One-carbon metabolism in neurodevelopmental disorders: using broad-based nutraceutics to treat cognitive deficits in complex spectrum disorders

Folate and choline, two nutrients involved in the one-carbon metabolic cycle, are intimately involved in regulating DNA integrity, synthesis, biogenic amine synthesis, and methylation. In this review, we discuss evidence that folate and choline play an important role in normal cognitive development, and that altered levels of these nutrients during periods of high neuronal proliferation and synaptogenesis can result in diminished cognitive function. We also discuss the use of these nutrients as therapeutic agents in a spectrum of developmental disorders in which intellectual disability is a prominent feature, such as in Fragile-X, Rett syndrome, Down syndrome, and Autism spectrum disorders. A survey of recent literature suggests that nutritional supplements have mild, but generally consistent, effects on improving cognition. Intervening with supplements earlier rather than later during development is more effective in improving cognitive outcomes. Given the mild improvements seen after treatments using nutrients alone, and the importance of the genetic profile of parents and offspring, we suggest that using nutraceutics early in development and in combination with other therapeutics are likely to have positive impacts on cognitive outcomes in a broad spectrum of complex neurodevelopmental disorders.

Cognitive and social functions and growth factors in a mouse model of Rett syndrome

Rett syndrome (RTT) is an autism-spectrum disorder caused by mutations in the X-linked gene encoding methyl-CpG-binding protein 2 (MeCP2). Abnormalities in social behavior, stereotyped movements, and restricted interests are common features in both RTT and classic autism. While mouse models of both RTT and autism exist, social behaviors have not been explored extensively in mouse models of RTT. Here, we report cognitive and social abnormalities in Mecp2(1lox) null mice, an animal model of RTT. The null mice show severe deficits in short- and long-term object recognition memories, reminiscent of the severe cognitive deficits seen in RTT girls. Social behavior, however, is abnormal in that the null mice spend more time in contact with stranger mice than do wildtype controls. These findings are consistent with reports of increased reciprocal social interaction in RTT girls relative to classic autism. We also report here that the levels of the neurotrophins brain-derived neurotrophic factor (BDNF), insulin-like growth factor-1 (IGF-1), and nerve growth factor (NGF) are decreased in the hippocampus of the null mice, and discuss how this may provide an underlying mechanism for both the cognitive deficits and the increased motivation for social contact observed in the Mecp2(1lox) null mice. These studies support a differential etiology between RTT and autism, particularly with respect to sociability deficits.

Phenotypic characterization of mice heterozygous for a null mutation of glutamate carboxypeptidase II

Glutamate is the major excitatory neurotransmitter in the mammalian central nervous system. Disturbed glutamate signaling resulting in hypofunction of N-methyl-D-aspartate receptors (NMDAR) has been implicated in the pathophysiology of schizophrenia. Glutamate Carboxypeptidase II (GCP II) hydrolyzes N-acetyl-alpha L-aspartyl-L-glutamate (NAAG) into glutamate and N-acetyl-aspartate. NAAG is a neuropeptide that is an NMDAR antagonist as well as an agonist for the metabotropic glutamate receptor-3 (mGluR3), which inhibits glutamate release. The aggregate effect of NAAG is thus to attenuate NMDAR activation. To manipulate the expression of GCP II, LoxP sites were inserted flanking exons 1 and 2, which were excised by crossing with a Cre-expressing mouse. The mice heterozygous for this deletion showed a 50% reduction in the expression level of protein and functional activity of GCP II in brain samples. Heterozygous mutant crosses did not yield any homozygous null animals at birth or as embryos (N > 200 live births and fetuses). These data are consistent with the previous report that GCP II homozygous mutant mice generated by removing exons 9 and 10 of GCP II gene were embryonically lethal and confirm our hypothesis that GCP II plays an essential role early in embryonic development. Heterozygous mice, however, developed normally to adulthood and exhibited increased locomotor activity, reduced social interaction, and a subtle cognitive deficit in working memory.

Subbing slides

INTRODUCTIONWhen mounting sections on a slide, it is essential that the slide be ultraclean. To ensure that the section sticks to the slide, slides can be covered with a thin layer of gelatin. The process of cleaning and gelatin-coating is called "subbing." Several boxes of slides should be subbed at a time and stored, covered, in the refrigerator until they are needed. Subbed slides can also be purchased commercially.

The nissl stain: a stain for cell bodies in brain sections

INTRODUCTIONThe Nissl stain is used widely in many research labs to examine the overall morphology of the brain. It is often used to verify the location of a lesion or an electrode.

Longitudinal brain MRI study in a mouse model of Rett Syndrome and the effects of choline

Rett Syndrome (RTT), the second most common cause of mental retardation in girls, is associated with mutations of an X-linked gene encoding the transcriptional repressor protein MeCP2. Mecp2(1lox) mutant mice express no functional MeCP2 protein and exhibit behavioral abnormalities similar to those seen in RTT patients. Here we monitor the development of both whole brain and regional volumes between 21 and 42 days of age in this model of RTT using MRI. We see decreases in whole brain volumes in both male and female mutant mice. Cerebellar and ventricular volumes are also decreased in RTT males. Previous work has suggested that perinatal choline supplementation alleviates some of the behavioral deficits in both male and female Mecp2(1lox) mutant mice. Here we show that perinatal choline supplementation also positively affects whole brain volume in heterozygous females, and cerebellar volume in male RTT mice.

