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Previous Article | Next Article
Volume 16, Number 21, Issue of November 1, 1996 pp. 6830-6838
Copyright ©1996 Society for NeuroscienceDifferential Regulation of NMDAR1 mRNA and Protein by Estradiol in the Rat Hippocampus
Adam H. Gazzaley1, Nancy G. Weiland3, Bruce S. McEwen3, and John H. Morrison1, 2 1 Laboratories for Neurobiology of Aging, Fishberg Research Center for Neurobiology, New York, New York 10029-6574, 2 Department of Geriatrics and Adult Development, The Mount Sinai School of Medicine, New York, New York 10029, and 3 Laboratory of Neuroendocrinology, Rockefeller University, New York, New York 10021
ABSTRACT
Estradiol treatment increases the number of NMDA receptor binding sites, and changes evoked synaptic currents in a manner consistent with a steroid-induced functional enhancement of NMDA receptors in rat hippocampus. In this study, we investigate the cellular mechanisms of estradiol-induced NMDA receptor regulation at the protein and mRNA levels in ovariectomized rats treated with ovarian steroids using immunocytochemical and in situ hybridization techniques. Confocal laser scanning microscopy was used to quantify alterations in immunofluorescence intensity levels of NMDAR1 subunit proteins within neuronal somata and dendrites of discrete hippocampal fields, whereas in parallel, in situ hybridization was used to examine NMDAR1 mRNA levels in corresponding hippocampal regions. The data indicate that estradiol treatment in ovariectomized rats significantly increases immunofluorescence intensity levels in comparison with nonsteroid treated ovariectomized rats within the somata and dendrites of CA1 pyramidal cells and, to a lesser extent, within the granule cell somata of the dentate gyrus. In contrast, such alterations in immunofluorescence intensity occur without concomitant changes in mRNA hybridization levels. Thus, these data suggest that estradiol modulates NMDA receptor function via post-transcriptional regulation of the NMDAR1 subunit protein. The increase in immunofluorescence intensity may reflect an increase in the concentration of the subunit protein, which could account for estrogen-induced changes in pharmacological and physiological properties of the NMDA receptor.
Key words: excitatory amino acid receptors; NMDAR1; immunocytochemistry; in situ hybridization; estrogen; CA1; confocal microscopy
INTRODUCTION
Ovarian steroids affect brain regions and behaviors that are not directly associated with reproductive functions (McEwen et al., 1995
). However, the mechanisms by which these effects are produced have not yet been determined. NMDA receptors (NMDARs), a subtype of ionotropic glutamate receptors (Moriyoshi et al., 1991
Few studies have directly addressed the mechanisms underlying estrogen regulation of NMDARs. Autoradiographic analysis has revealed that NMDAR agonist binding sites are increased in the dendritic layer of CA1 in response to estradiol treatment in ovariectomized rats (Weiland, 1992
MATERIALS AND METHODS
Animal and tissue processing. Forty-three young adult Sprague Dawley rats (Charles River, Wilmington, MA), weighing ~250 gm, were maintained in a temperature- and light-controlled environment with a light (14 hr)/dark (10 hr) cycle (lights on at 0500 hr). Animals were treated in accordance with the principles and procedures of the National Institutes of Health Guide for the Care and Use of Laboratory Animals, and all surgeries were performed under Metofane anesthesia. Sixteen rats were used in the immunocytochemical analysis. All 16 rats were ovariectomized for 1 week, at which time 10 rats received SILASTIC capsules containing 180 µg of 17-estradiol/sesame oil, and the remaining 6 were sham operated. Two days later at 1000 hr, five of the estradiol-treated animals were injected subcutaneously with progesterone (1 mg in 0.3 ml oil/rat), and all remaining animals were injected with oil. This procedure resulted in the following groups of ovariectomized rats: six sham plus oil (OVX), five estradiol plus oil (OVX+E), and five estradiol plus progesterone (OVX+E+P). Five hours after progesterone or oil injection (1500 hr), the animals were deeply anesthetized with Metophane and transcardially perfused with cold 1% paraformaldehyde in 0.1 M PBS followed by cold 4% paraformaldehyde in PBS. The brains were removed, post-fixed in 4% paraformaldehyde, and sectioned at 40 µm on a vibratome (OTS 3000, Electron Microscopy Sciences, Fort Washington, PA). The sections were stored in PBS with 0.1% sodium azide at 4°C.
