Cortical–striatal gene expression in neonatal hippocampal lesion (NVHL)‐amplified cocaine sensitization

Cortical–striatal circuit dysfunction in mental illness may enhance addiction vulnerability. Neonatal ventral hippocampal lesions (NVHL) model this dual diagnosis causality by producing a schizophrenia syndrome with enhanced responsiveness to addictive drugs. Rat genome‐wide microarrays containing >24 000 probesets were used to examine separate and co‐occurring effects of NVHLs and cocaine sensitization (15 mg/kg/day × 5 days) on gene expression within medial prefrontal cortex (MPFC), nucleus accumbens (NAC), and caudate‐putamen (CAPU). Two weeks after NVHLs robustly amplified cocaine behavioral sensitization, brains were harvested for genes of interest defined as those altered at P < 0.001 by NVHL or cocaine effects or interactions. Among 135 genes so impacted, NVHLs altered twofold more than cocaine, with half of all changes in the NAC. Although no genes were changed in the same direction by both NVHL and cocaine history, the anatomy and directionality of significant changes suggested synergy on the neural circuit level generative of compounded behavioral phenotypes: NVHL predominantly downregulated expression in MPFC and NAC while NVHL and cocaine history mostly upregulated CAPU expression. From 75 named genes altered by NVHL or cocaine, 27 had expression levels that correlated significantly with degree of behavioral sensitization, including 11 downregulated by NVHL in MPFC/NAC, and 10 upregulated by NVHL or cocaine in CAPU. These findings suggest that structural and functional impoverishment of prefrontal‐cortical‐accumbens circuits in mental illness is associated with abnormal striatal plasticity compounding with that in addictive disease. Polygenetic interactions impacting neuronal signaling and morphology within these networks likely contribute to addiction vulnerability in mental illness .     

Brain region‐specific immunolocalization of the lipolysis‐stimulated lipoprotein receptor (LSR) and altered cholesterol distribution in aged LSR+/− mice

Brain lipid homeostasis is important for maintenance of brain cell function and synaptic communications, and is intimately linked to age‐related cognitive decline. Because of the blood–brain barrier's limiting nature, this tissue relies on a complex system for the synthesis and receptor‐mediated uptake of lipids between the different networks of neurons and glial cells. Using immunofluorescence, we describe the region‐specific expression of the lipolysis‐stimulated lipoprotein receptor (LSR), in the mouse hippocampus, cerebellum Purkinje cells, the ependymal cell interface between brain parenchyma and cerebrospinal fluid, and the choroid plexus. Colocalization with cell‐specific markers revealed that LSR was expressed in neurons, but not astrocytes. Latency in arms of the Y‐maze exhibited by young heterozygote LSR^+/? mice was significantly different as compared to control LSR^+/+, and increased in older LSR^+/? mice. Filipin and Nile red staining revealed membrane cholesterol content accumulation accompanied by significantly altered distribution of LSR in the membrane, and decreased intracellular lipid droplets in the cerebellum and hippocampus of old LSR^+/? mice, as compared to control littermates as well as young LSR^+/? animals. These data therefore suggest a potential role of LSR in brain cholesterol distribution, which is particularly important in preserving neuronal integrity and thereby cognitive functions during aging.     

Structure-Function Relationship of Tumor Necrosis Factor (TNF) and Its Receptor Interaction Based on 3D Structural Analysis of a Fully Active TNFR1-Selective TNF Mutant

