 |
||||
|
||||
|
||||
|
||||
Previous Article | Next Article
The Journal of Neuroscience, May 15, 2002, 22(10):4080-4094
Age and Sex Differences in Mitotic Activity within the Zebra Finch Telencephalon
Valerie DeWulf and Sarah W. Bottjer Program in Neuroscience, University of Southern California, Los Angeles, California 90089-2520
ABSTRACT
TOP
ABSTRACT
INTRODUCTION
Brain regions associated with song learning in zebra finches are larger and contain more neurons in males than females. Differences in cell proliferation, migration, survival, and specification may all contribute to the divergent development of the song-control system in developing birds. This study quantified levels of cell proliferation within the telencephalic ventricular zone (VZ) of juvenile and adult birds to look for both age and sex differences in mitotic activity that might contribute to the construction of song-control circuits. A single pulse of [3H]thymidine was administered to juveniles and adults of both sexes, and animals were killed 2 hr later. Analysis of thymidine labeling within the telencephalic VZ at the levels of area X, the anterior commissure, and high vocal center (HVC) revealed two major findings: (1) levels of mitotic activity decreased as a function of age in both males and females because of a reduction in the number of dividing cells within the VZ, and (2) sex differences in thymidine labeling occurred in restricted, localized segments of the VZ at the levels of area X and the anterior commissure in juveniles but not adults. Thus, overall proliferative activity decreases as birds mature, and the incidence of cell division in all regions of the VZ becomes equivalent in both sexes, such that no regions of sexually dimorphic proliferation are evident by adulthood. These data suggest that regions of sexually dimorphic proliferation within the VZ may contain precursor cells that give rise to song-control neurons, such that higher rates of mitotic activity in juvenile males could contribute to the growth of song-control nuclei such as HVC and area X.
Key words: neurogenesis; stem cell; proliferation; songbird; vocal learning; ventricular zone (VZ)
INTRODUCTION
Young male zebra finches learn to sing a close copy of their father's song during a sensitive period of development from ~20 to 90 d after hatching (Böhner, 1990
), whereas young females never learn to produce song behavior. The neural substrate underlying bird song, the song-control system, is highly sexually dimorphic (Nottebohm and Arnold, 1976
Neuroblasts originate in the proliferative ventricular zone (VZ) adjacent to the lateral ventricles (Goldman and Nottebohm, 1983
The present experiment directly tested whether the telencephalic VZ of zebra finches contains higher levels of proliferation in juveniles compared with adults and in males compared with females. We administered a single pulse of [3H]thymidine to juvenile (30 d) and adult (>90 d) birds of both sexes and killed the animals 2 hr later to examine proliferative activity uncontaminated by cell death or migration away from the VZ. Increased levels of thymidine labeling were evident at the levels of area X, the anterior commissure, and HVC in juveniles relative to adults, and single-cell analysis indicated that higher levels of mitotic activity were attributable to a larger number of dividing cells in the VZ. In addition, restricted regions of sexually dimorphic cell division were observed at the levels of area X and the anterior commissure in which cell proliferation was greater in juvenile males than juvenile females. No regions of the VZ demonstrated sex differences in thymidine labeling in adults. These observations suggest that sex differences in cell proliferation may contribute to the growth of song-control nuclei in males. Moreover, regions of sexually dimorphic proliferation within the VZ may offer clues to the location of the precursor cells that give rise to song-control neurons.
MATERIALS AND METHODS
Thymidine labeling and tissue preparation. Twenty-eight male and female zebra finches were taken from our breeding colony at either 30 d of age (juveniles; range, 28-32 d) or
90 d of age (adults) to measure levels of mitotic activity adjacent to the lateral ventricles within the telencephalon. Each bird received a single intramuscular injection of [3H]thymidine [2.5 µCi/gm dose; specific activity, 6.7 Ci/mmol; New England Nuclear (Boston, MA) or ICN (Cleveland, OH)] and was killed 2 hr later. This post-thymidine interval is short enough to effectively preclude loss of cells attributable to cell death or migration away from the VZ, both of which would produce specious estimates of actual proliferative activity. Age-related changes in the duration of S phase might also influence the rate of thymidine incorporation (i.e., less DNA would be labeled during the time that [3H]thymidine is available for longer S phases), but the length of S phase has been shown to remain constant over development despite large increases in the total length of the cell cycle (Caviness et al., 1995
All birds were overdosed with a barbiturate anesthetic (Equithesin) and transcardially perfused with avian saline followed by 2% paraformaldehyde-2% glutaraldehyde fixative. Brains were removed and bisected along the midline into two hemispheres for embedding (the left hemisphere in paraffin and the right hemisphere in the water-soluble plastic LR White; Ted Pella, Redding, CA). Before embedding, each hemisphere was post-fixed in either buffered formalin (left hemisphere) or 2% paraformaldehyde-2% glutaraldehyde (right hemisphere) for several days. To compensate for possible variation across sex and age groups (e.g., emulsion batches, lots of [3H]thymidine), all procedures included at least one animal from each of the four groups for both the paraffin- and the plastic-embedded brains.
Paraffin-embedded hemispheres. Paraffin sections were used to measure overall levels of proliferation adjacent to the lateral ventricles at three different levels of the brain: area X, the anterior commissure, and HVC in juveniles (males, n = 5; females, n = 6) and adults (males, n = 5; females, n = 5) (Fig. 1). Briefly, coronal sections were cut on a rotary microtome at a thickness of 10 µm, placed on chrome-alum-subbed slides, and immersed in a series of xylenes and graded alcohols for paraffin removal. The slides were then dipped in nuclear track emulsion (Kodak NTB2; Eastman Kodak Co., Rochester, NY), stored at 4°C for 3-8 weeks, developed (Kodak D19), and counterstained with thionin.
