Increased corticosterone secretion and early-onset of cognitive decline in female apolipoprotein E-knockout mice

In the present study, the interaction of age and apolipoprotein E (apoE)-genetic background on cognitive abilities was investigated in young (5-6 months) and aged (14-16 months) female apolipoprotein E-knockout (apoE0/0) and wild-type mice. Cognitive abilities are known to be affected by the steroid hormones corticosterone and estrogen. Therefore, we measured the activity and reactivity of the hypothalamic-pituitary-adrenal (HPA) axis expressed by circadian corticosterone concentrations and responses to novelty and controlled the regularity of the estrous cycle. Young female apoE0/0 mice acquired the water maze task and showed a similar latency and search strategy to locate the platform as young female wild-type mice. Similar corticosterone responses to novelty were observed in both genotypes. Regularity of the estrous cycle was disturbed in a small percentage of the young apoE0/0 female mice. However, in aged female apoE0/0 mice water maze performance was impaired with search strategies less persistent than in aged wild-type mice. In parallel, increased corticosterone concentrations were measured in apoE0/0 mice in response to novelty and during the circadian cycle. The percentage of mice with an irregular estrous cycle increased with age, but was comparable for apoE0/0 and wild-type mice. Thus, although disruption of the apoE gene affects the regularity of the estrous cycle in young mice, it is the enhanced corticosterone secretion, which parallels the cognitive decline in the aging female apoE0/0 mice.

Responses to noxious stimuli in mice lacking alpha(1d)-adrenergic receptors

Nociceptive behaviors were examined in the mice lacking alpha1d-adrenergic receptor (alpha1d-AR) and wild type littermates using tail-flick, hot-plate (hindpaw-licking and jumping), tail-pinch and formalin tests. The distribution of alpha1d-AR was studied using in situ hybridization in the wild type mice. Mutant mice showed longer tail-flick and hindpaw-licking latencies while their jumping latency was shorter. Mechanical and chemical nociception was not altered in alpha1d-knockout mice. In situ hybridization study revealed dense alpha1d-AR mRNA expression in the reticular thalamic nucleus, the hippocampus, the cingulate cortex and the spinal cord. These results suggest that alpha1d-AR in the spinal cord contributes to thermal pronociception; and that the jump behavior seen when escaping from heat is inhibited via the supraspinal alpha1d-AR.

Transgenic and knockout mice for DNA repair functions in carcinogenesis and mutagenesis

Genetically modified mouse models with defects in DNA repair pathways, especially in nucleotide excision repair (NER) and mismatch repair (MMR), are powerful tools to study processes like carcinogenesis and mutagenesis. The use of mutant mice in these studies has many advantages over using normal wild type mice with respect to costs, number of animals, predictive value towards carcinogenic compounds and the duration of study. Short-term carcinogenicity assays still require considerable number of animals and extensive pathological analyses. Therefore, alternatives demanding less animals and shorter exposure times would be desirable. In this respect, one approach could be the use of transgenic mice harbouring marker genes, that can easily detect mutagenic features of carcinogenic compounds, especially when such models are in a DNA repair deficient background. Here, we review the progress made in the development and use of DNA repair deficient mouse models as replacements for long-term cancer assays and discuss the applicability of enhanced gene mutant frequencies as early indicators of tumourigenesis. Although promising models exist, there is still a need for more universally responding and highly sensitive mouse models, since it is likely that non-genotoxic carcinogens will go undetected in a DNA repair deficient mouse. One attractive candidate mouse model, having a presumptive broad detective range, is the Xpa/p53 mutant mouse model, which will be discussed in more detail.

