section of whole-mount processed neural tubes fromE12.5 mouse embryos. The small arrow in h shows that the zonalimitans express ENC-1, and the large open arrow shows a bandof expression localized between basal and alar plate limits extendingthroughout the SC. i, Detail of a thick section of SC from thesame embryo as in g. The arrows show the expression in the dorsalarea of alar plate, and the open arrows in basal plate ventralto the sulcus limitans. j-l, ENC-1 expression detected by in situRNA hybridization. j, Sagittal sections of an E14.5 mouse embryo.The plane of section only cut a small tangential area of the telencephalicvesicle (T). The expression is visible in prosencephalic and mesencephalicbasal plates, from the MA to the isthmic negative gap (short arrow).The interstitial nucleus of Cajal appears intensely labeled (arrowhead).In the RH, the migrating cells from the rhombic lip to ventralareas are positive (long arrow). k, Sagittal section of an E16.5mouse embryo. In the telencephalon, the cortical plate (CP) appearsintensely positive, and some scattered expressing cells are presentin the POA and the ST. The mamillary nuclear complex at the basalplate express ENC-1. DT and PT show intense positive cells. TheSuC cortex express ENC-1. The isthmic segment are negative toENC-1 expression, whereas scattered cells fill the rhombencephalicbasal plate. Intense labeling is observed in the rhombic lip derivatives,the pontine, and the inferior olivary nuclei. l, Sagittal sectionof adult mouse brain. ENC-1 is strongly expressed in the HP andneocortex. Cells from the striatal and POA also expressed ENC-1.Caudally, transverse domains of expression are observed in ventralthalamic area (VT), caudal hypothalamus (Hy), and pretectal area(PT). The dorsal thalamus (DT) and the collicular plate do notexpress ENC-1 at this stage. For abbreviations, see Table 1.Scale bars: a, g, h, 300 µm; e, 220 µm; i, 100 µm; j, 600 µm;k, 480 µm; l, 360 µm; b is enlarged threefold more than a; c andd are enlarged 1.2-fold more than a; f is enlarged fivefold morethan a.
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In some regions, ENC-1 was expressed in the proliferative layer (the ventricular zone), whereas in other domains, its expressionwas restricted to mantle layers that contain postmitotic cells(Fig. 7, schema). The telencephalic expression of ENC-1 was primarilyrestricted to the mantle layer of the cortex (primordial plexiformlayer) and MGE (Fig. 6b). Mantle expression was also detectedin P1, MB, CB, and the dorsal rhombomeric regions (Fig. 6c,e).In RH, two new domains of ENC-1 expression were detected, a longitudinaldomain limited by the basal and alar plates extending throughoutRH and SC with the exception of rhombomeres 2 and 3 (r2 and r3)(Fig. 6c,e). The second domain was localized segmentally in theparamedian area of the floor plate on both sides of r4 (Fig. 6d,e).Ventricular zone expression was found in the anlage of the hippocampus(HP) (Fig. 6b), the diencephalic basal plate (from the rostralMB to MA) (Fig. 6d, asterisk), and in the r4 paramedian area (Fig.6d-f).
Fig. 7. Schematic diagram illustrating the ENC-1 expression domains in a medial view of the mouse brain at E12.5. The medial wallof the telencephalon is opened to show the internal ganglioniceminences. The transverse (neuromeric) subdivisions are indicatedby solid lines that are perpendicular to the principal longitudinalsubdivision that divides the alar and basal zones and definesthe longitudinal axis of the brain. Other longitudinal zones areindicated by black lines that are parallel to the longitudinalaxis. Four longitudinal zones are shown in the SC; from dorsalto ventral, they are the roof plate, alar plate, basal plate,and floor plate. These four zones extend rostrally. For the definitionsof the letter codes, see Table 1. The rhombomeres (r1-r8) andtheoretical prosomeres (P1-P6) are labeled.
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Expression of ENC-1 in the E12.5 neural tube continued to be strong in the forebrain. Expression in the MGE and cortical anlagewas separated by a zone of weaker expression in lateral ganglioniceminence (LGE) (Figs. 6g,h, 7, schema). Two interprosomeric boundaryzones expressed ENC-1, the P2/P3 and P1/P2 boundaries (Figs. 6h,7). The longitudinal domain of ENC-1 expression that extendedalong RH and SC was also present at this stage (Fig. 6h, openarrow). In SC, ENC-1 was expressed in the dorsal area of alarplate and in the subventricular zone of the sulcus limitans (Fig.6h,i).