Twenty-seven rats were used for the in situ hybridization study. All rats were ovariectomized for 1 week and then adrenalectomized. Eighteen rats were then treated with SILASTIC capsules containing 180 µg of 17-
70°C.
In situ hybridization. In situ hybridization was performed using previously published sequences of oligonucleotides (Oligos Etc., Wilsonville, OR) complementary to rat cDNA encoding subunit residues between putative transmembrane domains I and II, encoding amino acids 566-580, and recognizing all published splice variants (Monyer et al., 1992
end-labeled with terminal transferase (Boehringer Mannheim, Indianapolis, IN) using a 2:1 molar ratio of [
-35S] dATP:cDNA (1200-1400 Ci/mmol; New England Nuclear, Boston, MA). Unincorporated nucleotides were removed using NucTrap push columns (Stratagene Cloning Systems, La Jolla, CA). Hybridization was performed as described previously, (Orchinik et al., 1994
Quantitative in situ hybridization analysis. The films were analyzed by measuring the optical density of specific regions of the hippocampus using an automated paint function that covered the region of interest (Imaging Research, St. Catherines, Ontario, Canada). Bilateral measurements were taken from four sections per animal, nine animals per group in the principal cell layer of CA1, CA3, and the suprapyramidal layer of the dentate gyrus. Background was measured from the corpus callosum and subtracted from the total optical density.
Immunocytochemistry. Three nonadjacent sections from the rostral hippocampus of each rat were incubated with monoclonal antibodies to both the NMDAR1 subunit (54.1) (Siegel et al., 1994
CLSM and quantitative immunocytochemical evaluation. Quantitative CLSM analysis was performed on three sections from each rat brain, for each of the two antibodies, with a Zeiss LSM 410 inverted confocal microscope (Thornwood, NY). The investigator was blinded throughout the evaluation as to which sections were from which experimental group. The quantitative analysis performed in this study was adapted from a previous study that quantified relative differences in immunofluorescence intensity levels (Gazzaley et al., 1996b
For the study of somatic immunofluorescence intensity, six fields were randomly selected on each section within a centrally located region of the suprapyramidal blade of the dentate gyrus granule cell layer and the middle portion of the CA1 and CA3 pyramidal cell layer. The dendritic immunofluorescence intensity study consisted of six randomly selected dendritic fields, on each section, from the middle molecular layer of the dentate gyrus and the stratum radiatum of CA1 adjacent to the somatic regions analyzed in the somatic immunofluorescence analysis. All dendritic fields scanned were the same size (3832 µm2) and all were selected at a distance of ~70 µm from the principal cell layers. Each field was scanned only once, to reduce fluorescence quenching, and at the same predetermined z axis distance from the surface of the section. Scanning was performed with a two line average for a total scan time of 4.52 sec and an electronic zoom factor of 3.28, which increased the resolution to 0.0081 µm/pixel. Each digitized image consisted of a 512 × 512 × eight bit pixel array, in which every pixel was assigned a gray level intensity value ranging from 0 to 255. An image-analysis program (Zeiss) was used to determine the average pixel intensity of each field. To remove the negative contribution of unlabeled portions of the field to the average field intensity (i.e., nuclei and unlabeled regions between soma and dendrites), a photometric offset was used to establish a pixel intensity threshold below which a pixel would have no contribution to the average pixel intensity of the field. The threshold was set by viewing the image at a display magnification of 2× and manually increasing the thresholding value until a blue display, designating the thresholded area, completely occupied the unstained nuclei and abutted somatic and dendritic profiles (Fig. 1). Thus, the average pixel intensity of the portion of the field above threshold represents the immunofluorescence intensity within either the dendritic segments or the somata of the principal cell layers.
Fig. 1. CLSM images of NMDAR1 immunolabeled CA1 pyramidal cell somata (A, B) and dendrites (B, C) before (A, C) and after (B, D) intensity thresholding, as indicated by the blue color overlay. After the thresholding procedure, all unlabeled portions of the field (in blue) have no contribution to the average intensity of the field.