View larger version (57K):[in this window]
[in a new window]
Figure 1. Schematic coronal sections through the zebra finch brain at the levels of area X (a), the anterior commissure (b), and HVC (c). A, Anterior; D, dorsal; L, lateral; M, medial; P, posterior, V, ventral. Proliferation in the telencephalon occurs in the epithelium adjacent to the lateral ventricle, the VZ (black arrows), and the SVZ (gray arrows). Asterisks indicate the locations of thymidine-labeled cell clusters in the brain parenchyma. d, A separate cross section of the telencephalon indicating the boxed regions measured in the 1 µm plastic tissue analysis. e, Photomicrograph of the VZ in a 1-µm-thick section demonstrating the out-pocketing of the VZ in juvenile birds. Cx, Cortex; Str, striatum; Cb, cerebellum; V, lateral ventricle; LAD, lamina archistriatalis dorsalis; AC, anterior commissure; LH, lamina hyperstriatica; LMD, lamina medullaris dorsalis.
Plastic-embedded hemispheres. Observation of tissue sections in pilot studies had revealed that the density of cells within the VZ was extremely high, making it impossible to visualize individual cells even in 5-6 µm tissue sections. Therefore, to analyze thymidine labeling within single cells, we cut serial 1 µm sections from plastic-embedded hemibrains at the level of the anterior commissure (juvenile males, n = 8; juvenile females, n = 8; adult males, n = 7; adult females, n = 5). We trimmed ~2 mm of the lateral lobe of the telencephalon; the remaining tissue was then bisected into anterior and posterior halves at the optic tectum, and each brain quarter was embedded in separate capsules. Plastic-embedded sections were cut in the coronal plane on a JB-4 retracting rotary microtome (EBS Inc., Agawana, MA) and processed for tissue autoradiography by the same methods used for the paraffin-embedded tissue. The number of hemibrains embedded in plastic versus paraffin differed because originally several right hemibrains were trimmed incorrectly and the dorsolateral portion of the lateral ventricle was inadvertently removed. To increase the number of brains with intact lateral ventricles for complete single-cell analysis, additional birds were processed and the right hemispheres were embedded in plastic.
Analysis of autoradiograms
Proliferative zones of the zebra finch telencephalon. All analyses of cell proliferation were performed using a computer-aided imaging system (Analytical Imaging Concepts, Roswell, GA) yoked to a microscope. Observation of thymidine-labeled cells adjacent to the lateral ventricles revealed three different proliferative zones within the zebra finch telencephalon (Fig. 1). The proliferative epithelium described here is what has classically been referred to as the VZ in mammalian brain and consists of an epithelial cell layer adjacent to the lateral ventricles (Boulder Committee, 1970Mapping proliferation within the VZ
Our single-cell analysis revealed a sex difference in a small segment of the VZ in juvenile but not adult zebra finches (see below). This serendipitous discovery raised the question of how extensive such sexually dimorphic mitotic activity might be. In addition, the level of proliferative activity within the VZ was highly spatially differentiated in both juvenile and adult brains. For example, qualitative observation at the level of the anterior commissure indicated that levels of proliferation were highest in the ventral portion of the VZ within the striatum, raising the question of how great a quantitative difference would exist between levels of proliferation in cortex versus striatum. As a first step in exploring these questions, we decided to map the incidence of thymidine labeling in progressive segments along the DVZ and VVZ at the levels of the anterior commissure and area X in both juvenile and adult birds. We did not include the level of HVC, because the VVZ is gone by this level. Mapping proliferation in the VZ at the levels of area X and the anterior commissure. The 10 µm paraffin tissue sections generated for our original measurements of total proliferation were used to measure the incidence of mitotic activity along the DVZ and VVZ (separately) in juvenile and adult zebra finches of both sexes. To measure the incidence of mitotic activity in progressive segments along the DVZ, the total linear length of the DVZ (i.e., from the LH fiber tract to the dorsal tip of the VZ, see above and Fig. 1) was calculated and divided by 10. The resulting bins represent the incidence of proliferation in 10% increments along the length of the DVZ, thereby allowing us to compare levels of mitotic activity for corresponding locations within the DVZ among animals. The area, total number of silver grains, and silver-grain density within each bin were calculated. The same approach was used to measure the spatial distribution of thymidine labeling within the VVZ from the ventral tip of the VZ to the LMD fiber tract. Background measurements of silver-grain density were made and used to adjust silver-grain counts to exclude background labeling within the DVZ and VVZ as described above for the 10 µm tissue analysis. In this way, we were able to accurately map levels of proliferation in 10% intervals along the entire length of the DVZ and VVZ separately at the level of both area X and the anterior commissure. All statistical comparisons were made using 2 × 2 ANOVAs with age and sex as between-group factors in our 10 and 1 µm tissue analyses and bins as a within-group factor in our mapping study. Student's t tests were used to compare individual group differences. All tests were considered significant if they exceeded the 95% confidence level (two-tailed).
