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Previous Article | Next Article
Volume 16, Number 21, Issue of November 1, 1996 pp. 6853-6863
Copyright ©1996 Society for NeuroscienceRestricted Expression of the Actin-Regulatory Protein, Tropomyosin, Defines Distinct Boundaries, Evaginating Neuroepithelium, and Choroid Plexus Forerunners during Early CNS Development
Kelley Nicholson-Flynn, Sarah E. Hitchcock-DeGregori, and Pat Levitt Department of Neuroscience and Cell Biology, Robert Wood Johnson Medical School, University of Medicine and Dentistry of New Jersey, Piscataway, New Jersey 08854
ABSTRACT
In the hindbrain, rhombomeres represent morphological units that develop characteristic, segment-specific structures. Similar segments, known as prosomeres, have been proposed to exist in the forebrain. The neuroepithelial cells of the sharp boundary regions that form the borders between many segments often exhibit distinct shapes, reflecting unique cytoskeletal organization. The present investigation examined the expression of one family of actin-binding, regulatory proteins, the tropomyosins (TM), in boundaries. We found that high molecular weight TMs selectively concentrate in boundary cells and other neuroepithelial zones that exhibit unique cell shapes and movements. Specific TM expression is found at hindbrain boundaries as early as embryonic day 10 in the rat, whereas rhombomeres themselves were TM-negative. Highly restricted TM localization also defined some prosomere boundaries in the early forebrain, particularly those exhibiting unique cell shapes. Furthermore, several regions of the neuroepithelium that evaginate are TM-immunoreactive, including tuberal and preoptic neuroepithelium. Most striking, a subpopulation of neuroepithelial cells in the medial telencephalic wall expresses TM, apparently marking the neuroepithelial region that gives rise to the choroid plexus at least 2 d before its formation. This suggests that the medial cerebral wall is not entirely dedicated to generating cells that comprise allocortex. TM expression in the choroid plexus is maintained through initial evagination and appearance in all ventricles. The spatially restricted expression of TMs implicates that this actin-binding protein is involved in the dynamic regulation of cell shape or motility associated with boundary formation and morphogenesis of the neuroepithelium during critical stages of brain development.
Key words: tropomyosin; rhombomere; prosomere; choroid plexus; segmentation; cytoskeleton; cell shape; cell fate
INTRODUCTION
During CNS development in vertebrates, the neuroepithelium becomes divided into morphologically distinct segments. Transient hindbrain structures, known as rhombomeres, are units of cell lineage restriction in which cells of one segment rarely cross into an adjacent one (Fraser et al., 1990
; Birgbauer and Fraser, 1994
The unusual shape of many boundaries and the morphogenetic movements that are associated with their formation suggest that regulation of the cytoskeleton plays an important role in establishing segmented patterns, perhaps by differential expression of contractile or structural proteins in boundary cells. One study by Guthrie et al. (1991)
Tropomyosins (TM), a multigene family of coiled-coil, actin filament-binding proteins, regulate actomyosin function and stabilize the actin filament (Fujime and Ishiwata, 1971
-TM isoforms TMBr-1 and TMBr-3, exhibit tissue- and cell type-specific patterns of expression (Stamm et al., 1993
MATERIALS AND METHODS
Animals Timed pregnant Holtzman albino rats were obtained from Harlan Sprague Dawley. Rats were maintained under a 12 hr light/dark cycle with free access to food and water. Detection of the sperm plug was considered embryonic day (E) 0. Pregnant dams were anesthetized with Nembutal (i.p. injection, 50 mg/kg). The uterine horns were dissected from the abdominal cavity and placed in HBSS. The extraembryonic membranes were removed, and embryos were staged according to crown-rump length (Olson and Seiger, 1972Tissue lysate analysis. Tissue lysates of whole E16 and postnatal day (P) 10 brains were prepared in low-salt buffer, centrifuged at 1000 × g, and analyzed on 10% SDS-PAGE gels (Laemmli, 1970
