Sequence of Neuron Origin and Neocortical Laminar Fate: Relation to Cell Cycle of Origin in the Developing Murine Cerebral Wall

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The Journal of Neuroscience, December 1, 1999, 19(23):10357-10371

Sequence of Neuron Origin and Neocortical Laminar Fate: Relation to Cell Cycle of Origin in the Developing Murine Cerebral Wall
T. Takahashi¹^,², T. Goto¹^,², S. Miyama¹^,², R. S. Nowakowski³, and V. S. Caviness Jr¹
¹ Department of Neurology, Massachusetts General Hospital, Harvard Medical School, Boston, Massachusetts 02114, ² Department of Pediatrics, Keio University School of Medicine, Tokyo 160, Japan, and ³ Department of Neuroscience and Cell Biology, University of Medicine and Dentistry of New Jersey-Robert Wood Johnson Medical School, Piscataway, New Jersey 08854

  ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Neurons destined for each region of the neocortex are known to arise approximately in an "inside-to-outside" sequence froma pseudostratified ventricular epithelium (PVE). This sequenceis initiated rostrolaterally and propagates caudomedially. Moreover,independently of location in the PVE, the neuronogenetic sequencein mouse is divisible into 11 cell cycles that occur over a 6d period. Here we use a novel "birth hour" method that identifiessmall cohorts of neurons born during a single 2 hr period, i.e.,10-20% of a single cell cycle, which corresponds to ~1.5% of the6 d neuronogenetic period. This method shows that neurons arisingwith the same cycle of the 11 cycle sequence in mouse have commonlaminar fates even if they arise from widely separated positionson the PVE (neurons of fields 1 and 40) and therefore arise atdifferent embryonic times. Even at this high level of temporalresolution, simultaneously arising cells occupy more than onecortical layer, and there is substantial overlap in the distributionsof cells arising with successive cycles. We demonstrate additionallythat the laminar representation of cells arising with a givencycle is little if at all modified over the early postnatal intervalof histogenetic cell death. We infer from these findings thatcell cycle is a neuronogenetic counting mechanism and that thiscounting mechanism is integral to subsequent processes that determinecortical laminarfate.

Key words: neocortical histogenesis; neuronogenesis; pseudostratified ventricular epithelium (PVE); cell cycle; neuronogenetic sequence; transverse neuronogenetic gradient

  INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The laminar structure of the neocortex arises through a series of histogenetic processes that are initiated with neuronogenesisin a pseudostratified epithelium at the ventricular margin [pseudostratifiedventricular epithelium (PVE); see Fig. 1] (Sauer, 1935; Sidmanet al., 1959; Takahashi et al., 1995). Neuronogenesis is followedby neuronal migration (Rakic, 1972, 1978), assembly of neuronalsomata into layers (Rice and van der Loos, 1977; Rakic, 1981),and reduction of neuronal number by histogenetic cell death (Finlayand Pallas, 1989; Verney et al., 1999).

Traditional pulse labeling "birthday" studies have established that sequence of origin is more or less correlated with laminarorder. Thus, neurons destined for the deepest layer arise first,with cells destined for successively more superficial layers arisingmore or less in sequence thereafter (see Fig. 1A). For this reason,it has been hypothesized that proliferative mechanisms that determinesequence of origin are linked with those that determine the laminarfate of cells (Caviness, 1982; McConnell, 1989, 1991; McConnelland Kaznowski, 1991). A test of this hypothesis requires a criterion,independent of time (e.g., as measured in embryonic days), bywhich to define sequence of neuronogenetic order. Such a criterionis necessary because the sequence advances along a rostrolateralto caudomedial "transverse neurogenetic gradient" (Hicks and D'Amato,1968; Bisconte and Marty, 1975a; McSherry, 1984; McSherry andSmart, 1986; Bayer and Altman, 1991). Hence, corresponding eventsin the proliferative sequence occur at different times, with rostrolateralto caudomedial progression across the cerebralwall.

The cell cycle of origin is a suitable candidate criterion for progression of neuronogenetic sequence. We have previouslyestablished for the greater part of the transverse neurogeneticgradient in mouse that the neuronogenetic interval advances througha sequence of 11 cell cycles, and corresponding cycles are uniformin their kinetic and output parameters (Takahashi et al., 1995;Miyama et al., 1997).

For this analysis we exploit an innovative double S-phase labeling method (Takahashi et al., 1996a) (see Fig. 2) that specifiesthe "birth hour" of neurons at a 10-fold or better temporal resolutionthan standard "birthdating." The method is applied for two reasonsin neocortical fields 40 and 1 (see Fig. 1C). First, they lieat the rostrolateral (field 1) and dorsomedial (field 40) extremesof the transverse neuronogenetic gradient. Hence, correspondingevents in the neuronogenetic sequence will occur in the PVE givingrise to these two fields at different times. Second, we have previouslyestablished the timing of advance of the 11-cycle sequence inthe sectors of the PVE that give rise to each of these two fields(Takahashi et al., 1995; Miyama et al., 1997). Thus, in this analysiswe are able to correlate for extreme positions in the transverseneuronogenetic gradient of the PVE the laminar destiny of neuronsas a function of their cell cycle oforigin.

  MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Sequential S-phase labeling
We have devised in mouse a sequential S-phase labeling schedule using a single pulse of tritiated thymidine (³H-TdR) followed by cumulative label with bromodeoxyuridine (BUdR)(Takahashi et al., 1996b) that marks cohorts of neurons arisingin synchrony during a 2 hr interval as ³H-TdR-only-labeled cells (see Figs. 2, 3). Cells, which are eitherin S phase at the end of the 2 hr interinjection interval or whichre-enter S during a subsequent cell cycle, become labeled withBUdR and hence are not counted. Thus, the method, which is independentof the availability time of the tracers (Hayes and Nowakowski,1999), specifies literally the birth hour and not only the birthdayof neuron cohorts. Such cohorts represent 2 hr/T_C × 100% (T_c,total cell cycle duration) of the total output of a single cellcycle. Given that T_c increases as neuronogenesis proceeds (Takahashiet al., 1992, 1995, 1996a; Cai et al., 1997), 2 hr/T_C × 100% variesfrom ~20% [embryonic day (E) 12 or E12-E13] to 10% (E15-E16).Because there are 11 cell cycles during the 6 d neuronogeneticinterval in mouse, one cell cycle is 1/11 or ~9% of the totalnumber of cell cycles of neuronogenesis. Therefore, the "temporalresolution" of the 2 hr cohort labeling method used in this analysiswill be 9 × 10-20% or ~1-2% of the total neuronogenetic intervalinmouse.
In contrast, the maximum possible temporal resolution of the standard ³H-TdR pulse is (T_s + Clearance)/T_c, where T_s is the length ofS phase and "Clearance" is the clearance time for ³H-TdR, which for long survivals is several hours, i.e., approximatelythe length of S (Hayes and Nowakowski, 1999). In mouse this variesfrom 80-100% of the cell cycle at E11 to 40-50% of the cell cycleat E16 (Takahashi et al., 1995). Moreover, in practice the resolutionof the standard ³H-TdR pulse method in mouse is substantially less than a singlecell cycle because labeled cells have a wide number of silvergrains, indicating that they arise from several cell cycles insequence after the exposure to ³H-TdR (Angevine, 1965; Sidman, 1970; Polleux et al., 1997a). Thus,the standard birthday methods may have a resolution of two tothree cell cycles or ~20-30% of the total neuronogenetic interval,i.e., >10 times less resolution than the 2 hr cohort method. Inthe rhesus monkey (Rakic, 1974), where cell cycles are known tobe severalfold longer than the cycles in rodents, a cohort of³H-TdR heavily labeled cells will represent a lower fraction ofthe total output of a single cell cycle than in rodents (~25%at E40 at the outset of neuronogenesis) (Kornack and Rakic, 1998).Furthermore, there may be approximately 28 cell cycles duringa 2 month neocortical neuronogenetic interval in monkey, so thatone cell cycle is <4% of the total number of cell cycles occurringin the course of neuronogenesis (Caviness et al., 1995). Therefore,the approximate temporal resolution of the standard ³H-TdR pulse will be 4 × 25% or 1% of the total neuronogeneticinterval in monkey. Thus, this double-labeling cohort method inmice and the standard ³H-TdR pulse method in monkey may be expected to sample comparableportions of the neuronogenetic interval in the two species. Thereis the additional advantage that this method permits a quantitativeestimate of the total output of the cell cycle represented byeachcohort.

Animals and procedures
CD1 mice were maintained on a 12 hr (7:00 A.M.-7:00 P.M.) light/dark schedule. Conception was ascertained by the presenceof a vaginal plug (the day of conception = E0). Intraperitonealinjections of ³H-TdR (5 µCi/g body weight) were given at 7:00 A.M. to separatesets of dams on E11-E16 (see Fig. 2). Beginning at 9:00 A.M.,BUdR injections (50 µg/g body weight) were given at 3 hr intervalsthrough a period greater than T_C $-$ T_S determined previously forthe respective embryonicdate.
The pregnancy was allowed to continue to term, and pups were maintained until postnatal day 22 (P22), when they were anesthetizedwith ether and perfused via the left ventricle with 70% alcoholfor 3 min. They were dehydrated and embedded in paraffin and sectionedcoronally at 4 µm (Takahashi et al., 1992, 1993, 1994) and stainedimmunocytochemically for BUdR using DAB as a chromogen (Takahashiet al., 1992, 1994). After immunohistochemistry the slides weredipped in Kodak NTB2 nuclear emulsion and kept at 4°C for 6 weeks.They were developed and counterstained with 0.1% basicfuchsin.
For animals exposed on each of the embryonic dates E11-E16, the analysis was performed on data collected from the brains offour animals, two from each of two different litters. In eachanimal, "standard sectors" subjected to analysis in fields 1 and40 were all specified to be 250 µm in medial to lateral dimension(in a coronal section) and 4 µm in depth, corresponding to sectionthickness. With respect to the height or radial dimensions ofthe sector, each was subdivided into radial bins, 25 µm in height,with the bins numbered 1, 2, 3, and so on from the pial surfaceinward (Takahashi et al., 1996b). The number of ³H-TdR-only-labeled nuclei was counted for each bin. Because theheight or radial dimensions of the cortex in the two fields variedmodestly, bin position in the cortex was normalized by conversionto percentile height where percentile height for bin n = (n/N)× 100, where N is the total number of bins within the cortex.The number of ³H-TdR-only-labeled nuclei was then assigned to appropriate percentileheight where the height of the cortex was divided into 20 5-percentilesteps. For each brain the location of cortical laminar boundarieswas also specified with respect to this normalized adjustmentof cortical height so that ³H-TdR-only-labeled nuclei could be assigned to layers as wellas to countingbins.

Cohort distribution
For each of the labeled cohorts at each embryonic date, E11-E16, a "specimen weighted" distribution of cells by density acrossthe height of the cortex was calculated using the following three-stepprocedure.
(1) Number of cells per bin (i.e., per 5-percentile step) per brain. First, the total number of ³H-TdR-only-labeled nuclei in corresponding bins was counted andsummed as the total for that bin for each brain. (Counts werenot undertaken for cells with ³H-TdR + BUdR or BUdR-only labeling patterns because of their largenumbers.) For the E12-E16 cohorts, labeled nuclei were relativelyabundant (a total of 1980 cells were counted in the full set ofspecimens), so these distributions were based on eight sectionsper brain for four brains. For the E11 cohort in field 40, therewere relatively few labeled cells (only 25 cells were countedin four brains), so these distributions were based on counts madein 20 sections perbrain.
(2) Average percentile per bin per brain. For each brain the number of nuclei per bin was divided by the total number of nucleicounted for that brain. The percentiles for corresponding binswere then averaged across the four brains of each embryonic ageto give average percentile per bin perbrain.
(3) Normalized distributions. To enable comparisons of distributions across the full set of embryonic ages, the percentilesper bin per brain were normalized to produce the average numberof nuclei per bin per section. For this distribution, the averagepercentile per bin per brain for the cohorts at each embryonicage was multiplied by the total number of nuclei counted in allof the specimens of that age and then divided by the number ofsections used to obtain the average (i.e., 32, except at E11 when80 was used). This normalized distribution for each cohort hadunits of "number of nuclei per bin persection."
The specimen-weighted procedure was used to minimize the variation that might be produced from specimen-related parameters,i.e., processing differences, slight age differences, plane ofsection, etc. We also calculated an "overall" distribution inwhich every labeled nucleus had equal weight, regardless of thespecimen in which it occurred. The overall and specimen-weighteddistributions were virtuallyidentical.