Perfusion of brain tissues with fixative

INTRODUCTIONIn many experiments it is necessary to section the brain to determine the location of a treatment (lesion or electrode) or to look at the histology of the brain using various staining techniques. Because the texture of the brain is so soft (often likened to soft cheese), it must be "fixed" before it can be removed from the skull. A fixative is a chemical that cross-links the molecules of the tissue, rendering it hard and preserving the tissue. This protocol describes a method for perfusing the brain with fixative (specifically, it describes how to perfuse a rat brain; slight modifications may be needed for different animals). A relatively simple gravity feed and the pumping mechanism of the heart is used to get fixative into the brain. A cannula is placed in the heart, or directly in the ascending aorta, of a deeply anesthetized animal. Blood is flushed out with saline first, and then with a fixative. The choice of fixative is often important if a specific staining technique is to be used, especially in immunocytochemistry, because the fixative can interfere with the staining sensitivity.

Sectioning of brain tissues

INTRODUCTIONA fixed brain, although harder than the brain in its natural state, is still not hard enough to cut into very thin slices. To make uniform, thin sections, the brain must be frozen. A wide variety of sectioning devices are available, each with their own requirements. With a microtome, for example, a very sharp knife is drawn manually across a brain that has been frozen to a chilled platform using dry ice. After each cut, the knife is lowered mechanically by a preset amount, giving consistent sections of a required thickness. A drawback of this instrument is that the temperature of the platform can fluctuate, thus causing changes in the quality of the sections. Other instruments, such as a cryostat, maintain the platform-mounted brain and the knife inside an enclosed refrigerated compartment. The temperature is kept at -20°C, and electronics are used to control the speed of the knife and the thickness of the sections. Some models can be set up to make a series of sections automatically.

Dissection of rat brains

INTRODUCTIONIn this protocol, the perfused brain of a rat is separated from the surrounding tissue and post-fixed in a formalin/sucrose solution in preparation for freezing and sectioning. Dissection should be done as soon as possible after perfusion to prevent desiccation of the brain. This procedure can also be used to dissect fresh (non-perfused) brains, for example, for Golgi-Cox stain or neurochemical assays.

Testing spatial and nonspatial learning using a morris water maze

INTRODUCTIONAnimal studies of memory have used many different types of mazes and tasks, where the animal is required to learn the demands of the test and then perform correctly until a predetermined performance criterion is reached. Traditional studies have relied on water or food deprivation to motivate the animal to do the test using food or water rewards. In 1984, Richard Morris introduced the water maze. The maze consists of a large cylindrical tank of water with a hidden platform; the animal has to swim until it finds the platform. The animal generally uses cues outside the maze (extramaze cues) to develop a spatial map of the environment and guide its performance. This maze avoids the problems associated with food or water deprivation, because the animal's goal is to find the hidden platform so that it can stop swimming. Many types of memory can be studied by varying the visual cues, the placement of the platform, and the starting point of the animal. This protocol describes the use of the water maze to test rats in two behavioral tasks: a spatial task and a nonspatial, visual task.

Observational methods used to assess rat behavior: general principles

INTRODUCTIONThe behavioral approach to solving neuroscience questions, unlike cellular and molecular approaches, is difficult to define and is therefore sometimes considered a less-disciplined approach. Methods describing behavioral procedures are often thought to be crude when compared to the precision of physiological or molecular methods. This apparent lack of precision results from the problems inherent in the study of behavior--deciding what to measure among the large number of variables, understanding that behavior is the final output of a vast array of neurochemical and electrophysiological changes, designing reproducible experiments that have appropriate controls, and most importantly, interpreting results. Conflicting results from similar protocols have led to prolonged debates and controversies in interpretation of behavioral data; therefore, it is necessary to strive for a high degree of precision through the cultivation of excellent handling and observational skills and thorough documentation strategies. This article is an introduction to several methods used to measure and assess normal behavior in a rat, including suggestions about how to make objective behavioral observations. Behavioral tests can be used to establish a "behavioral baseline" for a normal animal, to assess the effects of drugs or a lesion on behavior, and to determine whether transgenic animals have a normal behavioral repertoire. It should be kept in mind that, along with the intended effect, experimental manipulations often have unintended side effects, and behavioral tests can also be used to determine some of the less obvious changes.

Observational methods used to assess rat behavior: behavioral patterns

INTRODUCTIONThis protocol describes a method for quantifying observation of normal rat behaviors in a controlled environment and in a defined area. It is necessary to have precise definitions of the behaviors to be quantified and a reliable procedure for quantifying them. The observation room should be quiet, and it should be equipped for light or dark observations (rats cannot see red light so dark observations can be made using a red light). Ideally, the observer should be separated from the animal by a one-way screen. If such a screen is not available, the observer should stand or sit in a constant, unobtrusive position and make as few movements as possible.

Observational methods used to assess rat behavior: neurological testing

INTRODUCTIONThe rat is the most frequently used animal for behavioral experiments, and several methods can be used to assess behavioral changes that result from modifications to its nervous system. Objective neurological tests can be used to establish a "behavioral baseline" for a normal animal, and to study the effects of drugs or a lesion on behavior. Neurological tests should be administered much like a doctor would administer a battery of tests after a trauma, with objective observation, precise documentation, and repeated measurements by the same experimenter. This protocol outlines a series of neurological tests designed to assess reflex movements in the rat. Male or female rats may be used, although data should be analyzed separately to determine if sex differences exist.