At E14.5 and E16.5, ENC-1 continued to be expressed in the maturing tissues of the CNS, in patterns very similar to thoseobserved in earlier stages (Fig. 6j,k). In the T, the corticalplate, including the hippocampal anlage (HP), was clearly labeled(Fig. 6k). Much less expression was found in LGE-derived striatum(ST), whereas the preoptic area (POA) expressed ENC-1. Hypothalamic(Hy) expression extended through infundibular and MA domains.The alar diencephalon showed expression of ENC-1 in superficialareas of the dorsal thalamus (DT) and pretectum (PT) (Fig. 6k).MB expression included the superior colliculus (SuC) and sometegmental areas. There was widespread expression of ENC-1 in thehindbrain, including rhombic lip derivatives (pontine and inferiorolivary nuclei). The isthmic region had little or no expression(Fig. 6j, short arrow).

ENC-1 expression in adult brain
ENC-1 continued to be strongly expressed in HP and neocortex, except in a thin layer that corresponds to the deep area oflayer I (Fig. 6l). Some cells in the ST and POA were also positivefor ENC-1. Expression was present in alternating transverse domainsof the ventral thalamus (P3), PT (P1), and inferior colliculus.The Hy expressed ENC-1 in the MA and infundibular regions (Fig.6l). In the adult, caudal regions of the brain had undetectablelevels of ENC-1 expression (Fig. 6l).

ENC-1 is expressed at E9.5 and E10.5 in the rostral-most somitomere of the presomitic mesoderm
ENC-1 is limited to only a somite-sized domain at the anterior end of the presomitic mesoderm. This region corresponds tothe rostral-most somitomere in the paraxial mesoderm (Tam andTrainor, 1994) (Fig. 5h, large open arrow). Figure 5i shows asagittal section from an E9.5 mouse embryo that contains the caudalparaxial mesoderm region, where ENC-1 was segmentally expressedjust before somitic segmentation could be morphologically recognized(Fig. 5i, open arrow). Because the embryonic axis developed andsomites and somitomeres are formed in a strict rostro-caudal sequence(Tam and Trainor, 1994), the new rostral-most somitomere thatexpress ENC-1 at E10.5 was localized in the tail bud (Fig. 5j,open arrows).

DISCUSSION

ENC-1 is a member of the kelch family of proteins and interacts with the actin cytoskeleton
We found significant amino acid homology between mouse ENC-1 and proteins of the kelch family. These proteins are characterizedby the presence of a motif of ~50 amino acids, which is repeatedtwo to seven times and invariably contains two adjacent glycineresidues. This motif is called the kelch repeat (Bork and Doolittle,1994; Cooley and Theurkauf, 1994). Among members of this family,kelch, SPE-26, calicin, and $alpha$ -scruin are synthesized as cytoskeletalcomponents during germ cell differentiation, and they occur inmembrane-associated dense structures (Xu and Cooley, 1993; Varkeyet al., 1995; von Bülow et al., 1995; Way et al., 1995b). Kelchco-localizes with actin filaments that form ring canals that regulatenutrient transport from the nurse cells and oocyte. Mutationsin the kelch gene affect this cytoplasm transport, producing afemale sterile phenotype (Xue and Cooley, 1993; Knowles and Cooley,1994). Mutations in SPE-26 cause sterility in C. elegans malesand hermaphrodites by disrupting the intracellular segregationof components necessary to form spermatids (Varkey et al., 1995).Five of six loss-of-function SPE-26 mutations were in the tandemrepeats, and one of the most severe mutations was a substitutionin a highly conserved glycine. In the case of $alpha$ -scruin, thereare six kelch repeats at the N terminus and six kelch repeatsat the C terminus that are responsible for $alpha$ -scruin-actin cross-linkingactivity that stabilizes Limulus sperm acrosomal microfilaments(Owen and De Rosier, 1993; Schmid et al., 1993, 1994). Becauseit has been suggested that kelch repeats identify a family ofactin-binding proteins (Cooley and Theurkauf, 1994; Knowles andCooley, 1994), and ENC-1 contains six of these repeats in theC-terminal half of the protein, we sought to examine the abilityof ENC-1 to interact with the actin cytoskeleton. ENC-1 associateswith the actin cytoskeleton (Fig. 4D, a,b) in a transfected medulloblastomacell line, which is a tumor arising in primitive cells of thedeveloping NS that have evidence of neuronal differentiation (Jacobsenet al., 1985). Additional evidence supporting the close associationof ENC-1 and the actin cytoskeleton is our finding that ENC-1and actin co-localize even after depolymerization of the actinfilaments by treatment with cytochalasin D (Fig. 4D, c,d). Moreover,immunoprecipitation studies using anti-actin antibodies demonstratedthat ENC-1 exists in a complex with actin (Fig. 4C).

