Organizational stressors and basic psychological needs: The mediating role of athletes' appraisal mechanisms.

This article reports the first study to quantitatively examine the relationships between the demands encountered by athletes that are associated with the organization within which they are operating, cognitive appraisals, and basic psychological need experiences. Three hundred and fifteen high-level British athletes completed a multisection questionnaire which assessed each of the aforementioned constructs. A series of path analyses provided valuable insight into the way in which the three dimensions (ie, frequency, intensity, and duration) of five organizational stressor categories were evaluated by athletes and, in turn, how such threat or challenge appraisals predicted feelings of need satisfaction and need frustration. Moreover, cognitive stress appraisals were found to mediate the relationship between organizational stressors and psychological need experiences. The role of secondary control appraisals was also explored and found to mediate the relationship between primary cognitive appraisals and basic psychological need experiences. Study limitations, proposed future research directions, and the implications of the findings for applied practitioners are discussed.

On parsing the neural code in the prefrontal cortex of primates using principal dynamic modes.

Nonlinear modeling of multi-input multi-output (MIMO) neuronal systems using Principal Dynamic Modes (PDMs) provides a novel method for analyzing the functional connectivity between neuronal groups. This paper presents the PDM-based modeling methodology and initial results from actual multi-unit recordings in the prefrontal cortex of non-human primates. We used the PDMs to analyze the dynamic transformations of spike train activity from Layer 2 (input) to Layer 5 (output) of the prefrontal cortex in primates performing a Delayed-Match-to-Sample task. The PDM-based models reduce the complexity of representing large-scale neural MIMO systems that involve large numbers of neurons, and also offer the prospect of improved biological/physiological interpretation of the obtained models. PDM analysis of neuronal connectivity in this system revealed "input-output channels of communication" corresponding to specific bands of neural rhythms that quantify the relative importance of these frequency-specific PDMs across a variety of different tasks. We found that behavioral performance during the Delayed-Match-to-Sample task (correct vs. incorrect outcome) was associated with differential activation of frequency-specific PDMs in the prefrontal cortex.

Effects of coach leadership and coach-athlete relationship on collective efficacy.

The study examined the independent and combined effects of coach leadership and coaching relationships on team efficacy. A total of 150 sport performers from football teams across a range of competitive levels completed a multisection self-report instrument to assess their individual perceptions of the level of collective efficacy, the type of coach leadership, and the quality of the coach-athlete relationship. Multiple regression analyses revealed that perceptions of both coach leadership and the coach-athlete relationship predicted variance in team efficacy. Overall, the findings suggest that the quality of coach-athlete relationships added to the prediction of individuals' collective efficacy beyond what was predicted by coaches' behaviors of leadership alone. Limitations and future research directions are discussed.

Vesicular glutamate transporter VGLUT2 expression levels control quantal size and neuropathic pain.

Uptake of L-glutamate into synaptic vesicles is mediated by vesicular glutamate transporters (VGLUTs). Three transporters (VGLUT1-VGLUT3) are expressed in the mammalian CNS, with partial overlapping expression patterns, and VGLUT2 is the most abundantly expressed paralog in the thalamus, midbrain, and brainstem. Previous studies have shown that VGLUT1 is necessary for glutamatergic transmission in the hippocampus, but the role of VGLUT2 in excitatory transmission is unexplored in glutamatergic neurons and in vivo. We examined the electrophysiological and behavioral consequences of loss of either one or both alleles of VGLUT2. We show that targeted deletion of VGLUT2 in mice causes perinatal lethality and a 95% reduction in evoked glutamatergic responses in thalamic neurons, although hippocampal synapses function normally. Behavioral analysis of heterozygous VGLUT2 mice showed unchanged motor function, learning and memory, acute nociception, and inflammatory pain, but acquisition of neuropathic pain, maintenance of conditioned taste aversion, and defensive marble burying were all impaired. Reduction or loss of VGLUT2 in heterozygous and homozygous VGLUT2 knock-outs led to a graded reduction in the amplitude of the postsynaptic response to single-vesicle fusion in thalamic neurons, indicating that the vesicular VGLUT content is critically important for quantal size and demonstrating that VGLUT2-mediated reduction of excitatory drive affects specific forms of sensory processing.