Distributions for each cell cycle
The final average distribution (from the preceding paragraph; see Fig. 4A) represents the number of cells per 2 hr cohortwhich is only 2/T_C of the entire output for a single cell cycle.Because T_C is known to vary during the neuronogenetic interval,for comparison, each of these distributions was used to estimatethe total number of cells that comprises the output for the entirecycle of which the cohort was a part. This was performed by multiplyingeach bin of each distribution by T_c/2, where T_C for each embryonicday for fields 1 and 40 was taken to correspond to values estimatedpreviously for the dorsomedial cortical zone (DCZ) and lateralcortical zone (LCZ), respectively, of the PVE (Miyama et al.,1997) (see Fig. 4B). Normal approximations for each distributionwere calculated using a least-squares fitting method (Takahashiet al., 1996b) (see Fig. 4C).
The location of each 2 hr cohort within the 11-cell cycle sequence was designated in terms of the fraction of the specificcycle that has been completed in that cortical area (Takahashiet al., 1995; Miyama et al., 1997). Thus, for example, if cyclestatus is designated cycle 6.9, it is meant that the referencepopulation will have completed 90% of the seventh cycle in theseries of 11 cycles (Takahashi et al., 1995; Miyama et al., 1997).Linear interpolation of the normal approximation parameters (i.e.,mean position, amplitude, and standard deviations) were used toestimate the distribution of cells at each integer cell cycle(see Fig. 4D). Interpolations for integer cell cycles before E12(for field 1) or E11 (for 40) and after E16 (for fields 1 and40) used an "imaginary" population of zero size positioned atthe border with the white matter or at the layer I border witha similar standard distribution to the nearest "real" population.All calculations were performed with MicrosoftExcel.

  RESULTS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The present analysis maps the final intracortical distributions of cohorts of cells arising from the murine neocortical PVEover each of the successive E11-E16. Cohorts produced during a2 hr period are mapped at P22 with respect to cortical heightand neocortical layer in both the posterior medial region of thesomatosensory I (SI) (field 1) and SII (field 40) representations(Fig. 1B) (Caviness, 1975). For both fields 1 and 40 we have followedthe standard six-layer convention for neocortical lamination buthave combined layers II and III as a single layer because layerII is typically either very narrow or even indistinguishable asa separate layer in the mouse neocortex (Caviness, 1975).

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Figure 1. Neuronogenesis in the pseudostratified ventricular epithelium (PVE) in relation to the "inside-out pattern" of neocortical layer formation. A, The founder proliferative populations and their progeny in both dorsomedial (DCZ) and lateral (LCZ) cortical zones of the PVE execute 11 cell cycles (CC1-CC11) over the course of the 6 d neuronogenetic interval, continuing from the eleventh (E11) embryonic day through E17 in the DCZ and E10 through E16 in the LCZ. The cycle sequence is initiated earlier and remains advanced by ~24 hr in LCZ relative to DCZ (note for each cell cycle, a 24 hr difference in time of occurrence of corresponding cell cycles in DCZ and LCZ). The first neurons to arise from either region of the PVE are destined for the deepest cortical layers (dotted curved lines connecting the PVE and layers VI and V), whereas progressively later forming neurons are destined for progressively more superficial layers (solid curved lines connecting the PVE and layers IV and II/III). The daughter cells arising from cycle 11 are the terminal output (TO) of neuronogenesis. Curved arrows in the PVE show interkinetic nuclear migration through G1, S, G2, and M phases of the cell cycle. Interkinetic nuclear migration is shown for CC2 in the magnified view in the inset in top left. A fraction of postmitotic cells (Q) leaves the PVE with each cycle and migrates toward the surface of the hemisphere as young neurons. B, C, DCZ and LCZ of the PVE of the embryonic cerebral hemisphere (B, coronal cutaway) give rise (curved arrows connecting B and C) to neurons destined, respectively, for fields 1 and 40 in the adult hemisphere (C, coronal cutaway).

The analysis exploits the fact that in the same coronal histological section cohorts distributed to fields 1 and 40 and arisingat the same embryonic date will have arisen from quite differentcell cycles (Miyama et al., 1997) (Fig. 1A). We have previouslydetermined from the patterns of alignment of radial glial fibers(Misson et al., 1991) that field 1 receives its neuronal complementprincipally from DCZ and field 40 from LCZ of the PVE (Fig. 1B,C)(Miyama et al., 1997). The additional evidence established inthis analysis is that the neuronogenetic interval giving riseto neurons of field 1 continues from early E11 (with the labelingparadigm used here, ³H-TdR-only-labeled cells were first observed on this date) toearly E17 (the last date ³H-TdR-only-labeled nuclei were observed). This corresponds tothe neuronogenetic interval in DCZ, whereas the neuronogeneticinterval for field 40 continues from late on E10 through E16 correspondingto the neuronogenetic interval of LCZ.

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Figure 2. Labeling schedule for the birth hour of a 2 hr cohort. Proliferative cells in the PVE within the ventricular zone (VZ) are asynchronously distributed through G1, S, G2, and M phases of cell cycle (top, left panel, open eclipses lined up inside the circle; M phase nuclei are shown as open circles with two zigzag lines). The PVE was exposed initially at 7 A.M. to ³H-TdR (arrowhead with "silver grains"), which was followed in 2 hr by BUdR (filled arrowhead). Cells that exit S-phase in the 2 hr interval between these exposures, and their postmitotic progeny, will be labeled with ³H-TdR but not BUdR (white nuclei with grains). They are readily distinguished in autoradiograms (a curved arrow with an asterisk = 2 hr cohort) from cells labeled in S phase by both ³H-TdR and BUdR (dark nuclei with grains) or cells labeled only by BUdR (dark nuclei with no grains). BUdR injections were continued (open arrowheads) for a time longer than the combined duration of G2, M, and G1 phases of the cell cycle (i.e., >T_C $-$ T_S) so that postmitotic cells reentering S phase (P or P fraction) will become marked with BUdR (bottom left, dark nuclei with grains under the letter P). The postmitotic daughter cells that leave the cycle (Q fraction of the original 2 hr cohort) may be recognized subsequently as cells labeled only by ³H-TdR (bottom left, white nuclei with grains, next to the letter Q). At P22, long after their migrations across the intermediate zone to the CP and redistribution in the cortex, their locations with respect to layers I-VI within fields 1 and 40 are mapped from autoradiograms.