Tumor necrosis factor (TNF) is an important cytokine that suppresses carcinogenesis and excludes infectious pathogens to maintain homeostasis. TNF activates its two receptors [TNF receptor (TNFR) 1 and TNFR2], but the contribution of each receptor to various host defense functions and immunologic surveillance is not yet clear. Here, we used phage display techniques to generate receptor-selective TNF mutants that activate only one TNFR. These TNF mutants will be useful in the functional analysis of TNFR.Six amino acids in the receptor binding interface (near TNF residues 30, 80, and 140) were randomly mutated by polymerase chain reaction. Two phage libraries comprising over 5 million TNF mutants were constructed. By selecting the mutants without affinity for TNFR1 or TNFR2, we successfully isolated 4 TNFR2-selective candidates and 16 TNFR1-selective candidates, respectively. The TNFR1-selective candidates were highly mutated near residue 30, whereas TNFR2-selective candidates were highly mutated near residue 140, although both had conserved sequences near residues 140 and 30, respectively. This finding suggested that the phage display technique was suitable for identifying important regions for the TNF interaction with TNFR1 and TNFR2. Purified clone R1-6, a TNFR1-selective candidate, remained fully bioactive and had full affinity for TNFR1 without activating TNFR2, indicating the usefulness of the R1-6 TNF mutant in analyzing TNFR1 receptor function.To further elucidate the receptor selectivity of R1-6, we examined the structure of R1-6 by X-ray crystallography. The results suggested that R31A and R32G mutations strongly influenced electrostatic interaction with TNFR2, and that L29K mutation contributed to the binding of R1-6 to TNFR1. This phage display technique can be used to efficiently construct functional mutants for analysis of the TNF structure-function relationship, which might facilitate in silico drug design based on receptor selectivity.     

Assembly,trafficking and function of α1β2γ2 GABAA receptors are regulated by N‐terminal regions,in a subunit‐specific manner

GABA_A receptors are pentameric ligand‐gated ion channels that mediate inhibitory fast synaptic transmission in the central nervous system. Consistent with recent pentameric ligand‐gated ion channels structures, sequence analysis predicts an α‐helix near the N‐terminus of each GABA_A receptor subunit. Preceding each α‐helix are 8–36 additional residues, which we term the N‐terminal extension. In homomeric GABA_C receptors and nicotinic acetylcholine receptors, the N‐terminal α‐helix is functionally essential. Here, we determined the role of the N‐terminal extension and putative α‐helix in heteromeric α1β2γ2 GABA_A receptors. This role was most prominent in the α1 subunit, with deletion of the N‐terminal extension or further deletion of the putative α‐helix both dramatically reduced the number of functional receptors at the cell surface. Conversely, deletion of the β2 or γ2 N‐terminal extension had little effect on the number of functional cell surface receptors. Additional deletion of the putative α‐helix in the β2 or γ2 subunits did, however, decrease both functional cell surface receptors and incorporation of the γ2 subunit into mature receptors. In the β2 subunit only, α‐helix deletions affected GABA sensitivity and desensitization. Our findings demonstrate that N‐terminal extensions and α‐helices make key subunit‐specific contributions to assembly, consistent with both regions being involved in inter‐subunit interactions.

     

Galpha(olf) is necessary for coupling D1 and A2a receptors to adenylyl cyclase in the striatum

In the brain, dopamine and adenosine stimulate cyclic AMP (cAMP) production through D1 and A2a receptors, respectively. Using mutant mice deficient in the olfactory isoform of the stimulatory GTP-binding protein alpha subunit, Galpha(olf), we demonstrate here the obligatory role of this protein in the adenylyl cyclase responses to dopamine and adenosine in the caudate putamen. Responses to dopamine were also dramatically decreased in the nucleus accumbens but remained unaffected in the prefrontal cortex. Moreover, in the caudate putamen of mice heterozygous for the mutation, the amounts of Galpha(olf) were half of the normal levels, and the efficacy of dopamine- and CGS 21680 A(2) agonist-stimulated cAMP production was decreased. Together, these results identify Galpha(olf) as a critical parameter in the responses to dopamine and adenosine in the basal ganglia.     

Abeta(25-35) and Abeta(1-40) act on different calcium channels in CA1 hippocampal neurons

The acute effects of beta-amyloid (25-35) and (1-40) on high voltage activated calcium channels were compared in CA1 pyramidal cells of adult mouse hippocampal slices using the whole-cell patch-clamp recording. Bath application of oligomeric beta-amyloid (25-35) reversibly increased the barium current (I(Ba)) to 1.61 (normalized amplitude), while oligomeric beta-amyloid (1-40) reversibly enhanced the I(Ba) to 1.74. Reverse-sequence beta-amyloid [(35-25) and (40-1)] had no effect. The effect of beta-amyloid (25-35) was blocked by nifedipine, a selective antagonist of L-type calcium channels. In contrast, the effect of beta-amyloid (1-40) was not blocked by nifedipine and I(Ba) was enhanced to 4.96. It is concluded that these oligomeric peptides may act through different types of calcium channels and/or receptors. The toxicity of Abeta(25-35) implicates a potentiation of L-type calcium channels while the one of Abeta(1-40) is related to an increase of non-L-type calcium channels, which may involve an increase in transmitter release.     

