An age-dependent novel hyperinnervation of circumvallate papillae by tyrosine hydroxylase-containing nerve fibers in NGF-overexpressing transgenic mice

The density of protein gene product 9.5- and tyrosine hydroxylase-immunoreactive nerve fibers innervating circumvallate papillae of the tongue was substantially increased in transgenic mice that overexpressed nerve growth factor (NGF) when compared with age-matched controls. The fiber density was age-dependent. Only transgenic mice contained NGF-immunoreactive basal cells in the vicinity of taste buds, indicating that target-derived NGF induced novel hyperinnervation of the circumvallate papillae.     

Sodium channel expression in optic nerve astrocytes chronically deprived of axonal contact.

Immunocytochemical and electrophysiological methods were used to examine the effect of retinal ablation on the expression of sodium channels within optic nerve astrocytes in situ and in vitro. Enucleation was performed at postnatal day 3 (P3), and electron microscopy of the enucleated optic nerves at P28-P40 revealed complete degeneration of retinal ganglion axons, resulting in optic nerves composed predominantly of astrocytes. In contrast to control (non-enucleated) optic nerve astrocytes, which exhibited distinct sodium channel immunoreactivity following immunostaining with antibody 7493, the astrocytes in enucleated optic nerves did not display sodium channel immunoreactivity in situ. Cultures obtained from enucleated optic nerves consisted principally (greater than 90%) of glial fibrillary acidic protein (GFAP)+/A2B5- ("type-1") astrocytes, as determined by indirect immunofluorescence; GFAP+/A2B5+ ("type-2") astrocytes were not present, nor were GFAP-/A2B5+ (O-2A) progenitor cells. Sodium channel immunoreactivity was not present in GFAP+/A2B5- astrocytes obtained from enucleated optic nerves; in contrast, GFAP+/A2B5- astrocytes from control optic nerves exhibited 7493 immunostaining for the first 4-6 days in culture. Sodium current expression, studied using whole-cell patch-clamp recording, was attenuated in cultured astrocytes derived from enucleated optic nerves. Whereas 39 of 50 type-1 astrocytes cultured from intact optic nerves showed measurable sodium currents at 1-7 days in vitro, sodium currents were present in only 6 of 38 astrocytes cultured from enucleated optic nerves. Mean sodium current densities in astrocytes from the enucleated optic nerves (0.66 +/- 0.3 pA/pF) were significantly smaller than in astrocytes from control optic nerves (7.15 +/- 1.1 pA/pF). The h infinity-curves of sodium currents were similar in A2B5- astrocytes from enucleated and control rat optic nerves. These results suggest that there is neuronal modulation of sodium channel expression in type-1 optic nerve astrocytes, and that, following chronic loss of axonal association in vivo, sodium channel expression is down-regulated in this population of optic nerve astrocytes.     

Sodium channel expression within chronic multiple sclerosis plaques

Multiple sclerosis (MS) is characterized by focal destruction of myelin sheaths, gliotic scars, and axonal damage that contributes to the accumulation of nonremitting clinical deficits. Previous studies have demonstrated coexpression of sodium channel Nav1.6 and the sodium-calcium exchanger (NCX), together with beta-amyloid precursor protein (beta-APP), a marker of axonal damage, in degenerating axons within acute MS lesions. Axonal degeneration is less frequent within chronic MS lesions than in acute plaques, although current evidence suggests that axonal loss in chronic lesions ("slow burn") is a major contributor to accumulating disability. It is not known, however, whether axonal degenerations in chronic and acute lesions share common mechanisms, despite radically differing extracellular milieus. In this study, the expression of sodium channels Nav1.2 and Nav1.6 and of NCX was examined in chronic MS plaques within the spinal cord. Nav1.2 immunostaining was not observed along demyelinated axons in chronic lesions but was expressed by scar and reactive astrocytes within the plaque. Nav1.6 immunoreactivity, which was intense at nodes of Ranvier in normal appearing white matter in the same sections, was present in approximately one-third of the demyelinated axons within these plaques in a patchy rather than continuous distribution. NCX was not detected in demyelinated axons within chronic lesions, although it was clearly present within the scar astrocytes surrounding the demyelinated axons. beta-APP accumulation occurred in a small percentage of axons within chronic lesions within the spinal cord, but beta-APP was not preferentially present in axons that expressed Nav1.6. These observations suggest that different mechanisms underlie axonal degeneration in acute and chronic MS lesions, with axonal injury occurring at sites of coexpression of Nav1.6 and NCX in acute lesions but independent of coexpression of these 2 molecules in chronic lesions.     