Observational methods used to assess rat behavior: general activity

INTRODUCTIONThe activity-inactivity continuum is an important parameter of behavior, and quantification of overall locomotor activity in the rat should identify it as a naturally nocturnal animal. Disruptions in nocturnal activity can be caused by damage in visual inputs to the brain or damage in the hypothalamus. Many commercial devices are available to measure activity automatically; some can be integrated with a computer to allow overnight monitoring in the absence of an observer. A less sophisticated but still accurate method of measuring activity is to create a home-made activity chamber by replacing the bottom of a box with Plexiglas or by marking lines on the bottom of a clean rat cage so that the observer can record rat activity by noting when the lines are crossed, while simultaneously recording other behaviors. Activity in rat pups can be observed as soon as they are 10 days old using smaller activity chambers. This protocol describes the construction of a home-made activity chamber and how to measure four activities: locomotion, rearing, circling, and grooming.

Behavioral and anatomical abnormalities in Mecp2 mutant mice: a model for Rett syndrome

Over 90% of Rett syndrome (RTT) cases have a mutation in the X-linked gene encoding methyl CpG binding-protein 2 (MeCP2). A mouse model that reprises clinical manifestations of the disease would be valuable for examining disease mechanisms. Here, we characterize physical and behavioral measures, as well as brain region volumes in young adult mice that have mutations in mouse methyl CpG binding-protein 2 gene (Mecp2) to serve as a baseline for other studies. Hemizygous males, which produce no functional protein, exhibit hypoactivity and abnormalities in locomotion, stereotypies, and anxiety reminiscent of the clinical condition. The mutant males also exhibit cognitive deficits in fear conditioning and object recognition relative to wildtypes. Volumetric analyses of male brains revealed a 25% reduction in whole brain volume in mutants relative to wildtypes; regional differences were also apparent. Mutants had decreased volumes in three specific brain regions: the amygdala (39%), hippocampus (21%), and striatum (29%). Heterozygous females, which produce varying amounts of functional protein, displayed a less severe behavioral phenotype. The mutant females exhibit abnormalities in locomotion, anxiety measures, and cognitive deficits in object recognition in an open field. This study provides the first evidence that the abnormal motor and cognitive behavioral phenotype in Mecp2 mice is consistent with specific volume reductions in brain regions associated with these behaviors, and shows how these data parallel the human condition. The Mecp2 mutant mice provide a very good model in which to examine molecular and behavioral mechanisms, as well as potential therapeutic interventions in RTT.

An altered neonatal behavioral phenotype in Mecp2 mutant mice

We examined somatic growth, somatosensory reflexes, and ultrasonic calls from postnatal day 3 to day 18 in Mecp2 mutant mice, a mouse model of Rett syndrome. Both Mecp2 null male and Mecp2 heterozygous female mice exhibited normal somatic growth, but transient delays in the development of some reflexes relative to sex-matched wild-type mice. Both Mecp2 null male and heterozygous female mice exhibited dramatic increases in ultrasonic vocalizations in response to social isolation; these differences were evident as early as postnatal day 5. These results suggest very early abnormalities in sensory reflex development and behavioral responsiveness in the Mecp2 mutants that may provide a target for early therapeutic intervention.

Reduced extinction of hippocampal-dependent memories in CPEB knockout mice

CPEB is a sequence-specific RNA binding protein that regulates translation at synapses. In neurons of CPEB knockout mice, synaptic efficacy is reduced. Here, we have performed a battery of behavioral tests and find that relative to wild-type animals, CPEB knockout mice, although similar on many baseline behaviors, have reduced extinction of memories on two hippocampal-dependent tasks. A corresponding microarray analysis reveals that about 0.14% of hippocampal genes have an altered expression in the CPEB knockout mouse. These data suggest that CPEB-dependent local protein synthesis may be an important cellular mechanism underlying extinction of hippocampal-dependent memories.

Neurogenesis of the cholinergic medial septum in female and male C57BL/6J mice

Sex differences exist in the structure and function of the cholinergic septo-hippocampal system throughout the lifespan of mammals. How and when these sex differences originate is unclear. Because estrogen modulates sexual differentiation of several brain regions during development and influences neurogenesis in adult mammals, we hypothesized that sexual dimorphism of the cholinergic septo-hippocampal system would extend to its neurogenesis. A birthdating agent 5'-bromo-2'-deoxyuridine (BrdU) was injected into pregnant dams on one of eight gestational days, ranging from embryonic day (E)10 to E17. The offspring were euthanized at 2 months of age, and brains were processed for BrdU and choline acetyltransferase (ChAT) immunoreactivity to label cholinergic neurons that became postmitotic on a given embryonic day and survived to adulthood. Unbiased stereology was used to compare the number of double-labeled neurons in the medial septum (MS) of female and male offspring. Cholinergic neurons in the MS were generated primarily between E11 and E14, similar to other published reports. We found sex differences in the pattern of peak neurogenesis but not in the length of neurogenesis, or in total number of neurons generated in the MS. Additionally, in adult female and male mice, we estimated the total number of cholinergic neurons using unbiased stereology and found no sex differences in the number of cholinergic neurons or in the volume of the MS in adulthood. These results suggest that sex differences noted in the function of the postnatal cholinergic septo-hippocampal system may originate from its neurogenesis.