Immunocytochemistry Whole embryos (E10-E14) or brains (E15-E16) were fixed by immersion in 4% paraformaldehyde in phosphate buffer, pH 6.5, for 2 hr, followed by immersion in 4% paraformaldehyde in phosphate buffer, pH 9.5, overnight at 4°C. The low- to high-pH fixation method (Berod et al., 1981Immunolocalization of TM was performed by a modification of previously published methods (Ferri and Levitt, 1993
-diaminobenzidine tetrahydrochloride as the substrate. Sections were washed extensively in PBS and dehydrated through a graded series of alcohols and Hemo-De (Fisher Scientific, Pittsburgh, PA), and coverslips were mounted with DPX mounting medium (BDH Limited, Poole, UK). Fluorescently labeled sections were washed and coverslips mounted with glycerol/PBS containing 5% n-propyl-galate aqueous mounting medium. Immunoperoxidase-stained sections were photographed in bright-field illumination with a Leica photomicroscope on Kodak Technical Pan black and white film. Fluorescently double-immunolabeled sections were photographed using a G/R double cube with P1600 Kodak color film. Alternate sections at each embryonic age were stained with cresyl violet for analysis of brain architecture with the aid of an atlas (Altman and Bayer, 1995
RESULTS
Characterization of the monoclonal anti-tropomyosin antibody TM311
Although the TM311 monoclonal antibody has been used in a variety of studies, precise molecular characterization has not been reported. It has been suggested that TM311 recognizes an epitope encoded by exon 1a of the
Fig. 1. Characterization of monoclonal anti-tropomyosin antibody, clone TM311. A, The epitope recognized by TM311 is contained within residues 14-32 of exon 1 of the
[View Larger Version of this Image (26K GIF file)]
Immunoblot analysis of tissue lysates from embryonic and postnatal brains showed that both E16 and P10 brains contained three TM311-immunoreactive bands (Fig. 1B). This pattern of immunoreactivity is similar to that reported by Stamm et al. (1993)
-TM genes, that have been cloned in the rat and contain exon 1a (for review, see Lees-Miller and Helfman, 1991
Rhombomere boundaries are labeled by TM311
At E10, the earliest age examined and corresponding to the onset of rhombomere formation in the rat, TM311 specifically labeled the cells that form the boundaries between rhombomere segments in the hindbrain (Fig. 2A,B). The TM311-immunoreactive cell bodies extended across the entire width of the neuroepithelium from the ventricular to the pial surfaces (Fig. 2B). TM311 immunoreactivity was expressed in each boundary that is morphologically evident. Figure 2A shows four TM311-labeled boundaries and a more posterior boundary that is just forming. Faint TM immunoreactivity was observed in this latter boundary in adjacent sections, indicating that TM expression occurs at the onset of morphological segmentation in the hindbrain. The specific pattern of TM immunoreactivity was maintained at E11 (Fig. 2C,D), when strong TM311 labeling of all rhombomere boundaries was observed.
Fig. 2. Tropomyosin is expressed at rhombomere boundaries in the developing rat hindbrain. Parasagittal sections at E10 (A, B), E11 (C, D), and E12 (E, F) labeled with the anti-tropomyosin TM311 illustrate several TM311-immunoreactive boundaries between rhombomeres in the hindbrain (filled arrows and arrowheads in A, C, E; boundaries shown at higher magnification in B, D, F are indicated by arrowheads). At E10, corresponding to the onset of rhombomere formation, the boundaries are narrow and lightly immunoreactive compared to later ages. Open arrow in A indicates a recently formed boundary that shows TM immunoreactivity in adjacent sections. Higher-magnification photomicrographs of individual rhombomere boundaries (B, D, F) show that TM311-immunoreactive boundaries are 4-8 cells wide and that the cells extend across the width of the neuroepithelium. Arrows in B and F indicate locations of cell bodies. In the CNS, TM311 immunoreactivity is also evident in the smooth muscle of blood vessels and in connective tissue (F). Scale bars: A, 145 µm; B, D, E, 35 µm; C, E, 625 µm.