RESULTS
Overall pattern of thymidine labeling in the brain: qualitative observations
Brain and body weights of zebra finches are at their adult levels by 25-30 d of age; therefore, we had conceived this study with the idea that cell division in the telencephalic neuroepithelium of 30-d-old zebra finches would likely have achieved adult (i.e., decreased) levels. If so, then we might be able to see isolated pockets of upregulated mitotic activity within the VZ in close proximity to the song-control nuclei HVC and area X of juvenile males. Both these regions grow substantially in overall volume through neuron addition during song learning in juvenile males after other, nonsong regions are fully developed (Bottjer et al., 1986
Mitotic activity within the telencephalon was localized to three distinct proliferative zones in juvenile and adult zebra finches of both sexes: the VZ, the SVZ, and scattered pockets of thymidine labeling adjacent to the VZ and SVZ in the brain parenchyma (Fig. 1; see Materials and Methods). The SVZ that we observed in the zebra finch telencephalon was localized to the striatum (adjacent to the VVZ) in both juveniles and adults, as is true in adult mammals (Garcia-Verdugo et al., 1998
Although the increased level of mitotic activity seen in juvenile brains was quite ubiquitous along the rostrocaudal axis of the telencephalon, the pattern of labeling was not uniform in either juveniles or adults. The relative thickness of the VZ and SVZ, as well as the incidence of thymidine labeling, varied depending on the dorsal-ventral and anterior-posterior location along the neuraxis. For example, each proliferative zone was thickest along the ventral aspect of the lateral ventricles within medial striatum of the avian basal ganglia (parolfactory lobe) at the level of the anterior commissure (Fig. 1) in both juveniles and adults. This region of thicker VZ along the ventral lateral ventricles always included relatively high numbers of silver grains, such that the highest levels of mitotic activity in the telencephalon occurred here. High levels of thymidine labeling were localized not only to this "hot spot" near the ventral horn of the lateral ventricles at the level of the anterior commissure but also to a smaller aggregation of thymidine labeling around the dorsal horn (Alvarez-Buylla et al., 1990
View larger version (73K):[in this window]
[in a new window]
Figure 2. Autoradiograms showing thymidine labeling within the ventral portion of the VZ at the level of the anterior commissure in a juvenile male (a) and an adult female (b). Thymidine labeling in the SVZ (arrowheads) and clusters of thymidine-labeled cells (arrows) adjacent to the VZ are apparent. A large out-pocketing in the VZ is apparent in juveniles, whereas the out-pocketing is much reduced in adults. V, Lateral ventricle.
The thickness of the VZ and incidence of silver grains also tended to be slightly higher within the ventral aspect of the VZ more rostrally, at the level of area X, but this tendency was much less pronounced than at the anterior commissure (Fig. 1). In addition, the SVZ was much less obvious at this level, particularly in adult brains. The SVZ tended to colocalize with thicker portions of the VZ along the ventral aspect of the lateral ventricles in both juvenile and adult brains and was first clearly recognizable adjacent to the VVZ midway through the rostral-caudal extent of area X in juveniles. In adults, the SVZ was not apparent until the caudalmost level of area X. A spatially differentiated pattern of proliferation was much less evident in the caudal telencephalon, at the level of HVC, by which point the basal ganglia are gone. The SVZ was not apparent in either juvenile or adult brains at the level of HVC. In summary, a spatially differentiated pattern of labeling was evident in the telencephalon of both juveniles and adults, despite the higher incidence of proliferative activity in juveniles than in adults.
Quantitative observations in 10 µm sections
Area X
Quantitative analysis at the level of area X confirmed that the overall area of the VZ was larger in juveniles than in adults (F(1,15) = 19.22; p = 0.0005) (Fig. 3a) but did not differ between males and females at either age (main effect of sex: F < 1). The total proliferative activity within the VZ at the level of area X was also significantly greater in juveniles than in adults, as indicated by a greater total number of silver grains (F(1,15) = 12.66; p = 0.003) (Fig. 3b), but there was no sex difference in number of silver grains within juveniles or adults (main effect: F(1,15) = 1.15; p = 0.3). The age difference in mitotic activity was robust: the total number of silver grains was more than five times higher in juveniles than adults at this level of the brain. This greatly increased number of silver grains in juvenile birds contributed to a significantly greater density of silver grains within this portion of the VZ in juveniles compared with adults (F(1,15) = 13.60; p = 0.002), but silver-grain density did not differ between males and females (F(1,15) = 2.07; p = 0.17) (Fig. 3c).
We did not quantify the incidence of labeling within the SVZ at area X, because this proliferative zone was not consistently represented at this level of the brain (see above). Only 3 of 9 adult brains had a clearly visible region of SVZ adjacent to the VVZ at area X, whereas 7 of 10 juveniles had an observable SVZ. Both juvenile and adult brains did have clusters of thymidine labeling adjacent to the VZ at area X. The total number of silver grains observed in these clusters within the brain parenchyma was significantly greater in juveniles than in adults (F(1,14) = 11.96; p = 0.004) (Fig. 4d), but mitotic activity did not differ between males and females (F < 1).
View larger version (29K):[in this window]
[in a new window]
Figure 3. A 10 µm tissue analysis demonstrating the area of the VZ (a), the total number of silver grains (b), and silver-grain density within the VZ (c) at the levels of area X, the anterior commissure, HVC, and the VZ immediately above HVC in juveniles (Juv) and adults (Ad) of both sexes (mean ± SEM).
