Does astroglial protein S100B contribute to West Nile neuro-invasive syndrome?

The clinical spectrum of West Nile Virus (WNV) infection ranges from a flu-like febrile condition to a more severe neuro-invasive disease that can cause death. The exact mechanism of neurodegeneration in neuro-invasive form of WNV infection has not been elucidated; however, a destructive role played by glial cells in promoting WNV mediated neurotoxicity has widely been speculated. The clinical studies revealed that the astroglial protein S100B is significantly elevated in the blood and CSF of patients with WNV infection, even in the absence of neuro-invasive disease. Therefore, the present study was designed to explore the potential role of S100B in the pathophysiology of WNV infection. The overarching hypothesis was that WNV primes astroglia to release S100B protein, which leads to a cascade of events that may have deleterious effects in both acute and chronic stages of WNV disease. To justify our hypothesis, we first ascertained increased levels of S100B in post-mortem tissue samples from WNV patients. Next, we looked at the effects of UV-inactivated WNV particles on astroglia using astroglial cell lines or primary cultures. Astroglial activation was measured as an increase in the expression of S100B and was analyzed by immunofluorescence and real-time PCR. Further, the in vitro effects of purified S100B protein on neutrophil migration and glutamate uptake were also determined in astroglial cell lines or primary cultures. We found that incubation of cultured astroglial cells with UV-inactivated WNV particles caused induction of S100B both at the mRNA and protein levels. Varying concentrations of S100B stimulated neutrophil migration in vitro. In addition, varying amounts of S100B caused inhibition of glutamate uptake in astroglia in a dose-dependent manner. Our data suggest that inactivated WNV particles are capable of inducing S100B synthesis in astroglia in vitro. We speculate that S100B release by activated astroglia may have multiple roles in the pathophysiology of WNV neuro-invasive disease, including induction of neutrophil migration to the sites where blood brain barrier is disrupted as well as glutamate neurotoxicity. To further elucidate the WNV-S100B neurotoxic pathway, in vivo studies using mouse models are warranted.

The design and delivery of a thermally responsive peptide to inhibit S100B-mediated neurodegeneration.

S100B, a glial-secreted protein, is believed to play a major role in neurodegeneration in Alzheimer's disease, Down syndrome, traumatic brain injury, and spinocerebellar ataxia type 1 (SCA1). SCA1 is a trinucleotide repeat disorder in which the expanded polyglutamine mutation in the protein ataxin-1 primarily targets Purkinje cells of the cerebellum. Currently, the exact mechanism of S100B-mediated Purkinje cell damage in SCA1 is not clear. However, here we show that S100B may act via the activation of the receptor for advanced glycation end product (RAGE) signaling pathway, resulting in oxidative stress-mediated injury to mutant ataxin-1-expressing neurons. To combat S100B-mediated neurodegeneration, we have designed a selective thermally responsive S100B inhibitory peptide, Synb1-ELP-TRTK. Our therapeutic polypeptide was developed using three key elements: (1) the elastin-like polypeptide (ELP), a thermally responsive polypeptide, (2) the TRTK12 peptide, a known S100B inhibitory peptide, and (3) a cell-penetrating peptide, Synb1, to enhance intracellular delivery. Binding studies revealed that our peptide, Synb1-ELP-TRTK, interacts with its molecular target S100B and maintains a high S100B binding affinity as comparable with the TRTK12 peptide alone. In addition, in vitro studies revealed that Synb1-ELP-TRTK treatment reduces S100B uptake in SHSY5Y cells. Furthermore, the Synb1-ELP-TRTK peptide decreased S100B-induced oxidative damage to mutant ataxin-1-expressing neurons. To test the delivery capabilities of ELP-based therapeutic peptides to the cerebellum, we treated mice with fluorescently labeled Synb1-ELP and observed that thermal targeting enhanced peptide delivery to the cerebellum. Here, we have laid the framework for thermal-based therapeutic targeting to regions of the brain, particularly the cerebellum. Overall, our data suggest that thermal targeting of ELP-based therapeutic peptides to the cerebellum is a novel treatment strategy for cerebellar neurodegenerative disorders.

