Yihe Guo

Behavioral responses to cocaine and amphetamine administration in mice lacking the dopamine D1 receptor.

Cocaine and amphetamine can induce both short-term and long-term behavioral changes in rodents. The major target for these psychostimulants is thought to be the brain dopamine system. To determine whether the dopamine D1 receptor plays a crucial role in the behavioral effects of psychostimulants, we tested both the locomotor and stereotyped behaviors in D1 receptor mutant and wild-type control mice after cocaine and amphetamine treatments. We found that the overall locomotor responses of D1 receptor mutant mice to repeated cocaine administration were significantly reduced compared to those of the wild-type mice and the responses of the D1 receptor mutant mice to cocaine injections were never significantly higher than their responses to saline injections. D1 receptor mutant mice were less sensitive than the wild-type mice to acute amphetamine stimulation over a dose range even though they exhibited apparently similar behavioral responses as those of the wild-type mice after repeated amphetamine administration at the 5 mg/kg dose. Immunostaining experiments indicated that there was no detectable neurotoxicity in the nucleus accumbens in both D1 receptor mutant and wild-type mice after repeated amphetamine administration. The data suggest that the D1 receptor plays an essential role in mediating cocaine-induced behavioral changes in mice. Moreover, the D1 receptor also participates in behavioral responses induced by amphetamine administration.

Inhibition of gap junction communication in alveolar epithelial cells by 18α-glycyrrhetinic acid

Cultured alveolar epithelial cells exhibit gap junction intercellular communication (GJIC) and express regulated levels of connexin (Cx) 43 mRNA and protein. Newly synthesized radiolabeled Cx43 protein equilibrates with phosphorylated Cx43 isoforms; these species assemble to form both connexons and functional gap junction plaques. The saponin 18α-glycyrrhetinic acid (GA) rapidly and reversibly blocks GJIC at low concentrations (5 μM). Extended exposure to 18α-GA at higher concentrations causes inhibition of GJIC and time- and dose-dependent reductions in both Cx43 protein and mRNA expression. The latter toxic effects are paralleled by disassembly of gap junction plaques and are reversed less readily than acute effects on GJIC. These observations demonstrate 18α-GA-sensitive regulation of intercellular communication in epithelial cells from the mammalian lung and suggest a role for Cx43 expression and phosphorylation in acute and chronic regulation of GJIC between alveolar epithelial cells.

Immediate early gene expression in cat visual cortex during and after the critical period: differences between EGR-1 and Fos proteins

Immediate early gene (IEG) expression in the cat visual cortex is highly responsive to visual input and may initiate genetic mechanisms responsible for neuronal plasticity. The present study used immunohistochemical methods to address two issues regarding IEG expression in response to visual input. One was to define the differential response of distinct IEG families by comparing EGR-1 (also termed zif-268, NGFI-A, and Krox-24) and Fos proteins. The second was to determine whether IEG expression, in addition to reflecting neural activity, is related to the state of plasticity by comparing young and adult visual cortex. Immunoreactivity of the two IEG proteins was compared between 5-week-old and adult cats under three conditions of visual input: ambient light to assess basal levels of expression, 1 week of darkness to assess the effect of reduced activity, and exposure to light after 1 week of darkness to determine rapid changes in expression as a result of visual input. At both ages, there were marked differences in the expression of the two IEG proteins. EGR-1 responded to visual input with sustained changes in its level of expression. It showed high basal levels, reduced expression in darkness, and a rapid return to high constitutive levels with the introduction of light. Fos showed a markedly different profile. It had very low basal expression which was not demonstrably affected by darkness and its principal response was a marked transient induction upon exposure to light after darkness. These unique changes in expression highlight the complex response across IEGs to environmental input and suggest a genetic on/off signaling mechanism. There were marked differences in the laminar distribution of EGR-1 and Fos proteins between young and adult cats. In young animals, cells in all visual cortical layers showed high levels of EGR-1 and Fos proteins. In adults, immunostaining was largely specific to cells located above and below layer IV and only very faint labeling occurred within layer IV. These differences in laminar distribution between ages are inconsistent with a simple explanation of IEG expression in terms of neural activity level; rather, they suggest a relation between IEG expression and the state of plasticity in visual cortex.