ENC-1 also shares significant homology to kelch repeats found in a large number of ORFs within the genome of poxviruses. Thefunctional role of these repeats is unknown, but the poxvirusesdo associate with actin as part of their intracellular movement(Hiller et al., 1979, 1981; Krempien et al., 1981). Recently,it was shown that the intracellular, enveloped form of vacciniavirus induces the formation of actin tails as a mechanism to facilitatedirect spread between cells by exploiting the actin cytoskeleton,which directs virions to the cell surface (Cudmore et al., 1995).Kelch-related proteins might mediate such viral interactions.

Interestingly, another domain of ~120 amino acids is present at the N terminus of ENC-1 and several members of the kelch family.This domain, found primarily in zinc finger proteins, is calledBTB/POZ and defines a newly characterized protein-protein interactioninterface (Godt et al., 1993; Bardwell and Treisman, 1994; Zollmanet al., 1994). This domain mediates both dimer and heterodimerformation in vitro (for review, see Albagli et al., 1995) (Chenet al., 1995). The presence of the BTB/POZ domain could allowENC-1 homodimerization resulting in a complex with two actin-bindingdomains that could cross-link and stabilize actin filaments. Alternatively,ENC-1 could interact with other proteins by forming heterodimersthrough the BTB/POZ domain.

ENC-1 is expressed throughout neural development and in the adult brain
ENC-1 is the only member of the kelch gene family that is primarily expressed in the NS. Northern blot analysis showed highexpression levels of ENC-1 in brain, but not in any other mousetissue examined (Fig. 1). To gain insight about the functionalrole of ENC-1, we examined the expression of ENC-1 during mousedevelopment. We have detected ENC-1 expression in the epiblastof E6.5 mouse embryos. At this stage, ENC-1 expression appearsto be localized to the anterior and distal region of the egg cylinder(Fig. 5a,b). Fate-mapping studies demonstrate that neuroectodermis derived from these epiblast regions (Lawson et al., 1991; Quinlanet al., 1995), which is consistent with the observation that laterin development, ENC-1 expression is primarily restricted to theneural plate. The expression of ENC-1 in early gastrula stageembryos makes it one of the earliest markers of neural induction.Others genes recognized to be expressed in early precursors ofthe developing vertebrate NS, including Otx-2, XlHbox 6, XIPOU2, and N-CAM, are distinguishable from ENC-1 in that their expressioncan also be detected in a variety of different lineages (Kintnerand Melton, 1987; Wright et al., 1990; Simeone et al., 1992, 1993;Pannese et al., 1995; Witta et al., 1995). For example, N-CAM,which is the most commonly used general marker of neural induction,is first detected at E8.0, and it is also expressed in other bodyregions such as somites, unsegmented mesoderm, and developingheart (Probstmeier et al., 1994). In contrast, other genes suchas type II $beta$ -tubulin and midsize neurofilament, which are specificallydetected within neural structures, are not expressed before NSdifferentiation is morphologically recognizable. ENC-1 expressionbefore development of NS tissues as well as its restricted expressionwithin these tissues strongly suggests a role in the regulationof NS development.