[View Larger Version of this Image (60K GIF file)]
At E12, the appearance of the boundary regions changed (Fig. 2E,F). The TM311-labeled zones remained discrete, but at this time the region, which exhibited a characteristic delta shape, contained darkly labeled cell bodies at the ventricular surface with slender processes extending to the pial surface (Fig. 2F). The boundary was approximately four to eight cells wide, similar to previous reports with localization of actin (Guthrie et al., 1991
TM311 labels boundaries between some prosomeres
Given that TM311 specifically labeled boundaries between rhombomeres in the hindbrain, we investigated whether TM expression was specific to boundaries between prosomeres. Labeling of boundaries was observed in several locations, corresponding to the most morphologically distinct zones of neuroepithelium. There was a TM311-immunoreactive boundary between the pretectum and the tectum in the midbrain (Fig. 3A,B). The labeled cells were arranged in a delta shape and had darkly stained cell bodies at the ventricular surface with fine processes extending toward the pial surface, similar to boundary labeling in the hindbrain at this age (compare with Fig. 2F). The tectal-pretectal boundary was labeled by TM311 in only three to four adjacent, 10-µm-thick sections and corresponds to the caudal extent of the P1 prosomere as defined by Bulfone et al. (1993)
Fig. 3. TM311 labels some prosomere boundaries. A, Midsagittal section through E12 rat showing TM311 immunoreactivity localized to the pretectum/tectum boundary (arrowhead). Note the TM immunoreactivity in dorsal root ganglia and intersomitic mesenchyme. B, Higher magnification of pretectum/tectum boundary (arrowhead in A), with TM311 immunolocalization that distinguishes the caudal boundary of prosomere P1. Note the blood vessel staining on either side of the TM311-positive boundary. C, Coronal section through E12 rat diencephalon at the level of the optic vesicle (OV) showing TM311 immunolocalization at the boundary between the dorsal thalamus (DT) and ventral thalamus (VT) (arrowhead, P2-P3 boundary). A boundary is also suggested between the VT and hypothalamus (H; arrow), contrasting the P3-P4 prosomeres. D, Increased magnification of TM311 immunolocalization at the zona limitans intrathalamica, the border between the DT and VT, a representation of the P2-P3 prosomeric boundary (arrowhead in C). Note the floor plate labeling in presumptive pons (arrow in A). Scale bars: A, 470 µm; B, D, 50 µm; C, 150 µm.
[View Larger Version of this Image (90K GIF file)]
In a similar manner, TM-expressing cells marked the boundary between the dorsal and ventral thalamus. Again, this labeling, shown in the coronal plane (Fig. 3C,D), marked only the cells that form the boundary between the segments, whereas the neuroepithelial cells that make up the bulk of the dorsal and ventral thalamus were TM311-negative. This restricted cellular zone between the dorsal and ventral thalamus, the zona limitans intrathalamica, corresponds to the boundary between the P2 and P3 prosomeres (Bulfone et al., 1993
Segmentation of the diencephalon has also been described by an alternative model (Figdor and Stern, 1993
TM311 labels midline boundaries
The roof and floor plate are comprised of cells with shapes distinct from surrounding neuroepithelium. In the hindbrain, we noted that a region in the presumptive pons was labeled with TM311 (Fig. 3A). Examination of adjacent sections revealed that the zone is very narrow (three to four 10-µm-thick sections) and is situated in the midline. This corresponds to TM311 labeling of the floor plate of the neural tube. In fact, TM expression was present in the ventral midline neuroepithelium and in the roof- and floorplate at all levels of the neural tube (Figs. 4C, 5C,E) (data not shown).