Behavioral alterations in mice deficient for the extracellular matrix glycoprotein tenascin-R

We investigated the behavior of mice deficient for the extracellular matrix (ECM) glycoprotein tenascin-R (TN-R) in comparison to their wild-type (WT) littermates. A longitudinal study including tests for exploration and anxiety, motor coordination and cognition was carried out. Mice were tested at different ages, ranging from 3 weeks to 11 months and under different housing conditions. TN-R deficient mice displayed decreased motivation to explore and an increased anxiety profile in the free choice open field (FCOF), open field (OF) and elevated plus maze (EPM) tests. Moreover, the anxiety level of TN-R deficient mice was more strongly influenced by environmental factors as compared to WT littermates. TN-R deficient mice showed motor coordination impairments in the wire hanging, Rotarod and pole test. Thus TN-R ablation leads to an altered behavioral phenotype in mice that may negatively affect their fitness under natural conditions.

Mice deficient for the close homologue of the neural adhesion cell L1 (CHL1) display alterations in emotional reactivity and motor coordination

Motor and cognitive phenotypes were assessed in mice deficient for the close homologue of the L1 adhesion molecule (CHL1). The CHL1-deficient mice displayed signs of decreased stress and a modification of exploratory behaviour. The mice also showed motor impairments on the Rotarod, but they were able to move as fast as controls in the alleys of a T-maze. The observed changes were assumed to be related to a deficit in attention. In addition, gender differences in CHL1 deficits were found and are discussed in view of a possible interaction with other cell adhesion molecules (CAMs) during development. The results are discussed in relation with motor and cognitive deficits in the human, caused by mutations of the distal part of the chromosome 3 which contains the CHL1 orthologue.

Abnormal behavioral phenotypes of serotonin transporter knockout mice: parallels with human anxiety and depression

Evidence of a link between genetic variation of the serotonin transporter and depression and anxiety prompted the generation of serotonin transporter knockout mice. Loss of serotonin reuptake function in knock-outs causes reduced clearance of extracellular serotonin and associated alterations in serotonin neuronal firing and receptor function. Behavioral phenotyping function in knock-outs revealed genetic background-related abnormalities, including increased anxiety-like behaviors, reduced aggression, and exaggerated stress responses. Ongoing studies focus on identifying environmental, genetic, and developmental factors interacting with the htt mutation to produce these abnormalities. Serotonin transporter null mutant mice provide a model system to study how genetic variation in serotonin transporter function affects risk for neuropsychiatric disease.

Learning deficits in forebrain-restricted brain-derived neurotrophic factor mutant mice

Brain-derived neurotrophic factor (BDNF) participates in synaptic plasticity and the adaptive changes in the strength of communication between neurons thought to underlie aspects of behavioral adaptation. By selectively deleting BDNF from the forebrain of mice using the Cre site-specific DNA recombinase, we were able to study the requirements for BDNF in behaviors such as learning and anxiety. Early-onset forebrain-restricted BDNF mutant mice (Emx-BDNF(KO)) that develop in the absence of BDNF in the dorsal cortex, hippocampus, and parts of the ventral cortex and amygdala failed to learn the Morris Water Maze task, a hippocampal-dependent visuo-spatial learning task. Freezing during all phases of cued-contextual fear conditioning, a behavioral task designed to study hippocampal-dependent associative learning, was enhanced. These mice learned a brightness discrimination task well but were impaired in a more difficult pattern discrimination task. Emx-BDNF(KO) mice did not exhibit altered sensory processing and gating, as measured by the acoustic startle response or prepulse inhibition of the startle response. Although they were less active in an open-field arena, they did not show alterations in anxiety, as measured in the elevated-plus maze, black-white chamber or mirrored chamber tasks. Combined, these data indicate that although an absence of forebrain BDNF does not disrupt acoustic sensory processing or alter baseline anxiety, specific forms of learning are severely impaired.