View larger version (25K):[in this window]
[in a new window]
Figure 4. A 10 µm tissue analysis demonstrating the area of the SVZ (a), the total number of silver grains (b), and silver-grain density within the SVZ (c) at the level of the anterior commissure in juveniles (Juv) and adults (Ad) (mean ± SEM). d, The total number of silver grains overlying labeled cell clusters adjacent to the VZ within the brain parenchyma in 10-µm-thick tissue at the levels of area X and the anterior commissure in juveniles and adults of both sexes (mean ± SEM).
Anterior commissure
The pattern of proliferation at the level of the anterior commissure was similar to that observed at area X in that the area of the VZ was larger in juveniles than in adults (F(1,16) = 25.36; p = 0.0001) (Fig. 3) and did not differ as a function of sex (F < 1). Overall levels of proliferation were also significantly higher in juveniles than adults, as indicated by the total number of silver grains (F(1,16) = 13.12; p = 0.002). However, the density of silver grains did not differ between juveniles and adults (F(1,16) = 1.22; p = 0.29), because the relative age difference for both VZ area and total number of silver grains was roughly comparable (Fig. 3, compare a and b). There was no sex difference at either age in the total number of silver grains or the silver-grain density within the VZ (both F < 1). The SVZ was also larger and more proliferatively active in juveniles than adults at the level of the anterior commissure. Area measurements of the SVZ demonstrated that this proliferative zone was approximately four times larger in juvenile males and females than adults at this level of the brain (F(1,18) = 19.56; p = 0.0003; F < 1 for main effect of sex) (Fig. 4a). The total number of silver grains within the SVZ was higher in juveniles than adults but did not differ as a function of sex (F(1,18) = 9.28; p = 0.007; main effect of sex: F(1,18) = 1.84; p = 0.19) (Fig. 4b). The silver-grain density within the SVZ did not vary as a function of age (F(1,18) = 1.23; p = 0.28) or sex (F < 1) (Fig. 4c). The number of silver grains in the brain parenchyma adjacent to the VZ at the level of the anterior commissure was approximately twice as high in juveniles as in adults (F(1,18) = 19.87; p = 0.0003) (Fig. 4d), and there was no sex difference in thymidine labeling adjacent to the VZ (F < 1).HVC
The area of the VZ at the level of HVC did not differ among the four groups (age: F < 1; sex: F < 1) (Fig. 3). However, the level of proliferation within the VZ, as measured by total number of silver grains, was higher in juveniles than adults (F(1,16) = 5.28; p = 0.04) and did not differ between the sexes (F < 1). The density of silver grains within the VZ at this level of the telencephalon was relatively low and did not vary as a function of either age (F(1,16) = 3.41; p = 0.08) or sex (F < 1). The SVZ was not present at the level of HVC, and clusters of thymidine labeling near the VZ were observed within the brain parenchyma in 9 of 10 juveniles but only in a few adults. These scattered clusters of thymidine labeling were not localized to a specific region along the dorsal-ventral axis but rather were randomly distributed along the entire extent of the VZ (Fig. 1c). In addition to overall measurements of proliferation in the VZ at the level of HVC, we also measured the incidence of thymidine labeling immediately dorsal to HVC, because it seemed possible that precursor cells HVC neurons might reside in the segment of VZ directly overlying HVC. If so, then there might be a higher level of thymidine incorporation in this region of the VZ. Measurements of the size of this segment of the VZ demonstrated an age difference (F(1,10) = 5.44; p = 0.04) but no sex difference (F(1,10) = 1.17; p = 0.3) (Fig. 3). The age difference was because the area of VZ overlying HVC was slightly larger in adult birds than in juveniles, which presumably reflects the much larger size of HVC in adults (and hence, a greater linear stretch of VZ was measured in adults). Despite this difference, there were significantly more silver grains within this small region of VZ in juveniles than in adults (F(1,10) = 15.90; p = 0.003), but there was no difference between males and females at either age (F(1,10) = 3.40; p = 0.1). The silver-grain density within the VZ above HVC was also higher in juvenile zebra finches than in adults (F(1,10) = 14.18; p = 0.004), and there was no sex difference (F < 1).Quantitative observations in 1 µm sections
The increased area of the juvenile VZ compared with that of adults indicates that VZ cells may be larger and/or more numerous in juveniles than in adults. In addition, the heightened incidence of thymidine labeling in juvenile birds suggests that many more VZ cells are actively dividing in the juvenile telencephalon. To determine which cell parameters change with age, we performed a single-cell analysis at the level of the anterior commissure within three subregions of the VZ: the VVZ, the IntVZ, and the DVZ (see Materials and Methods; Fig. 1d). To determine the degree of correspondence between our measurements of total proliferative activity in 10 µm sections and this single-cell analysis, we also measured the area and total number of silver grains within each subregion of the VZ measured. In the following description, these estimates of total proliferative activity within each subregion are given first, followed by the cell analyses.