Sodium channel expression in hypothalamic osmosensitive neurons in experimental diabetes

Vasopressin is synthesized by neurons in the supraoptic nucleus of the hypothalamus and its release is controlled by action potentials produced by specific subtypes of voltage-gated sodium channels expressed in these neurons. The hyperosmotic state associated with uncontrolled diabetes mellitus causes elevated levels of plasma vasopressin, which are thought to contribute to the pathologic changes of diabetic nephropathy. We demonstrate here that in the rodent streptozotocin model of diabetes there are increases in expression of mRNA and protein for two sodium channel alpha-subunits and two beta-subunits in the neurons of the supraoptic nucleus. Transient and persistent sodium currents show parallel increases in these diabetic neurons. In the setting of chronic uncontrolled diabetes, these changes in sodium channel expression in the supraoptic nucleus may be maladaptive, contributing to the development of secondary renal complications.     

3R tau expression modifies behavior in transgenic mice

Tauopathy is a group of disorders characterized by the accumulation of hyperphosphorylated tau protein in the brain, resulting in dementia. Here, tau‐related behavior was evaluated in a mouse model with brain overexpression of the shortest human tau isoform (0N3R). Two groups of animals [tau‐transgenic (tau‐tg) and control littermates] were tested for learning and memory at 1 and 7 months. In the Morris water maze, all mice learned the task at 1 month of age and did not learn at 7 months. In contrast, at 7 months, the tau‐tg animals demonstrated better retention of the passive avoidance response compared with their control littermates, which did not learn. In the open field test, no differences were measured between transgenic and nontransgenic young mice, but significantly higher locomotion was observed in the 7‐month‐old tau‐tg mice compared with controls. Behavior during the elevated plus maze test was the same at 1 month, but at 7 months increased entrance to the different arms was observed in the tau‐tg group. Tau expression and phosphorylation levels were analyzed at 8 months. In the subcortical brain region associated with passive avoidance behavior, the tau‐tg mice demonstrated increased brain tau expression coupled with reduced relative phosphorylation. In contrast, increased tau expression and phosphorylation were measured in the cerebral cortex of the tau‐tg mice. In conclusion, 7‐8‐month‐old tau‐tg mice overexpressing nonmutated 0N3R human tau isoform demonstrated enhanced behavior in the passive avoidance test, paralleled by relative tau hypophosphorylation in the subcortical brain region. © 2010 Wiley‐Liss, Inc.     

Structural and functional neuropathology in transgenic mice with CNS expression of IFN-alpha.