Cohorts by day of origin

Similarities in cohort distribution in fields 40 and 1
The labeled cohort of cells born within a 2 hr interval can be readily identified as being labeled only with ³H-TdR (Fig. 3, arrowheads). The number of cells in each 2 hr cohortis relatively small, and in the cortex as a whole, as expected(see Materials and Methods), the number of cells doubly labeledwith both ³H-TdR and BUdR (Fig. 3, curved arrowhead) is much greater thanthe number of cells in the 2 hr cohort. Because the total numberof ³H-TdR (singly labeled plus doubly labeled) corresponds to a "standard"³H-TdR birthday experiment, the small number of cells in the 2hr cohort confirms the high temporal resolution of the method.

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Figure 3. Distribution of the E13 cohort in field 1. A cohort of cells leaving S phase in synchrony over the 2 hr interval between 7 and 9 A.M. on E13 were marked by the sequential ³H-TdR-BUdR exposure schedule described in Figure 2. The Q fraction of the postmitotic daughter cells of this cohort (arrowheads, cells labeled only with ³H-TdR) are distributed over the height of layer VI in field 1. Filled arrows, Cells labeled only with BUdR; curved arrows, cells labeled with both ³H-TdR and BUdR; open arrows, nonlabeled cells. Dotted line marks the white matter/layer VI boundary. L, Lateral ventricle. Scale bar, 10 um.

On day of E11-E16, the 2 hr cohort is distributed across a limited span of the cortical height of fields 40 and 1 (Figs. 3,4A). In both cortical fields the earliest arising cohort occupiesthe deepest cortical laminae, and the latest arising cohort occupiesthe most superficial cortical laminae. This pattern, in confirmationof previous investigations in all mammalian species (Angevineand Sidman, 1961; Hicks and D'Amato, 1968; Fernandez and Bravo,1974; Rakic, 1974; Caviness, 1982; Luskin and Shatz, 1985; Bayerand Altman, 1991), is evident whether illustrated from the perspectiveof the distribution of a cohort in single animals (Fig. 5) orfrom the mean distributions of the cohort across sets of animals(Fig. 4A). A systematic shift from deep to superficial positionsin the cortex is evident with each successive cohort, both withrespect to the mean and median position of the labeled cells andalso with respect to their range of distributions (Fig. 6).

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Figure 4. Distributions within fields 1 (left) and 40 (right) of neuronogenetic output with respect to both embryonic days and cell cycles. For each plot, the height of fields 40 and 1 have been normalized as a percentile (abscissa), and the projection of the cortical layer has been scaled appropriately to each field. The shaded bars at the bottom indicate the borders of each of the cortical laminae. A vertical dotted line in each of the graphs marks the boundary between layers V and IV (also see Materials and Methods). A, The positions of cells of 2 hr cohorts, labeled on each of embryonic days. The average number of cells of each cohort observed in a standard coronal sector per section is given on the ordinate. The individual cohorts are identified with respect to both their embryonic day of origin (E11-E16) and their cell cycle of origin (in parentheses after embryonic date). Note that cells of an E11 cohort are detected in field 40 but not in field 1. In field 40 the E11 cohort arises near the completion of cycle 3 (at cycle 2.9). B, The plot of 2 hr cohort distribution represented in A is transformed to output of corresponding cell cycle by multiplying the number per cohort by T_C/2 hr (T_c = cell cycle length in hours) for the respective cycle. Note that the form of each distribution in plots A and B is the same but that the number of cells per distribution on the ordinate in B is larger than in A, and the relative heights are changed because of the lengthening of the cell cycle. For A-D, the distributions represent "net output," that is, the populations remaining after cell death (Verney et al., 1999). C, For each of the distributions plotted in B, a "best fit" normal distribution was calculated. These normal distributions account for virtually all of the variance seen in B; see Results. D, The contribution of the output of each of the full 11-cycle series is reconstructed as normal distribution by interpolation from the curves shown in C. Note that a portion of the output of cycles 1-5 is not represented within the six layers of the cortex and is assumed to have contributed to the subplate and been eliminated by cell death. TO refers to the terminal output after cycle 11 (Takahashi et al., 1996a).

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Figure 5. Animal to animal variation in neuron distribution by cohort. The distributions of the E12-E16 cohorts, normalized to percentile height, are plotted for separate animals in fields 1 (left) and 40 (right). The projection of the cortical layers, scaled appropriately to each field, is shown at the bottom. The distributions are essentially indistinguishable except for the cohorts distributed to midcortical layers that vary from animal to animal. These are the E13 cohort in field 40 and the E14 cohort in field 1 (bars above distributions). See Results for details.

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Figure 6. Intracortical distribution presented as median and range that contains 95% of the cells in each 2 hr cohort. Distributions within fields 1 and 40 are mapped for each embryonic day with respect to cortical height expressed as percentile (on the ordinate). The 95% range of distributions is some 22-56% of the cortical height. Note that an E11 cohort is present only in field 40. The distributions of E13 and E14 cohorts diverge sharply in fields 1 and 40 (A). By contrast, the distributions of cohorts with respect to cell cycle of origin (B) are closely similar in the two cortical fields. The bars on the right show the laminar borders for each cortical area.

Although each 2 hr cohort is a sampling of <10% (= 2/24 hr) of the output of its respective day of origin, there are no "gaps"between adjacent distributions. Indeed, the full sequence of cohortsarising successively on E11-E16 within both field 40 and field1 comprises a set of overlapping distributions that, taken together,span the full height of the cortex (Figs. 4A, 6). Although thefraction of the cortical wall subtended by a single 2 hr cohortis substantial, it is smaller, as expected, than the fractionof the cortical wall subtended by cells labeled by a single "pulse"of ³H-TdR in a traditional birthday analysis (Bisconte and Marty,1975b; Caviness, 1982; Bayer and Altman, 1991; Polleux et al.,1997a,b).