Selection for beta 2-microglobulin mutation in mismatch repair-defective colorectal carcinomas.

Novel peptide antigens complexed with human leukocyte antigen (HLA) and beta 2-microglobulin (beta 2M) molecules are presented at the cell surface to cytotoxic T lymphocytes (CTLs), provoking lysis of the antigen-presenting cell [1]. In tumor cells, genetically altered or abnormally expressed proteins provide a source of peptides that can be presented to CTLs; the resulting anti-tumour CTL responses may provide part of the body's defence against cancer. Disabling mutations in the HLA and beta 2M proteins required for peptide presentation allow a tumour cell to escape destruction by CTLs. Cells with deficient DNA mismatch repair have high spontaneous mutation rates [2] and produce many altered proteins that are a potential source of numerous unique peptides. Mutator tumour cells might therefore be particularly vulnerable to immune surveillance and CTL attack. Mutator phenotypes [3,4] and loss of beta 2M (or HLA) expression [5,6] are both relatively common among sporadic colorectal tumours. We have compared the frequency of beta 2M mutations in sporadic colorectal and other tumours with and without a mutator phenotype. Mutations were more frequent among colorectal tumours with the microsatellite instability indicative of a defect in DNA mismatch repair. The inactivating beta 2M mutations were predominantly frameshifts, which is consistent with the underlying mismatch repair defects. Evasion of immune surveillance by acquiring beta 2M mutations therefore occurs at high frequency in tumour cells with a mutator phenotype due to defective DNA mismatch repair.

The synthetic cannabinoid HU210 induces spatial memory deficits and suppresses hippocampal firing rate in rats.

BACKGROUND AND PURPOSE: Previous work implied that the hippocampal cannabinoid system was particularly important in some forms of learning, but direct evidence for this hypothesis is scarce. We therefore assessed the effects of the synthetic cannabinoid HU210 on memory and hippocampal activity. EXPERIMENTAL APPROACH: HU210 (100 microg kg(-1)) was administered intraperitoneally to rats under three experimental conditions. One group of animals were pre-trained in spatial working memory using a delayed-matching-to-position task and effects of HU210 were assessed in a within-subject design. In another, rats were injected before acquisition learning of a spatial reference memory task with constant platform location. Finally, a separate group of animals was implanted with electrode bundles in CA1 and CA3 and single unit responses were isolated, before and after HU210 treatment. KEY RESULTS: HU210 treatment had no effect on working or short-term memory. Relative to its control Tween 80, deficits in acquisition of a reference memory version of the water maze were obtained, along with drug-related effects on anxiety, motor activity and spatial learning. Deficits were not reversed by the CB(1) receptor antagonists SR141716A (3 mg kg(-1)) or AM281 (1.5 mg kg(-1)). Single unit recordings from principal neurons in hippocampal CA3 and CA1 confirmed HU210-induced attenuation of the overall firing activity lowering both the number of complex spikes fired and the occurrence of bursts. CONCLUSIONS AND IMPLICATIONS: These data provide the first direct evidence that the underlying mechanism for the spatial memory deficits induced by HU210 in rats is the accompanying abnormality in hippocampal cell firing.

Alternative processing of bovine growth hormone mRNA is influenced by downstream exon sequences.

In a previous report, we described the presence, in pituitary tissue, of an alternatively processed species of bovine growth hormone mRNA from which the last intron (intron D) has not been removed by splicing (R. K. Hampson and F. M. Rottman, Proc. Natl. Acad. Sci. USA 84:2673-2677, 1987). Using transient expression of the bovine growth hormone gene in Cos I cells, we observed that splicing of intron D was affected by sequences within the downstream exon (exon 5). Deletion of a 115-base-pair FspI-PvuII restriction fragment in exon 5 beginning 73 base pairs downstream of the intron 4-exon 5 junction resulted in cytoplasmic bovine growth hormone mRNA, more than 95% of which retained intron D. This contrasted with less than 5% of the growth hormone mRNA retaining intron D observed with expression of the unaltered gene. Insertion of a 10-base-pair inverted repeat sequence, CTTCCGGAAG, which was located in the middle of this deleted segment, partially reversed this pattern, resulting in cytosolic mRNA from which intron D was predominantly removed. More detailed deletion analysis of this region indicated that multiple sequence elements within the exon 5, in addition to the 10-base-pair inverted repeat sequence, are capable of influencing splicing of intron D. The effect of these exon sequences on splicing of bovine growth hormone precursor mRNA appeared to be specific for the growth hormone intron D. Deletions in exon 5 which resulted in marked alterations in splicing of growth hormone intron D had no effect on splicing when exon 5 of bovine growth hormone was placed downstream of the heterologous bovine prolactin intron D. Deletions in exon 5 which resulted in marked alterations in splicing of growth hormone intron D had no effect on splicing when exon 5 of bovine growth hormone was placed downstream of the heterologous bovine prolactin intron D. The results of this study suggest a unique interaction between sequences located near the center of exon 5 and splicing of the adjacent intron D.