[View Larger Version of this Image (197K GIF file)]
Data analysis. For the CLSM immunocytochemical analysis, an intensity value was computed for each animal in each of the three regions by determining the mean of the 24 individual field values (6 field values obtained from each of three sections). For both the immunocytochemical and in situ hybridization analyses, a mean value for each group was obtained from the individual values determined for each animal, in CA1, CA3, and the dentate gyrus. Percent difference was determined by comparing the steroid-treated ovariectomized rats with the nontreated ovariectomized rats [i.e., ((OVX+E)
RESULTS
NMDAR1: somatic immunofluorescence intensity
NMDAR1 immunolabeling was evaluated in three groups of rats: ovariectomized rats (OVX) and ovariectomized rats that had been treated with either estradiol (OVX+E) or estradiol plus progesterone (OVX+E+P). This steroid treatment paradigm has been used previously by Weiland and Orchinik (1995)
Fig. 2. Examples of CLSM images of NMDAR1 immunolabeled somata in CA1 (A-C), the dentate gyrus (D-F), and CA3 (G-I) of OVX (A, D, G), OVX+E (B, E, H), and OVX+E+P (C, F, I) rats. Note the presence of punctate staining within the cytoplasm surrounding the unlabeled nuclei (see Discussion). When comparing the CA1 fields, an increase in the somatic intensity of staining is evident in the OVX+E and OVX+E+P rats (B, C) as compared with the OVX rats (A). This increase in the steroid-treated ovariectomized rats is also apparent in the dentate gyrus (E, F compared with D), although to a lesser extent. There is no obvious difference in intensity levels among the three groups in the CA3 field (G-I). DG, Dentate gyrus; OVX, ovariectomized rats; OVX+E, estradiol-treated ovariectomized rats; OVX+E+P, estradiol plus progesterone-treated ovariectomized rats. Scale bars, 10 µm.
[View Larger Version of this Image (160K GIF file)]
Fig. 3. Examples of CLSM images of NMDAR1 immunolabeled dendrites in the CA1 subfield of an OVX rat (A), an OVX+E rat (B), and an OVX+E+P rat (C). Note the presence of punctate staining within the cytoplasm of the dendritic segments (see Discussion) and the increased intensity of staining within the CA1 dendrites of the steroid-treated ovariectomized rats (B, C) rats compared with the nonsteroid-treated ovariectomized rats (A). Scale bar, 10 µm.
[View Larger Version of this Image (121K GIF file)]
Immunofluorescence intensity levels of the cytoplasmic pool of receptors within the somata of the CA1 and CA3 pyramidal cell layers and the dentate gyrus granule cell layer were obtained by CLSM quantitative analysis. All statistical comparisons were made among the three groups, within a given hippocampal subfield. In the CA1 subfield of either the OVX+E or OVX+E+P group, quantitative data revealed a significant intensity increase within the pyramidal cell somata of 52.2% in comparison with the OVX group (Fig. 2a-c; see also Fig. 4a). No difference in intensity levels was evident between the two steroid-treatment groups.
Fig. 4. Bar graphs depicting NMDAR1 immunofluorescence intensity measurements in the somata (A) and dendrites (B) of the CA1, DG, and CA3 fields of the hippocampus. For somatic intensity measurements (A), there is a significant increase in both CA1 and the dentate gyrus when comparing OVX+E and OVX+E+P rats with OVX rats. Based on the results of the somatic intensity measurements (A), the CA1 and the DG dendritic fields were quantified (B). In B, note that there are significant increases only in the dendritic intensity measurements of steroid-treated rats as compared with the OVX rats in the CA1 subfield, although there is a trend toward increase in the dentate gyrus. Values represent mean ± SEM for six OVX rats and five OVX+E and OVX+E+P rats (24 measurements per rat). *p < 0.05, **p < 0.0001 compared with OVX group; ANOVA and Sheffe's test.
[View Larger Version of this Image (48K GIF file)]
In the dentate gyrus, a smaller but statistically significant intensity increase was observed within the somata of the granule cells in OVX+E (31.3%) and OVX+E+P (33.5%) rats relative to the OVX rats (Figs. 2d-f; Fig. 4a). This intensity increase was of a significantly lower magnitude than that recorded in the CA1 field, as determined by a statistical comparison of the CA1/DG ratio among the three groups, which revealed a significant increase in the ratio in the steroid-treatment groups as compared with the OVX group. As in the CA1 subfield, there was no significant difference between the OVX+E and the OVX+E+P groups.