Down-regulation of occludin expression in astrocytes by tumour necrosis factor (TNF) is mediated via TNF type-1 receptor and nuclear factor-κB activation

Tight junctions form the diffusion barrier of brain microcapillary endothelial cells and support cell polarity. Also astrocytes express tight junction components such as occludin, claudin-1, ZO-1 and ZO-2, but do not establish a permeability barrier. However, little is known about the function and regulation of these molecules in astrocytes. We studied the impact of tumour necrosis factor (TNF) on occludin and ZO-1 expression in astrocytes. TNF decreased occludin, but not ZO-1 expression. In brain microcapillary endothelial cells, as well as in epithelial cells, occludin expression was not influenced by TNF. Removal of TNF from astrocytes restored the basal level of occludin. Down-regulation was inhibited by caffeic acid phenethyl ester, a specific inhibitor of nuclear factor-kappaB (NF-kappaB) activation. Exposure of astrocytes isolated from mice deficient in either TNF type-1 receptor (TNFR1), TNF type-2 receptor (TNFR2), or both, respectively, revealed that down-regulation was mediated entirely by TNFR1. ZO-1, which can interact with occludin, was found to co-precipitate connexin43, but not occludin. These findings demonstrate that TNF selectively down-regulates occludin in astrocytes, but not in cells forming established tight junctions, through TNFR1 and suggest that NF-kappaB is involved as a negative regulator.     

Hypoxia‐inducible factors 1α and 2α exert both distinct and overlapping functions in long bone development

The hypoxia‐inducible factors have recently been identified as critical regulators of angiogenic–osteogenic coupling. Mice overexpressing HIFα subunits in osteoblasts produce abundant VEGF and develop extremely dense, highly vascularized long bones. In this study, we investigated the individual contributions of Hif‐1α and Hif‐2α in angiogenesis and osteogenesis by individually disrupting each Hifα gene in osteoblasts using the Cre‐loxP method. Mice lacking Hif‐1α demonstrated markedly decreased trabecular bone volume, reduced bone formation rate, and altered cortical bone architecture. By contrast, mice lacking Hif‐2α had only a modest decrease in trabecular bone volume. Interestingly, long bone blood vessel development measured by angiography was decreased by a similar degree in both ΔHif‐1α and ΔHif‐2α mice suggesting a common role for these Hifα subunits in skeletal angiogenesis. In agreement with this idea, osteoblasts lacking either Hif‐1α or Hif‐2α had profound reductions in VEGF mRNA expression but only the loss of Hif‐1α impaired osteoblast proliferation. These findings indicate that expression of both Hif‐1α and Hif‐2α by osteoblasts is required for long bone development. We propose that both Hif‐1α and Hif‐2α function through cell non‐autonomous modes to promote vascularization of bone and that Hif‐1α also promotes bone formation by exerting direct actions on the osteoblast. J. Cell. Biochem. 109: 196–204, 2010. © 2009 Wiley‐Liss, Inc.     