Cytokines belonging to the type I interferon (e.g. interferon-alpha) family are important in the host response to infection and may have complex and broad ranging actions in the central nervous system (CNS) that may be beneficial or harmful. To better understand the impact of the CNS expression of the type I interferons (IFN), transgenic mice were developed that produce IFN-alpha(1) chronically from astrocytes. In two independent transgenic lines with moderate and low levels of astrocyte IFN-alpha mRNA expression respectively, a spectrum of transgene dose- and age-dependent structural and functional neurological alterations are induced. Structural changes include neurodegeneration with loss of cholinergic neurons, gliosis, angiopathy with mononuclear cell cuffing, progressive calcification affecting basal ganglia and cerebellum and the up-regulation of a number of IFN-alpha-regulated genes. At a functional level, in vivo and in vitro electrophysiological studies revealed impaired neuronal function and disturbed synaptic plasticity with pronounced hippocampal hyperexcitability. Severe behavioral alterations were also evident in higher expressor GFAP-IFNalpha mice which developed fatal seizures around 13 weeks of age precluding their further behavioral assessment. Modest impairments in discrimination learning were measured in lower expressor GFAP-IFNalpha mice at various ages (7-42 weeks). The behavioral and electrophysiological findings suggest regional changes in hippocampal excitability which may be linked to abnormal calcium metabolism and loss of cholinergic neurons in the GIFN mice. Thus, these transgenic mice provide a novel animal model in which to further evaluate the mechanisms that underlie the diverse actions of type I interferons in the intact CNS and to link specific structural changes with functional impairments.     

Altered presynaptic gene expression in transgenic mice producing dopamine in the pineal gland.

Neurotransmitters are known to play an important role in the development of the nervous system. We recently generated transgenic mice that ectopically express tyrosine hydroxylase (TH) and thereby produce dopamine (DA) de novo in pinealocytes of the pineal gland (PG). The transgenic PG also exhibited a dramatic decrease in TH-immunoreactive (IR) fibers putatively arising from the superior cervical ganglion (SCG) (Cho et al. [1996] Proc Natl Acad Sci USA 93:2862-2866). In the current study, however, we found that there was no reduction in the number of fibers immunostained for neurofilament protein or PGP9.5, markers known to be heavily localized in fibers, despite the reduction of TH fiber density. Therefore, we investigated whether the decreased TH-IR fiber density is the consequence of reduced sympathetic innervation, or a decrease in TH expression within innervating fibers. Immunohistochemical analysis comparing control and transgenic PG demonstrated no apparent differences in numbers of NPY- and aromatic-L-amino acid decarboxylase (AADC)-IR fibers, indicating that TH expression is decreased in a normal number of innervating fibers. Furthermore, presynaptic neurons in the transgenic SCG showed abnormal and heterogeneous TH immunoreactivity and reduced TH and norepinephrine transporter (NET) mRNA levels. These results show that ectopic DA production in the PG lowers TH and NET gene expression in the SCG without altering sympathetic innervation to the PG and suggest that the alteration of target neurotransmitter phenotype may influence gene expression of phenotype-specific proteins in projecting neurons.     

Increased expression of water channel aquaporin 1 and aquaporin 4 in Creutzfeldt-Jakob disease and in bovine spongiform encephalopathy-infected bovine-PrP transgenic mice

Spongiform change is a cardinal feature in transmissible spongiform encephalopathies, including Creutzfeldt-Jakob disease (CJD) and bovine spongiform encephalopathy (BSE). It is characterized by swelling of the neuronal processes and vacuolization of the neuropil, leading to increased intraneuronal water content. The present study examines, by gel electrophoresis and Western blotting, the expression levels of the water channels aquaporin 1 (AQP1) and aquaporin 4 (AQP4) in the frontal cortex (area 8) homogenates of sporadic CJD cases (six men, four women; seven cases with methionine/methionine at codon 129 and PrP type 1; two cases with valine/valine at codon 129 and PrP type 2, and one case methionine/valine at codon 129 and PrP type 1) compared with age-matched controls, and cases with Alzheimer’s disease (AD, stage VI of Braak and Braak) and diffuse Lewy body disease (DLB). AQP1 and AQP4 protein levels were also studied in the cerebral cortex of BSE-infected bovine-PrP transgenic mice (BoPrP-Tg110 mice) examined at 60, 150, 210 and 270 days post-inoculation (dpi) compared with healthy brain-inoculated control mice. Quantitative densitometry of AQP bands normalized for β-actin was analyzed using Statgraphics plus 5.0 software from ANOVA and LSD statistical tests. Significant increased expression levels of AQP1 (as revealed with two different antibodies) and AQP4 were seen in CJD, but not in advanced AD and DLB cases when compared with controls. Immunohistochemistry revealed that AQP1 and AQP4 were expressed in astrocytes in diseased cases. No modifications in the expression levels of AQP1 and AQP4 were observed in BSE-infected bovine-PrP transgenic mice at 60, 150 and 210 dpi. However, a significant increase in the expression levels of AQP1 and AQP4 was found in mice at 270 dpi, the time corresponding with the appearance of PrP^res immunoreactivity in Western blots and typical spongiform lesions in the brain. Together, these findings show increased expression of water channels in the brain in human and animal prion diseases. These modifications may have implications in the regulation of water transport in astrocytes and may account for an imbalance in water and ion homeostasis in prion diseases.     