Quantitative analysis of the somata of the CA3 pyramidal cells revealed no difference in immunofluorescence intensity levels among the three groups (Figs. 2g-i, 4a).
NMDAR1: dendritic immunofluorescence intensity
To investigate the cytoplasmic pool of the NMDAR1 subunit protein within the dendrites of the two regions where a somatic intensity increase was observed, we analyzed fields of dendritic segments in the CA1 stratum radiatum and the dentate gyrus molecular layer. Quantitative analysis revealed a statistically significant increase in intensity within the dendritic segments of the CA1 field when comparing both the OVX+E and the OVX+E+P groups with the OVX group (35 and 32%, respectively) (Figs. 3a-c, 4b). There was no significant intensity difference between the two steroid-treated groups in the CA1 dendrites. Analysis of the dentate gyrus dendritic fields revealed no significant difference among the three groups, but there was a trend toward an increase in both steroid-treated groups compared with the OVX group (Fig. 4b).MAP2: somatic immunofluorescence intensity
To access whether the NMDAR1 intensity change may have been the result of a more general increase in protein production, an identical quantitative analysis was performed after immunocytochemical staining with a monoclonal antibody to MAP2. MAP2 was selected because it is localized specifically within the soma and dendrites of all principal cells in the hippocampus, and there are no reports of estradiol-induced changes in MAP2 cytoplasmic concentration. Quantitative and qualitative analysis revealed no significant differences in immunofluorescence intensity or distribution among the three groups in the somata of any hippocampal field analyzed (Figs. 5a-i, 6).
Fig. 5. Examples of CLSM images of MAP2-immunolabeled somata in CA1 (A-C), the dentate gyrus (D-F), and CA3 (G-I) of OVX rats (A, D, G), OVX+E rats (B, E, H), and OVX+E+P rats (C, F, I). Note that there are no obvious differences in intensity levels when comparing the different experimental groups within any hippocampal subfield. Scale bars, 10 µm.
[View Larger Version of this Image (149K GIF file)]
Fig. 6. Bar graphs depicting MAP2 immunofluorescence intensity measurements in the somata of the CA1, dentate gyrus, and CA3 fields of the hippocampus. Quantitative analysis revealed no statistically significant differences among the three groups when comparing within a hippocampal field. Values represent mean ± SEM for six OVX rats, five OVX+E rats, and OVX+E+P rats (24 measurements per rat).
[View Larger Version of this Image (33K GIF file)]
NMDAR1 mRNA labeling
To determine whether a change in immunofluorescence intensity levels of the NMDAR1 protein corresponded to an alteration in gene transcription, in situ hybridization analysis of NMDAR1 mRNA levels was performed. Hybridization signal was localized within the somata of the dentate gyrus granule cells and the pyramidal cells of the CA fields (Fig. 7), and no overt differences were observed in the overall distribution of hippocampal mRNA labeling in comparison with that described previously in the rat brain (Moriyoshi et al., 1991
Fig. 7. Photomicrographs of film autoradiograms show NMDAR1 mRNA hybridization in the hippocampus of an OVX rat (A), an OVX+E rat (B), and an OVX+E+P rat (C). Note that there is no overt difference in hybridization distribution or intensity in the hippocampal subfields among rats from different treatment groups.
[View Larger Version of this Image (176K GIF file)]
Fig. 8. Bar graphs depicting the quantification of NMDAR1 mRNA labeling in the CA1, dentate gyrus, and CA3 subfields of the hippocampus. There were no statistically significant differences in optical density measurements in any of the subfields among the three groups. Values represent mean ± SEM for nine OVX rats, nine OVX+E, and nine OVX+E+P rats.