Role of tissue transglutaminase type 2 in calbindin-D28k interaction with ataxin-1.

Spinocerebellar ataxia-1 (SCA1) is caused by the expansion of a polyglutamine repeats within the disease protein, ataxin-1. The mutant ataxin-1 precipitates as large intranuclear aggregates in the affected neurons. These aggregates may protect neurons from mutant protein and/or trigger neuronal degeneration by encouraging recruitment of other essential proteins. Our previous studies have shown that calcium binding protein calbindin-D28k (CaB) associated with SCAl pathogenesis is recruited to ataxin-l aggregates in Purkinje cells of SCAl mice. Since our recent findings suggest that tissue transglutaminase 2 (TG2) may be involved in crosslinking and aggregation of ataxin-l, the present study was initiated to determine if TG2 has any role in CaB-ataxin-l interaction. The guinea pig TG2 covalently crosslinked purified rat brain CaB. Time dependent progressive increase in aggregation produced large multimers, which stayed on top of the gel. CaB interaction with ataxin-l was studied using HeLa cell lysates expressing GFP and GFP tagged ataxin-l with normal and expanded polyglutamine repeats (Q2, Q30 and Q82). The reaction products were analyzed by Western blots using anti-polyglutamine, CaB or GFP antibodies. CaB interacted with ataxin-1 independent of TG2 as the protein-protein crosslinker DSS stabilized CaB-ataxin-l complex. TG2 crosslinked CaB preferentially with Q82 ataxin-1. The crosslinking was inhibited with EGTA or TG2 inhibitor cystamine. The present data indicate that CaB may be a TG2 substrate. In addition, aggregates of mutant ataxin-l may recruit CaB via TG2 mediated covalent crosslinking, further supporting the argument that ataxin-l aggregates may be toxic to neurons.

Tissue transglutaminase crosslinks ataxin-1: possible role in SCA1 pathogenesis.

Transglutaminase type 2 (TG2) has recently been implicated in crosslinking of mutant huntingtin protein into aggregates. Here we show that TG2 also crosslinks spinocerebellar ataxia-1 (SCA1) gene product ataxin-1. HeLa cell lysates expressing GFP tagged ataxin-1 with 2, 30 or 82 glutamines showed covalent crosslinking of ataxin-1 when incubated with exogenously added TG2. This crosslinking was inhibited by TG2 inhibitor cystamine. SCA1 transgenic mice which overexpress the mutant ataxin-1 in cerebellar Purkinje cells showed elevated nuclear TG2 in the absence of ataxin-1 nuclear aggregates. The addition of purified TG2 to the nuclear extracts or addition of SCA1 nuclear TG2 to GFP-Q82 HeLa cell lysates resulted in the formation of insoluble aggregates. These data indicate that ataxin-1 is a substrate of TG2. Further, in SCA1 TG2 may translocate to the nucleus in response to nuclear accumulation of mutant ataxin-1 at early stages of the disease.

Intranasal administration of IGF-I improves behavior and Purkinje cell pathology in SCA1 mice.