Fig. 4. TM is localized to areas of the neuroepithelium that undergo extensive morphogenetic movements. A, Midsagittal section through an E12 rat showing TM immunolocalization in the tuberal (Tu), preoptic (POA), and presumptive choroid plexus neuroepithelium (arrowhead). Note floor plate (FP) labeling in this section. B, Higher magnification of neuroepithelium containing the presumptive choroid plexus (arrowhead in A), which is labeled before evagination. Note the well delineated boundary between TM311-positive and -negative neuroepithelium. C, Coronal section through E12 rat prosencephalon showing TM311 immunoreactivity in the preoptic neuroepithelium (POA; arrowhead). D, Higher magnification of the TM311-labeled preoptic neuroepithelium (arrowhead in C). Te, Telencephalic vesicle. Scale bars: A, C, 350 µm; B, D, 65 µm.
[View Larger Version of this Image (66K GIF file)]
Fig. 5. Tropomyosin immunolabels cells that are the forerunners of the choroid plexus. A, Coronal section through E11 rat showing TM311-immunolabeled cells (arrowhead) at the dorsal midline of the telencephalon (Te) that will form the choroid plexus 2-3 d later. B, Higher magnification of the restricted zone of TM311-labeled neuroepithelium (arrowhead in A). C, Coronal section through E12 rat telencephalon showing intensely TM311-immunoreactive cells (arrowhead) at the ventral-most region of the medial wall of the dorsal telencephalon. These cells will form the choroid plexus of the lateral ventricles. D, Higher magnification of the TM311-immunoreactive choroid plexus precursors (arrowhead in C). E, Coronal section through E14 rat showing TM311-labeled choroid plexus (arrowhead) of the lateral ventricle (LV). F, Higher magnification showing TM311-labeled cells of the presumptive choroid plexus (arrowhead in E) distinguished from the TM311-negative presumptive allocortex. Note that the plexus has already formed in the LV and is TM311-positive (lower right side). G, Coronal section through the E16 rat telencephalon showing TM311-immunoreactive choroid plexus and choroid plexus precursors (arrowhead). H, Increased magnification showing TM311-positive cells of the developing choroid plexus at the ventro-medial wall of the dorsal telencephalon. Scale bars: A, C, E, G, 500 µm; B, 100 µm; D, F, H, 200 µm.
[View Larger Version of this Image (65K GIF file)]
Evaginating neuroepithelium expresses TM
TM311 labeled three large areas of the neuroepithelium that undergo dramatic morphogenetic movements at E12 (Fig. 4A). First, the preoptic area was heavily labeled with TM311 at the time this region is evaginating to form the optic cup (Fig. 4A,C,D). Second, the tuberal epithelium of the hypothalamus, which migrates down to surround Rathke's pouch to form the pituitary, was labeled with TM311 (Fig. 4A). Third, a zone of the neuroepithelium that appears to contribute to the choroid plexus strongly expressed TM (Fig. 4A,B). This latter region of the neuroepithelium migrates out into the lateral ventricles to form the epithelial component of the choroid plexus. All of these regions demonstrated strong immunoreactivity across the width of the neuroepithelium.The TM-expressing regions also highlighted distinctions between adjacent prosomeres. First, the TM311-positive tuberal epithelium contrasts with the less densely labeled anterior hypothalamus, distinguishing between the alar and basal domains of prosomere P5 (Fig. 4A). Second, the tuberal (TM311-positive) to mammillary (TM311-negative) epithelium change in TM expression highlights the boundary between prosomeres P4 and P5 (Fig. 4A). Third, the distinction between the presumptive choroid plexus (TM-positive) and the TM-negative thalamus that lies posterior to it corresponds to prosomeres P2 and P3 differences (Fig. 4A,B). Finally, the preoptic area is intensely TM-immunoreactive, whereas the cells of the developing anterior hypothalamus exhibit much less TM311 immunoreactivity (Fig. 4A,C,D), corresponding to a distinction between the P5 and P6 prosomeres.