Gene knockout of glycine transporter 1: characterization of the behavioral phenotype

N-methyl-d-aspartate receptor (NMDAR) activation requires both the binding of glutamate to its recognition site and occupancy of the strychnine insensitive glycine modulatory site (GMS). Pharmacological studies suggest that the glycine transporter, GlyT1, maintains subsaturating concentrations of glycine at synaptic NMDARs. To characterize further the role of GlyT1, we generated mice in which the gene encoding GlyT1 was inactivated by homologous recombination through insertion of a PGK-Neo cassette in place of exons 2 and 3. Real-time quantitative PCR revealed no transcripts in newborn homozygous [GlyT1(-/-)] mice and a 50% reduction in heterozygous (HZ) [GlyT1(+/-)] mice as compared with WT littermates. The activity of Na(+)-dependent glycine transport in forebrain homogenates was similarly affected. Homozygous mice died within 12 h of birth. In acute hippocampal slices, exogenous glycine or d-serine (10 microM) enhanced NMDAR currents with Schaffer collateral stimulation in WT mice but not HZ mice, suggesting that the GMS was more occupied in the latter. The NMDAR/alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid receptor ratio of the excitatory postsynaptic currents was significantly increased in the HZ mice. In the water maze, the HZ mice exhibited better spatial retention. Furthermore, HZ mice were less sensitive to an amphetamine disruption of prepulse inhibition than WT mice but were more sensitive to the effects of MK-801. Thus, reduced expression of GlyT1 enhances hippocampal NMDAR function and memory retention and protects against an amphetamine disruption of sensory gating, suggesting that drugs which inhibit GlyT1 might have both cognitive enhancing and antipsychotic effects.

The cholinergic basal forebrain system during development and its influence on cognitive processes: important questions and potential answers

This review seeks to address, though perhaps not answer fully, four important questions about the cholinergic basal forebrain (BF) system in developing mammals. First, what role does the cholinergic basal forebrain system play in the development of cognitive functions? Second, does the cholinergic BF system play a fundamentally similar role in development vs. adulthood? Third, does sexual dimorphism of the developing cholinergic BF system influence cognition differently in the two sexes? Finally, what role does the developing cholinergic BF system play in developmental disorders such as Down syndrome and Rett syndrome? Examples from the literature, primarily studies in mice and rats, are given in an attempt to answer these important questions.

Effects of environmental enrichment on spatial memory and neurochemistry in middle-aged mice

The present study compared the effects of environmental enrichment on spatial memory, glutamic acid decarboxylase (GAD) activity, and synaptophysin levels in middle-aged male and female mice. Prior to testing, a subset of 18-month-old male and female C57BL/6 mice was housed with two to three toys and a running wheel in the home cage for up to 29 d. Adult mice (7 mo) of both sexes and the remaining middle-aged mice were group (social) housed, but not exposed to enriching objects. After the enrichment period, all mice were tested in a 1-day version of the Morris water maze, in which both spatial and nonspatial memory were assessed. Immediately after testing, the hippocampus and frontoparietal cortex were dissected, and GAD activity and synaptophysin levels were measured. Environmental enrichment reduced the age-related impairment in spatial acquisition and retention; relative to adult social controls, middle-aged enriched mice were unimpaired, whereas middle-aged social controls were impaired. This reduction was similar in middle-aged males and females. Enrichment did not affect cued memory in either sex. Although hippocampal GAD activity was increased by enrichment in males, all other neurochemical measurements were unaffected by enrichment or aging in either sex. These data suggest that environmental enrichment initiated at middle age can reduce age-related impairments in spatial memory in males and females, although the underlying neurobiological mechanisms of this effect remain unknown.

Animal models of mental retardation: from gene to cognitive function

About 2-3% of all children are affected by mental retardation, and genetic conditions rank among the leading causes of mental retardation. Alterations in the information encoded by genes that regulate critical steps of brain development can disrupt the normal course of development, and have profound consequences on mental processes. Genetically modified mouse models have helped to elucidate the contribution of specific gene alterations and gene-environment interactions to the phenotype of several forms of mental retardation. Mouse models of several neurodevelopmental pathologies, such as Down and Rett syndromes and X-linked forms of mental retardation, have been developed. Because behavior is the ultimate output of brain, behavioral phenotyping of these models provides functional information that may not be detectable using molecular, cellular or histological evaluations. In particular, the study of ontogeny of behavior is recommended in mouse models of disorders having a developmental onset. Identifying the role of specific genes in neuropathologies provides a framework in which to understand key stages of human brain development, and provides a target for potential therapeutic intervention.

Early neonatal 192 IgG saporin induces learning impairments and disrupts cortical morphogenesis in rats

We have shown previously that neonatal intraventricular injections of the selective cholinergic immunotoxin 192 IgG saporin on postnatal day 7 (pnd 7) induce marked cholinergic loss in hippocampus and neocortex and a learning impairment on pnd 15. In the present study, we analysed the behavioural, morphological and neurochemical effects of earlier intraventricular injection of the immunotoxin 192 IgG saporin (pnd 1 and 3). We hypothesised that these earlier lesions would interrupt a critical stage in neocortical maturation, and impair behavior more profoundly than the later lesions. Passive avoidance (PA) learning and locomotor activity during the PA test were assessed on pnd 15. Retention of the PA task was assessed on pnd 16. Reactivity to spatial and object novelty was assessed on pnd 180 in a spatial open field test with five objects. Choline acetyltransferase (ChAT) activity was measured in basal forebrain targets on pnd 20 and pnd 180. Neonatal administration of 192 IgG saporin resulted in a slower acquisition of the PA task in females; retention and locomotor activity were not affected. On pnd 180, reaction to spatial novelty was mildly impaired in lesioned rats of both sexes. There was a marked reduction of ChAT in the hippocampus and neocortex of lesioned rats of both sexes, at both ages. Morphological analysis of the somatosensory cortex of lesioned rats revealed alterations in cortical development with sex specific variations in total cortical thickness. These results suggest that interrupting cholinergic basal forebrain innervation of neocortex and hippocampus during the first postnatal days affects the development of cognitive behaviour, neurochemistry and cortical organisation in a sex specific manner. Furthermore, the alterations in cortical organization are more profound than those noted after a lesion later in postnatal development. These behavioural and morphological abnormalities could be considered a model for several neurodevelopmental disorders associated with mental retardation.