Spinocerebellar ataxia type 1 (SCA1) is a neurodegenerative disease caused by the expansion of polyglutamine repeat within ataxin-1 protein. Cerebellar Purkinje cells are the primary targets of SCA1 pathology. These cells synthesize insulin-like growth factor-I (IGF-I) and express its receptors during their entire life. The aim of present study was to determine if intranasally administered IGF-I to SCA1 transgenic mice suppresses toxic effects of ataxin-1. Two-week old SCA1 heterozygous animals were randomly divided into two treatment groups of IGF-I (30 and 60 microg IGF-I/animal) and a vehicle-treated control group. The wildtype animals served as normal controls. IGF-I or vehicle was administered at 48 h intervals for the total of 10 doses. Animals were then subjected to rotarod test, sacrificed, brains removed and processed for immunohistochemical and Western blot analysis. Radiolabeled IGF-I and bioactive TAT peptide accumulated in the brains of SCA1 mice following intranasal administration validating the use of intranasal route. SCA1 mice showed SCA1 pathology with impaired motor function and downregulation of calcium binding proteins as compared to wildtype mice. However, 30 and 60 microg IGF-I-treated animals showed improved performance on the rotarod as compared to vehicle-treated SCA1 mice with significant improvement (p < 0.05) on day 3 in 60 microg IGF-I group. The immunohistochemical data further showed partial recovery in the expression of calbindin D28k and protein kinase C-gamma in Purkinje cells in IGF-I-treated SCA1 animals. Our results indicate that suppression of ataxin-1-mediated adverse effects by intranasal IGF-I treatment may be of a therapeutic value to treat SCA1.

Combined analysis of cytokine genotype polymorphism and the level of expression with allograft function in African-American renal transplant patients.

Cytokine gene polymorphism and expression levels were evaluated in a group of African-American patients who had undergone renal transplantation. It was hypothesized that possession of specific cytokine alleles might be influential in predisposing the recipient to allograft rejection. Thus, we sought to establish a relationship between cytokine gene polymorphism, the levels of cytokine expression, and the outcome of allograft function. Cytokine genotypes and mRNA transcript levels of IL-2, TNF-alpha, TGF-beta1, IL-10, IL-6 and IFN-gamma were determined using peripheral blood cells. Genomic DNA samples from 77 transplant recipients and 77 controls were tested by a multiplex PCR with specific primers for the above cytokines. The frequency distributions of cytokines were analyzed in respect to the clinical characterization, including delayed graft function (DGF), rejection episodes (REs) and stable graft function (SGF). The mRNA transcript level was tested both at pre- and early post-transplantation (day 1 and day 4) with primers for coding regions of the above cytokines in a RT-PCR assay. The majority of recipients with successful graft function were matched with their donors for only three out of the six HLA alleles. We have shown that the TGF-beta1 T/C G/G high producer and IFN-gamma T/A intermediate producer genotypes were associated with allograft rejection, whereas low IFN-gamma producer and high IL-10 producer genotypes were significantly protective of the allograft. There was some correlation between the TGF-beta1 high producer genotype and DGF, but it was not statistically significant. Overall, 77% of those who experienced REs carried the TGF-beta1 T/C G/G, high producer genotype as compared with 52% who experienced DGF, 39% with SGF (P<0.01, RR=2.0), and 27.3% of controls (P<0.003, RR=2.6). The IFN-gamma T/A intermediate producer genotype was found in 69.2% of patients with REs as compared with 26.8% of patients with SGF (P<0.008, RR=2.85). The IL-10, ATA/ATA low producer genotype was found in 38.5% of recipients with REs and 14.6% of recipients without REs (P<0.04, RR=0.53). Expression levels of mRNA transcript were correlated with genotype data, except for the TGF-beta1 high producer genotype where there was no significant difference between the level of mRNA transcript at pre- and post-transplantation. Low DRbeta1 and high DPbeta1 expression by recipient peripheral blood mononuclear cells before transplantation was associated with more SGF, whereas high DRbeta1 and low DPbeta1 expression at pretransplantation was associated with more REs (DRbeta1, P<0.001 and DPbeta1, P<0.05, respectively). We concluded that, dual analysis of cytokine genotype and expression levels by peripheral cells may be an important clue to understanding the contribution of the recipient's immune response to an allograft pre- and post-transplantation. Identification of peripheral markers diagnostic of rejection could allow advance anticipation of clinical outcome, and might reduce the need for tissue biopsy.

Calcium homeostasis and spinocerebellar ataxia-1 (SCA-1).