ENC-1 is expressed in complex temporal and spatial patterns in the developing and adult CNS and neural crest. It appears tohave distinct modules of expression that are delimited by longitudinaland transverse boundaries (Fig. 7) consistent with the prosomericmodel (Bulfone et al., 1993; Puelles and Rubenstein, 1993; Rubensteinet al., 1994; Shimamura et al., 1995). The fact that ENC-1 isexpressed in dividing and postmitotic neural cells (Fig. 7) impliesthat its function is linked not only to properties of undifferentiatedneural cells, such as a high proliferative potential, active migration,or process outgrowth, but also to properties of differentiatedneural cells. During the early stages of development, alar plateexpression of ENC-1 is localized primarily in domains that laterdevelop a cortical cytoarchitecture: the laterodorsal areas ofthe T, the anlage of the cerebral cortex; the rostral MB, theanlage of the SuC; and the dorsal areas of the SC, the anlageof the dorsal horn of the SC. The expression of ENC-1 in thesecortical postmitotic neurons suggests that this gene plays a rolein the histogenesis of cortical CNS tissues. From E12.5 to E16.5,ENC-1 is expressed in cells of the rhombencephalic mantle layerthat appear grouped in columnar clusters at different levels alongthe migration pathways defined by radial glia. The alternationof these ENC-1-positive clusters with columns of cells that donot express ENC-1 suggests the possibility of a clonal relationshipamong the cells that express ENC-1 and migrate along the radialglia. Interaction of ENC-1 with actin could be important for changesin the cytoskeleton associated with this cellular migration anddifferentiation (Sadler et al., 1982; Ostrovsky et al., 1983;Hatten, 1993; Lin et al., 1994).

ENC-1 expression in the rostral-most somitomere of the presomitic mesoderm
We detected expression of ENC-1 in the rostral-most somitomere of the presomitic mesoderm. It is the only apparent expressionof ENC-1 outside of the NS (Fig. 5i). Somitomeres are sphericalclusters of mesenchymal cells in the presomitic mesoderm thatpresage the segmentation of somites in the paraxial mesoderm (Tamand Trainer, 1994). Interestingly, Noch-1 and Dll1, which aremammalian homologs of the Drosophila neurogenic genes Notch andDelta, are expressed both in the NS and in the paraxial mesoderm(Reaume et al., 1992; Bettenhausen et al., 1995), and recentlyNoch-1 expression has been shown to be required for coordinatedsegmentation of somites (Conlon et al., 1995). The somitomerematures with a concomitant increase in cell number and cell-packingdensity, reverting to an epithelial structure at the time of segmentation(Tam and Trainer, 1994). This epithelialization process dependson cell-cell and cell-matrix interactions (Christ and Ordahl,1995). Our finding that ENC-1 is expressed in the rostral-mostsomitomere of the presomitic mesoderm, before its conversion intosomites, but not in somitomeres in the cranial mesoderm, whichnever segment into somites, suggests that ENC-1 is expressed atthe time of epithelialization that precedes the formation of somites.Actin distribution is diffuse and random before this morphogeneticevent, but during epithelialization, actin becomes prominent inthe apical regions of the epithelial cells (Ostrovsky et al.,1983). It is possible that ENC-1 plays a role in the actin rearrangementthat accompanies this cellular reorganization that takes placein the epithelialization process during somite formation.

FOOTNOTES

Received Oct. 1, 1996; revised Feb. 5, 1997; accepted Feb. 14, 1997.

This work was supported by National Institutes of Health Grant 1 U01 CA64898, the Nissen Family, and the Preuss Foundation.P.J.A.B. is a Research Fellow of the Spanish Ministerio de Educaciony Ciencia. We thank Patrick P. L. Tam and Roger A. Pedersen forhelpful discussions, Ingeborg Holt for technical assistance, andLucy Avila and Norma Shipp for help with the manuscript.