Expression of two forms of glutamic acid decarboxylase (GAD67 and GAD65) during postnatal development of cat visual cortex

The postnatal development of GAD67 and GAD65 protein expression and of GAD67 positive neurons and GAD65 containing axon terminals in cat visual cortex was studied. Western blot analysis showed that the expression of both GAD67 and GAD65 increased to approximately two-thirds of the adult level during the first 5 postnatal weeks and gradually increased thereafter. In adult cats, immunohistochemistry showed that GABA and GAD67 containing neurons were found in all cortical layers. Faint cell body staining was seen with the antibody to GAD65, but it densely labeled puncta. In neonates, GABA and GAD67 immunoreactivity was most intense in two distinct bands, one superficial (Layer 1/Marginal zone), another deep (Layer VI/Subplate). Unlike in adults, GAD65 positive cell bodies were clearly evident in neonates and distributed similarly to, but less frequently than, GABA and GAD67. These GAD65 positive cells frequently had morphologies suggestive of embryonic cells and largely disappeared in older animals. During postnatal development, the neurochemical differentiation of GAD67 positive neurons and GAD65 positive axon terminals across visual cortical laminae followed an inside-outside developmental pattern, which reached adult levels after 10 weeks of age. These results suggest that postnatal development of the visual cortical GABA system involves three distinct processes: (A) a dying off of embryonic GABA cells which could play a role in formation of the cortical plate; (B) a period of relative quiescence of the VC GABA system in the first 5 postnatal weeks which could maximize excitatory NMDA effects during the rising phase of the critical period; (C) the prolonged postnatal maturation of the adult GABA system which could be involved in the crystallization of adult physiological properties and the disappearance of neural plasticity.

Vascular dysfunction in a murine model of severe hemolysis.

Spectrin is the backbone of the erythroid cytoskeleton; sph/sph mice have severe hereditary spherocytosis (HS) because of a mutation in the murine erythroid alpha-spectrin gene. sph/sph mice have a high incidence of thrombosis and infarction in multiple tissues, suggesting significant vascular dysfunction. In the current study, we provide evidence for both pulmonary and systemic vascular dysfunction in sph/sph mice. We found increased levels of soluble cell adhesion molecules in sph/sph mice, suggesting activation of the vascular endothelium. We hypothesized that plasma hemoglobin released by intravascular hemolysis initiates endothelial injury through nitric oxide (NO) scavenging and oxidative damage. Likewise, electron paramagnetic resonance spectroscopy showed that plasma hemoglobin is much greater in sph/sph mice. Moreover, plasma from sph/sph mice had significantly higher oxidative potential. Finally, xanthine oxidase, a potent superoxide generator, is decreased in subpopulations of liver hepatocytes and increased on liver endothelium in sph/sph mice. These results indicate that vasoregulation is abnormal, and NO-based vasoregulatory mechanisms particularly impaired, in sph/sph mice. Together, these data indicate that sph/sph mice with severe HS have increased plasma hemoglobin and NO scavenging capacity, likely contributing to aberrant vasoregulation and initiating oxidative damage.

Fetal gene defects precipitate platelet-mediated pregnancy failure in factor V Leiden mothers

We describe a mouse model of fetal loss in factor V Leiden (FvL) mothers in which fetal loss is triggered when the maternal prothrombotic state coincides with fetal gene defects that reduce activation of the protein C anticoagulant pathway within the placenta. Fetal loss is caused by disruption of placental morphogenesis at the stage of labyrinth layer formation and occurs in the absence of overt placental thrombosis, infarction, or perfusion defects. Platelet depletion or elimination of protease-activated receptor 4 (Par4) from the mother allows normal placentation and prevents fetal loss. These findings establish a cause–effect relationship for the observed epidemiologic association between maternal FvL status and fetal loss and identify fetal gene defects as risk modifiers of pregnancy failure in prothrombotic mothers. Pregnancy failure is mediated by Par4-dependent activation of maternal platelets at the fetomaternal interface and likely involves a pathogenic pathway independent of occlusive thrombosis. Our results further demonstrate that the interaction of two given thrombosis risk factors produces markedly disparate consequences on disease manifestation (i.e., thrombosis or pregnancy loss), depending on the vascular bed in which this interaction occurs.

Comparison of the expression of two forms of glutamic acid decarboxylase (GAD67 and GAD65) in the visual cortex of normal and dark-reared cats.

In normal development, there are dramatic changes in both the level and the laminar pattern of expression of the two forms of glutamate decarboxylase (GAD67, GAD65), the synthetic enzyme for gamma-aminobutyric acid (GABA). We have used antibodies to determine whether these normal postnatal changes in the expression of the two GADs depend on visual input by comparing normal and dark-reared cat visual cortex. Western blot analysis showed no significant differences in the levels of expression of the two enzymes between rearing conditions at either 5 or 20 weeks. Immunohistochemistry was used to compare the laminar distribution of the GADs in the two rearing conditions. At 1 week of age, both GAD67 and GAD65 immunoreactivity is concentrated in deep layers of visual cortex. At 5 and 20 weeks in both rearing conditions, GAD67-stained cells bodies were distributed rather uniformly across all cortical layers. GAD65 primarily labeled puncta (synaptic terminals) and these were also distributed rather uniformly across all visual cortical layers in both rearing conditions. Counts of GAD67-positive cell bodies and GAD65-positive puncta also revealed no differences between the rearing conditions. Thus, both GAD67, which produces the basal pool of GABA, and GAD65, which is specialized to respond to short-term increases in demand in synaptic terminals, developed normal levels of expression and normal intracellular and laminar distributions in the absence of visual input. Physiological studies suggest immaturity in the GABA system of dark-reared visual cortex. The present results indicate that such abnormalities are not due to presynaptic alterations in GABA synthetic enzymes.