DNA mismatch binding defects, DNA damage tolerance, and mutator phenotypes in human colorectal carcinoma cell lines.

DNA mismatch binding in vitro, resistance to DNA methylation damage, and spontaneous mutation rates were examined in human colorectal adenocarcinoma cell lines. Of 11 cell lines, 3 (DLD1, HCT15, and LoVo) were defective in mismatch binding. All three lines had a mutator phenotype. These properties indicate that DLD1 and HCT15 may, like LoVo, carry mutations in the mismatch recognition protein hMSH2. Mismatch binding was normal in the remaining eight lines, including HCT116 in which a second mismatch repair protein, hMLH1, is defective. Two lines, SW620 and SW48, did not express detectable levels of the DNA repair enzyme O6-methylguanine-DNA methyltransferase. SW620 exhibited the expected sensitivity to N-methyl-N-nitrosourea. In contrast, SW48 cells were highly resistant to N-methyl-N-nitrosourea and also slightly to methyl methanesulfonate, indicating that they are tolerant to DNA methylation damage. SW48 exhibited the spontaneous mutator phenotype and microsatellite instability that are hallmarks of a defect in mismatch repair. This cell line provides evidence for the association between methylation tolerance and defective mismatch correction in human colorectal carcinoma cells. The properties of methylation-tolerant, mismatch repair-defective cells identify possible selective pressures that might facilitate the natural selection of mismatch repair-defective tumors.

N-(2-chloroethyl)-N'-cyclohexyl-N-nitrosourea sensitivity in mismatch repair-defective human cells.

To determine whether loss of mismatch repair (MMR) confers sensitivity to N-(2-chloroethyl)-N'-cyclohexyl-N-nitrosourea (CCNU), the sensitivity of MMR-defective (MMR-) variants was compared to that of their parental cells. Loss of MMR confers between 2- and 5-fold hypersensitivity to CCNU on HeLa, Raji, or Chinese hamster ovary cells. We also examined whether the sensitivity to CCNU is a general feature of MMR-human tumor cells. The majority expressed O6-methylguanine-DNA-methyltransferase (MGMT; Mex+ phenotype) that confers resistance to CCNU independent of their MMR status. The single Mex- MMR- SW48 cells were 4-fold more sensitive to CCNU than the Mex- MMR+ SW620 cells. CCNU sensitivity of the Mex+ cells was analyzed after treatment with the MGMT inhibitor O6-benzylguanine. The MMR- AN3CA, LS174T, LoVo, and DU145 cells were 1.4-4.3-fold more sensitive to CCNU than the MMR+ HeLaS3, HT29, and A2780 cells. Hypersensitivity to CCNU was not seen in the MMR- cell lines DLD1, HEC1A, and HCT116, suggesting that other parameters, besides the MGMT and MMR defects, affect the cell's response to this drug. In contrast, loss of MMR was always associated with tolerance to the methylating agent N-methyl-N-nitrosourea. The sensitivity to CCNU in MMR- cells suggests a possible involvement of this repair pathway in repairing interstrand cross-links and may have implications for clinical treatment of MMR- tumors.

Cannabinoids reveal the necessity of hippocampal neural encoding for short-term memory in rats.