[View Larger Version of this Image (31K GIF file)]
DISCUSSION
In the present study, quantitative confocal microscopic evaluation of NMDAR1 immunofluorescence intensity revealed that both estradiol and estradiol plus progesterone treatment in ovariectomized rats induced a significant intensity increase within the somata and dendrites of CA1 pyramidal cells in comparison with nonsteroid treated ovariectomized rats. A smaller, although statistically significant, increase was also observed within the somata of the dentate gyrus granule cells of steroid-treated animals in comparison with nontreated ovariectomized animals but not within their dendrites. Because there was a trend toward an intensity increase in the granule cell dendrites, the absence of a significant change may have been the result of an inability to detect small intensity increases because of a degree of variability inherent in this technique. Additionally, there were no detectable differences in intensity levels within CA3 pyramidal cell somata of animals from all three groups. In situ hybridization analysis revealed no accompanying detectable alterations in NMDAR1 mRNA levels in any hippocampal subfield in steroid-treated rats as compared with OVX rats.Interpretation of NMDAR1 immunofluorescence intensity data
The use of confocal microscopy yields high-resolution, cross-sectional images of neurons, which when coupled with gray-level intensity quantification and a photometic offset, enabled us to obtain intensity measurements within major cellular compartments. Several factors contribute to the validity of the immunofluorescence intensity results as representing significant alterations between nontreated ovariectomized rats and steroid-treated ovariectomized rats. First, methodological variability was reduced by rigidly controlling tissue processing, immunofluorescent staining, confocal parameters, and analysis design. As a result, variability was minimized and intensity changes that were both consistent and of a substantial magnitude yielded statistically significant results. Additionally, the positive findings were regionally specific and occurred with greatest magnitude in CA1, the hippocampal field, in which estrogen-induced morphological changes have been observed (Gould et al., 1990Immunoelectron microscopic descriptions of the ultrastructural distribution of the NMDAR1 subunit aids in the interpretation of our results. Similar to our qualitative CLSM observations, electron microscopic descriptions of rat hippocampal neurons revealed a patchy distribution of NMDAR1 immunocytochemical deposition throughout the somatodendritic cytoplasm (Petralia et al., 1994
Mechanism of estrogen regulation of the NMDAR
Consideration of both the immunofluorescence intensity and in situ hybridization data together suggests that alterations in NMDAR1 immunofluorescence are the result of post-transcriptional regulation of the NMDAR1 protein. Reasonable possibilities of post-transcriptional regulation include an increase in rate of protein translation and/or post-translational modifications such as an alteration in the rate of protein degradation. Given the association of NMDAR1 protein with microtubules in the dendrites, intensity increases in the CA1 dendrites may be the result of increased dendritic transport. It is possible that the in situ hybridization technique is not sensitive enough to detect subtle changes in mRNA levels; however, post-transcriptional control of NMDAR1 protein expression has been demonstrated previously in PC12 cells, in which NMDAR1 mRNA is transcribed but not translated (Sucher et al., 1993The mechanism of regulation suggested by these results is somewhat different from the classical cellular mechanism of steroid hormone regulation of gene transcription. This is indicated by previous observations that suggest that estrogen regulation of NMDARs may be mediated by trans-synaptic interactions (Weiland, 1992
A more detailed characterization of estrogen-induced NMDAR protein regulation remains to be elucidated. The subcellular distribution of the NMDAR1 subunit has been demonstrated to be controlled by specific amino acid sequences that are located within a C-terminal exon that is subject to alternative splicing (Ehlers et al., 1995
Functional significance
Estradiol has an important role in cognitive function in experimental animals (Luine, 1994In addition to increasing the duration of EPSPs in CA1 neurons in a manner suggestive of NMDAR enhancement, estrogen treatment also induced repetitive firing in some CA1 neurons that resembled epileptic bursting responses (Wong and Moss, 1992
FOOTNOTES
Received June 17, 1996; revised July 25, 1996; accepted Aug. 16, 1996.
This work was supported by the Charles A. Dana Foundation and National Institutes of Health Grants AG-06647 (J.H.M.), NS-30105 (N.G.W.), and NS-07080 (B.S.M.). We thank Dr. George Huntley for helpful comments on this manuscript.
Correspondence should be addressed to Dr. John H. Morrison, Fishberg Research Center for Neurobiology, The Mount Sinai School of Medicine, P.O. Box 1065, One Gustave L. Levy Place, New York, NY 10029-6574.
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Estrogen-Induced Increase in the Magnitude of Long-Term Potentiation Occurs Only When the Ratio of NMDA Transmission to AMPA Transmission Is Increased
J. Neurosci., August 24, 2005; 25(34): 7780 - 7791.
[Abstract] [Full Text] [PDF]
N. R. Miller, T. Jover, H. W. Cohen, R. S. Zukin, and A. M. Etgen
Estrogen Can Act via Estrogen Receptor {alpha} and {beta} to Protect Hippocampal Neurons against Global Ischemia-Induced Cell Death
Endocrinology, July 1, 2005; 146(7): 3070 - 3079.