Spinocerebellar ataxia-1 (SCA-1) belongs to a group of polyglutamine neurodegenerative disorders characterized by the expansion of a glutamine tract within the mutant disease-causing protein. In SCA-1, the expression of mutant ataxin-1 induces a progressive functional loss and the subsequent degeneration of a set of neurons including cerebellar Purkinje cells. Studies on SCA-1 transgenic mice have provided further understanding of the molecular and cellular events important for the disease. This review discusses what has been learned about the pathogenesis of SCA-1 through the transgenic mouse models in reference to Ca(2+) dependent pathways. This article also discusses the role of Ca(2+) regulating cytoplasmic and nuclear proteins in the pathogenesis of SCA-1. Finally, we discuss the use of double mutant mouse models to understand the association between Ca(2+) binding proteins and Purkinje cell pathology in SCA-1.

Desmethyl tirilazad improves neurologic function after hypoxic ischemic brain injury in piglets.

OBJECTIVE: Desmethyl tirilazad is a lipid-soluble free radical quencher. Deferoxamine reduces free radicals by chelating iron and reducing hydroxyl formation. Free radical inhibitors have shown promise in several hypoxic ischemic brain injury models, and we wished to see if this work could be extended to our newborn piglet model. DESIGN: Randomized controlled trial. SUBJECTS: Piglets (0 to 3 days old). INTERVENTION: Carotid snares and arterial and venous catheters were placed under 1.5% isoflurane anesthesia. In Experiment 1, piglets were randomly assigned to receive either 3 mg/kg desmethyl tirilazad or vehicle at -15 and 90 mins. In Experiment 2, piglets were randomly assigned to receive either 20 mg/kg desmethyl tirilazad at -15 mins followed by 8 mg/kg/hr for 90 mins or 100 mg/kg deferoxamine at -15 mins or vehicle. At time 0, both carotid arteries were clamped and blood was withdrawn to reduce the blood pressure to two-thirds normal. At 15 mins, inspired oxygen was reduced to 6%. At 30 mins, the carotid snares were released, the withdrawn blood was reinfused, and the oxygen was switched to 100%. On the third day after the hypoxic ischemic injury, the animals were killed by perfusing their brains with 10% formalin. We tested the timing of lipid peroxidation and inhibition of lipid peroxidation by these agents by freezing the brains of a subset of pigs in liquid nitrogen. MEASUREMENTS: Neurologic examination and brain pathology were scored by blinded observers. Thiobarbituric acid-reactive substance and oxidized and reduced glutathione were measured on frozen brains. MAIN RESULTS: Desmethyl tirilazad (20 mg/kg) and 100 mg/kg deferoxamine inhibit lipid peroxidation. Desmethyl tirilazad (20 mg/kg) improves neurologic exam, but 3 mg/kg Desmethyl tirilazad or 100 mg/kg deferoxamine does not. Neither desmethyl tirilazad nor deferoxamine improves pathologic results. CONCLUSIONS: High-dose desmethyl tirilazad improves neurologic function after hypoxic ischemic brain injury in the newborn piglet.

Relationship between ataxin-1 nuclear inclusions and Purkinje cell specific proteins in SCA-1 transgenic mice.