Sex differences in neurochemical markers that correlate with behavior in aging mice

Sex differences in neurochemical markers that correlate with behavior in aging mice NEUROBIOL AGING. We examined whether the enzymatic activities of choline acetyltransferase (ChAT) and glutamic acid decarboxylase (GAD) were altered similarly with age in male and female mice, and whether these changes were correlated with age-related alterations in memory and anxiety. ChAT and GAD activities were measured in neocortex, hippocampus, and striatum of behaviorally characterized male and female C57BL/6 mice (5, 17, and 25 months). Generally, ChAT activity was increased, and GAD activity decreased, with age. However, disparate changes were revealed between the sexes; activities of both enzymes were decreased in 17-month males, whereas alterations in females were not observed until 25-months. Furthermore, enzyme-behavior correlations differed between the sexes; in males, ChAT activity was related to one behavioral task, whereas in females, activities of both enzymes were correlated with multiple tasks. Significant enzyme-behavior correlations were most evident at 17 months of age, likely the result of behavioral and enzymatic sex differences at this age. These data represent the first comprehensive report illustrating differential alterations of ChAT and GAD activities in aging male and female mice.

Selective immunolesions of cholinergic neurons in mice: effects on neuroanatomy, neurochemistry, and behavior

The ability to selectively lesion mouse basal forebrain cholinergic neurons would permit experimental examination of interactions between cholinergic functional loss and genetic factors associated with neurodegenerative disease. We developed a selective toxin for mouse basal forebrain cholinergic neurons by conjugating saporin (SAP), a ribosome-inactivating protein, to a rat monoclonal antibody against the mouse p75 nerve growth factor (NGF) receptor (anti-murine-p75). The toxin proved effective and selective in vitro and in vivo. Intracerebroventricular injections of anti-murine-p75-SAP produced a dose-dependent loss of choline acetyltransferase (ChAT) activity in the hippocampus and neocortex without affecting glutamic acid decarboxylase (GAD) activity. Hippocampal ChAT depletions induced by the immunotoxin were consistently greater than neocortical depletions. Immunohistochemical analysis revealed a dose-dependent loss of cholinergic neurons in the medial septum (MS) but no marked loss of cholinergic neurons in the nucleus basalis magnocellularis after intracerebroventricular injection of the toxin. No loss of noncholinergic neurons in the MS was apparent, nor could we detect loss of noncholinergic cerebellar Purkinje cells, which also express p75. Behavioral analysis suggested a spatial learning deficit in anti-murine-p75-SAP-lesioned mice, based on a correlation between a loss of hippocampal ChAT activity and impairment in Morris water maze performance. Our results indicate that we have developed a specific cholinergic immunotoxin for mice. They also suggest possible functional differences in the mouse and rat cholinergic systems, which may be of particular significance in attempts to develop animal models of human diseases, such as Alzheimer's disease, which are associated with impaired cholinergic function.

Neonatal 5,7-DHT lesions cause sex-specific changes in mouse cortical morphogenesis

Both monoaminergic and cholinergic afferent projections to the neocortex putatively modulate cortical morphogenesis and plasticity. Previously we showed that neonatal electrolytic lesions of the cholinergic nucleus basalis magnocellularis (nBM) projections to the neocortex result in significant decreases of cortical layer width that correlate with cognitive alterations. Such electrolytic lesions, performed for lack of a selective neurotoxin in mice, may affect mono-aminergic fibers of passage. Here, we investigate the effects of neonatal 5,7 dihydroxytryptamine (5,7-DHT) focal injections into the nBM region on cortical laminar morphology in adult male and female mice. 5,7-DHT lesions on the first postnatal day resulted in significant cortical depletion of both serotonin and norepinephrine that attenuated with age. Generally, cortical layer widths increased in response to the lesion; the effects were layer, region, and sex specific. Previous reports from our laboratories described long-term behavioral alterations after comparable focal, neonatal 5,7-DHT lesions. The studies described here provide an anatomical basis for such behavioral alterations. Our data suggest that monoaminergic and cholinergic projections to the cortex may have opposite effects on the developing cortical neuropil. Jointly, our morphological and behavioral findings may have important implications for a variety of developmental disorders in humans and provide some insights into sex differences in the penetrance of these disorders.

Cholinergic basal forebrain is critical for social transmission of food preferences

Studies using selective lesions of basal forebrain cholinergic neurons suggest that these neurons play a role in attentional processing, but not learning and memory. However, the tests of learning and memory used thus far have been restricted largely to spatial tasks. In the present study, we examined whether the cholinergic basal forebrain plays a role in a form of nonspatial associative memory, the social transmission of food preferences. Sham-operated control rats were compared to rats with 192 IgG-saporin lesions of the medial septum/diagonal band cholinergic projections to hippocampus or nucleus basalis magnocellularis/substantia innominata cholinergic projections to neocortex. Both lesions impaired 24-h retention of a learned social food preference relative to controls, despite performance on an immediate retention trial that was indistinguishable from controls. Moreover, 24-h retention of the socially learned food preference correlated strongly with cholinergic enzymatic activity in the neocortex, but not in the hippocampus. Immunohistochemical data confirmed significant and selective lesion-induced cholinergic depletions in the intended brain regions. These data provide evidence that the cholinergic basal forebrain, particularly the cholinergic projection to neocortex, is involved in the formation and/or retrieval of social memories related to food preference, and suggest a role for cortical acetylcholine in consolidation of associative memory processes.