Impact of environmental housing conditions on the emotional responses of mice deficient for nociceptin/orphanin FQ peptide precursor gene

Nociceptin/orphanin FQ (N/OFQ) is a newly discovered neuropeptide that has been implicated in the neurobiological regulation of the behavioral responses to stress and fear. To investigate the role of this peptide in the expression of stress/anxiety-related behaviors in mice, a gene targeting approach to disrupt N/OFQ in the pre-proN/OFQ gene was used. The impact of environmental housing conditions (single and social housing) was assessed on N/OFQ-knockout male and female mice in different experimental paradigms known to trigger distinctive types of stress and anxiety states. Neurological examination of homozygous mutant adult animals indicated that basic neurological functions (vision, audition, olfaction, tactile and pain sensitivity, motor performances) were normal. When housed individually, N/OFQ-knockout animals displayed responses similar to control animals in behavioral tests of emotional reactivity (behavioral despair, locomotor activity, light-dark preference, and acoustic startle tests). In contrast, increased emotional responses were detected when individually housed mice were crowded together (five per cage) under conditions of competitive access to food, water, space, and social contacts. Under those conditions, male mice deficient for N/OFQ developed greater home-cage aggression and increased fear/anxiety-like behaviors in the light-dark and acoustic startle tests, when compared to their wild-type littermates. Group-housed female mutants also showed higher level of anxiety in the acoustic startle test, but needed additional restrain stress to express detectable levels of anxiety in the light-dark test. These data indicate a clear environment-induced rise in fear reactions of N/OFQ-knockout mice. They further suggest that N/OFQ system is essential for development of adequate coping strategies to acute and chronic stress.

Corpus callosum and visual cortex of mice with deletion of the NMDA-NR1 receptor: I. Accelerated development of callosal projection neurons

Many pharmacological experiments show that the ionotropic receptor NMDA has both neurotrophic and neuroexcitotoxic effects. The neurotrophic function is manifested in many ways including acceleration of neuronal development, enhancement of neuronal migration, neuroprotection, blockage of apoptosis, prevention of aging and prematurity, as well as effects on synaptic plasticity and synaptogenesis. On the other hand, the neuroexcitotoxic function is manifested in its role in neurological and psychiatric diseases such as epilepsy, Parkinson's disease and schizophrenia. The present study explores the consequences of complete and partial absence of NMDA-NR1 receptors throughout development. Using DiI tracing in vitro, the development of corpus callosum projection neurons in transgenic mice with deletion of the NMDA-NR1 receptor was observed in visual cortex. Compared to littermate controls, the histogenesis and neuronal development of corpus callosum cells of origin was found to be accelerated in NR1-/- mice. That is, the corpus callosum projection neurons in NR1 knockout mice developed earlier and faster than in littermate heterozygous and wild-type mice. However, the corpus callosum projection neurons in NR1 heterozygous mice developed earlier and faster than in littermate wild-type mice. This suggests that NMDA-NR1 receptors are involved in sequencing and/or temporal regulation of neuronal development, and that there is a gene-dose effect. Studies from other laboratories suggest that the observed phenomenon of prematurity or accelerated development is a direct effect of altered expression of genes found in mice with deletion of the NMDA-NR1 receptor.

The apoptosis-necrosis continuum: insights from genetically altered mice

Apoptosis can be defined as a carefully regulated process, characterized by specific morphologic and biochemical features. It is initiated by both physiologic and pathologic stimuli, and its full expression requires a signaling cascade in which caspase activation plays a central role. Knockout mice lacking key genes encoding proteins constituting the core apoptotic cascade have helped us to establish the functional hierarchy of the mechanisms controlling apoptosis in animal development and, to a lesser extent, in disease. Induced mutant mice have also revealed the intimate crosstalk between apoptotic and other homeostatic pathways and have defined distinct temporal and tissue-specific roles of individual apoptotic effectors. Eliminating genes controlling caspase-dependent apoptosis can convert an apoptotic phenotype to a necrotic one, both in vitro and in vivo. This suggests that necrosis and apoptosis represent morphologic expressions of a shared biochemical network through both caspase-dependent mechanisms as well as non-caspase-dependent effectors such as cathepsin B and apoptosis-inducing factor. The cell death program, whether by apoptosis or necrosis, is mediated through an integrated cascade, which can be accessed at multiple sites, and propagated through numerous branch points. An understanding of the physiologic conditions that influence these decisions is required to adequately prevent, or induce, cell death.