Protection against hypoxic-ischemic injury in transgenic mice overexpressing Kir6.2 channel pore in forebrain

The role of the K-ATP channel pore-forming subunit Kir6.2 on protection from cerebral hypoxic-ischemic injury was assessed in transgenic mice overexpressing normal Kir6.2 or a dominant negative form (AFA) of this subunit in the forebrain. The resulting mice overexpress either the Kir6.2 or the AFA transgene mainly in the cerebral cortex and hippocampus. The Kir6.2 transgenic mice are resistant to hypoxic-ischemic injury showing a decreased region of cortical damage as compared to the dominant negative AFA and the wild-type mice. Moreover, the overexpression of Kir6.2 allowed an important silencing of the neurons present in forebrain regions thus protecting them from ischemic injury. Interestingly, the phenotype observed in Kir6.2 transgenic mice was observed without increased sulfonylurea binding. Taken together, these results indicate that the transgenic overexpression of Kir6.2 in forebrain significantly protects mice from hypoxic-ischemic injury and neuronal damage seen in stroke.     

Analysis of the human tyrosine hydroxylase promoter-chloramphenicol acetyltransferase chimeric gene expression in transgenic mice.

To investigate cis-elements responsible for catecholaminergic (CAnergic) neuron-specific expression of the tyrosine hydroxylase (TH) gene, we produced lines of transgenic mice carrying 5.0-kb, 2.5-kb and 0.2-kb fragments from the 5'-flanking region of the human TH gene fused to a reporter gene, chloramphenicol acetyltransferase (CAT), and designated them as TC 50, TC 25, and TC 02, respectively, and reporter gene expression in transgenic mice was analyzed by CAT assay by immunocytochemistry with anti-CAT antibody. High-level CAT expression was observed in the brain and adrenal gland using the 5.0-kb promoter of the TC 50 mice, but ectopic expression was consistently observed in several somatic tissues, e.g. thymus, colon, and testis. In brain, expression was achieved in CAnergic neurons with the largest construct (5.0 kb), but not with 2.5 kb or 0.2 kb of 5' flanking sequence. However, TC 50 mice also expressed CAT immunoreactivity in non-CAnergic neurons. In the TC 25 line CAT immunoreactivity was detected only in some non-CAnergic neurons. In the TC 02 line no CAT immunoreactivity was detected in any of the tissues examined. These results indicate that the 5.0-kb DNA fragment of the TH gene upstream region contains activity to express CAT in CAnergic neurons and surprisingly, lacks some regulatory elements attenuating ectopic expression, and that the 2.5-kb and 0.2-kb fragment are not sufficient for the proper expression. We discuss the presence of the tissue-specific regulatory elements in the structure portion of the TH gene and/or 3'-flanking region.     

