1 Program in Neuroscience and , 2 Department of Anatomy & Cell Biology, USUHS, Bethesda, MD 20814, USA
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Abstract |
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Introduction |
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It is not clear whether the early generated layers, including the subplate and deep neocortical layers, are important to subsequent laminar formation and migration of neurons into the cortex. A genetic model of distorted cortical layer formation, the reeler mouse, suggests that layers form without certain positional cues, although in a misplaced manner. In reeler mice, the preplate, which normally splits and allows the subsequent layers to form between its deepest element (the subplate) and its most superficial element (layer 1), does not divide and the normally occurring inside-out pattern of laminar genesis does not take place (Caviness and Rakic, 1978). Instead, cortical layers build up beneath each other in an upside-down fashion and the subplate remains superficial, towards the pia. Even in reeler mice, however, the subplate appears to play an important role in cortical development, since axons from the thalamus grow directly into the superficially located subplate and then downward into layer 4, the normal recipient layer from the thalamus (Frost and Caviness, 1980
; Caviness and Frost, 1983
; Molnar and Blakemore, 1995
).
One way to test the impact of early generated cortical layers on later-born layers is to investigate the maturation of cerebral cortex in animals that continue to develop after interference with the early produced layers. Other studies have evaluated the impact of subplate deletion on subsequent formation of cortical architecture by removing the subplate postnatally, after a substantial portion of cortex has already formed (Ghosh et al., 1990; Ghosh and Shatz, 1992a
, 1994
). Although this method is highly useful and important in evaluating structures that mature later in cortical development, such as thalamocortical distribution, it does not allow assessment of the impact of the subplate on earlier events. To test the role of early generated layers on subsequent events we conducted an experimental series in which we disrupted the development of the subplate and/or deeper cortical layers by in utero injection of methylazoxymethanol acetate (MAM) into pregnant ferrets on appropriate gestational days. MAM is a toxin that prevents cells from dividing for a short period of time, thereby effectively preventing the birth of a given population of cells that would normally divide at the time of the injection (Matsumoto and-Higa, 1966
; Zedeck et al., 1970
; Matsumoto et al., 1972
; Johnston et al., 1979
; Cattabeni and Di Luca, 1997
). Using this method can therefore interfere with the formation of a specific layer of neocortex (Johnston and Coyle, 1979
; Jones et al., 1982
; Virgili et al., 1988
; Fasolo et al., 1992
). Our results indicate that MAM injections early during cortical development result in severely disrupted cortex together with dramatic alteration of radial glial and CajalRetzius cells, while later injections of MAM, timed to disrupt layer 4 development, cause more subtle cortical changes and do not produce dramatic alterations in cortical structure or radial glia.
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Materials and Methods |
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Several techniques were used to assess the effect of MAM treatment on the development and architecture of the parietal cortex; all further analyses were made within 1 week of birth (i.e. by P7) except for BRDU immunohistochemistry (see below). The architecture was assessed using standard histological techniques including Nissl stain and immunoreactivity for various markers specific for neurons and glia, including antibodies directed against MAP2, CajalRetzius cells (CR50), vimentin and glial fibrillary acidic protein (GFAP). We also used injections of anatomical tracers into live slices to study the architecture of the MAM treated brains, since previous studies revealed that slice preparations were useful in this regard, particularly for evaluating the status of radial glial cells (Juliano et al., 1996). Additional animals in each group (i.e. normal, early MAM-treated or late MAM-treated) were reacted for immunoreactivity against BRDU. Several animals in the late (E33) MAM-treated group were reacted for BRDU when they reached maturity (after 1 month). Western blots were conducted on tissue obtained from P0 animals treated with MAM on E24 and from normal P0 kits to test for the presence of GFAP. In two pregnant animals, MAM was injected on E24 and the embryos evaluated at E27 and E35 to determine the effect of MAM at shorter times after the in utero injection.
All assessments were made in the parietal cortex before P7. The only exceptions to this were cases of several animals that received BRDU after E33 MAM treatment, in which the brains were analyzed at 12 months of age. Before P7, ferret brains are immature and morphological landmarks are not clearly developed. To ensure that we assessed comparable regions across animals, a coronal block of neocortex was selected in each brain corresponding to landmarks that correlate with parietal cortex in the adult ferret. This block included the region immediately posterior to the anterior commissure and immediately anterior to the thalamus. Within each section, only regions in the dorsolateral portion of the neocortex were used for analysis; this restriction excluded the most medial and lateral portions of cortex (Fig. 1). Although it is not possible to judge accurately cortical regions by cytoarchitecture before P7 in ferret, enough landmarks are present to assign injection sites to lateral portions of parietal cortex, which correspond to the forelimb representation in area 3b (Juliano et al., 1996
; Noctor et al., 1997
; McLaughlin et al., 1998
). In addition, for the animals treated with MAM early during corticogenesis the brains are even smaller than normal or E33 MAM-treated brains, with fewer external landmarks, making the certainty of the cortical site chosen difficult. The internal regions chosen to identify the desired cortical region were present in the brains of all groups, however, so it is likely that similar sites were assessed under all treatment conditions.