Correspondence should be addressed to Dr. Mark A. Israel, Preuss Laboratory for Molecular Neuro-Oncology, Brain Tumor ResearchCenter, Department of Neurological Surgery, HSE 722, Universityof California San Francisco, 513 Parnassus Avenue, San Francisco,California 94143-0520.

REFERENCES

Albagli O, Dhordain P, Deweindt C, Lecocq G, Leprince D (1995) The BTB/POZ domain: a new protein-protein interaction motif common to DNA- and actin-binding proteins. Cell Growth Differ 6:1193-1198[Abstract].
Ausubel FM, Brent R, Kingston RE, Moore DD, Seidman JG, Smith JA, Struhl K (1994) In: Current protocols in molecular biology. New York: Wiley.
Bardwell VJ, Treisman R (1994) The POZ domain: a conserved protein-protein interaction motif. Genes Dev 8:1664-1677[Abstract/Free Full Text].
Ben-Ze'ev A (1991) Animal cell shape changes and gene expression. BioEssays 13:207-212[Web of Science][Medline].
Benezra R, Davis RL, Lockshon D, Turner DL, Weintraub H (1990) The protein Id: a negative regulator of helix-loop-helix DNA binding proteins. Cell 61:49-59[Web of Science][Medline].
Bettenhausen B, Hrabe de Angelis M, Simon D, Guenet J-L (1995) Transient and restricted expression during mouse embryogenesis of Dll1, a murine gene closely related to Drosophila delta. Development 121:2407-2418[Abstract].
Bork P, Doolittle RF (1994) Drosophila kelch motif is derived from a common enzyme fold. J Mol Biol 236:1277-1282[Web of Science][Medline].
Bulfone A, Puelles L, Porteus MH, Frohman MA, Martin GR, Rubenstein JLR (1993) Spatially restricted expression of Dlx-1, Dlx-2 (Tes-1), Gbx-2, and Wnt-3 in the embryonic day 12.5 mouse forebrain defines potential transverse and longitudinal segmental boundaries. J Neurosci 13:3155-3172[Abstract].
Bulfone A, Smiga SM, Shimamura K, Peterson A, Puelles L, Rubenstein JLR (1995) T-brain-1: a homolog of Brachyury whose expression defines molecularly distinct domains within the cerebral cortex. Neuron 15:63-78[Web of Science][Medline].
Calof AL (1995) Intrinsic and extrinsic factors regulating vertebrate neurogenesis. Curr Opin Neurobiol 5:19-27[Medline].
Chang-Yeh A, Mold DE, Huang CC (1991) Identification of a novel murine IAP-promoted placenta-expressed gene. Nucleic Acids Res 19:3667-3672[Abstract/Free Full Text].
Chen W, Zollman S, Couderc J-L, Laski FA (1995) The BTB domain of bric à brac mediates dimerization in vitro. Mol Cell Biol 15:3424-3429[Abstract].
Christ B, Ordahl CP (1995) Early stages of chick somite development. Anat Embryol 191:381-396[Medline].
Conlon RA, Rossant J (1992) Exogenous retinoic acid rapidly induces anterior ectopic expression of murine Hox-2 gene in vivo. Development 116:357-358[Web of Science][Medline].
Conlon RA, Reaume AG, Rossant J (1995) Notch1 is required for the coordinate segmentation of somites. Development 121:1533-1545[Abstract].
Cooley L, Theurkauf WE (1994) Cytoskeletal functions during Drosophila oogenesis. Science 266:590-596[Abstract/Free Full Text].
Couly GF, Le Douarin NM (1987) Mapping of the early neural primordium in quail-chick chimeras. The prosencephalic neural folds: implications for the genesis of cephalic human congenital abnormalities. Dev Biol 120:198-214[Web of Science][Medline].
Cudmore S, Cossart P, Griffiths G, Way M (1995) Actin-based motility of vaccinia virus. Nature 378:636-638[Medline].
DiBello PR, Withers DA, Bayer CA, Fristrom JW, Guild GM (1991) The Drosophila Broad-Complex encodes a family of related proteins containing zinc fingers. Genetics 129:385-397[Abstract].