Normal and pathological expression of GFAP promoter elements in transgenic mice

The expression of the glial fibrillary acidic protein (GFAP), a component of astroglial intermediate filaments, is regulated under developmental and pathological conditions. In order to characterize DNA sequences involved in such regulations, we produced transgenic mice bearing 2 kb of the 5′ flanking region of the murine GFAP gene linked to the Escherichia coli β-galactosidase (β-gal) reporter gene. Seven transgenic lines were obtained. We observed that the regulatory elements present in the transgene GFAP-nls-LacZ direct an expression in the neural and non-neural tissue and target in vivo an unexpected subpopulation of astrocyte. In the developing brain, β-gal activity and GFAP appeared simultaneously and in the same region, on embryonic day 18 (E18), suggesting that the 2 kb of the promoter contains the regulatory sequences responsible for the perinatal vimentin/GFAP switch. In addition, we demonstrated that the 2 kb sequence of the GFAP promoter used in the transgene possess elements which are activated after a surgical injury, thus permitting to study some aspects of reactive gliosis in these transgenic mice. These transgenic lines provide a useful tool by enabling further studies of astroglial and, probably, neuronal physilogies.     

Synaptophysin expression in motor neurons of transgenic mice with amyotrophic lateral sclerosis

BACKGROUND: Affected signal convection of synaptophysin on motor neurons may cause injury of motor neurons and then induce neurodegeneration and cell death in the end. OBJECTIVE: To investigate the number and density of synaptophysin on motor neurons in the anterior horn of lumbar spinal cord and sensorimotor cortex of the transgenic mouse model of amyotrophic lateral sclerosis (ALS). DESIGN: Randomized controlled animal study. SETTING: Brain Injury and Repair Group, HFI Institute of Melbourne University. MATERIALS: Transgenic mice expressing a mutated human superoxide dismutase 1 (SOD-1) were taken as ALS group (n =36), while those derived from the B6SJL-TgN gene line were taken as control group (n =36), according to the difference of gender and three postnatal time points (postnatal 60, 90 and 120 days), twelve mice of either gender were allocated in each subgroup. METHODS: The experiment was carried out in Brain Injury and Repair Group, HFI Institute of Melbourne University from November 2003 to June 2004. ① Fluorogold labeling was used for the motor neurons in the lumbar and sensorimotor cortex. ② Immunofluorescence was applied for the labeling of synaptophysin; positive control sections were represented by adding the synaptophysin antibody and the staining, showing a positive result. For negative controls, the synaptophysin antibody was omitted. ③ Stereological counting system was adopted in the statistical analysis. MAIN OUTCOME MEASURES: ① Fluorogold labeling of motor neurons; ② number of synaptophysin on the motor neurons. RESULTS: ① Fluorogold labeling of motor neurons: The motor neurons in the lumbar and sensorimotor cortex were clearly labeled by fluorogold under the detection of fluorescent microscope. ② The number of synaptophysin on the motor neurons: The number statistically decreased at the mid stage (postnatal 90 days) and late stage (postnatal 120 days) [motor neuron somas at lumbar spinal cord: (0.75±0.06), (0.59±0.09)/μm; motor neuron dendrite at lumbar spinal cord: (0.71±0.06), (0.55±0.03)/μm; motor neuron somas at sensorimotor cortex: (0.79±0.03), (0.63±0.08)/μm; motor neuron dendrite at sensorimotor cortex: (0.76±0.07), (0.61±0.08)/μm, P < 0.01]. The reduction of synaptophysin was parallel between the gender differences. CONCLUSION: Loss of synaptophysin on motor neurons is directly related to the progression of ALS.     

Microglial K+ channel expression in young adult and aged mice

The K⁺ channel expression pattern of microglia strongly depends on the cells' microenvironment and has been recognized as a sensitive marker of the cells' functional state. While numerous studies have been performed on microglia in vitro, our knowledge about microglial K⁺ channels and their regulation in vivo is limited. Here, we have investigated K⁺ currents of microglia in striatum, neocortex and entorhinal cortex of young adult and aged mice. Although almost all microglial cells exhibited inward rectifier K⁺ currents upon membrane hyperpolarization, their mean current density was significantly enhanced in aged mice compared with that determined in young adult mice. Some microglial cells additionally exhibited outward rectifier K⁺ currents in response to depolarizing voltage pulses. In aged mice, microglial outward rectifier K⁺ current density was significantly larger than in young adult mice due to the increased number of aged microglial cells expressing these channels. Aged dystrophic microglia exhibited outward rectifier K⁺ currents more frequently than aged ramified microglia. The majority of microglial cells expressed functional BK‐type, but not IK‐ or SK‐type, Ca²⁺‐activated K⁺ channels, while no differences were found in their expression levels between microglia of young adult and aged mice. Neither microglial K⁺ channel pattern nor K⁺ channel expression levels differed markedly between the three brain regions investigated. It is concluded that age‐related changes in microglial phenotype are accompanied by changes in the expression of microglial voltage‐activated, but not Ca²⁺‐activated, K⁺ channels. GLIA 2015;63:664–672     