[Abstract] [Full Text] [PDF]
C. Li, W. G. Brake, R. D. Romeo, J. C. Dunlop, M. Gordon, R. Buzescu, A. M. Magarinos, P. B. Allen, P. Greengard, V. Luine, et al.
Estrogen alters hippocampal dendritic spine shape and enhances synaptic protein immunoreactivity and spatial memory in female mice
PNAS, February 17, 2004; 101(7): 2185 - 2190.
[Abstract] [Full Text] [PDF]
Y. Tang, W. G.M. Janssen, J. Hao, J. A. Roberts, H. McKay, B. Lasley, P. B. Allen, P. Greengard, P. R. Rapp, J. H. Kordower, et al.
Estrogen Replacement Increases Spinophilin-immunoreactive Spine Number in the Prefrontal Cortex of Female Rhesus Monkeys
Cereb Cortex, February 1, 2004; 14(2): 215 - 223.
[Abstract] [Full Text] [PDF]
M. M. Adams and J. H. Morrison
Estrogen and the Aging Hippocampal Synapse
Cereb Cortex, December 1, 2003; 13(12): 1271 - 1275.
[Abstract] [Full Text] [PDF]
I. Chen
Focusing on the Big Picture
Sci. Aging Knowl. Environ., September 10, 2003; 2003(36): nf17 - 17.
[Abstract] [Full Text]
P. R. Rapp, J. H. Morrison, and J. A. Roberts
Cyclic Estrogen Replacement Improves Cognitive Function in Aged Ovariectomized Rhesus Monkeys
J. Neurosci., July 2, 2003; 23(13): 5708 - 5714.
[Abstract] [Full Text] [PDF]
W J Cutter, R Norbury, and D G M Murphy
Oestrogen, brain function, and neuropsychiatric disorders
J. Neurol. Neurosurg. Psychiatry, July 1, 2003; 74(7): 837 - 840.
[Full Text] [PDF]
Y. Ji, A. Z. Murphy, and R. J. Traub
Estrogen Modulates the Visceromotor Reflex and Responses of Spinal Dorsal Horn Neurons to Colorectal Stimulation in the Rat
J. Neurosci., May 1, 2003; 23(9): 3908 - 3915.
[Abstract] [Full Text] [PDF]
D. Yokomaku, T. Numakawa, Y. Numakawa, S. Suzuki, T. Matsumoto, N. Adachi, C. Nishio, T. Taguchi, and H. Hatanaka
Estrogen Enhances Depolarization-Induced Glutamate Release through Activation of Phosphatidylinositol 3-Kinase and Mitogen-Activated Protein Kinase in Cultured Hippocampal Neurons
Mol. Endocrinol., May 1, 2003; 17(5): 831 - 844.
[Abstract] [Full Text] [PDF]
V. Znamensky, K. T. Akama, B. S. McEwen, and T. A. Milner
Estrogen Levels Regulate the Subcellular Distribution of Phosphorylated Akt in Hippocampal CA1 Dendrites
J. Neurosci., March 15, 2003; 23(6): 2340 - 2347.
[Abstract] [Full Text] [PDF]
C. L. Jordan, S. E. Christensen, R. J. Handa, J. L. Anderson, W. A. Pouliot, and S. M. Breedlove
Evidence That Androgen Acts Through NMDA Receptors to Affect Motoneurons in the Rat Spinal Nucleus of the Bulbocavernosus
J. Neurosci., November 1, 2002; 22(21): 9567 - 9572.
[Abstract] [Full Text] [PDF]
L. Wang, S. Andersson, M. Warner, and J.-A. Gustafsson
Estrogen Actions in the Brain
Sci. Signal., June 25, 2002; 2002(138): pe29 - pe29.
[Abstract] [Full Text] [PDF]
Y. Shi and E. H. Schlenker
Neonatal sex steroids affect ventilatory responses to aspartic acid and NMDA receptor subunit 1 in rats
J Appl Physiol, June 1, 2002; 92(6): 2457 - 2466.
[Abstract] [Full Text] [PDF]
ABSTRACT