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Timed pregnant ferrets were obtained from Marshal Farms (New Rose, NY). MAM injections were made into pregnant ferrets on appropriate days of gestation. Ferrets were anesthetized with halothane (2%) and the MAM injected i.p.; each ferret received 12 mg/kg of MAM (Sigma) dissolved in saline. BRDU injections were made into pregnant ferrets on different embryonic days after MAM injections on E24 or E33. The injections were made i.p. under halothane anesthesia (2%) and delivered 60 mg/kg of BRDU (Sigma) dissolved in saline with 0.007 N NaOH. After the kits were born, BRDU-labeled cells were revealed using standard immunohistochemical techniques (see below). In this set of experiments, kits were examined from P0 to P7, except for several E33 MAM-treated animals that received BRDU injections, which were assessed on P28 and P42, when the laminar pattern of the somatosensory cortex is histologically mature (Juliano et al., 1996). This allowed us to assess the final position of BRDU-positive cells in mature cortex. On the appropriate date, each kit received an i.p. injection of sodium pentobarbital (50 mg/kg) and, when insensitive to pain, was perfused through the heart with saline followed by 4% paraformaldehyde in 0.1 M phosphate buffer. The brains were removed and sunk in 10% and then 20% sucrose in phosphate buffer at 4°C and then frozen in isopentane at 35°C and kept in a freezer at 70°C, until processed as below. In most instances, when the brains were cut, alternate sections were saved for either BRDU, CR50, MAP2, GFAP or vimentin immunohistochemistry, or Nissl staining (see below).
Immunohistochemistry
The brains were cut in a cryostat at 16°C at 30 µm thickness. Antibodies against vimentin (Boehringer Mannheim, anti-vimentin, clone V9), MAP2 (Boehringer Mannheim, anti-MAP2), GFAP (Boehringer Mannheim, anti-GFAP) or CR50 (a generous gift from K. Nakajima, RIKEN, Japan and M. Ogawa, Kochi Medical School, Japan) were applied to the sections after blocking with 10% normal horse serum, 0.2% gelatin plus 0.1% Triton X (Sigma). After 12 h incubation with the primary antibody (diluted 1:4 with 2% normal horse serum and 0.1% Triton X), the sections were rinsed with 0.1 M PBS, pH 7.4, and incubated in the secondary antibody (Vector, antimouse IgG conjugated to fluorescein or Texas Red at 1:100 in 2% normal horse serum and 0.1% Triton X or Vector Vectastain Elite ABC kit) for 2 h. At this point, the resulting label was visualized with fluorescent microscopy or using a Vector VIP peroxidase substrate kit. Control sections received no primary antibody.
For BRDU immunohistochemistry, sections were treated with 95% ethanol and 5% acetic acid for 30 min, 1 mg/ml pepsin (Sigma) in 2 N HCl for 1 h at 37°C, then rinsed in 0.1 M PBS, pH 8.5. Sections were incubated in the primary antibody (anti-BRDU Boeringer-Mannheim; 1:20 with 2% normal horse serum and 0.1% Triton X-100) at 4°C overnight. The following day, sections were rinsed in 0.1 M PBS, pH 7.4, and then incubated in the secondary antibody (Vector Vectastain Elite ABC kit) for 1 h, rinsed in 0.1 M PBS, pH7.4, and finally incubated in ABC for 1 h. The immunoreaction product was visualized with DAB.
Immunohistochemistry Quantification
In order to determine relative numbers of MAP2-positive neurons in the subplate region of normal and E24 MAM-treated animals, MAP2 immunoreactive (IR) cells were counted in a defined region (see Fig. 2). Cells were sampled in a 200 x 150 µm sector of five sections through the subplate region of the somatosensory cortex in each animal (see rectangles in Fig. 2A,C
). Three animals in each group were counted; the groups include (i) normal BRDU-IR, (ii) normal MAP2-IR and (iii) E24 MAM-treated MAP2-IR. A mean value was determined for each animal and used in a two-tailed t-test to determine the relative number of labeled cells in each group.