Differences in cohort distribution in fields 40 and 1
Cells with the same embryonic day of origin are distributed more superficially in field 40 than in field 1 (Figs. 4A, 6A),a difference to be expected given the substantial distance upthe transverse neuronogenetic gradient of field 40 with respectto field 1 (Bayer and Altman, 1991; Miyama et al., 1997). Thesuperficial shift in cohort distributions in field 40 with respectto field 1 on E14 is much greater than that in cohorts arisingon E13 and earlier and in cohorts arising on E15 and later (Fig.6A). The distribution of cells of the E14 cohort in field 40 islimited almost completely to layer IV, whereas in field 1 cellsof this same cohort are limited almost entirely to layers VI-V(Fig. 4A). This confirms the earlier observations in mouse bySmart (Smart and McSherry, 1982; Smart and Smart, 1982) that movementup or down the transverse neuronogenetic gradient (as lateralto medial or medial to lateral) through the cortex is associatedwith only moderate differences in distribution of cells of a givendate of origin when the distribution is centered over layers VIor II/III but with substantial differences in such distributionswhen the distributions are centered over layers V-IV.
This difference in layer destination in fields 40 and 1 of neurons arising on the same embryonic day underscores the longestablished observation that there are systematic shifts in timeof enactment of corresponding proliferative events across thePVE (Hicks and D'Amato, 1968; Smart and McSherry, 1982; McSherry,1984; Bayer and Altman, 1991). Judging from the finding that themidcortical distribution of the E13 cohort in field 40 is thesame as that of the E14 cohort in field 1 (Fig. 4A), it wouldappear that the sector of PVE giving rise to field 40 is advanced~24 hr with respect to the sector giving rise to field 1. Thisis consistent with a 24 hr advance in the proliferative processin LCZ with respect to DCZ (Fig. 1A), which was established tobe the case in an earlier analysis based on independent methods(Miyama et al., 1997).

Embryo-to-embryo variation in cohort distribution in fields 40 and 1
Animals from the same litter may differ by as much as 20 hr in their relative maturities (Theiler, 1972; Smart and Smart,1982). We evaluate here whether the temporal resolution of the2 hr cohort method is sufficiently sensitive to detect possibledifferential maturity in embryos of the same litter expressedas slight differences in cohort distribution (Fig. 5). Observationsare based on cohort distributions in four embryos at each age,two animals from each of two litters. With the exception of thecohorts arising on E13 (field 40) and E14 (field 1), the intracorticaldistributions at each age in both fields 1 and 40 are substantiallyoverlapping and virtually indistinguishable in all four specimens.At E13 (field 40) and E14 (field 1), however, there are slightdifferences in the deep to superficial order of the peak densitiesacross midcortical layers. We infer that these slight differencesin distribution of these cohorts reflect relatively small differencesin sequence of origin caused by small differences in relativematurity, evident even in comparison of the paired animals fromthe same litters. That embryo-to-embryo differences should bemost readily evident in this way at E13 (field 40) and E14 (field1) is to be expected. This is because relatively small differencesin sequence of origin are associated with relatively large differencesin laminar distribution (see Differences in cohort distributionin fields 40 and 1), particularly for the midcortical layers thatare formed on E13 in field 40 and on E14 in field 1. The relativeuniformity in distribution overall is presumed to reflect theselection of embryos that were at similar stages ofmaturity.

Cohort distribution at P0 as compared with that at P22
The original cycle output sampled by a 2 hr cohort will have been reduced by histogenetic cell death by P22, a process thatappears largely to run its course by the end of the second postnatalweek in mice and rats (Leuba et al., 1977; Finlay and Slattery,1983; Finlay and Pallas, 1989; Ferrar et al., 1992; Miller, 1995;Spreafico et al., 1995; Verney et al., 1999). Thus, the cohortsample at P22 (Fig. 4A,B) represents the net total of output andcell death. Where we use the expression "net output" in the contextof this manuscript, it is understood that what is intended isthe net contribution or output by cycle followed by cell death.To estimate the qualitative contribution of cell death to thedistribution of the cohorts, we examined the distribution patternsof each of the E13-E15 cohorts at P0 in each of the fields 1 and40 (Fig. 7). Only the general shape and location of the distributionscan be compared, because at P0 the cortical plate (CP) (Fig. 7,between the two arrowheads), which is still narrow (because theneuropil has not yet expanded), corresponds to layers II/III-IVin the P22 cortex (at approximately the 50-percentile in Fig.4). With this limitation in mind, it can be seen that the distributionsof each 2 hr cohort at E13, E14, and E15 in both fields 1 and40 at P0 (Fig. 7) are essentially identical to that at P22 (Fig.4A). The closeness of distributions of the same cohort in thesame field at the two ages (P0 and P22) applies for the relativeposition of the peak of the distribution at the two ages withrespect to V/IV border and importantly also for the relativelywide and low density distribution of the "shoulders" of the cohort.Specifically, the E13 peak falls in the lower half of layer VI/V,the E14 peak falls below the V/IV border in field 1 but aboveit in field 40, and the E15 peak falls well within the supragranularlayers (compare Fig. 4A,B with Fig. 7). The largest apparent discrepancybetween the distributions at P0 (Fig. 7) and at P22 (Fig. 4A,B)is that the overlap of the E13 and E14 distributions at P0 seemsto be greatly reduced from P22. This discrepancy is only apparent,however, and is well within the embryo-to-embryo range seen inFigure 5. Overall, therefore, these observations indicate thatthe "laminar footprint" of a cohort of cells, that is, the spanof laminae through which a cohort is distributed, establishedbefore cell death, is not appreciably altered by cell death.

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Figure 7. Intracortical distributions of cohorts of cells arising on E13-E15 determined at P0. The cortical plate (CP, between two arrowheads) at P0 corresponds to layers II/III-IV at P22. Note that the distribution pattern of each cohort at P0 is essentially identical to that at P22 (Fig. 4A).