Spatial reference memory and neocortical neurochemistry vary with the estrous cycle in C57BL/6 mice

Estrous cycle-related variations of spatial reference memory and neurochemistry in intact female mice were examined. Spatial reference memory was tested in cycling females, ovariectomized (OVX) females, and males by using a 1-day water maze protocol. Choline acetyltransferase (ChAT) and glutamic acid decarboxylase (GAD) activities were measured in the hippocampus and neocortex. Estrus females exhibited worse spatial acquisition and 30-min retention than did proestrus and metestrus females, higher neocortical ChAT activity than proestrus females, and higher neocortical GAD activity than OVX females and males. Neocortical, rather than hippocampal, neurochemistry was more sensitive to hormonal modulation, suggesting that hormonal mediation of neocortical function may play a critical role in regulating spatial reference memory in female mice.

Mice are not little rats: species differences in a one-day water maze task

The present study examined species differences in spatial and non-spatial memory in the Morris water maze. Male Wistar rats and C57BL/6 mice were tested in a one-day water maze task in which spatial learning, retention, and non-spatial learning were assessed within 3 h. Rats and mice appeared to use different strategies for locating the hidden escape platform. Whereas rats evinced a clear spatial strategy, mice appeared to rely less on spatial cues and more on alternative non-spatial strategies. The sensitivity of this behavioral protocol to subtle species differences highlights the potential use of this one-day water maze task as a tool for evaluating rapidly learning and memory in rodents.

Neonatal 192 IgG-saporin lesions of basal forebrain cholinergic neurons selectively impair response to spatial novelty in adult rats

The role of the developing cholinergic basal forebrain system on cognitive behaviors was examined in 7 day-old rats by giving lesions with intraventricular injections of 192 IgG-saporin or saline. Rats were subjected to passive avoidance on postnatal days (PND) 22-23, water maze testing on PND 50-60, and a open-field test (in which reactions to spatial and object novelty were measured) on PND 54. Behavioral effects of the lesions were evident only in the open-field test with 5 objects. Unlike controls, the lesioned rats did not detect a spatial change after a displacement of 2 of the 5 objects. Control and lesioned rats, however, showed comparable novelty responses to an unfamiliar object. Lesion effectiveness was confirmed by 75% and 84% decreases in choline acetyltransferase activity in cortex and hippocampus. These results suggest that the developing cholinergic system may be involved in spatial information processing or attention to spatial modifications.

Reference memory, anxiety and estrous cyclicity in C57BL/6NIA mice are affected by age and sex

Age-related changes in learning and memory are common in rodents. However, direct comparisons of the effects of aging on learning and memory in both males and females are lacking. The present study examined whether memory deteriorates with increasing age in C57BL/6NIA mice, and whether age-related changes in learning and memory are similar in both sexes. Male and female mice (five, 17 and 25 months of age) were tested in a battery of behavioral tasks including the Morris water maze (spatial and non-spatial reference memory), simple odor discrimination (olfactory reference memory), plus maze (anxiety/exploration), locomotor activity, and basic reflexes. Five-month-old mice learned the water maze and odor discrimination tasks rapidly. Relative to five-month-old mice, 25-month-old mice exhibited impaired spatial and olfactory reference memory, but intact non-spatial reference memory. The spatial reference memory of 17-month-old mice was also impaired, but less so than 25-month mice. Seventeen-month-old mice exhibited intact non-spatial (visual and olfactory) reference memory. Five and 25-month-old mice had similar levels of plus maze exploration and locomotor activity, whereas 17-month-old mice were more active than both groups and were slightly less exploratory than five-month-old mice. Although sex differences were not observed in the five- and 25-month groups, 17-month-old females exhibited more impaired spatial reference memory and increased anxiety relative to 17-month-old males. Estrous cycling in females deteriorated significantly with increased age; all 25-month-old females had ceased cycling and 80% of 17-month-old females displayed either irregular or absent estrous cycling. This study is the first to directly compare age-related mnemonic decline in male and female mice. The results suggest that: (i) aged mice exhibit significant deficits in spatial and olfactory reference memory relative to young mice, whereas middle-aged mice exhibit only a moderate spatial memory deficit and; (ii) spatial reference memory decline begins at an earlier age in females than in males, a finding that may be related to the cessation of estrous cycling.

Neonatal 192 IgG-saporin lesions of basal forebrain cholinergic neurons selectively impair response to spatial novelty in adult rats

The role of the developing cholinergic basal forebrain system on cognitive behaviors was examined in 7 day-old rats by giving lesions with intraventricular injections of 192 IgG-saporin or saline. Rats were subjected to passive avoidance on postnatal days (PND) 22-23, water maze testing on PND 50-60, and a open-field test (in which reactions to spatial and object novelty were measured) on PND 54. Behavioral effects of the lesions were evident only in the open-field test with 5 objects. Unlike controls, the lesioned rats did not detect a spatial change after a displacement of 2 of the 5 objects. Control and lesioned rats, however, showed comparable novelty responses to an unfamiliar object. Lesion effectiveness was confirmed by 75% and 84% decreases in choline acetyltransferase activity in cortex and hippocampus. These results suggest that the developing cholinergic system may be involved in spatial information processing or attention to spatial modifications.