TM311 appears to mark neuroepithelial choroid plexus precursors
TM311 labeled a discrete domain of cells in the dorsal neuroepithelium that is generally defined as presumptive allocortex (Fig. 4A,B). Analysis of a series of midsagittal, parasagittal, and coronal sections through the telencephalon and diencephalon at different ages, however, revealed that the TM311 immunoreactivity marks a region that appears to contain the neuroepithelial forerunners of the choroid plexus. As early as E11, almost 3 d before expansion of the choroid plexus into the lateral ventricles (Das, 1979The expression of high molecular weight TMs was maintained at E14 and E16 in the neuroepithelium that appears to migrate into the lateral ventricles to become the choroid plexus (Fig. 5E-H). At this age, the TM311 immunoreactivity was present not only in the epithelial cells of the choroid plexus proper, but in a restricted region of neuroepithelial cells in the ventral-most part of the telencephalic wall. The immunolabeling of the choroid precursors in the medial wall was most intense at the ventricular surface, but is present in fine processes extending throughout the width of the neuroepithelium. TM labeling also was observed in the connective tissue underlying the epithelium. Beyond E16, the region of TM311-labeled cells adjacent to the choroid plexus decreased.
In the hindbrain, at all ages examined, the velum medulare and the directly adjacent neuroepithelial cells, thought to be cerebellar precursors, were TM311-positive, whereas the remaining presumptive cerebellar neuroepithelium was TM311-negative. When we followed the pattern of labeling through development, it was evident that the TM-immunoreactive cells appear to contain the forerunners of the choroid plexus of the fourth ventricle (data not shown). TM311 also labeled the region containing the precursors of the choroid plexus of the roof of the third ventricle. In all areas, TM311 continued to label the choroid plexus as it formed during fetal development.
Allocortical and choroid plexus precursors are derived from distinct cell populations
The differential labeling with TM311 in the ventromedial wall of the dorsal telencephalon suggested that there is an early spatial segregation of the neuroepithelial cells that form the choroid plexus from those that give rise to the allocortex. To support this, we performed double-labeling experiments with TM311 and MAP2 at E15. MAP2 is a marker that labels neurons, such as those in the primordial plexiform layer of the allocortex (Fig. 6). TM311 immunolabeling was similar to that seen in Figure 5E-H, with TM immunolabeling present in the choroid plexus itself and in the apposed ventral neuroepithelium of the medial wall of the telencephalon. The TM311 immunoreactivity was complementary to MAP2 at all ages examined. The differential labeling of the cells in this region shows that the neuroepithelium in the medial telencephalic wall is spatially segregated to give rise to functionally distinct cell populations.
Fig. 6. Color photomicrograph highlighting the molecular distinction between neuroepithelium-containing choroid plexus and allocortical precursors. Coronal section through E15 rat telencephalon reveals the sharp boundary (arrow) between the region containing the TM311-labeled presumptive choroid plexus (ventrally, in red) and allocortex, shown by MAP2-positive neurons in the primordial plexiform layer (dorsally, in green). TM is also expressed in the smooth muscle of the blood vessels and in connective tissue. Scale bar, 40 µm.