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Acute Slices
Live slices were prepared from three groups of animals ranging in age from P0 to P7 (day of birth is considered to be P0): (i) normal kits (n = 12), (ii) kits whose mothers received MAM treatment on E24 or 28 (early group, n = 21), and (iii) kits whose mothers received MAM treatment on E33 (late group, n = 25). Slices were prepared at P07 by injecting each kit with 50 mg/kg pentobarbital i.p.; the brains were then removed. During brain removal, ice-cold artificial CSF (containing in mM: NaCl 124, NaHCO3 26, NaH2PO4 1.2, KCl 3.2, MgSO4 1.2, CaCl2 2.4, glucose 10) was perfused often onto the brain until it was blocked and cut. The somatosensory cortex was cut into 400 µm thick coronal slices using a tissue chopper and placed directly in an oxygenated chamber perfused with artificial CSF. A mixture of oxygen (95%) and carbon dioxide (5%) was bubbled through polyethylene tubing from below into the chamber near the stage that held the slices. The same gas mixture was also bubbled into the CSF that perfused the slices from below. At this point, injections of fluorescent dextrans (dextran fluorescein or fluororuby, Molecular Probes, Inc.) were made iontophoretically (3 µA, alternating positive current for 4 min) through pipettes with a tip thickness of 1015 µm. The injections were made at a depth of 200 µm into the approximate center of the slice. The injection sites were all made in the dorsal and lateral portions of parietal cortex (presumptive somatosensory cortex) or into immediately underlying structures including the ventricular zone (VZ) or into the intermediate zone (IZ). The slices remained in the chamber for 58 h to allow for transport. The slices were maintained at room temperature, as described previously (Juliano et al., 1996). We determined in earlier studies that unhealthy slices do not transport dextran tracers (Juliano et al., 1996
). Several other studies report using similar methods for maintaining acute slices (e.g. Blanton et al., 1989
; Yuste et al., 1995
; Wiser and Calloway, 1996
; Flint et al., 1997
; Calloway, 1998
; Kandler and Katz, 1998
). In addition, during most sessions, representative slices were removed and used for Ca2+ imaging. Although these Ca2+ imaged sections were used for other purposes, they also served as a good control to measure the health and viability of the slices, which were found to display calcium transients for at least the length of time the slices were maintained in the chamber. In most instances, the slices were fixed overnight in 4% buffered paraformaldehyde with 10% sucrose in phosphate buffer, then they were sunk in 20% sucrose in phosphate buffer. After this, the slices were further sectioned at 40 µm thickness using a freezing microtome. The label resulting from the dextran injections was visualized using either conventional fluorescent or confocal microscopy (BioRad, MRC 600). Many injections were drawn from the digitized confocal images (x20) to visualize further details across several sections using the Neurolucida reconstruction program (MicroBrightField, Inc.).
Western blots
Tissue samples were obtained from either normal or E24 MAM-treated P0 kits; regions of the telencephalon were dissected that included the cortex, the IZ and the VZ. The brain pieces were homogenized in 10 mM Tris buffer, pH 7.6; total soluble protein was determined (with the Bio-Rad protein detection kit). The samples and sample buffer were boiled and loaded (100 µg total protein) onto 12% acrylamide gels alongside low molecular weight non-stain markers. A Bradford assay was performed to ensure that the total protein concentration in each sample was the same. After running the gels, they were transferred to a Hybond-ECL membrane (Bio-Rad). To detect GFAP, an anti-GFAP antibody was used at 1:1000 and visualized using an ECL Western blotting analysis system (Amersham) and exposed to Hyperfilm-ECL.
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Results |
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The total number of animals for all experimental conditions and for acute slice injections can be seen in Tables 1 and 2. The cytoarchitecture of the somatosensory cortex at P07 in normal animals consists of a dense cortical plate (i.e. developing and differentiating upper and middle layers of cerebral cortex) and a poorly formed layer 5 and 6; the subplate is also observable. At this age, layer 4 cannot be distinguished from the other layers that make up the dense cortical plate (Fig. 2A
). In this paper we use the term cortical plate to refer to the full thickness of the cortex including layers 26 (if distinguishable); dense cortical plate refers to the undifferentiated layers 24 observed in ferret somatosensory cortex during P07. The border between layer 6 and the subplate or the white matter (in older brains) is easily distinguishable; layer 5 cannot always be distinguished from layer 6 before 1 week of age.