Magnitude of cohort dispersion
The degree of dispersion within neocortical layers of the sampled 2 hr cohorts may be characterized quantitatively. For thisdetermination (see Materials and Methods) the output of the fullset of 11 neuronogenetic cycles is considered to be distributedto layers I-VI, taken here to correspond to 100% of height ofthe cortex. Here we have ignored the relatively minor neuron distributionof a portion of the E11 cohort to the subplate in mouse, whichis eventually largely eliminated by histogenetic cell death (Verneyet al., 1999). The 2 hr in which each of the labeled cohorts isformed correspond to 1.5% of the total neuronogenetic interval.If sequence of production alone were sufficient to specify corticalposition, then each 2 hr cohort would occupy 1.5% of the corticalthickness. This is clearly not true (Figs. 4A), and if we considerthe 95% range of intracortical distribution for the normalizedfits, each is distributed through ~ 22-56% of cortical height(a mean of 41%) (Fig. 6). That is, the distribution of the outputof only 1.5% of the neuronogenetic interval is dispersed to anaverage of 41% and perhaps as much as 56% of the cortical thickness.This represents a dilution in dispersion of 27-fold (i.e., 41/1.5%)to possibly as much as 37-fold (i.e., 56/1.5%) of the 2 hr cohort.Although dispersion is greater in the middle of the neuronogeneticinterval than at its beginning and end, this difference is relativelyminor. Exceptions to this broad dispersion of neurons are encounteredonly with the earliest arising cohort. Thus, the intracorticalrange of distribution of the E11 cohort, the earliest sampled,is only 5% of the cortical height. Observe, also, that there areonly a few cells in this cohort; we presume that most of the remainderof the cells of this cohort were destined for the subplate andeliminated by histogenetic cell death (Verney et al., 1999).

Cohorts by cell cycle of origin

Each cohort population is synchronized with respect to the time it exits S phase and completes the cycle before exit fromthe PVE (Fig. 2). The proliferative population represented bythe cohort, on the other hand, is cycling asynchronously. Thecycle status of each cohort is represented here as the mean cyclestatus of the region of the PVE from which the cohort arises,as determined by earlier analyses (Takahashi et al., 1995; Miyamaet al., 1997). As noted above, the distribution of the E13 cohortin field 40 matches closely that of the E14 cohort in field 1.An earlier analysis (Miyama et al., 1997) had established thatboth the E13 cohort in field 40 and the E14 cohort in field 1arise with the seventh cycle of the 11-cycle series that constitutesthe murine neuronogenetic interval. Their cycle status is designatedcycle 6.9 (E13 cohort in field 40) and cycle 6.8 (E14 cohort infield 1) because the population of origin will have completed90 and 80%, respectively, of the seventh cycle in the series of11 cycles (Takahashi et al., 1995; Miyama et al., 1997).

When the birth of cohorts is normalized in this way to cell cycle of origin (Fig. 6, compare A, B), it becomes apparent thatthe correspondence in the intracortical distributions in fields40 and 1 is in good accord for the entire series of cohorts. Theaccord is particularly good for cohorts arising through cycle7, which in both fields are distributed in overlapping deep tosuperficial order within the infragranular layers VI-V. The cohortsarising at the end of the neuronogenetic interval, i.e., withcycles 8-11, are similarly distributed to granular and supragranularlayers in both fields 1 and 40, although those in the latter fieldappear to be positioned slightly more deeply than those in field1.

Output per cell cycle
The net output sampled in each cohort (Fig. 4A) is adjusted to net output per cycle by multiplying by T_C/2 for the respectivecycle (Fig. 4B) (see Materials and Methods). Then, a normal distributionwas "fit" to the net output per cycle for each cohort. These normaldistributions account for 86-100% of the observed variance "fitted"(Fig. 4C) (see Materials and Methods). Overall only ~6% of allcells were not accounted for by the normal fits, and the onlycycle for which a normal fit accounts for <90% of the varianceis for the E14 cohort in cortical field 1 (for which R² = 0.86). As mentioned earlier in this manuscript (Embryo-to-embryovariation in cohort distribution in fields 40 and 1), this cohortrepresents the neurons for the mid-region of the cortex (thatis, upper layer VI, layer V, and layer IV) where relatively largedifferences in laminar distribution are probably associated withrelatively small differences in maturity of the sampled specimens(Fig. 5). Although normal distributions are close fits for theobserved distributions of the set of cohorts, these fits are,as noted, not perfect. Each is slightly skewed with respect toa true normal distribution. The observed skew is not systematic,however, in that it is sometimes toward the depth and sometimestoward the surface of the cortex; a plot of the residuals (datanot shown) confirms the impression that the cells falling outsideof the fit to normal distributions are not located in any systematiclocation in thecortex.
The portion of the cells (~6% of the total arising from all cycles) falling outside of the normalized fit may represent "biologicalnoise," for example corresponding, as noted above, to small differencesin relative maturity of the embryos of the same litter (Fig. 5).They also may simply reflect limits of the precision of the totalset of mechanisms that appoint the laminar positions of neuronsin the cortex. We also consider the possibility that certain ofthe neurons with positions outside of the best-fit normal distributionmay arise from proliferative sources outside of the neocorticalPVE. For example, substantial numbers of GABAergic interneuronsmay be formed in the ganglionic eminence rather than in the neocorticalPVE (De Carlos et al., 1996; Anderson et al., 1997; Tamamaki etal., 1997; Lavdas et al., 1998; Meyer et al., 1998). Immigrantneurons of a cohort such as these, in numbers that are small relativeto those arising in the neocortical PVE (of the order of 6% ofthe respective cohort), would reach the cortex on different schedulesand by means of guidance mechanisms quite different from thosearising in the neocortical PVE. As a consequence they might besystematically shifted in their intracortical positions away fromthe mean cohort position of the cells arising in the PVE. Thatis, the 2 hr cohort tracking method will not distinguish amongintracortical neurons generated at the same time in differentlocations.

Proportionate output by cycle to layers
We have approximated by linear interpolation of the normal fits the output and its distribution for each cell cycle of thefull 11-cycle neuronogenetic sequence (Fig. 4D) (see Materialsand Methods). We have then used this estimated output for eachcell cycle to estimate the proportional and numerical contributionsof each cycle to the full cortex and to each cortical layer infields 1 and 40 (Figs. 8, 9).

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Figure 8. A schematic diagram of the contribution, patterns of distribution, and intermixing of neurons by cycle of origin. This plot is a summary of the individual distributions plotted in Figure 4D and shows the contribution and distribution pattern of net output from each cycle to each cortical layer. The output of each cycle is color-coded and numbered. TO refers to the terminal output after cycle 11 at the end of the neuronogenetic interval. Cell number per counting sector (ordinate; also see Materials and Methods) is a net number, that is, a number that is obtained at P22 after histogenetic cell death is completed. Net neuronal output is lowest to midcortex, corresponding to layer V, where the contribution arises principally with cycles 7 and 8 in both fields. It is evident that all layers, and particularly the deepest levels of layer VI, represent the contributions of many cycles.