VVZ
Visual inspection at the level of the anterior commissure had revealed that the VVZ was thicker in juveniles than in adults (see above). Quantitative analysis confirmed that the area of each segment measured within the VVZ was significantly larger in juveniles than in adults (VVZ1, F(1,22) = 36.87, p < 0.0001; VVZ2, F(1,22) = 22.56, p < 0.0001) (Fig. 5a), but VZ area did not differ as a function of sex (p > 0.25 for both VVZ1 and VVZ2). Levels of proliferation within the VVZ, as measured by the total number of silver grains within each segment, were also significantly higher in juveniles than adults (VVZ1, F(1,22) = 7.92, p = 0.01; VVZ2, F(1,22) = 5.35, p = 0.03) but showed no sex difference (p > 0.3 for both VVZ1 and VVZ2) (Fig. 5b). The silver-grain density was approximately equivalent between juveniles and adults within VVZ1 (F(1,22) = 3.63; p = 0.07) but was significantly higher in juveniles than adults in VVZ2 (F(1,22) = 5.36; p = 0.03) (Fig. 5c). There was no sex difference in silver-grain density within either segment of the VVZ (p
The area of individual cells within both segments of the VVZ was the same among juveniles and adults of both sexes (age: VVZ1, F < 1; VVZ2, F(1,22) = 1.69, p = 0.21; sex: F < 1 for both VVZ1 and VVZ2) (Fig. 6a). The total number of cells (both labeled and unlabeled) was significantly greater in juveniles than adults (VVZ1, F(1,22) = 18.33, p = 0.0003; VVZ2, F(1,22) = 11.56, p = 0.003), and there was no sex difference in cell number (p > 0.15 for both segments) (Fig. 6b). The total number of thymidine-labeled cells was also significantly greater in juveniles than in adults (VVZ1, F(1,22) = 7.65, p = 0.01; VVZ2, F(1,22) = 19.48, p = 0.0002; sex: both F < 1) (Fig. 6c). In summary, these data indicate that the increased incidence of mitotic activity in juvenile birds revealed by total silver-grain counts is attributable to a larger number of dividing cells in juveniles than adults.
View larger version (26K):[in this window]
[in a new window]
Figure 5. A 1 µm tissue analysis demonstrating VZ area (a), the total number of silver grains (b), and silver-grain density (c) (segments shown in Fig. 1d) at the level of the anterior commissure in juveniles (Juv) and adults (Ad) of both sexes (mean ± SEM). The asterisk indicates a main effect of sex in the total number of silver grains in DVZ2.
The proportion and density of labeled cells were significantly higher in juveniles than adults only in VVZ2 (percentage labeled: VVZ1, F(1,22) = 2.78, p = 0.11; VVZ2, F(1,22) = 23.13, p < 0.0001) (density labeled: VVZ1, F < 1; VVZ2, F(1,22) = 12.57, p = 0.002) (Fig. 7). There was no sex difference in the percentage of cells labeled or in the labeled cell density at either age (all values of p > 0.20 for both percentage of cells labeled and labeled cell density in VVZ1 and VVZ2). VVZ1 lies in the more ventral aspect of the VVZ, which includes the area of out-pocketing in the VZ (Fig. 1), and this segment tended to be relatively larger and more proliferatively active than the segment of VVZ just above it (i.e., the numbers of total cells and of labeled cells were higher overall within VVZ1 than VVZ2) (Fig. 6). It is interesting that there was no selective increase in proliferation within VVZ1 of juvenile birds, as evidenced by the fact that the proportion and density of labeled cells were not different between juveniles and adults (Fig. 7). In contrast, within VVZ2, we observed not only an absolute increase in total number of cells and labeled cells in juveniles relative to adults but also an increase in the proportion and density of dividing cells in young birds.
View larger version (32K):[in this window]
[in a new window]
Figure 6. A 1 µm tissue analysis demonstrating cellular area (a), the total number of cells (labeled and unlabeled) (b), and the total number of labeled cells (c) within each VZ segment measured at the level of the anterior commissure in juveniles (Juv) and adults (Ad) of both sexes (mean ± SEM).
View larger version (43K):[in this window]
[in a new window]
Figure 7. A 1 µm tissue analysis demonstrating the percentage of cells labeled (a) and labeled cell density (b) within each VZ segment measured at the level of the anterior commissure in juveniles (Juv) and adults (Ad) of both sexes (mean ± SEM). The asterisk indicates a significant difference in the proportion of labeled cells between juvenile males and females in DVZ2.