Major histocompatibility complex Class I expression in oligodendrocytes induces hypomyelination in transgenic mice

Increased expression of MHC Class I occurs in the central nervous system in association with demyelinating diseases such as multiple sclerosis and experimental allergic encephalomyelitis. To determine if MHC Class I expression by oligodendrocytes induces white matter pathology, the MHC Class I gene was expressed in transgenic mice under the control of the myelin basic protein (MBP) promoter. These mice display a neurological phenotype at 21 days-of-age. We examined these mice at 1, 3, and 12 weeks-of-age. MHC Class I was detected in the brains and spinal cords of transgenic mice but not in control mice. Class I was located in oligodendrocyte perikarya but not in myelin sheaths. The central nervous system of these transgenic mice was hypomyelinated and contained hypertrophic microglia and astrocytes. These observations establish that Class I expression by oligodendrocytes delays normal myelination but does not cause inflammatory demyelination. This hypomyelinating animal model is of potential use in studying the interactions between immunologically active molecules and remyelination in disorders of myelin. © 1996 Wiley-Liss, Inc.     

CNS interleukin-3 (IL-3) expression and neurological syndrome in antisense-IL-3 transgenic mice.

Interleukin-3 (IL-3) is an important mediator of physiological and pathophysiological processes affecting the central nervous system (CNS). It stimulates the proliferation and activation of microglia and can enhance differentiation of cholinergic and sensory neurons. To examine the role of IL-3 in the CNS, we utilized transgenic mice expressing a murine antisense IL-3 (AS-IL-3) RNA under the control of the T cell B19 promoter so that expression is limited to hematopoietic cells. The AS-IL-3 transgenic mice develop either a progressive neurologic dysfunction, which includes ataxia, bradykinesia, and paralysis, or a lymphoproliferative syndrome. Histopathology demonstrated accumulations of reactive astrocytes in the cerebellum, brain stem, and spinal cord, accompanied by activated microglia. Partial loss of cerebellar nuclei neurons as well as neurons in the cranial nerve nuclei and spinal cord motor neurons is seen. Despite depletion of IL-3 peripherally, expression of IL-3 mRNA and protein is turned on in the CNS of the transgenic mice. Astrocytes cultured from the AS-IL-3 mice contain IL-3 mRNA and may thus be responsible for the activation of the microglia. This model should provide important insights into the role of cytokines in neurological disorders.     

Altered hippocampal synaptic transmission in transgenic mice with astrocyte-targeted enhanced CCL2 expression