[View Larger Version of this Image (109K GIF file)]
DISCUSSION
Tropomyosin marks many boundaries in the developing rat CNS
The mechanisms regulating the formation of boundaries between neuroepithelial zones during embryonic development remain unknown, but the present study serves as a first indication that the microfilament-regulatory protein TM may play an important role. High molecular weight tropomyosins are expressed in cells that occupy boundaries between rhombomeres in the hindbrain from E10 to E13, throughout the period during which rhombomeres are present, whereas the neuroepithelium of the segments themselves exhibits no TM immunoreactivity. Furthermore, we identified three zones in which TM marks only the boundary region between prosomeres, with the cells appearing similar to those stained at rhombomere boundaries. TM has a well established role in regulating actomyosin function and actin filament dynamics in both muscle and nonmuscle cells (Lees-Miller and Helfman, 1991It has been suggested that the unique structure of hindbrain segments is generated because of a higher rate of cell division in the rhombomeres, whereas the boundary cells divide more slowly, leading to a bulging of rhombomeric neuroepithelium (Guthrie et al., 1991
The mechanism regulating TM expression at boundaries is unclear. Anterior limits of expression of many hox genes fall along rhombomere boundaries, consistent with the possibility that TM expression is transcriptionally regulated by these genes. Regulation, however, is unlikely to occur through a single hox gene (or even simple combination), because no single hox gene is present in all cells of every boundary region. Fgf-3, however, was described recently in rhombomere boundary cells during or soon after boundary formation in the developing chick brain (Mahmood et al., 1995
TM311 labels morphogenetically active regions of the neuroepithelium
In contrast to the exclusive labeling of boundary cells demonstrated in both hind- and forebrain, we also identified TM311-labeling of morphogenetically active zones that highlight distinctions between prosomeres. For example, the tuberal hypothalamus (P5) is TM311-positive, whereas the mammillary epithelium (P4) is negative. These patterns are similar to those shown with differential hybridization with probes to homeobox genes, nonhomeobox transcription factors, and other differentiation factors (Bulfone et al., 1993Although it is plausible that specific isoforms of cytoskeletal proteins would be expressed by cells in regions of the neuroepithelium undergoing morphogenetic movements, we did not anticipate that these regions would correspond to precise prosomeric organization. The regionalization of the forebrain is not typically emphasized based on pronounced morphological characteristics, but zones of neuroepithelial cells clearly undergo movements that contribute to telencephalic differentiation. The observed pattern of TM expression suggests an important role for TM in aspects of regulation of forebrain morphogenesis. It is important to note that TM311-labeled cells are located in regions of the neuroepithelium that actively evaginate as epithelial sheets rather than through individual cell movements. Furthermore, cells express TM before their actual migration, as observed with the choroid plexus. This expression may reflect the necessity for neuroepithelial cells to regulate microfilament structure collectively at the onset of evagination. TM has been localized previously to regions where epithelial cells migrate or contract in unison, such as in the ``purse string'' mechanism of wound healing (Bement et al., 1993
TM expression and choroid plexus formation
The dorsomedial telencephalic wall often is designated as generating exclusively allocortex (Bulfone et al., 1993The segregation of allocortical neuronal and choroid plexus precursors, based on our analysis of MAP2 and TM311 double immunolabeling, is evident as early as E13 and throughout all other ages evaluated (E13-E16). In fact, labeling of the dorsomedial prosencephalic wall at E11, before telencephalic vesicle formation, indicates an early molecular distinction in this neuroepithelium, where only a part is dedicated to generating cells that will comprise allocortex (Bulfone et al., 1993
The discrete regulation of the expression of high molecular weight TMs in the early developing rat CNS suggests a central role in modulating actin filament dynamics. The control of such dynamics, based on our understanding of non-neural epithelium, is likely to be critical for folding regions of the neuroepithelium and maintenance of border regions in the neural tube during embryonic growth. The present study provides the first indication that microfilament regulation by TM is a central component of neuroepithelial specialization.
FOOTNOTES
Received June 17, 1996; revised Aug. 13, 1996; accepted Aug. 16, 1996.
This work was supported by the American Heart Association, New Jersey Affiliate Pre-Doctoral Fellowship 95-FS-13 (K.N.-F.); GM36326 and HL35726 (S.E.H.-D.); and MH45507 (P.L.). We thank Dr. Kathie Eagleson for critical review of this manuscript, Yongmi An, Robin Hammell, and Dr. Norma Greenfield for providing TM proteins and peptides, and Dr. Itzhak Fischer for providing the MAP2 antibody.
Correspondence should be addressed to Dr. Pat Levitt, Department of Neuroscience and Cell Biology, Robert Wood Johnson Medical School, UMDNJ, 675 Hoes Lane, Piscataway, NJ 08854.
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