IntVZ
The pattern of proliferation within the IntVZ at the level of the anterior commissure was similar to that seen within the VVZ. The area of the segment measured within the IntVZ was significantly greater in juveniles than in adults (F(1,22) = 7.89; p = 0.01), and there was no sex difference at either age (F < 1) (Fig. 5). The total number and density of silver grains in the IntVZ were also significantly higher in juveniles than in adults (number of silver grains: F(1,22) = 8.74, p = 0.007; silver-grain density: F(1,22) = 7.94, p = 0.01) and did not vary as a function of sex (both number and density: F < 1). Measurements of cell area within the IntVZ revealed that the size of individual cells was the same among all groups (age: F(1,22) = 1.14, p = 0.3; sex: F < 1) (Fig. 6). The total number of IntVZ cells (both unlabeled and labeled) was greater in juveniles than adults and did not differ between males and females (age: F(1,22) = 5.44, p = 0.03; sex: F < 1). The total number of thymidine-labeled cells in the IntVZ was also greater in juveniles than adults and showed no sex difference (age: F(1,22) = 9.00, p = 0.007; sex: F < 1). The age difference in the incidence of thymidine-labeled cells was also significant for the proportion of cells labeled (age: F(1,22) = 6.77, p = 0.02; sex: F(1,22) = 1.25, p = 0.28) (Fig. 7) and approached significance for labeled cell density (age: F(1,22) = 4.08, p = 0.06; sex: F(1,22) = 1.83, p = 0.19).DVZ
Both segments measured within the DVZ (Fig. 1d) demonstrated an age but not a sex difference in VZ area (age: DVZ1, F(1,17) = 8.69, p = 0.009; DVZ2, F(1,21) = 9.19, p = 0.006; sex: both F < 1) (Fig. 5). The total number and density of silver grains were greater in juveniles than adults within both DVZ1 and DVZ2 (number: DVZ1, F(1,17) = 23.14, p = 0.0002; DVZ2, F(1,21) = 12.52, p = 0.002; density: DVZ1, F(1,17) = 19.77, p = 0.0004; DVZ2, F(1,21) = 9.67, p = 0.005). There was no effect of sex on the number or density of silver grains within DVZ1 (both F < 1), but there was a significant main effect of sex on both of these measures within DVZ2 (number: F(1,21) = 7.53, p = 0.01; density: F(1,21) = 4.36, p = 0.05). Individual t tests revealed that juvenile males had an increased total number of silver grains in DVZ2 (immediately above the LH fiber tract) compared with juvenile females (t(11) = 2.56; p = 0.03), but the incidence of thymidine labeling was equivalent among adults in this region (t(10) = 1.23; p = 0.25). Individual t tests for silver-grain density revealed no differences in either juveniles (t(11) = 1.84; p = 0.09) or adults (t(10) = 1.13; p = 0.28). Measurements of individual cells in the DVZ revealed no difference in cellular area among juveniles or adults of either sex (age: DVZ1, F(1,17) = 1.18, p = 0.29; DVZ2, F < 1; sex: DVZ1, F(1,17) = 2.33, p = 0.15; DVZ2, F < 1) (Fig. 6). The total number of cells was greater in juveniles than in adults in both segments of the DVZ (DVZ1, F(1,17) = 10.04, p = 0.006; DVZ2, F(1,21) = 5.40, p = 0.03) but did not differ between males and females (both F < 1). The number of thymidine-labeled cells was significantly greater in juveniles than adults within both segments of the DVZ (DVZ1, F(1,17) = 30.03, p < 0.0001; DVZ2, F(1,21) = 8.74, p = 0.008), but there was no main effect of sex in the number of labeled cells (DVZ1, F(1,17) = 1.3, p = 0.27; DVZ2, F(1,21) = 2.27, p = 0.15). Juvenile males tended to have a higher incidence of labeled cells than juvenile females in DVZ2; however, this difference was not significant (t(11) = 1.74; p = 0.11). Both the proportion and density of labeled cells were higher in juveniles than adults in both DVZ segments measured (percentage labeled: DVZ1, F(1,17) = 12.68, p = 0.002; DVZ2, F(1,21) = 10.83, p = 0.004; labeled cell density: DVZ1, F(1,17) = 12.93, p = 0.002; DVZ2, F(1,21) = 7.87, p = 0.01). There was no main effect of sex within DVZ1 (percentage labeled: F(1,17) = 3.0, p = 0.10; labeled cell density: F(1,17) = 2.78, p = 0.11), but there was a main effect of sex on the proportion of cells labeled in DVZ2 (percentage labeled: F(1,21) = 5.10, p = 0.03; labeled cell density: F(1,21) = 2.30, p = 0.14) (Fig. 7). This sex difference was attributable to a larger proportion of labeled cells in males than females for juveniles (t(11) = 2.96; p = 0.01) but not adults (t < 1). Individual t tests also revealed a marginal sex difference in labeled cell density for juveniles but not adults (juveniles: t(11) = 2.11, p = 0.06; adults: t < 1). The increased incidence of labeled cells in juvenile males compared with juvenile females corresponds to the same segment of the DVZ in which we observed a sex difference in the number and density of silver grains (Fig. 5b,c). Although the total number of labeled cells tended to be greater in juvenile males than juvenile females in DVZ2 (Fig. 6), this measure was not statistically different, presumably because juvenile females had a greater total number of cells (labeled and unlabeled), thereby offsetting a sex difference in the absolute number of labeled cells. However, the proportion of labeled cells was significantly greater in juvenile males than juvenile females in DVZ2 (Fig. 7). Thus, the sex difference in thymidine labeling in the DVZ just above the LH fiber tract (DVZ2) is the result of a selective increase in the incidence of dividing cells in juvenile males compared with juvenile females.Mapping proliferation in the VZ at the levels of the anterior commissure and area X
Our initial studies had revealed the existence of a sex difference in mitotic activity in a small segment of the VZ, as well as a spatially differentiated pattern of cell division across the VZ. To search for other examples of sex differences in proliferation and to compare levels of proliferative activity between different subregions of the VZ, we decided to map levels of thymidine labeling in 10% increments along the VVZ (from the ventral horn to the LMD fiber tract) and DVZ (from the LH fiber tract to the dorsal horn) at the levels of the anterior commissure and area X in 10 µm tissue sections (see Materials and Methods). These data allowed us to compare overall levels of proliferation (total number of silver grains) between the DVZ (within cortex) and the VVZ (within striatum) and to construct a map of mitotic activity along the dorsal-ventral axis for both the DVZ and VVZ at these two levels of the telencephalon.
