Charles V. Vorhees

Morris water maze: procedures for assessing spatial and related forms of learning and memory.

The Morris water maze (MWM) is a test of spatial learning for rodents that relies on distal cues to navigate from start locations around the perimeter of an open swimming arena to locate a submerged escape platform. Spatial learning is assessed across repeated trials and reference memory is determined by preference for the platform area when the platform is absent. Reversal and shift trials enhance the detection of spatial impairments. Trial-dependent, latent and discrimination learning can be assessed using modifications of the basic protocol. Search-to-platform area determines the degree of reliance on spatial versus non-spatial strategies. Cued trials determine whether performance factors that are unrelated to place learning are present. Escape from water is relatively immune from activity or body mass differences, making it ideal for many experimental models. The MWM has proven to be a robust and reliable test that is strongly correlated with hippocampal synaptic plasticity and NMDA receptor function. We present protocols for performing variants of the MWM test, from which results can be obtained from individual animals in as few as 6 days.

Hypoxia-ischemia induces DNA synthesis without cell proliferation in dying neurons in adult rodent brain

Recent studies suggest that postmitotic neurons can reenter the cell cycle as a prelude to apoptosis after brain injury. However, most dying neurons do not pass the G1/S-phase checkpoint to resume DNA synthesis. The specific factors that trigger abortive DNA synthesis are not characterized. Here we show that the combination of hypoxia and ischemia induces adult rodent neurons to resume DNA synthesis as indicated by incorporation of bromodeoxyuridine (BrdU) and expression of G1/S-phase cell cycle transition markers. After hypoxia-ischemia, the majority of BrdU- and neuronal nuclei (NeuN)-immunoreactive cells are also terminal deoxynucleotidyl transferase-mediated biotinylated UTP nick end labeling (TUNEL)-stained, suggesting that they undergo apoptosis. BrdU+ neurons, labeled shortly after hypoxia-ischemia, persist for >5 d but eventually disappear by 28 d. Before disappearing, these BrdU+/NeuN+/TUNEL+ neurons express the proliferating cell marker Ki67, lose the G1-phase cyclin-dependent kinase (CDK) inhibitors p16INK4 and p27Kip1 and show induction of the late G1/S-phase CDK2 activity and phosphorylation of the retinoblastoma protein. This contrasts to kainic acid excitotoxicity and traumatic brain injury, which produce TUNEL-positive neurons without evidence of DNA synthesis or G1/S-phase cell cycle transition. These findings suggest that hypoxia-ischemia triggers neurons to reenter the cell cycle and resume apoptosis-associated DNA synthesis in brain. Our data also suggest that the demonstration of neurogenesis after brain injury requires not only BrdU uptake and mature neuronal markers but also evidence showing absence of apoptotic markers. Manipulating the aberrant apoptosis-associated DNA synthesis that occurs with hypoxia-ischemia and perhaps neurodegenerative diseases could promote neuronal survival and neurogenesis.

Deficiency in Na,K-ATPase α Isoform Genes Alters Spatial Learning, Motor Activity, and Anxiety in Mice

Several disorders have been associated with mutations in Na,K-ATPase α isoforms (rapid-onset dystonia parkinsonism, familial hemiplegic migraine type-2), as well as reduction in Na,K-ATPase content (depression and Alzheimers disease), thereby raising the issue of whether haploinsufficiency or altered enzymatic function contribute to disease etiology. Three isoforms are expressed in the brain: the α1 isoform is found in many cell types, the α2 isoform is predominantly expressed in astrocytes, and the α3 isoform is exclusively expressed in neurons. Here we show that mice heterozygous for the α2 isoform display increased anxiety-related behavior, reduced locomotor activity, and impaired spatial learning in the Morris water maze. Mice heterozygous for the α3 isoform displayed spatial learning and memory deficits unrelated to differences in cued learning in the Morris maze, increased locomotor activity, an increased locomotor response to methamphetamine, and a 40% reduction in hippocampal NMDA receptor expression. In contrast, heterozygous α1 isoform mice showed increased locomotor response to methamphetamine and increased basal and stimulated corticosterone in plasma. The learning and memory deficits observed in the α2 and α3 heterozygous mice reveal the Na,K-ATPase to be an important factor in the functioning of pathways associated with spatial learning. The neurobehavioral changes seen in heterozygous mice suggest that these mouse models may be useful in future investigations of the associated human CNS disorders.