Developmental expression of the immediate early gene EGR-1 mirrors the critical period in cat visual cortex

Immediate early gene (IEG) expression in the central nervous system is thought to play a role in coupling extracellular stimulation with the transcriptional events responsible for long-term functional changes in neurons. The goal of the present study was to determine the postnatal developmental profile of EGR-1 protein (also termed zif268, Krox-24, NGFI-A) expression across the layers of cal visual cortex and relate it to the state of visual cortical development and plasticity. Using a polyclonal antibody, EGR-1 immunoreactivity was studied in animals of various postnatal ages (from 0.5 week to adult). In very young animals (0.5 weeks), EGR-1 positive cells were restricted to deep cortical layers (layer VI/Subplate). With the increasing age, EGR-1 immunoreactivity spread across layers of the visual cortex in an inside-outside manner, and by 5 weeks of age, EGR-1 protein was highly expressed in all layers. EGR-1 expression remained high until approximately 10 weeks of age and then gradually began to decline in layer IV with little change in supra- and infragranular layers. In adult animals, EGR-1 was located predominantly in the layers above and below layer IV. This pattern of EGR-1 expression in developing cat visual cortex has both temporal and laminar similarities with the development of visual cortical connectivity, with the development of orientation selective receptive field properties, and with the level of visual cortical plasticity, suggesting an involvement of EGR-1 expression in these processes.

Caveolin-1-dependent apoptosis induced by fibrin degradation products.

In mice lacking the blood coagulation regulator thrombomodulin, fibrinolytic degradation products (FDP) of fibrin induce apoptotic cell death of a specialized cell type in the placenta, polyploid trophoblast giant cells. Here, we document that this bioactivity of FDP is conserved in human FDP, is not limited to trophoblast cells, and is associated with an Aalpha-chain segment of fibrin fragment E (FnE). The majority of proapoptotic activity is arginine-glycine-aspartic acid (RGD)-independent and requires caveolin-1-dependent cellular internalization of FnE. Internalization through caveoli is mediated by an epitope contained within Aalpha52-81 that is necessary and sufficient for cellular uptake of FnE. Aalpha52-81 does not cause apoptosis itself, and competitively inhibits FnE internalization and apoptosis induction. Apoptotic activity per se resides within Aalpha17-37 and requires the N-terminal neoepitope generated by release of fibrinopeptide A. Cellular internalization of FnE elicits depression of mitochondrial function and consequent apoptosis that is strictly dependent on the activity of caspases 9 and 3. These findings describe the molecular details of a novel mechanism linking fibrin degradation to cell death in the placenta, which may also contribute to pathologic alterations in nonplacental vascular beds that are associated with fibrinolysis.

Natural, high-mannose glycoproteins inhibit ROS binding and ingestion by RPE cell cultures

Previous studies have suggested that a mannose receptor mediates the phagocytic uptake of effete rod outer segments by retinal pigment epithelial cells. In the present study, the effect of adding a soluble ligand for the mannose receptor, horseradish peroxidase, was examined. Cultured retinal pigment epithelial cells from Long Evans rats were preincubated with various concentrations of horseradish peroxidase for 20 min followed by a challenge of FITC-labeled bovine rod outer segments for 3 h. Both counts of total rod outer segments (bound and ingested) and ingested rod outer segments were determined. Rod outer segment uptake was reduced, in a concentration-dependent fashion, by an average of 60% of control values when horseradish peroxidase was added to retinal pigment epithelial cultures. Similarly, total rod outer segment values were reduced to 50% of controls in the presence of at least a 10 micrograms ml-1 horseradish peroxidase concentration. Horseradish peroxidase inhibition of retinal pigment epithelial phagocytic capacity was reversible. Other high mannose glycoproteins, such as invertase, beta-glucoronidase, and ovalbumin, were equally effective in preventing rod outer segment ingestion by retinal pigment epithelial cells. These data further support the hypothesis that a mannose receptor on the retinal pigment epithelial apical surface facilitates phagocytosis of rod outer segments.