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In the group of animals that received early MAM, two dates of injection were used: E24 or E28. Injections on either of these days resulted in severely disorganized cortical architecture. The brains of these animals were significantly smaller than their normal counterparts. This was tested by measuring the cross sectional area in single sections at the level of the anterior commissure in five normal and five early MAM-treated animals. The cross sectional area at this rostrocaudal level was significantly smaller in the MAM-treated group (7.41 mm2 in E24 MAM-treated compared to 16.28 mm2 in normal animals; P 0.001, two-sample t-test). The cortical plate was very thin, with a mean value of 103 µm in thickness from the pia to the cellular border with the white matter compared with a mean value of 411 µm in cortical thickness in normal animals at P1. Although the layers were not clearly defined in these brains, it was always possible to see a sharp decrease in the density of cells that represented the boundary between the cortex and underlying white matter. Neither a clear laminar pattern nor a distinct subplate were found (Fig. 2C
). Occasional clusters of cells were seen in abnormal arrangements, suggesting that cells were not able to migrate to their proper location (arrowheads in Fig. 2C
). Layer 1 was present, but varied in thickness and tended to be more normal in appearance towards lateral portions of the parietal cortex. This can be observed in Figure 2C
, demonstrating a thinning of layer 1 towards the medial aspect of the cortex, on the right side of the image.
Dextran Injections into Acute Slices
In normal animals, injections of fluorescently labeled dextrans into acute live slices resulted in characteristic and precise patterns of label that were strongly radial in nature. This distribution of label occurred after injections into, or near, the VZ. The labeled elements consisted largely of radial glia, which extended long distances from the VZ to the pial surface (Figs 3A, 4A); neurons migrating to the neocortex were studded along the glial processes (Juliano et al., 1996
). Dextran injections into E33 MAM-treated slices resulted in label similar to that in normal animals. This was true whether the injections were placed in the IZ or in the VZ. Presumptive radial glia labeled with the dextrans were distinctly spoke-like, extending from the VZ toward the cortical surface (Fig. 3B
).
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BRDU Label
Injections of BRDU were made into pregnant ferrets both before and after MAM treatment on E33. In both situations (BRDU delivered E30 and E38) cells were generated and migrated into distinct laminar patterns appropriate for the gestational age of injection. Figure 5 shows an example of BRDU-positive cells observed after an E33 MAM injection followed by BRDU administration on E38. The labeled cells are located in a distinct laminar pattern appropriate for the time of BRDU injection.
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Immunoreactivity
To quantify the effect of early MAM treatment on the number of neurons populating the subplate underlying somatosensory cortex on P0, we studied the number of MAP2-positive cells in the region of the subplate in normal and E24 MAM-treated animals. MAP2 has been identified as a marker for subplate neurons in ferret (Ghosh and Shatz 1992a, 1993
). Significantly more MAP2-positive cells were found in normal subplate compared to a similar region in animals treated with MAM at E24 (two-sample t-test, Figs 8 and 9
). Figure 8
shows MAP2 immunoreactivity in normal (Fig. 8B
) and E24 MAM-treated (Fig. 8C
) P0 somatosensory cortex. In both groups, MAP2-labeled cells were observed in the subplate with the characteristic inverted pyramidal shape (Valverde and Facal-Valverde, 1988
; Antonini and Shatz, 1990
). The regions chosen for analysis are indicated with rectangles in Figure 2A,C
. Figure 8A
illustrates BRDU positive cells in the same region on P0 in a normal animal after BRDU injection on E24. Figure 9
demonstrates that in normal animals, there are similar numbers of BRDU-positive cells (after BRDU injection on E24) and MAP2-positive cells in the analyzed subplate region of normal P0 animals. Neurons that reside in the subplate region of ferret somatosensory cortex are born on several days, including E24 (Noctor et al. 1997
). This analysis provides information about MAP2-positive cells immediately below the cortical plate (i.e. where the subplate normally lies). It does not rule out the possibility that other MAP2-IR cells may be scattered in other locations in the IZ; it only verifies that they are not in the vicinity of the subplate.
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Since it is well accepted that as the cortex matures, radial glia differentiate into astrocytes, we decided to determine if interruption of the early generated cortical layers also results in the presence of premature astrocytes in the development of ferret somatosensory cortex. To do this, sections were studied for immunoreactivity against GFAP (an established marker for astrocytes). In normal P0 kits, there is a small amount of positive staining near the pia (Fig. 11A). The staining pattern is similar in P0 animals treated with MAM on E33, i.e. a few immunoreactive fibers occur near the pia, but very little additional positive staining exists in the cortex or IZ. In kits treated with MAM on E24, however, there are many GFAP-positive cells (presumptive astrocytes) throughout the thickness of the cortex and IZ, which appear comparable in overall distribution to the vimentin immunoreactivity in similar animals (Fig. 11B
).