Felgner PL, Ringold GM (1989) Cationic liposome-mediated transfection. Nature 337:387-388[Medline].
Godt D, Couderc J-L, Cramton SE, Laski FA (1993) Pattern formation in the limbs of Drosophila: bric à brac is expressed in both a gradient and a wave-like pattern and is required for specification and proper segmentation of the tarsus. Development 119:799-812[Abstract/Free Full Text].
Goebel SJ, Johnson GP, Perkus ME, Davis SW, Winslow JP, Paoletti E (1990) The complete DNA sequence of vaccinia virus. Virology 179:247-266[Web of Science][Medline].
Harrison SD, Travers AA (1990) The tramtrack gene encodes a Drosophila finger protein that interacts with the ftz transcriptional regulatory region and shows a novel embryonic expression pattern. EMBO J 9:207-216[Web of Science][Medline].
Hatten ME (1993) The role of migration in central nervous system neuronal development. Curr Opin Neurobiol 3:38-44[Medline].
Hiller G, Weber K, Schneider L, Parajsz C, Jungwirth C (1979) Interaction of assembled progeny pox viruses with the cellular cytoskeleton. Virology 98:142-153[Web of Science][Medline].
Hiller G, Jungwirth C, Weber K (1981) Fluorescence microscopical analysis of the life cycle of vaccinia virus in chick embryo fibroblast. Virus-cytoskeleton interactions. Exp Cell Res 132:81-87[Web of Science][Medline].
Jacobsen PF, Jenkyn DJ, Papadimitriou JM (1985) Establishment of a human meduloblastoma cell line and its heterotransplantation into nude mice. J Neuropathol Exp Neurol 44:472-485[Web of Science][Medline].
Kintner CR, Melton DA (1987) Expression of Xenopus NCAM RNA is an early response of ectoderm to induction. Development 99:311-325[Abstract].
Knowles BA, Cooley L (1994) The specialized cytoskeleton of the Drosophila egg chamber. Trends Genet 10:235-241[Web of Science][Medline].
Krempien U, Schneider L, Hiller G, Weber K, Katz E, Jungwirth C (1981) Conditions for pox virus-specific microvilli formation studied during synchronized virus assembly. Virology 113:556-564[Web of Science][Medline].
Lawson KA, Meneses JJ, Pedersen RA (1991) Clonal analysis of epiblast fate during germ layer formation in the mouse embryo. Development 113:891-911[Abstract].
Li H, Choudhary SK, Milner DJ, Munir MI, Kuisk IR, Capetanaki Y (1994) Inhibition of desmin expression blocks myoblast fusion and interferes with the myogenic regulators MyoD and myogenin. J Cell Biol 124:827-841[Abstract/Free Full Text].
Lin C-H, Thompson CA, Forscher P (1994) Cytoskeletal reorganization underlying growth cone motility. Curr Opin Neurobiol 4:640-647[Medline].
Massung RF, Jayarama V, Moyer RW (1993) DNA sequence analysis of conserved and unique regions of swinepox virus: identification of genetic elements supporting phenotypic observations including a novel G-protein-coupled receptor homologue. Virology 197:511-528[Web of Science][Medline].
Oschwald R, Richter K, Grunz H (1991) Localization of a nervous system-specific class II beta-tubulin gene in Xenopus laevis embryos by whole-mount in situ hybridization. Int J Dev Biol 35:399-405[Medline].
Ostrovsky D, Sanger JW, Lash JW (1983) Light microscope observations on actin distribution during morphogenetic movements in the chick embryo. J Embryol Exp Morphol 78:23-32[Web of Science][Medline].
Osumi-Yamashita N, Ninomiya Y, Doi H, Eto K (1994) The contribution of both forebrain and midbrain crest cells to the mesenchyme in the frontonasal mass of the mouse embryos. Dev Biol 164:409-419[Web of Science][Medline].