Co-localization and functional interaction between adenosine A(2A) and metabotropic group 5 receptors in glutamatergic nerve terminals of the rat striatum

The anti-Parkinsonian effect of glutamate metabotropic group 5 (mGluR5) and adenosine A(2A) receptor antagonists is believed to result from their ability to postsynaptically control the responsiveness of the indirect pathway that is hyperfunctioning in Parkinson's disease. mGluR5 and A(2A) antagonists are also neuroprotective in brain injury models involving glutamate excitotoxicity. Thus, we hypothesized that the anti-Parkinsonian and neuroprotective effects of A(2A) and mGluR5 receptors might be related to their control of striatal glutamate release that actually triggers the indirect pathway. The A(2A) agonist, CGS21680 (1-30 nM) facilitated glutamate release from striatal nerve terminals up to 57%, an effect prevented by the A(2A) antagonist, SCH58261 (50 nM). The mGluR5 agonist, CHPG (300-600 mum) also facilitated glutamate release up to 29%, an effect prevented by the mGluR5 antagonist, MPEP (10 microm). Both mGluR5 and A(2A) receptors were located in the active zone and 57 +/- 6% of striatal glutamatergic nerve terminals possessed both A(2A) and mGluR5 receptors, suggesting a presynaptic functional interaction. Indeed, submaximal concentrations of CGS21680 (1 nM) and CHPG (100 microm) synergistically facilitated glutamate release and the facilitation of glutamate release by 10 nM CGS21680 was prevented by 10 microm MPEP, whereas facilitation by 300 microm CHPG was prevented by 10 nM SCH58261. These results provide the first direct evidence that A(2A) and mGluR5 receptors are co-located in more than half of the striatal glutamatergic terminals where they facilitate glutamate release in a synergistic manner. This emphasizes the role of the modulation of glutamate release as a likely mechanism of action of these receptors both in striatal neuroprotection and in Parkinson's disease.     

Mass spectrometric characterization of recombinant rat 5‐hydroxytryptamine receptor 1A (5‐HT1AR) expressed in tsA201 human embryonic kidney cells

The 5‐hydroxytryptamine 1A receptor (serotonin 1A receptor; 5‐HT_1AR) is involved in a large series of brain functions, and roles in anxiety, depression, and cognition have been reported. So far, published information on mass spectrometrical characterization of 5‐HT_1AR is limited to the presence of two 5‐HT_1AR peptides in rat's whole brain as observed by in‐solution digestion followed by LC‐MS/MS. Knowledge about the protein sequence and PTMs, however, would have implications for generation of specific antibodies and designing studies on the 5‐HT_1AR at the protein level. A rat recombinant 5‐HT_1AR was extracted from the tsA201 cell line, run using several gel‐based principles with subsequent in‐gel digestion with several proteases, chymotrypsin, trypsin, AspN, proteinase K, and pepsin followed by nano‐LC‐ESI‐MS/MS analysis on a high capacity ion trap and an LTQ Orbitrap Velos. Using two search engines, Mascot and Modiro?, the recombinant 5‐HT_1AR was identified showing 94.55% sequence coverage. A single phosphorylation at S301 was identified and verified by phosphatase treatment and a series of amino acid substitutions were detected. Characterization of 5‐HT_1AR, a key player of brain functions and neurotransmission, was shown and may enable generation of specific antibodies, design of future, and interpretation of previous studies in the rat at the protein level.     

Characterization,expression analysis and localization pattern of toll‐like receptor 1 (tlr1) and toll‐like receptor 2 (tlr2) genes in grass carp Ctenopharyngodon idella

In this study, the toll‐like receptor 1 (tlr1) and toll‐like receptor 2 (tlr2) genes of grass carp Ctenopharyngodon idella were cloned and characterized. tlr1 and tlr2 were found to be highly expressed in immune system organs such as spleen, middle kidney and heart kidney. The expression level of tlr1 and tlr2 was found to be up‐regulated at the later stage of viral challenge process. Moreover, subcellular localization indicated that Tlr1 and Tlr2 shared similar localization pattern and both of them may locate in the plasma membrane of transfected cells.     