To further verify the presence of GFAP in E24 MAM-treated kits, Western blots were prepared on tissue obtained from normal and E24 MAM-treated brains at P0. The samples were taken from the designated region of the parietal cortex and underlying white matter in the VZ. These data are presented in Figure 12, and demonstrate that although small amounts of GFAP are present in normal P0 ferret brains, the MAM-treated brains contain substantially greater amounts of this protein. Two bands immunoreactive for GFAP were observed, one at 55 kDa and one at 49 kDa. This was not unusual compared to previous studies, and is likely to be a result of degradation of the molecule (Bigbee et al., 1983
; Sheng et al., 1994
).
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Another component of early-generated cortex are the Cajal Retzius cells, which populate layer 1. These cells also originate early during development and may have been affected by MAM treatment early during corticogenesis. To assess the presence and distribution of Cajal-Retzius cells, we used the CR50 antibody, which was generated against reelin (Ogawa et al., 1995; D'Arcangelo et al., 1997
). Evaluation of normal and E33 MAM-treated sections taken from P0 parietal cortex reveals that CR50 immunoreactivity is restricted to layer 1. The labeled cells have an elongated, horizontal morphology and appear similar in shape and distribution to previous reports of CajalRetzius cells (Fig. 13A,C
; e.g. Ramon y Cajal, 1911; Derer and Derer, 1990; Frotscher, 1997; Marin-Padilla, 1998). In P0 sections taken from animals treated with MAM on E24, however, the distribution of CR50-IR cells was dramatically disorganized. Rather than being horizontally positioned in the outer portion of layer 1, the cells were dispersed throughout the thickness of the cortical plate in a wide range of orientations, and extended into the IZ (Fig. 13B,D
). Although the distribution of CR50-positive cells in E24 MAM-treated animals was consistently disorganized, there was variation in the number of displaced cells and in whether they were located in relative superficial positions (i.e. in or near layer 1) or more deeply, extending into the IZ (Fig. 14
). Furthermore, we found that the relationship between the disorganization of CR50-IR cells and the thickness of layer 1 was inversely correlated. Therefore the CR50-IR cells were more disorganized and deeply located in sites where layer 1 was very thin; they were more superficially located, although somewhat disorganized, in sites where layer 1 was thicker (Figure 14
). Inspection of the sections in the E24 MAM-treated animals indicated that the CR50-IR cells appeared to occur in a greater density. To assess this possibility we counted the CR50-IR cells in a defined region of normal and E24 MAM-treated brains. Within a defined region of neocortex (see Materials and Methods), there are approximately the same numbers of CR50-IR cells in normal (n = 1593.6) and E24 MAM-treated brains (n = 1618.2). Because the E24 MAM-treated brains are substantially smaller than normal brains, more cells distribute over a smaller area, although approximately the same number of cells are present.
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To help determine the time course of events in the abnormal vimentin and GFAP immunoreactivity, MAM was injected on E24 and the embryos removed by cesarean section on E27 or E35, for one set of kits each. The E27 time point allowed a relatively short interval between the administration of MAM and the assessment of radial glial morphology, as revealed by staining with antibodies directed against vimentin. On E27, the pattern of immunoreactivity appeared similar to that seen in both the normal and E33 MAM-treated animals, but somewhat sparser (Fig. 15). Although the pattern of staining was sparser than that seen in normal P0 animals and fetuses at later embryonic dates (e.g. E38), the stained processes were distinctly radial and extended from the VZ to the pial surface. Nissl stains of this material demonstrated that the elements of the cortical plate formed by E27 appeared relatively normal. At this time point, although very thin, there was no obvious disruption of the cortical plate; layer 1 was present and contained cells, including presumptive neurons. In kits studied at E35 after E24 MAM treatment, vimentin immunoreactivity was distorted and the radial glia were not aligned in their normal radial pattern.
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Discussion |
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MAM has been used by a number of researchers to interfere with the development of a specific neocortical layer or layers. These and the present study indicate that MAM treatment is relatively discrete, and acts for a restricted window of time (Kind et al.,1992; Woo and Finley, 1996
; Woo et al., 1996
; Cattabeni and Di Luca, 1997
). In our study, the differences between injections of MAM at early and mid-gestational points during cortical neogenesis are dramatic. Later injections (E33) result in a relatively distinct disruption of layer-specific development (Kind et al.,1992; Woo et al., 1996
). Subsequent injections of BRDU indicate that cells continue to be generated and migrate into the cortex in a layer-specific manner after MAM treatment. Although there may be effects on later generated cells, these are not evident. Early MAM injections, however, severely disturb the formation of cortical layers and result in distorted radial glial cells. Injections of MAM early during cortical genesis almost certainly interfere with the division of precursor cells as well as cells undergoing their final division at the time of injection, which could contribute to a poorly formed laminar pattern. We cannot rule out that the thin and disarrayed cortical plate after early MAM treatment is partially due to eliminating a portion of precursor cells that are substrates for subsequently born cells. Cells continue to be born and migrate into the cortical plate, however, after early MAM treatment. BRDU is incorporated into dividing cells at several time points after the MAM injection (e.g. Figs 7, 8
) suggesting that auxiliary mechanisms contribute to the jumbled cortical pattern in addition to a possible reduction in cortical precursors.