Impairments in learning and memory accompanied by neurodegeneration in mice transgenic for the carboxyl-terminus of the amyloid precursor protein

In Alzheimer's disease (AD), a progressive decline of cognitive functions is accompanied by neuropathology that includes the degeneration of neurons and the deposition of amyloid in plaques and in the cerebrovasculature. We have proposed that a fragment of the Alzheimer amyloid precursor protein (APP) comprising the carboxyl-terminal 100 amino acids of this molecule (APP-C100) plays a crucial role in the neurodegeneration and subsequent cognitive decline in AD. To test this hypothesis, we performed behavioral analyses on transgenic mice expressing APP-C100 in the brain. The results revealed that homozygous APP-C100 transgenic mice were significantly impaired in cued, spatial and reversal performance of a Morris water maze task, that the degree of the impairment in the spatial learning was age-dependent, and that the homozygous mice displayed significantly more degeneration of neurons in Ammon's horn of the hippocampal formation than did heterozygous or control mice. Among the heterozygotes, females were relatively more impaired in their spatial learning than were males. These findings show that expression of APP-C100 in the brain can cause age-dependent cognitive impairments that are accompanied by hippocampal degeneration.

Sexually dimorphic responses to neonatal basal forebrain lesions in mice: II. Cortical morphology

Previous studies in the mouse have shown that neonatal lesions to the cholinergic basal forebrain (nBM) areas result in transient cholinergic depletion of neocortex and precipitate altered cortical morphogenesis. Lesion-induced morphological alterations in cortex persist into adulthood and are accompanied by behavioral changes, including spatial memory deficits. The current study investigated whether neonatal nBM lesions affect male and female mice differently in adulthood. Quantitative morphometry of cortical layer width was employed to assess alterations in cytoarchitecture in neonatally nBM-lesioned and littermate control mice of both sexes following behavioral testing. Our results showed significant decreases in cortical layer IV and V widths across somato/motor cortex in neonatally nBM lesioned mice of both sexes. Sexually dimorphic responses were observed in cortical layer II/III and total cortical width, limited to the area containing the "barrel cortex" representation of the whisker hairs. In lesioned females, layer II/III and total cortical width were decreased relative to female controls, and in lesioned males, layer II/III was increased relative to controls, whereas total cortical width was unchanged. In male but not female mice we observed significant correlations between decreased widths in layer IV and V and impaired performance on a spatial memory task. The current data further support a role of developing cholinergic cortical afferents in the modulation of cortical morphogenesis and cortical circuits involved in cognitive behaviors. In addition, our observations provide further evidence for sexually dimorphic development and function in cognitive centers of the rodent brain.

Sexually dimorphic responses to neonatal basal forebrain lesions in mice: I. Behavior and neurochemistry

The nucleus basalis magnocellularis (nBM) provides the primary source of cholinergic input to the cortex. Neonatal lesions of the nBM produce transient reductions in cholinergic markers, persistent abnormalities in cortical morphology, and spatial navigation impairments in adult mice. The present study examined sex differences in the effects of an electrolytic nBM lesion on postnatal day 1 (PND 1) in mice on behavior and neurochemistry in adulthood. Mice were lesioned on PND 1 and tested at 8 weeks of age on a battery of behavioral tests including passive avoidance, cued and spatial tasks in the Morris water maze, simple and delayed nonmatch to sample versions of an odor discrimination task, and locomotor activity measurements. Following behavioral testing, mice were sacrificed for either morphological assessment or neurochemical analysis of a cholinergic marker or catecholamines. There were no lesion or sex differences in acquisition or retention of passive avoidance, performance of the odor discrimination tasks, or activity levels. Control mice showed a robust sex difference in performance of the spatial water maze task. The lesion produced a slight cued but more dramatic spatial navigation deficit in the water maze which affected only the male mice. Neurochemical analyses revealed no lesion-induced changes in either choline acetyltransferase activity or levels of norepinephrine or serotonin at the time of testing. The subsequent report shows a sex difference in lesion-induced changes in cortical morphology which suggests that sexually dimorphic cholinergic influences on cortical development are responsible for the behavioral deficits seen in this study.

Postnatal choline supplementation in preweanling mice: sexually dimorphic behavioral and neurochemical effects

The aim of this study was to investigate the effects of postnatal choline supplementation on neurochemical and behavioral parameters in preweanling BALB/cByJ mice. Mouse pups were injected daily subcutaneously with choline chloride (0.85 mM/g body weight) from Postnatal Day (PND) 1 to PND 16. Pups performed a passive avoidance (PA) learning task on PND 17-18 and a 30-min locomotor activity test on PND 19. The choline treatment affected retention of the PA task on PND 18. The treatment also increased locomotor activity in females, but not in males, on PND 19. Choline acetyltransferase (ChAT) enzymatic activity was measured on PND 20 and revealed that choline administration in the first 2 weeks of postnatal life selectively affects male pups. Choline's effect, as seen in previous rat experiments, was to decrease ChAT activity in the hippocampal region.