The principal generalization is that the distribution of neurons arising with each successive cycle is highly concordant withrespect to neocortical layer in fields 40 and 1, although thereare significant differences in the relative contributions of cyclesto given layers in the two fields. As a general overview, thereis an increasing neuronal net output with advance through the11 cycles. This is to be expected from the estimates of totaloutput (i.e., before histogenetic cell death) from source PVE(Takahashi et al., 1996a). The infragranular layers (layers VIand V) in both fields 40 and 1 consume some 30% of this outputfrom source, and this fraction is contributed by the initial 8of the 11 (or nearly 75%) of the total cell cycles. By contrast,granular and supragranular layers (layers IV and II/III, respectively),although collectively consuming some 70% of the output from sourcePVE, receive this from only the three terminal cell cycles. Moreover,this accelerating pattern of output from source is fully in accordwith the quantitative impressions from numerous birthday studiesin a broad range of species. Such studies have emphasized thesurge of neuronal output later in the neuronogenetic interval(Hicks and D'Amato, 1968; Fernandez and Bravo, 1974; Rakic, 1974;Bisconte and Marty, 1975b; McSherry, 1984; Luskin and Shatz, 1985;Bayer and Altman, 1991).
With respect to the distribution of cycle output to neocortical layers, each layer represents a mixture of neurons arisingfrom two or more cycles (Figs. 8, 9B). Cycles 7-10, the principalcontributors to the cortical neuronal population, give rise tocells that are distributed over two or more layers. Conversely,the neuronal contributions of the initial six cycles are confinedto the height of layer VI, whereas that of terminal cycle 11 isessentially limited to layer II/III (Fig. 9A).

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Figure 9. A summary of the cell cycle of origin of neurons for each cortical layer. A, The proportion of the output of each cycle (cycle numbers at the top of each histogram), expressed as percentage (ordinate), is plotted with respect to layer of destination (abscissa) for fields 1 (left) and 40 (right). Virtually 100% of the output of cell cycles 1-6 is distributed exclusively in layer VI in both fields, but the output of cycles 7-11 goes to multiple layers. B, The proportion of its cells, expressed as percentage (ordinate), that each layer receives from each of the 11 cycles of neuronogenesis. Each of the cortical layers receives output from multiple cell cycles.

Numerical output to layers in relation to cycle of origin
The net output of the full series of 11 cell cycles to each of the two neocortical fields, estimated by the linear interpolation(Figs. 4D, 8), is virtually identical (398 in field 40 and 382in field 1). That is, the estimated net output for all cell cyclesin the two fields differs only by ~5%. Thus, the present estimateof net output to the two cortical fields in the course of the11 cycles of the neuronogenetic interval is on the order of 400cells subtended by 1000 µm² (250 × 4 µm) of pial surface or 4 × 10⁵ cells subtended by 1 mm² of pial surface. Elsewhere we have obtained a similar estimateby direct counts (Goto et al., 1999).
Our estimates in mouse, obtained by these different methods, compare with values of up to 2 × 10⁵ cells subtended by 1 mm² of pial surface obtained in the murine neocortex by direct countingprocedures (Leuba et al., 1977; Schüz and Palm, 1989). The somewhathigher estimate obtained in our analyses may reflect the factthat our calculations include the contributions of the cyclesat the initiation and termination of the neuronogenetic interval.These were not directly measured here but were estimated and usedto calculate the cycle-by-cycle output distributions. All of thesecells appear to be essentially eliminated by cell death (Spreaficoet al., 1995) and therefore would not have figured in estimatesbased on direct counts. In contrast to the foregoing estimateof total cells subtended by 1 mm² of pial surface, our estimates of the relative proportion ofneurons contributed to each layer in fields 40 and 1 by the fullseries of cycles is in close accord with the number of neuronsin each layer as a proportion of the total in layers II/III-VIas estimated by direct cell counts (Leuba et al., 1977). Thisaccord suggests that the sampling and reconstruction proceduresundertaken in this manuscript estimate the actual compositionof fields 1 and 40 of the mouse neocortex reasonablyfaithfully.

  DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The cytological character of the cells of the PVE remains homogeneous throughout the neuronogenetic interval. The proliferativeoutput, by contrast, is represented by multiple neuronal classes,distinguished by both criteria of morphology and connectivity.We demonstrate here that cohorts of neurons arising from a smallfraction of a single cell cycle and from the same region of thePVE may have different laminar fates in the cortex. Although arisingfrom a small fraction of a single cell cycle, the neurons of eachcohort become widely dispersed in the cortex where they becomeintermixed with neurons arising during both previous and subsequentcell cycles. These observations have implications for mechanismsthat govern the sequencing of neuronogenetic events in the PVEand those that govern the postmigratory distribution of neuronswithincortex.

Neuronogenetic sequence in PVE is correlated with cell cycle

Cell cycle sequence, in contrast to the flow of embryonic time, is established here to be a sensitive correlate of neuronogeneticsequence. That is, the neurons of corresponding laminar distributionarise with the corresponding sequence of cycles of the 11-cycleseries, independently of whether in field 1 or 40 and when (embryonictime) their origin actually occurs. Moreover, the length of G1phase (T_G1), the regulated kinetic parameter, and Q (or Q fraction),the regulated output parameter, are also strongly correlated withcell cycle sequence independently of region of the PVE (Takahashiet al., 1995, 1996a; Miyama et al., 1997). Because neuronogeneticevents (i.e., those that determine laminar fate) and proliferativeparameters (T_G1 and Q) are coordinated in this way by cell cyclesequence, it is plausible that they share common regulatory mechanisms.That is, it is plausible that those mechanisms that specify neuronallaminar fate are not only coordinate with but are dependent onthose mechanisms that regulate the proliferative parameters ofthe advancing sequence of cell cycles (Caviness et al., 1999).

The temporal resolution of the 2 hr cohort labeling method used in this analysis is 1.5% of the neuronogenetic interval, i.e.,~10- to 20-fold greater than the standard birthday protocols (seeMaterials and Methods). If neurons settled in the cortex in thesame precise sequence as their birth hour, each cohort would occupyonly 1.5% of the cortical thickness. Depending on the cohort,this output is distributed instead through >22-56%, with a meanof 41% of the cortical height. This degree of dispersion is some27 times greater than expected if sequence of origin were thesole determinant of position. In addition, because the final configurationof the cortex is highly orderly with neurons sorted systematicallyby class into layers and sublayers, the broad dispersion of singlecohorts indicates that neurons destined for different layers andrepresentative of different classes arise with the same cycle.Thus, it is evident that cell cycle of origin alone is also notsufficient to specify uniquely either laminar position or cellclass. Likewise, the kinetics of the cycle of origin is seen tobe insufficient to specify laminar destination, whatever rolethese parameters may have in the determination of regional neocorticaldistinctions (Dehay et al., 1993; Miyama et al., 1997; Polleuxet al., 1997a,b).