Spinocerebellar ataxia-1 (SCA-1), like other polyglutamine diseases, is associated with aggregation of mutant protein ataxin-1 in the nuclei of susceptible neurons. The role of ataxin-1 aggregates in the pathogenesis of susceptible neurons, especially cerebellar Purkinje cells, is unknown. The present study was initiated to determine the temporal relationship between ataxin-1 aggregation and the sequence of specific biochemical changes in Purkinje cells in SCA-1 transgenic mice (TM). Earlier, we demonstrated that SCA-1 TM with no Purkinje cell loss and no alterations in home cage behavior show decreased expression of calcium-binding proteins calbindin-D28k (CaB) and parvalbumin (PV) in Purkinje cells. To determine if increased expression of mutant ataxin-1 in TM is also associated with earlier biochemical changes in Purkinje cells, both heterozygous and homozygous (B05 line of SCA-1) TM were used. The age of onset of ataxia in SCA-1 TM was at 12 weeks in heterozygotes and 6 weeks in homozygotes. In 6 week old heterozygous TM, Western blot analysis of growth associated protein 43 (GAP-43) and synaptophysin revealed no significant alterations as compared with the age-matched nontransgenic mice (nTM), whereas CaB was significantly reduced. beta-III-Tubulin was used as a specific Purkinje cell marker protein, immunohistochemical localization showed strong beta-III-tubulin immunoreactivity (IR) in Purkinje cells in 6 week old heterozygous TM, whereas CaB and PV IR were markedly reduced in the same neurons (double immunofluorescence staining). Most Purkinje cells from heterozygous (12 weeks old) and homozygous (6 weeks old) TM contained ataxin-1 nuclear inclusions (NIs). Cells with and without visible NIs revealed reduced PV and CaB IR; however, the changes were overtly more severe in cells with visible NIs. In contrast, the same cells were strongly immunoreactive to beta-III-tubulin. CaB, which is also present in the nucleus, colocalized with ataxin-1 and ubiquitin positive NIs. Further, RT-PCR analysis of CaB mRNA in the cerebellum in 6 week old heterozygous TM demonstrated a significant decrease in mRNA in comparison with the aged-matched nTM. These data suggest that there are selective alterations in the expression of CaB and PV in Purkinje cells which possibly occur earlier than ataxin-1 aggregation. Further, we speculate that ataxin-1 aggregates may not be toxic in general; however, they may deplete specific proteins essential for Purkinje cell viability in SCA-1 TM.

The effects of calbindin D-28K and parvalbumin antisense oligonucleotides on the survival of cultured Purkinje cells.

The role of calcium binding proteins, calbindin D-28k (CaB) and parvalbumin (PV) in Purkinje cell survival was investigated using oligonucleotide antisense strategy. Purkinje cell enriched cultures were prepared from the cerebella of 0-1 day old Balb/c mouse pups. Purkinje cells were identified by size, asymmetric arbors, immunoreactivity to CaB and PV, uptake of gamma-aminobutyric acid (GABA) and failure to express glial fibrillary acidic protein. The cells at different days in vitro were treated with antisense or mismatched antisense phosphorothioate oligonucleotides for CaB and PV mRNA (complexed with lipofectin). Neuronal specific [3H]-GABA uptake was used as a measure of Purkinje cell survival. The cultures treated for 24 h with antisense oligos (CaB+PV) showed a significant decrease in [3H]-GABA uptake as compared with the cultures treated with lipofectin alone or with lipofectin + mismatched antisense oligos to CaB and PV mRNA. The results of the present study suggest that the expression of calcium buffering proteins CaB and PV may have a significant involvement in Purkinje cell viability.

Inhibition of calcium ATPase by phencyclidine in rat brain.

Phencyclidine (PCP) is a potent psychotomimetic drug of abuse and has profound effect on the functioning of the central nervous system (CNS). Many of the CNS functions are known to be mediated by calcium (Ca2+). In the present study we have investigated the effects of PCP on Ca2+ ATPase activity in rat brain both in vitro and in vivo. For in vitro studies, synaptic membrane fractions prepared from normal rat brain were incubated with PCP at different concentrations (25-100 microM) before the addition of substrate. For in vivo studies, rats were treated with a single moderate dose of PCP (10 mg/kg, i.p.) and animals were sacrificed at 1,2, 6 and 12 h after treatment. Ca2+ ATPase activity in synaptic membrane fractions was assayed by estimation of inorganic phosphate. PCP inhibited the Ca2+ ATPase in vitro in a concentration dependent manner with significant effect at 50 and 100 microM. A significant time-dependent reduction of the Ca2+ ATPase activity was evident in vivo. As early as 2 h after the treatment of rats with PCP the ATPase activity was significantly reduced. The reduction of Ca2+ ATPase observed even at 12 h after treatment suggesting a prolonged presence of the drug in the brain tissue. Further, kinetic studies in vitro indicated PCP to be a competitive inhibitor of Ca2+ ATPase with respect to the substrate, ATP. The present findings indicate that PCP inhibits synaptic membrane Ca2+ ATPase thus altering cellular Ca2+ homeostasis in CNS which may partially explain the pharmacological effects of the drug and/or its neurotoxicity.