The memory-disruptive effects of Delta(9)-tetrahydrocannabinol (Delta(9)-THC) and the synthetic cannabinoid WIN 55,212-2 (WIN-2) were assessed in rats exposed to varying doses of each drug (Delta(9)-THC, 0.5-2.0 mg/kg; WIN-2, 0.25-0.75 mg/kg) during performance of a delayed nonmatch to sample (DNMS) task. Cannabinoids affected performance in a dose x delay-dependent manner, with WIN-2 showing a potency more than four times that of Delta(9)-THC. These effects on DNMS performance were eliminated if the cannabinoid CB1 receptor antagonist SR141617A (Sanofi Research Inc.) was preadministered, but doses of the antagonist alone had no effect on performance. Simultaneous recording from ensembles of hippocampal neurons revealed that both WIN-2 and Delta(9)-THC produced dose-dependent reductions in the frequency (i.e., "strength") of ensemble firing during the sample phase of the task to the extent that performance was at risk for errors on >70% of trials as a function of delay. This decrease in ensemble firing in the Sample phase resulted from selective interference with the activity of differentiated hippocampal functional cell types, which conjunctively encoded different combinations of task events. A reduction in ensemble firing strength did not occur in the nonmatch phase of the task. The findings indicate that activation of CB1 receptors renders animals at risk for retention of item-specific information in much the same manner as hippocampal removal.

Large-scale analysis of gene expression changes during acute and chronic exposure to [Delta]9-THC in rats.

Large-scale cDNA microarrays were employed to assess transient changes in gene expression levels following acute and chronic exposure to cannabinoids in rats. A total of 24,456 cDNA clones were randomly selected from a rat brain cDNA library, amplified by PCR, and arrayed at high density to investigate differential gene expression profiles following acute (24 h), intermediate (7 days), and chronic (21 days) exposure to Delta(9)-tetrahydrocannabinol (Delta(9)-THC), the psychoactive ingredient of marijuana. Hippocampal mRNA probes labeled with (33)P obtained from both vehicle and Delta(9)-THC-treated animals were hybridized with identical cDNA microarrays. Results revealed a total of 49 different genes altered by Delta(9)-THC exposure; of these, 28 were identified, 10 had homologies to expressed sequence tags (ESTs), and 11 had no homology to known sequences in the GenBank database. Chronic or acute cannabinoid receptor activation altered expression of several genes (i.e., prostaglandin D synthase, calmodulin) involved in biochemical cascades of cannabinoid synthesis or cannabinoid effector systems. Other genes [i.e., neural cell adhesion molecule (NCAM), myelin basic protein], whose relation to cannabinoid system function was not immediately obvious, were also significantly altered. Verification of the changes obtained with the large-scale screen was determined by RNA dot blots in different groups of animals treated the same as those in the large-scale screen. Results are discussed in terms of the different types of genes affected at different times during chronic Delta(9)-THC exposure.

Cannabinoid receptors: G-protein-mediated signal transduction mechanisms.

The recent discovery and cloning of cannabinoid receptors has provided a major breakthrough in the understanding of the biochemical mechanisms of action of delta 9-tetrahydrocannibinol (delta 9-THC). Cannabinoid receptors are coupled to G-proteins and inhibit adenylyl cyclase in a variety of systems. In the brain, cannabinoid-inhibited adenylyl cyclase and the receptors are particularly prevalent in the cerebellum, where they are localized to cerebellar granule cells (Fig. 1). In these cells, cannabinoid receptors are co-localized with other Gi/o-linked receptors such as gamma-aminobutyric acid (GABAB) receptors, where they share common effector systems (adenylyl cyclase catalytic units) but not common G-proteins. This sharing of effectors leads to the phenomenon of receptor convergence, in which agonists of different receptor types can produce the same biological response in certain cells. In cultured hippocampal neurons, cannabinoids also act through G-proteins to increase potassium conductance. In these cells, the predominant electrophysiological response at relatively low (microM) concentrations of cannabinoids is mediated through a voltage-sensitive potassium A current (IA) (Fig. 1). The action of cannabinoid receptors in this system is to shift the voltage sensitivity of IA channels to higher voltage ranges, thus increasing K+ conductance at lower membrane potentials and decreasing the probability of multiple action potentials. When combined with data from other groups showing a cannabinoid receptor-mediated decrease in calcium conductance, along with the unique localization of cannabinoid receptors in the brain, it is clear that these receptor-effector combinations are well situated to mediate many of the well-known neurobiological effects of delta 9-THC.

Genomic organization of the human TIMP-1 gene. Investigation of a causative role in the pathogenesis of X-linked retinitis pigmentosa 2.