Aging and cancer in transgenic and mutant mice

Mutant and genetically modified animal models, which are characterized by shortening or extension of the life span, give a unique possibility to evaluate the role of aging genes in mechanisms of carcinogenesis. Transgenic and null mutant ("knockout") animal models also offer an important opportunity to identify and study both carcinogens and chemopreventive agents. The analysis of the available data on transgenic and mutant mice has shown that only a few models represent examples of life span extension. Ames dwarf mutant mice, p66-/- knockout mice, alpha-MUPA and O6-methylguanine-DNA methyltransferase (MGMT) transgenic mice live longer than wild-type strains. The incidence of spontaneous tumors in these mice was similar to those in controls, whereas the latent period of tumor development was increased. Practically all models of accelerated aging (excepting p53+/m mice) show the increased tumor incidence and shortening of tumor latency. These observations are in agreement with an earlier established positive correlation between tumor incidence and the rate of tumor incidence increase associated with aging and the aging rate in a population. Thus, genetically modified animals are a valuable tool in unraveling mechanisms underlying aging and cancer.

Impaired water maze learning performance in μ-opioid receptor knockout mice

Previous study has demonstrated that the lack of mu-opioid receptor decreased LTP in the dentate gyrus of the hippocampus, suggesting the possibility that the lack of mu-opioid receptor may accompany a change in learning and memory. However, no behavioral study has been undertaken to correlate LTP deficits with spatial memory impairment in mu-opioid receptor knockout mice. Therefore, the present study investigated the hypothesis that mu-opioid receptors contribute to learning and memory by using the Morris water maze, and comparing responses in wild type and mu-opioid receptor gene knockout mice. Our results indicated that mu-opioid receptor knockout mice showed a significant spatial memory impairment compared to wild type in the Morris water maze. This result suggests that the expression of mu-opioid receptor plays an important role in spatial learning and memory examined by Morris water maze.

Prostaglandin E2 inhibits the potassium current in sensory neurons from hyperalgesic Kv1.1 knockout mice

Prostaglandin E(2) (PGE(2)) enhances the sensitivity of sensory neurons to various forms of noxious stimulation. This occurs, in part, by the suppression of a delayed rectifier-like potassium current in these neurons. However, the molecular identity of this current remains unclear. Recent studies demonstrated that a mutant mouse lacking a delayed rectifier potassium channel gene, Kv1.1, displayed lowered thresholds to thermal stimulation in behavioral assays of pain perception, i.e. the Kcna1-null mice were hyperalgesic. Here we examined whether PGE(2) can alter the sensitivity of Kcna1-null mice to noxious stimulation and examine the capability of PGE(2) to inhibit the potassium current in these knockout mice. Behavioral assays were used to assess the effect of PGE(2) on either thermal hyperalgesia or mechanical sensitivities. In addition, the whole-cell patch-clamp technique was used to study the effects of PGE(2) on the total potassium current recorded from isolated mouse sensory neurons. Even with a reduced threshold to thermal stimulation, PGE(2) could still sensitize the response of Kcna1-null mice to thermal and mechanical stimulation by amounts that were similar to that in wild type mice. The activation properties of the potassium current were similar for both the wild type and the Kcna1-null mice, whereas the inactivation properties were different in cells exhibiting large amounts of steady-state inactivation (>50%) measured at +20 mV. PGE(2) suppressed the total potassium current in both groups of mice by 40-50% without altering the voltage dependence of activation. In addition, PGE(2) produced similar amounts of suppression in both groups of mice when currents were examined with the steady-state inactivation protocol. Based on these results, it is unlikely that Kv1.1 is the molecular identity of the potassium channel(s) modulated by PGE(2) to sensitize nociceptive sensory neurons. Also, the enhanced thermal sensitivity as observed in the Kcna1-null mice might be due to more central neurons of the pain sensing pathway.