We believe that the data presented here support the idea that MAM eliminates a cohort of cells generated at the time of injection, i.e. E24 or E33. This treatment leads to relatively minor architectural changes after the E33 injection and relatively major structural and histochemical changes after the E24 injection. The mechanism of action of MAM has been well described and, as indicated above, several other investigators find that MAM interferes with the generation of neocortical layers by eliminating a specific population of cells. There remains the possibility that the administration of MAM acts in some other (i.e. toxic) way that alters cellular function, leading to the findings reported here. Several studies identify MAM as a carcinogen, but those experiments have used either dosages much higher than those used here, or multiple doses (Zedeck and Swislocki, 1975; Zedeck and Brown, 1977
). Our interpretation is also supported by the observation that MAM injections during later stages of corticogenesis (E33) do not result in any of the changes observed in radial glia or CajalRetzius cells.
MAM treatment may also interfere with the development of other neural centers that influence the neocortex, most notably the thalamus. Although we cannot completely discount the possibility that an alteration in thalamocortical projection influenced the development of cortical layering, in ongoing parallel studies we find a strong projection from the thalamus to the neocortex in similar E24 MAM-treated animals (Palmer et al., 1997). In addition, Algan and Rakic (1997) using a different model of cell cycle disruption, ionizing radiation, found that delivering doses of X-rays during the development of the lateral geniculate nucleus does not substantially reduce the thickness of the visual cortex or the overall laminar pattern, suggesting that these particular features are not dramatically altered by reduced input from the thalamus. This treatment does, however, reduce the total surface devoted to area 17.
Our analysis of MAP2-positive cells in the subplate region finds that the number of MAP2-IR cells are drastically reduced in the animals treated with MAM on E24 compared to normal animals. This analysis was confined to the subplate region and it is possible that cells technically belonging to the subplate may be elsewhere, ectopically placed. Theoretically, subplate neurons may be generated before or after the MAM injection, since subplate neurons that populate somatosensory cortex are born over a period of several days (Noctor et al., 1997) and could be found in the subplate region, or may be located in other sites because of a failure to migrate properly. The likelihood that ectopically placed neurons are present is confirmed by our BRDU data (Figs 6, 7
), which show that in the E24 MAM-treated animals a greater percentage of BRDU-positive cells are found in the IZ than in normal animals. The BRDU-positive cells identified in Figures 6 and 7
are not subplate neurons since they are BRDU-labeled on dates after the MAM injection and after the birth of the subplate. Even if we counted ectopically placed MAP2 neurons, we could not be sure if they were cells intended for the subplate or other layers. The counting of MAP2-positive cells that we accomplished in Figure 9
demonstrates that cells intended for the subplate have not made it to that site; it is possible that a few subplate cells were born and have located elsewhere, i.e. in the IZ or cortical plate. Probably, many subplate cells are eliminated by the MAM treatment, and some get lost in the IZ or are inappropriately located in the cortical plate.
Shortly after early MAM injection (on E27 after E24 injection) both the radial glia and cortical plate look relatively normal. This suggests that the process of disorganization does not begin immediately, but takes place over a period of some days. In addition, injections of BRDU at different dates after early MAM treatment indicate that neurons continue to be born and make their way to the cortical plate. In fact, 4 days after (E28) the early MAM injection, BRDU injections reveal that cells continue to be born and migrate into cortex in numbers at least equal to the normal animal. They form a quasi-laminar pattern, with the greatest percentage of cells born on that day reaching the cortex (Figs 6, 7). BRDU injections at a later time (E38) after early MAM injection, show that cells continue to be born, but fewer are found in the cortical plate at P0. Even in the normal animal at this age the migrating cells have not clearly attained their discrete laminar arrangement and maintain a substantial presence in the IZ. They would normally reside in layer 2 if further development and migration were permitted. Since the disrupted pattern of radial glia takes place gradually after E24 MAM treatment, the earlier born neurons may travel into cortex more easily than those generated later.