Gray matter deficits in bipolar disorder are associated with genetic variability at interleukin‐1 beta gene (2q13)

Twin, family and recent molecular studies support the hypothesis of genetic overlapping between schizophrenia and bipolar disorder. Brain structural features shared by both psychiatric disorders might be the phenotypic expression of a common genetic risk background. Interleukin‐1 (IL‐1) cluster (chromosome 2q13) genetic variability, previously associated with an increased risk both for schizophrenia and for bipolar disorder, has been also associated with gray matter (GM) deficits, ventricular enlargement and hypoactivity of prefrontal cortex in schizophrenia. The aim of the present study was to analyze the influence of IL‐1 cluster on brain morphology in bipolar disorder. Genetic variability at IL‐1B and IL‐1RN genes was analyzed in 20 DSM‐IV ( Diagnostic and Statistical Manual of Mental Disorders ‐Fourth Edition) bipolar patients. Magnetic resonance imaging (MRI) measurements were obtained for whole‐brain GM and white matter, dorsolateral prefrontal cortex (DLPFC), superior temporal gyrus, hippocampus and lateral ventricles. MRI data were corrected for age and cranial size using regression parameters from a group of 45 healthy subjects. A ?511C/T polymorphism (rs16944) of IL‐1B gene was associated with whole‐brain GM deficits (P = 0.031) and left DLPFCGM deficits (P = 0.047) in bipolar disorder patients. These findings support the hypothesis of IL‐1 cluster variability as a shared genetic risk factor contributing to GM deficits both in bipolar disorder and in schizophrenia. Independent replication in larger samples would be of interest to confirm these results.     

Multi‐scale effects of impoundments on genetic structure of creek chub (Semotilus atromaculatus) in the Kansas River basin

1. Habitat fragmentation has been implicated as a primary cause for the ongoing erosion of global biodiversity, yet our understanding of the consequences in lotic systems is limited for many species and regions. Because of harsh environmental conditions that select for high colonisation rates, prairie stream fishes may be particularly vulnerable to the effects of fragmentation. Hence, there is urgent need for broader understanding of fragmentation in prairie streams such that meaningful conservation strategies can be developed. Further, examination at large spatial scales, including multiple impoundments and un‐impounded catchments, will help identify the spatial extent of species movement through the landscape. 2. Our study used data from 10 microsatellite loci to describe the genetic structure of creek chub (Semotilus atromaculatus) populations across four catchments (three impounded and one un‐impounded) in the Kansas River basin. We investigated whether genetic diversity was eroded in response to habitat fragmentation imposed by reservoirs and whether intervening lentic habitat increased resistance to dispersal among sites within a catchment. 3. Our analyses revealed that genetic diversity estimates were consistent with large populations regardless of the location of the sampled tributaries, and there was little evidence of recent population reductions. Nevertheless, we found a high degree of spatial genetic structure, suggesting that catchments comprise a set of isolated genetic units and that sample sites within catchments are subdivided into groups largely defined by intervening habitat type. Our data therefore suggest that lentic habitat is a barrier to dispersal among tributaries, thus reducing the opportunity for genetic rescue of populations in tributaries draining into reservoirs. Isolation by a reservoir, however, may not be immediately deleterious if the isolated tributary basin supports a large population.     

Cell‐specific effects on surface α7 nicotinic receptor expression revealed by over‐expression and knockdown of rat RIC3 protein

We tested whether surface α7 nicotinic acetylcholine receptor expression is dependent on an endogenous chaperone named Resistance to Inhibitors of Cholinesterase 3 (RIC3) by comparing RIC3 protein in rat GH4C1 and human SH‐EP1 cells, which express strikingly different surface receptor levels following α7 transfection. Cloned rat RIC3 exists in at least two isoforms because of an ambiguous splice site between exons 4 and 5. Both rat isoforms permit surface α7 expression in SH‐EP1 and human embryonic kidney (HEK) cells measured by α‐bungarotoxin binding. Contrary to expectations, endogenous RIC3 protein expression determined by immunoblots did not differ between untransfected GH4C1 or SH‐EP1 cells. siRNA against rat RIC3 exon 4 and shRNA against exons 2, 5 and 6 knocked down transfected rat RIC3 expression in SH‐EP1 cells and simultaneously blocked toxin binding. However, no RNAi construct blocked binding when co‐transfected with α7 into GH4C1 cells. shRNA against rat exons 2 and 5 knocked down rat RIC3 protein transfected into GH4C1 cells with a time course suggesting a protein half‐life of a few days. These results suggest GH4C1 cells may possess unknown chaperone(s) allowing high surface α7 expression in the absence of known RIC3 splice variants.