Targeted disruption of the murine Nhe1 locus induces ataxia, growth retardation, and seizures.

In most cells, the ubiquitously expressed Na+/H+exchanger isoform 1 (NHE1) is thought to be a primary regulator of pH homeostasis, cell volume regulation, and the proliferative response to growth factor stimulation. To study the function of NHE1 during embryogenesis when these cellular processes are very active, we targeted the Nhe1 gene by replacing the sequence encoding transmembrane domains 6 and 7 with the neomycin resistance gene. NHE activity assays on isolated acinar cells indicated that the targeted allele is functionally null. Although the absence of NHE1 is compatible with embryogenesis, Nhe1 homozygous mutants (-/-) exhibit a decreased rate of postnatal growth that is first evident at 2 wk of age. At this time, Nhe1 -/- animals also begin to exhibit ataxia and epileptic-like seizures. Approximately 67% of the -/- mutants die before weaning. Postmortem examinations frequently revealed an accumulation of a waxy particulate material inside the ears, around the eyes and chin, and on the ventral surface of the paws. Histological analysis of adult tissues revealed a thickening of the lamina propria and a slightly atrophic glandular mucosa in the stomach.

The effects of neonatal isoflurane exposure in mice on brain cell viability, adult behavior, learning, and memory.

BACKGROUND: Volatile anesthetics, such as isoflurane, are widely used in infants and neonates. Neurodegeneration and neurocognitive impairment after exposure to isoflurane, midazolam, and nitrous oxide in neonatal rats have raised concerns regarding the safety of pediatric anesthesia. In neonatal mice, prolonged isoflurane exposure triggers hypoglycemia, which could be responsible for the neurocognitive impairment. We examined the effects of neonatal isoflurane exposure and blood glucose on brain cell viability, spontaneous locomotor activity, as well as spatial learning and memory in mice. METHODS: Seven-day-old mice were randomly assigned to 6 h of 1.5% isoflurane with or without injections of dextrose or normal saline, or to 6 h of room air without injections (no anesthesia). Arterial blood gases and glucose were measured. After 2 h, 18 h, or 11 wk postexposure, cellular viability was assessed in brain sections stained with Fluoro-Jade B, caspase 3, or NeuN. Nine weeks postexposure, spontaneous locomotor activity was assessed, and spatial learning and memory were evaluated in the Morris water maze using hidden and reduced platform trials. RESULTS: Apoptotic cellular degeneration increased in several brain regions early after isoflurane exposure, compared with no anesthesia. Despite neonatal cell loss, however, adult neuronal density was unaltered in two brain regions significantly affected by the neonatal degeneration. In adulthood, spontaneous locomotor activity and spatial learning and memory performance were similar in all groups, regardless of neonatal isoflurane exposure. Neonatal isoflurane exposure led to an 18% mortality, and transiently increased Paco2, lactate, and base deficit, and decreased blood glucose levels. However, hypoglycemia did not seem responsible for the neurodegeneration, as dextrose supplementation failed to prevent neuronal loss. CONCLUSIONS: Prolonged isoflurane exposure in neonatal mice led to increased immediate brain cell degeneration, however, no significant reductions in adult neuronal density or deficits in spontaneous locomotion, spatial learning, or memory function were observed.

A developmental test battery for neurobehavioral toxicity in rats: a preliminary analysis using monosodium glutamate calcium carrageenan, and hydroxyurea.

