BRIEF REPORT |
Correspondence to: Michael R. Kreutz, AG Molecular Mechanisms of Plasticity, Dept. of Neurochemistry/Molecular Biology, Leibniz Institute for Neurobiology, Brenneckestr. 6, 39118 Magdeburg, Germany. E-mail: Kreutz@ifn-magdeburg.de
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Summary |
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We investigated by immunohistochemistry (IHC) the distribution of caldendrin, the founding member of a novel family of neuronal calcium-binding proteins closely related to calmodulin, in human forebrain. Caldendrin immunoreactivity was unevenly distributed, with prominent staining in the paleo- and neocortex, hippocampus, and hypothalamus. With the exception of the hypothalamus, labeling was restricted to the somatodendritic compartment of neurons. This distribution completely matches that reported in rat, indicating that the cellular function is most likely conserved among species. Therefore, one prerequisite for functional studies in rodent models aimed at elucidation of mechanisms with relevance for humans can be based on the present findings.
(J Histochem Cytochem 51:11091112, 2003)
Key Words: EF-hand proteins, dendrites, axons, pyramidal cells, interneuron, calcium-binding protein, calmodulin
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Introduction |
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THE INTRACELLULAR TRANSDUCTION of neuronal Ca2+ signals is brought about by binding of the cation to calcium-binding proteins (CaBPs). The prototype of a ubiquitously expressed CaBP with Ca2+-sensing function is calmodulin (CaM), which is believed to be the common ancestor of a family of proteins termed Ca2+-sensor proteins, which are characterized by the occurrence of two or more EF-hand motifs at Ca2+-binding sites (
Analysis of caldendrin's cellular functions requires the use of rodent animal models. Previous studies, however, have shown astonishing species differences in the expression of CaBPs, which ultimately limit the significance of rodent studies in terms of generalization to human conditions (
All brains were obtained from pathologists with full consent of each family and in accordance with the ethics and rules outlined by German law and the local ethics commission of the University of Magdeburg. Brains of three individuals without neurological or psychiatric disorders (two men, 49 and 63 years, and one woman, 54 years) were studied. Brains were removed within 48 hr after death. The tissue preparation was performed as described earlier (
For Western blots, frozen tissue from the dorsolateral prefrontal cortex (female, 58 years, tissue obtained 21 hr after death) was homogenized in 20 mM Tris-HCl, pH 7.3, containing a protease inhibitor cocktail (Complete; Roche, Mannheim, Germany) and centrifuged at 100,000 x g for 15 min at 4C to separate soluble proteins and the insoluble pellet. Rat prefrontal and frontal cortex was used for comparison. After SDS-PAGE on 520% gels, proteins were blotted onto nitrocellulose, blocked with 5% non-fat dry milk, and incubated in 1:200 diluted rabbit anti-caldendrin antiserum (purified IgG fraction/concentration 1µg/µl) overnight. Detection was performed with HRP-conjugated anti-rabbit secondary antibody and the ECL detection kit (Amersham Biosciences; Freiburg, Germany). Caldendrin-IR was detected with the same rabbit polyclonal antiserum (1.5 cm posterior to the splenium of the corpus callosum at intervals of about 1.2 cm. After preincubation of the sections with methanol/H2O2 to block endogenous peroxidases and repeated washing with PBS, the antibody was applied at a working dilution of 1:100 in PBS. Thereafter the sections were processed with the avidinbiotin method (Vectastain-peroxidase kit; Vector, Burlingame, CA) and the reaction product was visualized with 3,3'-diaminobenzidine. The color reaction was enhanced by adding 2 ml of a 0.5% (v/v) nickel ammonium sulfate solution to the diaminobenzidine (
Comparison of the rat and human caldendrin cDNAs revealed a high degree of conservation among species (
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Caldendrin showed a widespread but uneven distribution in human forebrain. No apparent gender differences in caldendrin's regional and cellular localization were found in the three brains examined. To determine to what extent postmortem time affects staining, we chose brains that were processed after different postmortem delays. There were no differences with regard to intracellular staining intensity and/or regional staining patterns between a brain with a short-term (12 hr, male brain) and two others with a long-term postmortem interval (39 and 48 hr, male and female brains).
Fourteen different paleo- and neocortical areas were studied: gyrus semilunaris, gyrus ambiens, gyrus parahippocampalis, gyrus entorhinalis, gyrus occipitotemporalis lateralis, gyri temporales inferior and medius, gyri longus and breves insulae, gyrus precentralis, gyrus postcentralis, gyri frontales medius and superior, and gyrus cinguli. Caldendrin-IR neurons were found in all cortical areas under investigation. Typically, layer III and V pyramidal neurons stood out by intense immunostaining (Fig 1B and Fig 1C). Intracellularly, the immunoreaction was located in the perikarya and the dendrites of the nerve cells, with a staining pattern that closely resembled those of the dendritic marker MAP2 (not shown). The strongest intracellular staining intensity was observed in cingulate cortex pyramids (Fig 1C). Sometimes the neuropil showed weak to moderate immunostaining to caldendrin. A variety of interneurons were also found to express the protein. The weakest reactions were seen in entorhinal, parahippocampal, and temporal neurons.
The vast majority of pyramidal neurons showed faint to moderate immunostaining (not shown). Dentate gyrus granule cells were devoid of reaction product. Hippocampal interneurons were not immunoreactive for caldendrin. For the amygdaloid complex, the presence of some scattered neurons expressing the protein was evident (not shown).
Both basal ganglia and thalamus were characterized by multiple faintly stained neurons (not shown). No particular nuclei were caldendrin-IR.
In addition to cortical areas, the hypothalamus was the brain region with the most prominent immunolocalization of caldendrin. The protein was localized in neurons of different hypothalamic nuclei. The most pronounced immunostaining appeared in suprachiasmatic neurons near the III ventricle (Fig 1D). Remarkable immunostaining was confined to certain neurons of the paraventricular, the supraoptic (Fig 1E), the lateral, and the arcuate nuclei (not shown). Interestingly, a few strongly stained axons were detected within neurosecretory nuclei (Fig 1F) near the hypothalamic stalk (Fig 1G). This observation was somewhat surprising because it is at variance with results obtained in all other investigated rat and human brain regions. Preliminary data in rat, however, support the presence of caldendrin-IR in neurohypophyseal axons (Landwehr et al. unpublished observations). It is noteworthy that the antisera employed in this study also detects two shorter splice isoforms of caldendrin that are virtually absent from all other rat brain structures (
In human forebrain, however, the distribution of caldendrin-IR was very similar to the somato-dendritic localization of the protein in rat brain. Interestingly, as in rat always only a subpopulation of cells was caldendrin-IR. With respect to the almost identical expression pattern of caldendrin-IR, one can therefore conclude that cellular functions of caldendrin in rat and human are most likely similar. In addition, the almost identical distribution at the light microscopic level suggests that caldendrin expression in a subset of mainly principal and few interneurons has evolved due to differential requirements for somatodendritic Ca2+ signaling in these cells. Recent functional studies have linked caldendrin signaling to voltage-dependent Ca2+ channels (
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Acknowledgments |
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Supported by the DFG (Kr1879/2-1, 2-2), the Fonds of the Chemische Industrie, the Land Sachsen-Anhalt (FKZ: 2508A/0086 and 3004A/0088H), and the Fritz Thyssen Stiftung.
The excellent technical assistance of S. Funke and H. Dobrowolny is gratefully acknowledged.
Received for publication October 11, 2002; accepted February 19, 2003.
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