PURPOSE: To evaluate the role of TIMP-1 in inherited retinal degeneration. METHODS: The genomic structure of the TIMP-1 gene was established and male patients with x-linked retinitis pigmentosa 2 from five families were screened for sequence alterations by direct sequencing in all exons, exon-intron boundaries, and the 5' upstream region of the gene. RESULTS: TIMP-1 appears to be expressed in the retina at low levels and consists of six exons spanning a genomic region of approximately 4.5 kb on Xp11.23. No disease-specific sequence alterations were identified. A site substitution in exon 5 was observed in samples from control subjects and patients, but it did not alter the amino acid sequence of the protein product. CONCLUSIONS: The results of this study exclude mutations in the TIMP-1 coding sequence, splice sites, and the 5' upstream region as a cause of retinal degeneration in x-linked retinitis pigmentosa 2. However, an as yet unidentified regulatory element that lies outside these intervals may be implicated. The role of this tightly regulated protein in the normal functioning of the retina has yet to be determined.

Effects of long-term exposure to delta9-THC on expression of cannabinoid receptor (CB1) mRNA in different rat brain regions.

The time course of changes across 21 days of continuous exposure to Delta9-tetrahydrocannabinol (Delta9-THC) was assessed for the level of cannabinoid receptor (CB1) mRNA expression in three different rat brain regions: cerebellum, hippocampus and corpus striatum. Expression levels of CB1 mRNA were determined using semi-quantitative reverse transcriptase-polymerase chain reaction (RT-PCR) following a protocol which included a gene standard, 28S ribonucleic acid protein (rRNA), for normalization of levels of RNA in the three different brain regions. The levels of CB1 mRNA were assessed in four different rats at each of seven time points (6 h, and 1, 2, 3, 7, 14 and 21 days) during a 21-day Delta9-THC one dose day-1 (10 mg kg-1) treatment regimen. In the cerebellum and hippocampus, CB1 mRNA levels were increased above vehicle control animals at 7 and 14 days of treatment. In the striatum the levels of CB1 transcripts were severely reduced from days 2-14. CB1 message expression in all three brain areas returned to vehicle control levels by day 21 of Delta9-THC treatment, a time at which behavioral tolerance has been previously reported. An additional measure, receptor stimulated GTPgammaS binding, performed over the same time period revealed differential desensitization within the 3 brain areas as a function of chronic exposure to Delta9-THC. Hippocampus was the earliest to desensitize decreasing to 35% of control by treatment day 7, followed by a decrease in the cerebellum to that same level on day 14 of treatment. The striatum showed only half that degree of desensitization (65%) over the entire 21-day treatment period. Comparisons suggests that CB1 message may be regulated by different effector systems in each of the three areas during chronic Delta9-THC exposure.

Hippocampal cell firing correlates of delayed-match-to-sample performance in the rat.

Hippocampal CA1 and CA3 neurons were recorded in rats performing a delayed-match-to-sample (DMTS) task. Complex spike cells showed significant firing peaks following sample and match responses and during delivery of water reward. Individual cells were classified into 4 subtypes according to the presence or absence of firing in each of these 3 phases. There were significant differences in delay interval firing among the 4 subtypes, but firing during the delay did not predict the correct response: 34% of the cells showed a linear change in firing during the delay. Further analyses revealed significant lever position firing biases in approximately 70% of the cells tested irrespective of subtype. The complexity of firing correlates of the neurons recorded in this DMTS task suggests that the hippocampus divides specific aspects of the performance demands of the task across different cell subtypes, which together provide sufficient information to resolve the matching-to-sample problem on any given trial.

Mapping studies on a pericentric inversion (18) (p11.31 q21.1) in a family with both schizophrenia and learning disability.

Chromosomal abnormalities that co-occur with psychiatric disorders can be useful direct pointers to the locus of susceptibility genes. Two families with pericentric inversions of chromosome 18, inv 18(p11.3 q21.1) and psychiatric illness have previously been described. We have fine mapped the chromosomal breakpoints of the rearrangement in a clinically well, inversion carrier from one of these families where other inversion carriers suffered from chronic schizophrenia or severe learning disability. Yeast artificial chromosomes (YACs) from the Whitehead/MIT physical maps of human chromosome 18 have been positioned relative to the chromosomal breakpoints and a number of YACs that span these breakpoints have been identified. Linkage and association studies have previously suggested these regions of chromosome 18q and 18p as candidate loci harbouring genes involved in bipolar disorder and schizophrenia.