The degree of dispersion of single cohorts and the degree of intermixing of multiple sequential cohorts determined by thepresent method is similar, in fact, to that observed in certaincortical regions in monkey (Rakic, 1974, 1976, 1982; Granger etal., 1995). As previously noted in Materials and Methods, theapproximate temporal resolution of the standard ³H-TdR pulse in monkey will be ~1% of the total neuronogeneticinterval. For example, the cells born on E45-E50 in monkey aredistributed across layers VI-IV in the Rolandic cortex (Rakic,1982), whereas those born on E55 span layers VI-III in field 24(Granger et al., 1995). Thus, the degree of dispersion of cohortsarising through comparable fractions of the neuronogenetic intervalis closely similar in species as disparate in size, gestationalinterval, and organizational complexity as mouse and monkey. Thissuggests that those mechanisms that relate time of origin to corticallaminar distribution are under similar regulatorycontrols.

Specification of neuronal class and cell cycle sequence

The layers of the neocortex, and other cortical structures, represent a sorting of neuronal somata by class. This suggeststhat laminar fate of neurons is determined in some way by propertiesof cell class (McConnell, 1989; McConnell and Kaznowski, 1991).The mechanism of neuronal sorting by class into layers is notwell understood but depends, presumably, on positional relationshipsthat form between the neuron and its afferent axonal bed (Cavinessand Rakic, 1978; Pinto-Lord and Caviness, 1979).

Mechanisms that determine neuronal class in the course of the proliferative process are equally obscure (Alexiades and Cepko,1997; Chang and Harris, 1998; Perron et al., 1998). Because laminarfate is found here to correlate with cell cycle of origin, itfollows that the determination of neuronal fate is also correlatedwith cycle of origin. The correlation is certainly systematicbut only approximate. It is as though a narrow cell-class "bandwidth filter" ascends a specified sequence of class options withprogression through the 11-cycle sequence of the neuronogeneticinterval. The height of the window of the filter is always widerthan the band corresponding to a single class, but the multipleclasses that are admitted must be classes that are within thesequence continuum. For example, in the course of cycles 1-6,the window would be open to classes native to layer VI but closedto those of overlying layers. In the course of cycles 9-11, thewindow would be open to classes native to layers II/III but closedto those of deeper layers. Within the class range viewed by theopen window at a given cycle, the probability of class might haveits unique threshold of expression among cells arising from thatcycle. Whatever the nature of these mechanisms, the sequence ofproduction followed by the phenomenon of dispersion must reflecttheir action. Specifically, the degree of dispersion must reflectthe amount of relative displacement necessary to position neuronsof a class, arising and migrating with sequential cycles, withneurons of common class in a common laminararray.

It is clear, moreover, that the processes that act to disperse and sort neurons with respect to their sequence of origin andclass act virtually from the time the neurons leave the proliferativeepithelium. Thus, for E14 in mouse, cohorts arising over 2 hrare distributed at the outset of migration over a span of intermediatezone that is three- to fivefold what would be expected solelyfrom the length of the interval over which they arise (Takahashiet al., 1996b). Moreover, this degree of dispersion is maintainedas the cells migrate into the CP (Takahashi et al., 1996b). Theobservations presented here indicate that there is an additionalincrease in dispersion of between four- and sixfold during theadditional steps required for cohorts to complete their migrationsinto outer levels of the CP and their postmigratory positionalrearrangements intolaminae.

Cell cycle sequence, cell class, and cortical histogenesis

Current evidence favors the view that cell class specification is an event that occurs during the proliferative process inthe PVE (Caviness and Rakic, 1978; McConnell, 1988; McConnell,1989; Walsh and Cepko, 1990; Mione et al., 1994, 1997; Kornackand Rakic, 1995; Alexiades and Cepko, 1997; Chang and Harris,1998; Perron et al., 1998). We suggest that with advance throughthe cell cycle succession, the transcriptional profiles of allcells advance in a way that simultaneously partially limits therange of allowable cell classes, but yet allows for each daughtercell to select from a range of cell class options that are seento arise with that cycle. The final class choice for a specificcell of the PVE would occur by chance (i.e., perhaps influencedby competition for cell external factors) and be governed by mechanismsthat set the gains for the probability of that choice for thatcycle. This illusive specification process, whatever its nature,must be viewed as an event of singular importance to neocorticalhistogenesis. This is because ultimately it is the consequencesof the class specification process that assure the laminar structureof the neocortex (McConnell, 1988, 1989).

The mechanisms that ultimately position cells by class in appropriate laminar order act only after the neuron has initiatedits movement away from the epithelium of origin and entered thedeveloping cortex. These positioning events and those of celldeath (Finlay and Pallas, 1989; Ferrar et al., 1992; Miller, 1995;Spreafico et al., 1995; Verney et al., 1999) and synaptogenesis(Bourgeois and Rakic, 1993; Bourgeois et al., 1994; Granger etal., 1995) to follow are the principal postmigratory events ofneocortical histogenesis. The regulation of these events occurringwithin the cortex after migration may be largely independent ofthose mechanisms that direct the neuronogenetic process that precedesthem (Rakic et al., 1994; Verney et al., 1999).

  FOOTNOTES

Received May 20, 1999; revised Sept. 10, 1999; accepted Sept. 10, 1999.

This work was supported by National Institutes of Health Grants NS12005 and NS33433, NASA Grant NAG2-750, and a grant fromthe Pharmacia Upjohn Fund for Growth and Development Research(T. T.). T.T. was supported by a fellowship of The Medical Foundation,Inc., Charles A. King Trust, Boston, MA. We gratefully acknowledgevaluable suggestions and other assistance of Pradeep Bhide andNancyHayes.
Correspondence should be addressed to Takao Takahashi, Department of Pediatrics, Keio University School of Medicine, Tokyo160, Japan. E-mail: tata{at}med.keio.ac.jp.

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
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