Owen C, DeRosier D (1993) A 13 Å map of the actin-scruin filament from the Limulus acrosomal process. J Cell Biol 123:337-344[Abstract/Free Full Text].
Pannese M, Polo C, Andreazzoli M, Vignali R, Kablar B, Barsacchi G, Boncinelli E (1995) The Xenopus homologue Otx2 is a maternal homeobox gene that demarcates and specifies anterior body regions. Development 121:707-720[Abstract].
Porteus MH, Brice AEJ, Bulfone A, Usdin TB, Ciaranello RD, Rubenstein JLR (1992) Isolation and characterization of a library of cDNA clones that are preferentially expressed in the embryonic telencephalon. Mol Brain Res 12:7-22[Medline].
Probstmeier R, Bilz A, Schneider-Schaulies J (1994) Expression of the neural cell adhesion molecule and polysialic acid during early mouse embryogenesis. J Neurosci Res 37:324-335[Web of Science][Medline].
Puelles L, Rubenstein JLR (1993) Expression patterns of homeobox and other putative regulatory genes in the embryonic mouse forebrain suggest a neuromeric organization. Trends Neurosci 16:472-479[Web of Science][Medline].
Quinlan GA, Williams EA, Tan S-S, Tam PPL (1995) Neuroectodermal fate of epiblast cells in the distal region of the mouse egg cylinder: implication for body plan organization during early embryogenesis. Development 121:87-98[Abstract].
Reaume AG, Conlon RA, Zirngibl R, Yamaguchi TP, Rossant J (1992) Expression analysis of a Notch homologue in the mouse embryo. Dev Biol 154:377-387[Web of Science][Medline].
Richter K, Grunz H, Dawid IB (1988) Gene expression in the embryonic nervous system of Xenopus laevis. Proc Natl Acad Sci USA 85:8086-8090[Abstract/Free Full Text].
Roberts C, Platt N, Streit A, Schachner M, Stern CD (1991) The L5 epitope: an early marker for neural induction in the chick embryo and its involvement in inductive interactions. Development 112:959-970[Abstract].
Rosette C, Karin M (1995) Cytoskeletal control of gene expression: depolymerization of microtubules activates NF-kB. J Cell Biol 128:1111-1119[Abstract/Free Full Text].
Rubenstein JLR, Martinez S, Shimamura K, Puelles L (1994) The embryonic vertebrate forebrain: the prosomeric model. Science 266:578-580[Free Full Text].
Sadler TW, Greenberg D, Coughlin P (1982) Actin distribution patterns in the mouse neural tube during neurulation. Science 215:172-174[Abstract/Free Full Text].
Sambrook J, Fritsch EF, Maniatis T (1989) In: Molecular cloning: a laboratory manual, Ed 2. New York: Cold Spring Harbor Laboratory.
Schmid MF, Jakana J, Matsudaira P, Chiu W (1993) Imaging frozen, hydrated acrosomal bundle from Limulus sperm at 7 Å resolution with a 400 kV electron cryomicroscope. J Mol Biol 230:384-386[Web of Science][Medline].
Schmid MF, Agris JM, Jakana J, Matsudaira P, Chiu W (1994) Three-dimensional structure of a single filament in the Limulus acrosomal bundle: scruin binds to homologous helix-loop-beta motifs in actin. J Cell Biol 124:341-350[Abstract/Free Full Text].
Senkevich TG, Muravnik GL, Pozdnyakov SG, Chizhikov VE, Ryazankina OI, Shchelkunov SN, Koonin EV, Chernos VI (1993) Nucleotide sequence of XhoI fragment of ectromelia virus DNA reveals significant differences from vaccinia virus. Virus Res 30:73-88[Web of Science][Medline].
Shimamura K, Hirano S, McMahon AP, Takeichi M (1994) Wnt-1-dependent regulation of local E-cadherin and N-catenin expression in the embryonic mouse brain. Development 120:2225-2234[Abstract].
Shimamura K, Hartigan DJ, Martinez S, Puelles L, Rubenstein JLR (1995) Longitudinal organization of the anterior neural plate and neural tube. Development 121:3923-3933[Abstract].