In vivo studies of the genetically modified mouse kidney

Gene-targeted mice provide a powerful approach to study the physiological and pathophysiological role of a given protein in kidney function and can give insights on the functional importance of these proteins under in vivo conditions as well as on the potential compensating mechanisms in their absence. Full utilisation of these animal models requires adaptation of the respective methods to the size of the mouse. This applies especially to in vivo studies in mice which have to deal with rather small structures and volumes, e.g. vessels for cannulation, plasma volumes or urinary flow rates. Here some aspects which can help to study kidney function in the mouse in vivo are outlined. The applicability of these in vivo methods are stressed by reviewing their very recent application in mice being deficient for either ROMK or SGK1.

Insulin receptor knockout mice

To examine the role of the insulin receptor in fuel homeostasis, we and others have carried out genetic ablation studies in mice. Mice lacking insulin receptors are born with normal features, but develop early postnatal diabetes and die of ketoacidosis. In contrast, mice lacking insulin receptors in specific cell types as a result of conditional mutagenesis develop mild metabolic and reproductive abnormalities. These experiments have uncovered novel functions of insulin receptors in tissues such as brain and pancreatic beta-cells. Combined knockout studies of insulin and Igf1 receptors indicate that the insulin receptor also promotes embryonic growth. Experimental crosses of mice with insulin receptor haploinsufficiency have been instrumental to the genetic analysis of insulin action by enabling us to assign specific roles to different insulin receptor substrates and identify novel elements in insulin signaling.

Insights into the regulation of gastric acid secretion through analysis of genetically engineered mice

The regulation of acid secretion in the stomach involves a complex network of factors that stimulate secretion in response to the ingestion of a meal and maintain homeostasis of gastric pH. Genetically engineered mouse models have provided a new opportunity to investigate the importance and function of specific molecules and pathways involved in the regulation of acid secretion. Mouse mutants with disruptions in the three major stimulatory pathways for acid secretion in parietal cells, gastrin, histamine, and acetylcholine, have been generated. Disruption of the gastrin pathway results in a major impairment in both basal and induced acid secretion. Histamine and acetylcholine pathway mutants also have significant alterations in acid secretion, although the impairment does not appear to be as severe as in gastrin pathway mutants, perhaps due in part to the hypergastrinemia that occurs. Mice with a disruption in the somatostatin pathway have increased gastric acid secretion, which confirms an important negative regulatory role for this factor. This review discusses these genetically engineered mouse models, as well as others, that provide insight into the complex regulation of in vivo gastric acid secretion. The regulation of growth and cellular morphology of the stomach in these mouse models is also presented. In addition, transgene promoters that are expressed in the gastric epithelium are discussed because these promoters will be important tools to alter cellular physiology in new mouse models in the future.

Glycosphingolipid functions: insights from engineered mouse models

Glycosphingolipids are remarkable for their structural complexity and their distinctive patterns that mark different tissues and stages of development. The physiological functions of glycosphingolipids are likely to be profound and are only beginning to emerge. Much of this new information is due to the study of mutant mice lacking specific sets of glycosphingolipids, the topic of this review.

Cardiovascular diseases: new insights from knockout mice

Knockout (KO) mice models have generated a wealth of new information on the developmental and physiopathological roles of several hormones and their receptors. In these mice, KO of a specific gene can be lethal at embryonic stages or during early adulthood. Furthermore, in conditions of non-lethality, KO mice may compensate for the repression of a particular protein expression. As a result of these two aspects, various phenotypic expressions occur in KO mice models for several peptides and their respective receptors, as well as for the enzymes involved in their processing.