Effects of MAM Treatment on Radial Glia
One of the more dramatic features of early MAM injections is the disorganized radial glia. Our interpretation that radial glia are disorganized after early MAM treatment is supported by observations that include lack of radial organization in the IZ after dextran injections in acute slices, absence of a normal pattern of vimentin immunoreactivity, and a substantial increase in GFAP immunoreactivity (demonstrated immunohistochemically and with Western blots). Why would early MAM injections result in a distorted distribution of radial glia, while the late MAM injections have no effect on these cells? It is generally assumed that radial glia are generated early in cortical development and are present when neurons that populate the cerebral cortex are born (Schmechel and Rakic, 1979; Altman and Bayer, 1991
). They then provide, at least partially, a scaffold for neurons to reach the neocortex (Rakic, 1971
, 1972
, 1977
, 1990
, 1995
). This idea seems to be validated by the current study, since several days after early MAM injection at E24, the radial glia are present and relatively intact. The radial glia are apparently in place at the time of MAM injection at E24; the process of radial glial distortion takes place over a period of several days, supported by our observation that 3 days after injection the cortical structure appears relatively normal, but by birth is highly abnormal in appearance. MAM treatment alone does not seem to cause specific distortion or death of radial glia, since later injections do not result in radial glial malformation (e.g. injections on E33). Therefore a specific aspect of interfering with early, but not later, developing cortex results in this process. The observation that early injections of MAM result in radial glial distortion also argues against the idea that disruption of radial glia is due to reactive gliosis. If the glial distortion was due to reactive gliosis, as a result of MAM injection alone, one would expect this finding after later injections of MAM as well. We cannot entirely eliminate the possibility, however, that other undetected effects of MAM treatment may occur that influence neural development.
It seems highly likely that the radial glia are differentiating into astrocytes earlier than normal. It is widely accepted that many radial glia become astrocytes after they are no longer necessary as guides for neurons traveling to the neocortex (Schmechel and Rakic, 1979; Raff, 1989
; Voigt, 1989
, Culican et al., 1990
). Our demonstration of a change in morphology, plus increased expression of the characteristic marker for astrocytes, GFAP, strongly suggests that the radial glia of early MAM-treated animals differentiate into astrocytes. If this is the case, several mechanisms might contribute to this conversion. Early interruption of the generation of cortical cells will block (at least partially) the formation of the cortical layers produced first, including the subplate. It is not clear which comes first: the failure of layers to form or the disruption of radial glia. One possibility is that the lack of a feature normally supplied by the early generated neocortex causes the radial glia to differentiate into astrocytes. The subplate is a substantial component of the early generated neocortex and contains many cell adhesion and extracellular matrix molecules that are not present in other parts of the developing cortical plate (see Allendoerfer and Shatz, 1994, for review). These molecules may be important for maintenance of radial glial attachment, as well as for axonal guidance or other growth processes. Interestingly, Hunter and Hatten (1995) demonstrated that a diffusable factor present in mouse embryonic neocortex induces astrocytes to alter their cell phenotype into radial glia-like. They suggest an inhibitory factor may be present during cortical neogenesis and layer formation, which maintains radial glia in their proper morphology. With cortical maturity, this factor is withdrawn and radial glia are free to differentiate into astrocytes. It is possible that in our study, the early MAM treatment induces withdrawal of the normally present inhibition resulting in early formation of astrocytes. The subplate, with its high complement of trophic substances may be a source for the factor causing radial glia differentiation. In normal ferrets, transformation of radial glia into astrocytes is coincident with the developmental period in which subplate neurons disappear from the cortex (Voigt, 1989
; Allendoerfer and Shatz, 1994
; Juliano et al., 1996
). Although our study of E27 embryos after E24 MAM treatment suggests that the cortical layers begin to form normally after MAM treatment, perhaps after transformation of the radial glial guides, newly generated cortical neurons cannot find their way to the cortex, leading to the severely disrupted cortical pattern we observed. A recent study by Hunter-Schaedle (1997) reports that radial glia in the reeler mouse are also disrupted and display early differentiation into astrocytes. She suggests that poorly developed radial glia may participate in the disturbed formation of layers in the reeler neocortex.