Simeone A, Acampora D, Gulisano M, Stornaiuolo A, Boncinelli E (1992) Nested expression domains of four homeobox genes in developing rostral brain. Nature 358:687-690[Medline].
Simeone A, Acampora D, Mallamaci A, Stornaiuolo A, D'Apice MR, Nigro V, Boncinelli E (1993) A vertebrate gene related to orthodenticle contains a homeodomain of the bicoid class and demarcates anterior neuroectoderm in the gastrulating mouse embryo. EMBO J 12:2735-2747[Web of Science][Medline].
Simpson P (1995) Positive and negative regulators of neural fate. Neuron 15:739-742[Web of Science][Medline].
Tam PPL, Trainor PA (1994) Specification and segmentation of the paraxial mesoderm. Anat Embryol 189:275-305[Medline].
Tsai DE, Kenan DJ, Keene JD (1992) In vitro selection of an RNA epitope immunologically cross-reactive with a peptide. Proc Natl Acad Sci USA 89:8864-8868[Abstract/Free Full Text].
Turner DL, Weintraub H (1994) Expression of achaete-scute homolog 3 in Xenopus embryos converts ectodermal cells to a neural fate. Genes Dev 8:1434-1447[Abstract/Free Full Text].
Varkey JP, Muhlrad PJ, Minniti AN, Do B, Ward S (1995) The Caenorhabditis elegans SPE-26 gene is necessary to form spermatids and encodes a protein similar to the actin-associated proteins kelch and scruin. Genes Dev 9:1074-1086[Abstract/Free Full Text].
von Bülow M, Heid H, Hess H, Franke WW (1995) Molecular nature of calicin, a major basic protein of the mammalian sperm head cytoskeleton. Exp Cell Res 219:407-413[Web of Science][Medline].
Way M, Sanders M, Chafel M, Tu Y-H, Knight A, Matsudaira P (1995a) $beta$ -scruin, a homolog of the actin crosslinking protein scruin, is localized to the acrosomal vesicle of Limulus sperm. J Cell Sci 108:3155-3162[Abstract].
Way M, Sanders M, Garcia C, Sakai J, Matsudaira P (1995b) Sequence and domain organization of scruin, an actin-cross-linking protein in the acrosomal process of Limulus sperm. J Cell Biol 128:51-60[Abstract/Free Full Text].
Weitzer G, Milner DJ, Kim JU, Bradley A, Capetanaki Y (1995) Cytoskeletal control of myogenesis: a desmin null mutation blocks the myogenic pathway during embryonic stem cell differentiation. Dev Biol 172:422-439[Web of Science][Medline].
Witta SE, Agarwal VR, Sato SM (1995) XIPOU 2, a noggin-inducible gene, has direct neuralizing activity. Development 121:721-730[Abstract].
Wright CVE, Morita EA, Wilkin DJ, De Robertis EM (1990) The Xenopus XlHbox 6 homeo protein, a marker of posterior neural induction, is expressed in proliferating neurons. Development 109:225-234[Abstract].
Xue F, Cooley L (1993) Kelch encodes a component of intercellular bridges in Drosophila egg chambers. Cell 72:681-693[Web of Science][Medline].
Ye BH, Lista F, Coco FL, Knowles DM, Offit K, Chaganti RS, Dalla-Favera R (1993) Alterations of a zinc finger-encoding gene, BCL-6, in diffuse large-cell lymphoma. Science 262:747-750[Abstract/Free Full Text].
Zimmerman K, Shih J, Bars J, Collazo A, Anderson DJ (1993) XASH-3, a novel Xenopus achaete-scute homolog, provides an early marker of planar neural induction and position along the mediolateral axis of the neural plate. Development 119:221-232[Abstract].
Zollman S, Godt D, Prive GG, Couderc J-L, Laski FA (1994) The BTB domain, found primarily in zinc finger proteins, defines an evolutionarily conserved family that includes several developmentally regulated genes in Drosophila. Proc Natl Acad Sci USA 91:10717-10721[Abstract/Free Full Text].

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