The anterior commissure
DVZ. Histograms of the total number of silver grains within each 10% increment of the DVZ at the level of the anterior commissure indicated no overall effect of age or sex (age: F(1,17) = 3.34, p = 0.09; sex: F < 1) (Fig. 8a,b). However, there was a main effect of bins (F(9,153) = 4.47; p < 0.0001), indicating that the level of proliferation varied along the dorsal-ventral axis of the DVZ. The incidence of cell division was highest near the dorsal horn in juvenile males and females (Fig. 8a, bins 8-10). These three bins at the tip of the DVZ are adjacent to the dorsal horn of the lateral ventricles and correspond to a region of increased mitotic activity described by Alvarez-Buylla et al. (1990)
VVZ. The pattern of thymidine labeling along the dorsal-ventral axis of the VVZ at the level of the anterior commissure was similar between juveniles and adults of both sexes, with the highest levels of proliferation occurring near the ventral horn (in bins 2, 3, and 4) (Fig. 8c,d). This area resides within the region of the VVZ that bulges out into the brain parenchyma as an out-pocketing of the VZ (Fig. 2), which corresponds to a region of increased mitotic activity referred to as a proliferative hot spot close to the ventral horn of the lateral ventricles (Alvarez-Buylla et al., 1990
View larger version (48K):[in this window]
[in a new window]
Figure 8. Histograms of the total number of silver grains within each bin of the DVZ of juveniles (Juv) (a) and adults (Ad) (b) and in the VVZ of juveniles (c) and adults (d) at the level of the anterior commissure (mean ± SEM). Asterisks indicate significant differences in thymidine labeling between juvenile males and females in DVZ bin 1 (a) and VVZ bin 8 (c). DH, Dorsal horn.
Area X
DVZ. Thymidine labeling in the DVZ at the level of area X did not demonstrate a strong pattern of spatially differentiated proliferation in juveniles or adults (Fig. 9a,b). The total number of silver grains across bins demonstrated an age difference in the incidence of thymidine labeling (F(1,18) = 7.63; p = 0.01), reflecting a more than twofold increase in overall levels of mitotic activity in juveniles compared with adults. There was no main effect of sex (F(1,18) = 2.14; p = 0.16) or bins (F(9,162) = 1.83; p = 0.07). The total number of silver grains in bin 1 (immediately dorsal to the LH) of juvenile males and females revealed no sex difference (t(10) = 1.50; p = 0.17). Thus, the pattern of sexually dimorphic labeling we observed just dorsal to the LH at the level of the anterior commissure (more silver grains in bin 1 of juvenile males) (Figs. 5b, 8a) did not extend rostrally to this level of the telencephalon.
VVZ. The spatial distribution of thymidine labeling along the dorsal-ventral axis of the VVZ at the level of area X was different among males and females at both ages (Fig. 9c,d). Juvenile males demonstrated a slight increase in the total number of silver grains in bins 1-6, followed by lower levels between bins 7 and 10, whereas juvenile females demonstrated relatively consistent levels of proliferative activity in bins 1-10. Adults did not demonstrate as much change in the spatial distribution of thymidine labeling, and both males and females demonstrated low levels of proliferation throughout the VVZ at this level. Statistical analysis revealed an overall effect of age, sex, and an age-by-sex interaction (age: F(1,17) = 17.35, p = 0.0006; sex: F(1,17) = 5.40, p = 0.03; age by sex: F(1,17) = 4.84, p = 0.04) but no effect of bins (F < 1). Overall, juvenile males had higher levels of proliferation throughout the VVZ than juvenile females (F(1,17) = 10.70; p = 0.005), but levels of thymidine labeling were equivalent in adults (F < 1). When we compared thymidine labeling within individual bins between juvenile males and females, bins 1, 2, 4, and 5 demonstrated sex differences in proliferation and a tendency toward a sex difference in bins 3, 6, 7, and 8 (bin 1: t(9) = 2.46, p = 0.04; bin 2: t(9) = 2.40, p = 0.04; bin 3: t(9) = 1.89, p = 0.09; bin 4: t(9) = 2.50, p = 0.04; bin 5: t(9) = 3.02, p = 0.02; bin 6: t(9) = 2.07, p = 0.07; bin 7: t(9) = 2.13, p = 0.06; bin 8: t(9) = 2.12, p = 0.06). Interestingly, the segment of the VVZ containing bins 4 and 5 is located approximately adjacent to area X, raising the possibility that this region of the VZ (and adjacent regions at this level) might contain precursor cells that produce area X neurons.
View larger version (52K):[in this window]
[in a new window]
Figure 9. Histograms of the total number of silver grains within each bin of the DVZ of juveniles (Juv) (a) and adults (Ad) (b) and in the VVZ of juveniles (c) and adults (d) at rostral levels of area X (mean ± SEM). Asterisks in c indicate significant differences in thymidine labeling between juvenile males and females in VVZ bins 1, 2, 4, and 5. DH, Dorsal horn.
Comparing levels of proliferation between the VVZ and the DVZ
To directly compare both area and levels of proliferation between the DVZ and the VVZ, we collapsed the binned data from our mapping study within each of these regions at the levels of the anterior commissure and area X (Fig. 10).
View larger version (47K):[in this window]
[in a new window]
Figure 10. The area and total number of silver grains within the DVZ and VVZ at the levels of the anterior commissure (a, b) and area X (c, d) (mean ± SEM). The asterisk in d indicates a significant difference between juvenile (Juv) males and females within the VVZ at area X. Ad, Adult.