Differential information processing by hippocampal and subicular neurons.

It has been known for some years that hippocampal neurons are critically involved in processing of information necessary for encoding memories. What is less understood is the role of the subiculum in this process. We describe here differential response characteristics of subicular and hippocampal neurons in rats during execution of a delayed-nonmatch-to-sample short-term memory task. Subicular neurons, unlike hippocampal neurons, fire primarily in the delay interval of the task and appear to provide a temporal linkage between events encoded in hippocampus during the sample and nonmatch phases. Indeed, a large proportion of subicular neurons fire robustly for the entire duration of the delay only. Further analyses using electrical activation methods indicate that subicular neurons that receive short latency inputs from the anterior thalamus and do not project to cingulate cortex are the most responsive to stimuli with behavioral significance.

Cannabinoids selectively decrease paired-pulse facilitation of perforant path synaptic potentials in the dentate gyrus in vitro.

Perforant path synaptic potentials recorded from the outer molecular layer of the dentate gyrus were tested for paired-pulse potentiation and stimulus sensitivity in the presence and absence of the potent cannabinoid receptor ligand, WIN 55,212-2. Extracellular perforant path synaptic potential amplitudes were increased by 51% in 2 mM Ca2+ medium and 60% in 3 mM Ca2+ medium at a conditioning-test (C-T) interval of 10 ms, decreasing to 10-15% facilitation at an 80 ms C-T interval. Exposure to the potent cannabinoid receptor ligand WIN 55,212-2 produced a marked and dose-dependent reduction in the amplitude of the facilitated perforant path synaptic potentials. Maximum paired-pulse facilitation was reduced to 35% and 25% in 2.0 and 5.0 microM WIN 55,212-2 respectively. The effect was selective for potentials facilitated at C-T intervals of 10-60 ms. Input/output (I/O) curves of perforant path field potentials were shifted to the right in a dose-dependent (2.0 and 5.0 microM) manner by WIN 55,212-2. Significant differences in peak amplitudes of perforant path potentials were obtained at all suprathreshold stimulus intensities. A comparison of WIN 55,212-2 (5 microM) with the GABAB receptor agonist baclofen (200 microM) showed that when both drugs were administered independently each produced similar decreases in perforant path paired-pulse potentiation. However when administered together at these concentrations baclofen and WIN failed to potentiate each other, suggesting nonadditivity due to effects on a common process.(ABSTRACT TRUNCATED AT 250 WORDS)

Cannabinoid receptor activation in CA1 pyramidal cells in adult rat hippocampus.

Intracellular assessments of the physiological actions of cannabinoid receptor agonists and antagonists on adult hippocampal CA1 pyramidal cells in the in vitro slice preparation were performed using current clamp and conventional sharp-electrode intracellular recording procedures. Several manipulations were performed to delineate putative currents and conductance mechanisms affected by the cannabinoid receptor agonist WIN 55,212-2 (WIN-2). This compound produced a tonic hyperpolarization of the pyramidal cell membrane that was bicuculline sensitive, reversed by changing the chloride gradient, and abolished by the addition of TTX to the bathing medium. Instantaneous membrane input resistance, computed from hyperpolarizing current pulses (peak R(in)) was also reduced significantly in the presence of WIN-2 and was accompanied by enhancement of a superimposed slow depolarization that reduced steady-state R(in) (SSR(in)); both effects were resistant to barium. Intracellular perfusion of cesium acetate (CsAc) and the sodium/potassium channel blocker, QX314, each blocked the effect of WIN-2 on R(in) and SSR(in). WIN-2 also reduced input resistance calculated from depolarizing current injections (R(d)). This effect was also blocked by atropine, as well as media containing TTX or low Ca(2+). Each of the above effects of WIN-2 was blocked by the cannabinoid receptor antagonist SR141716A, showing a dependence on CB1 cannabinoid receptors. Several known pre- and postsynaptic processes in adult pyramidal cells are discussed which could be responsible for these cannabinoid-produced changes in membrane resistances.