Dominantly inherited ataxias.

Molecular genetic studies in the past decade have demonstrated the enormous genetic heterogeneity among the dominantly inherited ataxias. Mutations at several distinct loci give rise to the progressive dominant ataxias and at least 2 different mutations cause episodic ataxias with dominant inheritance. The well-established genotypes for progressive dominant ataxias have all involved expansions of repeated CAG sequences. Clinically these patients present with progressive cerebellar deficits as well as signs relating to pathology in other neural systems in a variable fashion. Some of these other signs serve as diagnostic clues to the underlying genotype, but the identification of the genotype from the clinical phenotype alone is usually difficult. The CAG expansions involved usually are unstable with intergenerational expansions as well as contractions of the repeat size. Phenotypic features such as age of onset and to a lesser extent disease progression rate and the presence of specific clinical signs depend on the CAG repeat size. Identification of the mutations has allowed precise genotypic diagnosis in several families allowing more accurate genetic counseling, including predictive testing of at risk individuals when sought. Also, increasing information about the gene products and their abnormal distributions in disease brain is rapidly giving rise to rational ideas about the pathogenesis of neuronal degeneration in these diseases and raising hope for meaningful treatment strategies.

Phencyclidine block of Ca2+ ATPase in rat heart sarcoplasmic reticulum.

Phencyclidine hydrochloride (PCP) also known as Angel Dust is a very potent psychotomimetic drug of abuse. Besides its central nervous system (CNS) effects PCP produces a number of adverse effects in a variety of tissues including the cardiovascular system. Since PCP is known to alter the cellular calcium homeostasis the present studies were initiated to determine the changes in cardiac Ca2+ ATPase activity in rats treated with PCP. For in vitro studies the cardiac sarcoplasmic reticulum (SR) fractions prepared from normal rats were incubated with 25, 50 and 100 microM PCP and the enzyme activities were estimated. Whereas, for in vivo studies the cardiac SR fractions prepared from rats treated with PCP (10 mg/kg body wt. single dose, intra-peritoneally (i.p.)) and sacrificed at different time intervals were used. PCP reduced the Ca2+ ATPase activity significantly both in vitro and in vivo. A 50% inhibition of the enzyme activity was obtained with 100 microM PCP in vitro. A significant reduction of SR Ca2+ ATPase was also evident as early as 1 h after treatment of rats with PCP. The reduction of Ca2+ ATPase activity in SR was irreversible even at 12 h after treatment. The in vitro kinetic studies revealed that PCP was found to be a competitive inhibitor of Ca2+ ATPase with respect to the substrate, ATP, and non-competitive with respect to Ca2+ activation. These results indicate that PCP alters the myocardial Ca2+ homeostasis by inhibiting the Ca2+ ATPase in cardiac SR in rats. Inhibition of SR Ca2+ ATPase may result in the impairment of contraction and relaxation coupling processes in the myocardium.

Marine biomolecules inhibit rat brain nitric oxide synthase activity.