Cardiovascular and renal phenotyping of genetically modified mice: a challenge for traditional physiology

1. The advent of techniques to genetically modify experimental animals and produce directed mutations in both a conditional and tissue-specific manner has dramatically opened up new fields for physiologists in cardiovascular and renal research. 2. A consequence of altering the genetic background of mice is the difficulty in predicting the phenotypic outcome of the genetic mutation. We therefore suggest that physiologists may need to change their current experimental paradigms to face this new era. Hence, our aim is to propose a complementary research philosophy for physiologists working in the post-genomic era. That is, instead of using strictly hypothesis-driven research philosophies, one will have to perform screening studies of mutant mice, within a field of interest, to find valuable phenotypes. Once a relevant phenotype is found, in-depth studies of the underlying mechanisms should be performed. These follow-up studies should be performed using a traditional hypothesis-driven research philosophy. 3. The rapidly increasing availability of mutated mouse models of human disease also necessitates the development of techniques to characterize these various mouse phenotypes. In particular, the miniaturization and refinement of techniques currently used to study the renal and cardiovascular system in larger animals will be discussed in the present review. Hence, we aim to outline what techniques are currently available and should be present in a laboratory to screen and study renal and cardiovascular phenotypes in genetically modified mice, with particular emphasis on methodologies used in the intact, conscious animal.

Congenic C57BL/6 mu opiate receptor (MOR) knockout mice: baseline and opiate effects

Homozygous mu-opioid receptor (MOR) knockout (KO) mice developed on a chimeric C57B6/129SV background lack morphine-induced antinociception, locomotion and reward. Therefore it appears that MOR largely mediates these morphine actions. However, one factor that could affect the extent of knockout deficits in morphine-induced behavior is the genetic background against which the gene deletion is expressed. To examine the effect of genetic background chimeric C57B6/129SV MOR knockout mice from the 15th generation of those developed in our laboratory were backcrossed for 10 successive generations with C57BL/6 mice, a strain which is more sensitive to many of the properties of morphine, to produce congenic MOR (con-MOR) KO mice. Heterozygote conMOR KO mice display attenuated morphine locomotion and reduced morphine analgesia compared to wild-type mice. Homozygote con-MOR KO mice display baseline hyperalgesia, no morphine place preference, no morphine analgesia and no morphine locomotion. These results are not qualitatively different from those observed in the MOR KO strain with a chimeric C57B6/129SV background, and suggest that although the strain has separate influences on these functions, it does not substantially interact with deletion of the mu opiate receptor gene.

Progesterone in gestational diabetes mellitus: guilty or not guilty?

Insulin resistance is one of the metabolic changes in pregnancy, but only a fraction of women develop overt impaired glucose tolerance or frank diabetes. Most women are able to compensate this altered metabolic state by increasing the amount of insulin produced by the pancreatic beta cells. Progesterone might well be the key to the development of gestational diabetes. Previously high progesterone levels have already been shown to be correlated with the development of glucose abnormalities in pregnancy and now, in a new paper, progesterone receptor-knockout mice are found to have improved glucose tolerance. These mice showed increased insulin secretion, which is probably linked to the presence of increased numbers of beta cells in their pancreas. Is progesterone therefore the 'ultimate bad guy', prohibiting normal adaptation of the pancreatic beta-cell reserve during pregnancy?

Investigation of postjunctional alpha1- and alpha2-adrenoceptor subtypes in vas deferens from wild-type and alpha(2A/D)-adrenoceptor knockout mice