Elevated expression of neuroinflammatory factors in the central nervous system (CNS) contributes to the cognitive impairment in CNS disorders such as injury, disease and neurodegenerative disorders. However, information on the role of specific neuroimmune factors in normal and abnormal CNS function is limited. In this study, we investigated the effects of chronic exposure to the chemokine CCL2 on hippocampal synaptic function at the Schaffer collateral-CA1 synapse, a synapse that is known to play an important role in cognitive functions such as memory and learning. Synaptic function was measured in vitro using hippocampal slices obtained from transgenic mice that express elevated levels of CCL2 in the CNS through astrocyte expression and their non-transgenic littermate controls. Extracellular field potential electrophysiological recordings showed a significant reduction in the magnitude of synaptic responses in hippocampal slices from the CCL2 transgenic mice compared with slices from non-transgenic littermate controls. Two forms of short-term synaptic plasticity (post-tetanic potentiation and short-term potentiation) thought to be important cellular mechanisms of short-term memory were enhanced in hippocampal slices from CCL2 transgenic mice compared to non-transgenic hippocampal slices, whereas long-term synaptic plasticity (LTP), which is critical to long-term memory formation, was not altered. Western blot analysis of hippocampus from the CCL2 transgenic mice and non-transgenic mice showed no change in level of neuronal specific enolase, a neuronal specific protein, GFAP, an astrocyte specific protein, and several synaptic proteins compared with non-transgenic littermate controls. These results show that CCL2, which is known to be chronically produced at elevated levels within the CNS in a number of CNS disorders, can significantly alter hippocampal function and implicate a role for CCL2 in the cognitive dysfunction associated with these CNS disorders.     

Brain-derived neurotrophic factor signaling modifies hippocampal gene expression during epileptogenesis in transgenic mice

Brain-derived neurotrophic factor (BDNF) regulates neuronal survival, differentiation and plasticity. It has been shown to promote epileptogenesis and transgenic mice with decreased and increased BDNF signaling show opposite alterations in epileptogenesis. However, the mechanisms of BDNF action are largely unknown. We studied the gene expression changes 12 days after kainic acid-induced status epilepticus in transgenic mice overexpressing either the functional BDNF receptor trkB or a dominant-negative truncated trkB. Epileptogenesis produced marked changes in expression of 27 of 1090 genes. Cluster analysis revealed BDNF signalling-mediated regulation of functional gene classes involved in cellular transport, DNA repair and cell death, including kinesin motor kinesin family member 3A involved in cellular transport. Furthermore, the expression of cytoskeletal and extracellular matrix components, such as tissue inhibitor of metalloproteinase 2 was altered, emphasizing the importance of intracellular transport and interplay between neurons and glia during epileptogenesis. Finally, mice overexpressing the dominant-negative trkB, which were previously shown to have reduced epileptogenesis, showed a decrease in mRNAs of several growth-associated genes, including growth-associated protein 43. Our data suggest that BDNF signaling may partly mediate the development of epilepsy and propose that regrowth or repair processes initiated by status epilepticus and promoted by BDNF signaling may not be as advantageous as previously thought.     

Reduced secretagogin expression in the hippocampus of P301L tau transgenic mice

Neuropathological features in Alzheimer’s Disease (AD) include the presence of hyperphosphorylated forms of the microtubule-associated tau protein (tau) in hippocampal neurones. Numerous studies indicate a neuroprotective effect of calcium-binding proteins (Ca2+ binding proteins) in neurodegenerative diseases (e.g., AD). Secretagogin is a newly described Ca2+ binding protein that is produced by pyramidal neurones of the human hippocampus. Recently, secretagogin expressing hippocampal neurones were demonstrated to resist tau-induced pathology in AD in contrast to the majority of neighbouring neurones. This suggested a neuroprotective effect of secretagogin in hippocampal neurones. Here, we investigated secretagogin expression in wild type (wt) mice as well as in hemizygous and homozygous P301L tau transgenic (tg) mice, which show pronounced and widespread tau pathology in hippocampal neurones. Secretagogin expression was analyzed at the immunohistochemical and biochemical levels in brains of age-matched wt and hemi- and homozygous tau tg mice. In wt mice hippocampal secretagogin-immunoreactive neurones were invariably detected, while immunoreactivity was much lower (P < 0.001) in tau tg mice. Of note, hippocampal secretagogin immunoreactivity was absent in 62.5% of homozygous tau tg mice. In line with this finding, Western blot analysis demonstrated a significant reduction in protein expression levels of secretagogin in homozygous tau tg compared to wt mice. Our results suggest that increased levels of tau negatively influence secretagogin expression in the hippocampus of tau tg mice.