A large number of substances of medical importance have been isolated from marine flora and fauna and their chemical structures were elucidated. Among the many compounds isolated in our laboratories only two compounds were identified as neurotoxins as they produced depolarizing effects in nerve fibers. The Xestospongin D and Araguspongin C, isolated and purified to 100% from sponge, Haliclona exigua were tested for their effects on rat brain nitric oxide synthase (NOS) activity in vitro. The results showed that NOS activity was significantly inhibited in a concentration and time dependent manner with an estimated IC50 of 31.5 and 46.5 microM for Xestospongin D and Araguspongin C, respectively, and the maximum inhibition occurred within 3 min of incubation. To explore the mechanism of action of these compounds on NOS, we have conducted kinetic studies with L-arginine, NADPH and Ca2+ in the presence of IC50 concentrations of these two compounds. The maximum velocity (Vmax) and enzyme constant (Km) were calculated using the Michaelis Menten equation. The results show that both compounds are competitive inhibitors of NOS with the substrate, L-arginine and uncompetitive with NADPH and free Ca2+. The NOS inhibition by these two compounds was similar to N omega-nitro-L-arginine methylester (L-NAME), a known inhibitor of NOS. These results suggest that the marine biomolecules Xestospongin D and Araguspongin C are in vitro modulators of neuronal NOS.

Reduced immunoreactivity to calcium-binding proteins in Purkinje cells precedes onset of ataxia in spinocerebellar ataxia-1 transgenic mice.

Earlier we have shown alterations in immunoreactivity (IR) to the calcium-binding proteins parvalbumin (PV) and calbindin D-28k (CaB) in surviving Purkinje cells of patients with spinocerebellar ataxia-1 (SCA-1). In the present study we determined PV and CaB expression (by immunohistochemical and immunoblot analyses) in Purkinje cells of transgenic mice (TM) expressing the human SCA-1 gene with an expanded (line B05) and normal (line A02) CAG tract, as well as in age-matched nontransgenic mice (nTM). Heterozygotes in the B05 line develop progressive ataxia beginning around 12 weeks of age. A02 animals are phenotypically indistinguishable from wild-type (nontransgenic) animals. In the cerebella of 8-, 9-, and 12-week-old TM-B05 there was a progressive decrease in PV IR in Purkinje cells compared with nTM and TM-A02. Parvalbumin immunostaining in interneurons was well preserved in all groups. A progressive decrease was also observed in CaB IR in Purkinje cells of 8-, 9-, and 12-week-old TM-B05. Cerebellar Purkinje cells of 6-week-old TM-B05, which exhibit no ataxia and even lack demonstrable Purkinje cell loss, also revealed reduction in PV IR. This change was matched by a significant decrease in the amount of cerebellar PV in 6-week-old TM-B05 as determined by Western blot analysis. Calbindin D-28K immunohistochemistry did not detect any marked changes in CaB IR within Purkinje cells at 4 weeks. However, at 6 weeks immunostaining and immunoblot analysis revealed a significant decrease in CaB in TM-B05 compared with controls. These data suggest that decreased levels of calcium-binding proteins in Purkinje cells in SCA-1 transgenic mice may cause alteration in Ca2+ homeostasis.

Decreased parvalbumin immunoreactivity in surviving Purkinje cells of patients with spinocerebellar ataxia-1.

The distribution of two calcium-binding proteins, calbindin D28k (CaBP) and parvalbumin (PV), was investigated by immunohistochemistry in the brains of three individuals dying of nonneurologic illness and three patients with spinocerebellar ataxia-1 (SCA-1). SCA-1 has recently been proven to be due to an unstable CAG repeat mutation on chromosome 6. In the cerebellum of control individuals the Purkinje cells showed strong immunoreactivity to CaBP. Other cells were CaBP-negative. Parvalbumin was highly localized to Purkinje, basket, stellate, and Golgi cells. All surviving Purkinje cells in SCA-1 were strongly immunoreactive to CaBP. The number of PV-immunoreactive Purkinje cells was markedly reduced in SCA-1. In addition, there was a significant decrease in the intensity of PV immunostaining within the individual Purkinje cells compared with controls. However, in the hippocampus, temporal cortex, and lateral geniculate scattered PV-positive neurons were seen in SCA-1 patients, similar to those in controls. The present results suggest that the decreased PV-immunoreactivity in the surviving Purkinje cells in SCA-1 may reflect biochemical alterations preceding Purkinje cell degeneration.