Neonatal monoaminergic depletion in mice (Mus musculus) improves performance of a novel odor discrimination task

This experiment examined behavior and neurochemistry in adult mice (Mus musculus) after neonatal depletion of monoaminergic fibers projecting to the neocortex and hippocampus. Lesions were made on Postnatal Day 1; mice developed to adulthood and were assessed on simple odor discrimination (SOD) and odor delayed nonmatch-to-sample (DNMS) tasks, passive avoidance (PA), and locomotor activity. On SOD, lesioned mice performed faster than controls but with similar accuracy. On the DNMS task, the lesioned mice performed faster and more accurately than controls. On PA, the lesioned mice exhibited a retention deficit relative to controls. Locomotor activity was similar in the 2 groups. Postmortem analyses revealed that the lesions reduced significantly norepinephrine and serotonin levels in both the neocortex and hippocampus. The data suggest that cortically projecting monoaminergic fibers play an important role in normal cognitive development.

The effects of neonatal basal forebrain lesions on cognition: towards understanding the developmental role of the cholinergic basal forebrain

Abnormal development of the cholinergic basal forebrain has been implicated in numerous developmental disabilities such as Rett Syndrome and Down Syndrome. This review summarizes recent data using two rodent animal models that involve interrupting cholinergic basal forebrain projections on postnatal day 1 and postnatal day 7 when basal forebrain fibers are beginning to innervate their neocortical and hippocampal targets, respectively. In one model, electrolytic lesions in mice aimed at the basal forebrain on postnatal day 1 transiently reduce cholinergic markers in neocortex which induce permanent alterations in neocortical anatomy that correlate with impairments on cognitive tasks. Furthermore, the lesion effects are sex dependent. In another model, 192 IgG saporin lesions in rats on postnatal day 7 permanently reduce cholinergic markers in neocortex and hippocampus, and result in mild impairments in spatial processing, acquisition and exploratory activities. These data suggest that during the first postnatal week of development the cholinergic basal forebrain system is critical for normal neocortical differentiation and, possibly synaptogenesis in neural circuits that will be important for spatial memory and acquisition of spatial data. During the second postnatal week of development, the cholinergic basal forebrain system appears to take on a role largely similar to its adult role in selective attention and processing of new information. These studies also suggest strongly that interrupting cholinergic basal forebrain innervation of neocortex and hippocampus leads to anatomical and neurochemical abnormalities that may serve as neural substrates for some of the cognitive deficits seen in disorders such as Rett Syndrome and Down Syndrome.

Cholinergic regulation of cortical development and plasticity. New twists to an old story

Cholinergic afferents innervate cerebral cortex during the most dynamic period of neuronal differentiation and synapse formation, suggesting they play a possible regulatory role in these events. A number of in vivo studies have shown over the last decade that alterations in cholinergic innervation during early postnatal development can change various features of cortical ontogeny. In particular, neonatal lesions to basal forebrain cholinergic afferents result in delayed cortical neuronal development and permanently altered cortical cytoarchitecture and cognitive behaviors. Likewise, cholinergic manipulations affect morphological plasticity in cat visual cortex as well as in the somatosensory cortex of rodents. Furthermore, augmentation of cholinergic function by means of perinatal choline treatment enhances cognitive performance in a sex specific manner. Additional indications for a sexual dimorphism in cortical cholinergic innervation and resulting function are gathered from a variety of paradigms. Recent information about effects of NGF, BDNF and NTB-4/5 on cortical morphogenesis and plasticity reveals complex interactions between the cholinergic basal forebrain afferents and this neurotrophin family. Detailed studies on the expression of cholinergic receptor proteins in cortical development and their associated signal transduction pathways strongly point towards a morphogenetic function of muscarinic receptors, in particular. Transient receptor localization in thalamocortical terminal fields and on a variety of other non-cholinergic fiber bundles suggest a cholinergic role in target finding and/or synapse formation for cortical afferents and efferents. We propose a hypothesis regarding the mechanisms for cholinergic regulation of neuronal differentiation and synapse formation on the level of the individual growth cone and discuss possibilities for cholinergic interactions with differential gene expression. We conclude that understanding the precise role of the cholinergic system in cortical morphogenesis and its relationship to neurotrophin function will be of clinical relevance for a number of developmental brain disorders, including Down Syndrome and Rett Syndrome.

Different effects of postnatal day 1 versus 7 192 immunoglobulin G-saporin lesions on learning, exploratory behaviors, and neurochemistry in juvenile rats

Passive avoidance learning and retention, as well as locomotor and exploratory behaviors, were assessed in rats after intraventricular 192 immunoglobulin G-saporin injections on either Postnatal Day 1 (PND1) or PND7. PND1-lesioned rats were not significantly impaired on acquisition or retention of passive avoidance. PND7-lesioned rats acquired the task slower than controls, but retention was not affected. PND7-lesioned rats were less exploratory than controls and showed reduced wall rearing. Histological analysis of PND1- and PND7-lesioned rats revealed no neuronal degeneration in hippocampus or cortex. There was a marked reduction of choline acetyltransferase (ChAT) activity in the hippocampus, cortex, and septum in the PND7-lesioned rats and a slight but significant ChAT depletion in the cortex of PND1-lesioned rats. These data suggest that the cholinergic system is critical for the learning of passive avoidance and exploratory behaviors in the developing rat.

Sexually dimorphic effects of anti-NGF treatment in neonatal rats

This study investigated how chronic perinatal reduction of nerve growth factor (NGF) affected brain cholinergic markers in the two sexes. Rats received anti-NGF on postnatal days (PNDs) 2-12, and choline acetyltransferase (ChAT) activity was measured on PND 16. Anti-NGF significantly reduced cortical ChAT activity in males, but not in females; no sex-dependent effects were found in hippocampus or striatum. These data suggest sexual dimorphism in cholinergic responsiveness to NGF.