1. The subtypes of alpha(1)- and alpha(2)-adrenoceptor mediating contractions of vas deferens have been examined in wild-type and alpha(2A/D)-adrenoceptor knockout mice. 2. Maximum contractions to noradrenaline but not phenylephrine were significantly greater in vas from wild-type. The alpha(1A)-adrenoceptor antagonist RS100329 (5-methyl-3-[3-[4-[2-(2,2,2,-trifluoroethoxy)phenyl]-1-piperazinyl]propyl]-2,4-(1H)-pyrimidinedione) (10 nM) significantly shifted the potency of noradrenaline. The alpha(2D)-adrenoceptor antagonist BRL 44408 (2-[(4,5-dihydro-1H-imidazol-2-yl)methyl]-2,3-dihydro-1-methyl-1H-isoindole) significantly reduced the maximum contraction to noradrenaline in wild-type but not in knockout. 3. Following prazosin (0.1 micro M), a component of the contraction to noradrenaline in wild-type but not in knockout was sensitive to the alpha(2)-adrenoceptor antagonist yohimbine. 4. Nifedipine (10 micro M) or suramin (100 micro M) reduced the contraction to 10 Hz stimulation for 4 s to an early peak and small maintained response. The peak was abolished by the alpha(1)-adrenoceptor antagonist prazosin. 5. RS100329 or prazosin inhibited 10 Hz stimulation evoked contractions with a U-shaped concentration-response curve: inhibiting responses up to 0.1 micro M, with a reversal of inhibition above this concentration. In the presence of suramin or nifedipine, the reversal of inhibition by high concentrations of prazosin was reduced. 6. The alpha(1D)-adrenoceptor selective antagonist BMY7378 (8-[2-(4-(2- methoxyphenyl)piperazin-1-yl)ethyl]-8-azaspiro[4,5]decane-7,9-dione) produced inhibition of 10 Hz evoked contractions only in high concentrations. 7. In conclusion, contractions to nerve stimulation in mouse vas deferens involve largely alpha(1A)-adrenoceptors and purinoceptors. alpha(1)-Adrenoceptor antagonists in high concentrations increase the purinergic response presumably by blocking prejunctional alpha(2)-adrenoceptor-mediated inhibition. In the presence of nifedipine, responses are predominantly alpha(1)-adrenoceptor mediated. Contractions to exogenous noradrenaline involved both alpha(1A)- and alpha(2A/D)-adrenoceptors in wild-type mice.

Determination of group I metabotropic glutamate receptor subtypes involved in the frequency of epileptiform activity in vitro using mGluR1 and mGluR5 mutant mice

In mouse hippocampal slices, bicuculline elicited spontaneous epileptiform bursts with a duration of 200-300 ms and with a frequency of five to six events per minute. Application of group I metabotropic glutamate receptor agonist (RS)-3,5-dihydroxyphenylglycine ((RS)-DHPG) increased the burst frequency up to 300% at concentrations of 50 to 100 microM, while it decreased the burst duration below 100 ms. In slices of subtype I mGluR1 or subtype I mGluR5 knockout mice, bicuculline elicited spontaneous epileptiform bursts with similar duration and frequency as those measured in wild-type mice but without the previous effects seen following application of DHPG at concentrations up to 100 microM. Likewise, in slices of wild-type mice, preincubation with mGluR1 antagonist, 1-aminoindan-1,5-dicarboxylic acid (AIDA) or mGluR5 receptor antagonist, 2-methyl-6-(phenylethynyl)-pyridine (MPEP) blocked in both cases completely the increase in frequency following DHPG application. These findings suggest an interactive mechanism between mGluR1 and mGluR5 receptors in the modulation of epileptiform bursting activity by DHPG that could indicate a common intracellular signaling mechanism or possibly direct interaction between these two receptors.

Analysis of quantitative trait loci that influence animal behavior

Behavioral differences between inbred strains of mice and rats have a genetic basis that can now be dissected using quantitative trait locus (QTL) analysis. Over the last 10 years, a large number of genetic loci that influence behavior have been mapped. In this article I review what that information has revealed about the genetic architecture of behavior. I show that most behaviors are influenced by QTL of small effect, each contributing to less than 10% of the variance of a behavioral trait. The small effect of each QTL on behavioral variation suggests that the mutational spectrum is different from that which results in Mendelian disorders. Regions of DNA should be appropriately prioritized to find the molecular variants, for instance by looking at sequences that control the level of gene expression rather than variants in coding regions. While the number of allelic loci that can contribute to a trait is large, this is not necessarily the case: the analysis of selected strains shows that a remarkably small number of QTL can explain the bulk of the genetic variation in behavior. I conclude by arguing that genetic mapping has more to offer than a starting point for positional cloning projects. With advances in multivariate analyses, mapping can also test hypotheses about the psychological processes that give rise to behavioral variation.