Involvement of Layer 1 and CajalRetzius Cells
Abnormal radial glia may also be induced due to an incomplete formation of the preplate at the time of early MAM injection. During early cortical genesis, the first generated component of the neocortex is the preplate, which consists of the marginal zone (future layer 1) and the subplate (which largely dies in the adult). As cortical neurons are generated, the preplate splits into a superficial marginal zone and a deeper subplate to allow neurons of the cortical layers to insinuate themselves in between the two preplate layers. If early MAM treatment interferes with normal marginal zone formation, a usual substrate for radial glia would not be intact and might cause early astrocytic differentiation. The results presented here indicate that although layer 1 is present after early MAM treatment, it varies in thickness and an important cellular component of this layer is highly distorted. We found that the cells identified by CR50-IR cells (presumptive CajalRetzius cells) were not in their normal position in layer 1, but in disarray throughout the thickness of the cortical plate and into the IZ. Many researchers suggest that layer 1, and particularly the CajalRetzius neurons, play an important role in attracting and guiding subsequent neurons to their proper positions (e.g. Caviness and Rakic, 1978; Marin-Padilla, 1984
, 1998
; Ogawa et al., 1995
). Several lines of evidence suggest that CajalRetzius cells provide an environment that acts as a stop signal both for neurons migrating into the neocortex and axons growing into the cortex (Hirotsune et al., 1995
; Ogawa et al., 1995
; Del Rio et al., 1997; Frotscher, 1997
; Marin-Padilla, 1998
). In our study, the CR50-IR cells were disorganized and may further contribute to the poorly formed cortex after E24 MAM treatment. If the CR50-positive cells act as a stop signal, misplaced layer 1 neurons may induce migrating cells to stop before they enter the cortical plate. Furthermore, a recent study by Soriano et al. (1997) reports that CajalRetzius cells strongly influence the phenotype of radial glia in adult and developing cerebellum.
We do not know the mechanism contributing to the dispersed CR50-IR cells. Two scenarios seem possible: (i) distortion of the radial glial cells contributes to, or causes, the CR50-IR cell dispersion or (ii) the presumptive CajalRetzius cells are generated after the radial glial disruption and migrate to inappropriate positions without appropriate radial glial guides. Without further experiments, it is difficult to distinguish between these two possibilities, but available evidence strongly suggests that layer 1 CajalRetzius cells and radial glial cells are among the earliest generated components of neocortex and are probably already present during most of corticoneogenesis including the time of MAM injections. Since there are roughly the same number of CR50-positive cells in normal and E24 MAM-treated brains, it is likely that they exist at the time of the MAM injection and become distorted after further development. In addition, our earlier study, which determined the birth dates of neurons populating ferret parietal cortex, suggested that layer 1 cells are born prior to E24 (Noctor et al., 1997). It is probable, although hypothetical, that the disruption of radial glia and presumptive CajalRetzius cells occur together and the distortion of both elements reinforces the inability of the cortical plate to form properly in the E24 MAM-treated animals.
Relation to Reeler and Other Mouse Mutants
The effects of E24 MAM treatment are clearly not identical to those of the reeler mutant mouse, although there are some similarities. The cortical layers fail to form properly in both models. In both animals there is a disruption of reelin, although the mechanism is obviously different in the two animals. In the reeler mutant, the gene encoding reelin is absent, and this protein is not manufactured. In the E24 MAM-treated animal, reelin is present, as revealed by the CR50 antibody, but in inappropriate loci. The scrambler mutant, which also displays a disrupted laminar pattern, appears to have normal distribution of reelin, although the reeler gene pathway may be involved in the inverted cortical pattern (Gonzalez et al., 1997). These results imply that reelin is likely to be involved in guiding neuronal migration into the neocortex, as others have suggested. In addition, evidence from the reeler mouse mutation suggests that a specific feature of the preplate is important for subsequent formation of neocortex. Although in reeler the preplate fails to split and cortical layers pile up underneath the superficial structure (Caviness and Sidman, 1973
), the presence of the preplate itself is consequential to several features of subsequent cortical development. In this model, thalamocortical afferents first touch the subplate before turning and terminating in layer 4, suggesting that the preplate itself is an important feature for cortical development (Frost and Caviness, 1980
). If the formation of this region is disrupted after early MAM treatment, it may also contribute to the malformation of cortical layers and radial glia by removing a necessary component of proper cortical development.
Summary
These results are consistent with the idea that early generated cortex is necessary for proper laminar formation in the neocortex. The early generated layers may provide cues to the radial glia about where to maintain their processes and when to differentiate into astrocytes. Without the substrate normally provided by the first born layers of neocortex, the radial glia lose their spoke-like orientation and begin astrocytic differentiation. Concomitant with the radial glial distortion, presumptive Cajal Retzius cells become displaced, and further contribute to the malformed cortex.
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Notes |
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Address correspondence to Sharon L. Juliano, Department of Anatomy & Cell Biology, USUHS, 4301 Jones Bridge Road, Bethesda, MD 20814, USA. Email sjuliano{at}usuhs.mil.
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