Anterior commissure
The area of the entire DVZ was greater than that of the VVZ at the level of the anterior commissure (F(1,18) = 72.85; p < 0.0001). This increased area of the DVZ was attributable to the fact that the linear length of the DVZ was much greater than that of the VVZ at this level of the brain (data not shown). Thus, the enlarged area of the VVZ close to the ventral horn (see above) was offset by the greater length of the DVZ at the anterior commissure. As expected, there was also a main effect of age, reflecting the larger area of both the VVZ and DVZ in juveniles (F(1,18) = 25.01; p < 0.0001). The total number of silver grains was higher in the VVZ than the DVZ at this level, despite the smaller area of the VVZ (F(1,18) = 19.29; p = 0.0004). There was also a main effect of age for number of silver grains (F(1,18) = 10.70; p = 0.004), no effect of sex (F(1,18) = 1.22; p = 0.28), and an age-by-sex-by-region interaction (F(1,18) = 5.95; p = 0.03). This interaction was attributable to a sex difference in the VVZ but not the DVZ of juvenile birds (juvenile males vs females in VVZ: F(1,18) = 4.37; p = 0.05), whereas adult males and females were not different in either region. There was also an age-by-region interaction (F(1,18) = 8.53; p = 0.009), reflecting the fact that the number of silver grains was greater in the VVZ than the DVZ for juveniles (F(1,18) = 29.42; p < 0.0001) but not for adults (F < 1). This pattern indicates that the higher level of proliferative activity in the VVZ than the DVZ is unique to juveniles and is presumably primarily a result of the presence of the hot spot of labeling in the pronounced out-pocketing of the VVZ seen in juveniles along the ventralmost aspect of the lateral ventricles at this level (Fig. 2). In summary, levels of proliferation were significantly higher within the VVZ than the DVZ at the level of the anterior commissure in juvenile but not adult brains, with the highest levels of mitotic activity occurring within the VVZ of juvenile males compared with juvenile females or adults.Area X
Collapsing across bins from the DVZ versus the VVZ at the level of area X indicated a larger area in the VVZ than the DVZ (F(1,18) = 26.25; p < 0.0001) and a nonsignificant trend toward higher levels of thymidine labeling in the VVZ (F(1,18) = 3.66; p = 0.07) (Fig. 10c,d). Thus, the higher levels of proliferation evident in the VVZ of juveniles at the level of the anterior commissure were less evident at this more rostral level of the brain. (However, it was true that the incidence of mitotic activity at this level was higher within a restricted region of the VVZ close to the ventral horn, although this pattern was much less pronounced at area X than at the anterior commissure; see qualitative description above.) The areas of both the DVZ and VVZ were larger in juveniles than adults (main effect of age: F(1,18) = 57.91; p < 0.0001) and did not vary as a function of sex (F(1,18) = 1.60; p = 0.22). In addition, juveniles had significantly greater numbers of silver grains in both the DVZ and VVZ (main effect of age: F(1,18) = 16.83; p = 0.0007), and there was an effect of sex on levels of proliferation (F(1,18) = 5.04; p = 0.04) that was attributable to higher levels of mitotic activity in juvenile males than females within the VVZ (F(1,18) = 12.46; p = 0.002) but not the DVZ (F(1,18) = 3.14; p = 0.09). Thus, juvenile males demonstrate higher overall levels of proliferative activity throughout the VVZ compared with juvenile females at this level of the brain. This robust sex difference occurs within a region of the VZ that is in close proximity to area X (compare Fig. 9c).
DISCUSSION
The vast majority of studies investigating neurogenesis in the telencephalon of songbirds have focused on observing new neuron addition and/or seasonal neuronal turnover within song-control nuclei (Goldman and Nottebohm, 1983
Mitotic activity within the VZ is spatially differentiated throughout the telencephalon
Although mitotic activity was ubiquitous throughout the telencephalon of both juveniles and adults, a highly nonuniform pattern of proliferation occurred within the VZ, with the highest levels at the anterior commissure and lower levels at area X and HVC. This pattern suggests that the location of precursor cells that give rise to song-control neurons may be spatially remote from their target. However, a region with consistently higher levels of mitotic activity in juvenile males than females occurs in close proximity to area X, suggesting that this region may give rise to area X neurons.
There was also a difference in the total amount of proliferative activity between the DVZ and VVZ in juveniles (but not adults) at the level of the anterior commissure, where overall levels of proliferation were substantially higher within the VVZ than within the DVZ of young birds (Fig. 10). The VVZ of juveniles contained a prominent out-pocketing of the neuroepithelium (Fig. 2) that might represent a remnant of a sulcus such as the one that divides the medial and lateral ganglionic eminences, which are thought to generate cells destined for the striatum and pallidum, respectively, in embryonic mammals (Smart and Sturrock, 1979
We do not know whether cells generated in the dorsal versus ventral proliferative zones are restricted to the cortex and basal ganglia, respectively. However, this seems possible, because studies of telencephalic development have provided evidence for migrational boundaries that prevent movement across the corticostriatal sulcus of the VZ or from postmitotic cortex to striatum (Fishell et al., 1993
Proliferation is higher in juveniles than in adults
Overall levels of telencephalic proliferation are much higher in 30-d-old juvenile birds than adults, although brain size and mass have achieved adult levels by 30 d of age. These results are consistent with previous work in birds showing that neurogenesis decreases with age but continues into adulthood (Alvarez-Buylla et al., 1994
Telencephalic regions not involved with song learning appear to achieve their adult size by ~30 d of age in zebra finches, whereas song-control regions continue to show large-scale morphological changes in size and neuron number thereafter, during the period of vocal learning (Bottjer et al., 1985
Sex differences in proliferation
A major finding of the present study is that specific regions of the VZ demonstrate sexually dimorphic cell division in juvenile birds. Previ