Increase in brain nitric oxide synthase activity in daunorubicin-treated rats.

Anthracyclines such as daunorubicin are very effective anticancer agents. These drugs are known to cause side effects including cardiotoxicity. Anthracyclines are neurotoxic to laboratory animals. Nitric oxide is a novel and very important chemical messenger in the brain. However, at higher levels, nitric oxide causes well defined neurotoxicity. Therefore, we determined nitric oxide synthase activity in rat brain after daunorubicin treatment in an effort to explain the neurotoxicity produced by anthracyclines. Male Sprague-Dawley rats were treated with different subcutaneous doses of daunorubicin (0.1-4.0 mg/kg/week for five weeks) while control animals were injected with phosphate buffered saline. There was a significant increase (80%) of nitric oxide synthase activity in daunorubicin-treated animals as compared to controls. This activity was inhibited by N-monomethyl-L-arginine (NMMA), nitroarginine, N-6-aminohexyl-5-chloro-1-napthalene sulfonamide (W-7), a calmodulin antagonist, suggesting that the nitric oxide synthase activity is calmodulin dependent. Further, our in vitro studies demonstrated that daunorubicin interacted with calmodulin as measured by N-phenyl-1-napthylamine (NPN) fluorescence. These results indicate that daunorubicin increases nitric oxide synthase activity in rat brain which may increase the levels of nitric oxide. The increased levels of nitric oxide may cause neurotoxicity. Our results further indicate that daunorubicin interacts with calmodulin and enhances nitric oxide synthase activity which is dependent on calmodulin.

Developmental changes in cerebellar endothelin-1 receptors in the neurologic mouse lurcher mutant.

In order to elucidate the role of neuromodulator endothelin-1 (ET-1) in cerebellar degeneration we determined ET-1 receptor binding in the control and lurcher mice cerebella at different postnatal (P) ages. The lurcher mutant is a suggested animal model for human cerebellar ataxias. The cerebellar membranes were prepared from 5 to 20 day old lurcher mice and littermate controls. ET-1 receptor binding was determined using radioligand assay and affinity cross-linking. There was a significant decrease in [125I]ET-1 receptor binding with increasing postnatal age in the control and lurcher mice cerebella. Lurcher mice showed a significant increase in [125I]ET-1 receptor binding at P 9 to P 20 as compared with the controls. Whereas, at P5 to P7 no significant change was observed. By autoradiography, ET-1 receptors were localized in tile granule cell layer of 15 day old control and lurcher mice cerebella. Whereas, the lUrcher mice showed an increase in [125I]ET-1 binding in the cerebellum as compared with the littermate controls. The results of the present study suggest that the increase in ET-1 receptor binding as early as P9 (when neuronal loss is minimal) in the lurcher mutant may reflect upregulation of ET-1 receptors in the degenerating neurons. At P 15 to P 20, when about 50% to 75% neurons are lost respectively, these changes may also reflect astrogliosis.

Daunomycin inhibits insulin-like growth factor I-dependent protein tyrosine phosphorylation.

The effect of the antitumor antibiotic daunomycin (DN) was studied on insulin-like growth factor I (IGF-I)-dependent protein tyrosine phosphorylation. DN was found to inhibit IGF-I-dependent phosphorylation of the artificial substrate poly(Glu:Tyr)4:1 by intrinsic IGF-I receptor kinase either from mouse cerebellum or from rat spinal cord. IGF-I-dependent autophosphorylation of the IGF-I receptor was also inhibited as a function of DN concentration (10-100 microM). However, DN at 200 microM concentration had minimal effect on protein kinase C dependent phosphorylation. The IGF-I-dependent protein tyrosine phosphorylation of endogenous proteins of the rat spinal cord was also inhibited by 50 microM DN. The altered IGF-I-dependent protein tyrosine phosphorylation by DN may partially explain its mechanism of action as an antitumor agent. These observations may also explain the neurotoxic effects of DN.