Abstract A test battery for evaluating developmental neurobehavioral toxicity was designed to attempt to meet both the general requirements of a sound test system, namely, comprehensiveness, usability, and sensitivity and the specific requirements promulgated by Britain, France, and Japan as part of their reproductive guidelines for new drugs. Monosodium glutamate (MSG) and calcium carrageenan (CC) were used to obtain preliminary data with this test battery using continuous dietary exposure from prior to conception through 90 days of postnatal life. Observations were made on reproduction and on the physical and behavioral development of the offspring. Three dose levels were used with each of the food additives and the data from these subjects were compared to data from normally fed (negative) controls and a positive control group exposed to 550 mg/kg of hydroxyurea on the 12th day of gestation. Differences between MSG and negative control groups were observed in swimming development, open field, active and passive avoidance testing. Effects observed in the CC groups were inconsistent and not dose related. Prenatal treatment with hydroxyurea produced delayed startle and swimming development and reduced open field rearing activity. This pattern of effects was less than expected indicating that hydroxyurea is an adequate, but not optimal, positive control manipulation. It appears that the test protocol used in this research could, with some modification, serve as a usable screening technique for developmental neurobehavioral toxicity.

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

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

Developmental dissociation of methamphetamine-induced depletion of dopaminergic terminals and astrocyte reaction in rat striatum

In 60- and 80-day-old rats, TH-positive terminal depletion occurred simultaneously with increased glial fibrillary acid protein (GFAP)-containing astrocytes in the caudate-putamen nucleus following four 10 or 20 mg/kg methamphetamine treatments. At 40 days, astrocytes were increased without depletion of TH-positive terminals. At younger ages (20 days old) neither marker was altered. Processes leading to methamphetamine-induced gliosis and TH-positive terminal depletion may not be present in rats prior to 40 and 60 days, respectively. The data suggest that factors other than degenerated dopaminergic terminals, such as increased glutamate release and/or production of free radicals may be involved in triggering striatal gliosis.

Stage-specific effects of prenatal d-methamphetamine exposure on behavioral and eye development in rats

Pregnant Sprague-Dawley rats were treated with 0, 5, 10, 15, or 20 mg/kg d-methamphetamine (MA), expressed as the free base, by SC injection (b.i.d., 8 h apart) on days 7-12 or 13-18 of gestation. Plasma concentration of MA and amphetamine were determined after the last dose. MA reduced gestation weight gain. The late exposure resulted in an increase in maternal and offspring mortality and reduced offspring growth. Offspring treated early in gestation with MA showed delayed development of early locomotion. In addition, memory impairment, evidenced by decreased target quadrant times and platform crossings on test trials and increased latency on reversal trials in the Morris spatial navigation maze, reduced spontaneous alternation, and lengthened passive avoidance retention latency was seen in the early treated high-dose groups. A reduction of serotonin was found in the nucleus accumbens following late exposure to MA at 20 mg/kg. Animals in both exposure groups had eye defects; however, the type of defect was dependent on the developmental stage at the time of dosing. Anophthalmia occurred only after early MA exposure, whereas folded retina was drug related only after late MA exposure. The behavioral effects did not show graded dose dependency; however, the effects were sensitive to exposure period. The early exposed animals had more alterations in behavior whereas the late exposed group showed higher mortality, reduced body weights, and neurochemical alterations.

Developmental neurotoxicity of anticonvulsants: human and animal evidence on phenytoin.

Most epileptic women delivering children each year take anticonvulsants throughout pregnancy. The teratogenic potential of anticonvulsants is most notable for phenytoin, trimethadione, valproic acid, and carbamazepine. This review focuses on the human and animal evidence for the teratogenicity of phenytoin, with emphasis on neurobehavioral end points. The Fetal Hydantoin Syndrome (FHS) consists of craniofacial defects and any two of the following: pre/postnatal growth deficiency, limb defects, major malformations, and mental deficiency. Available data suggest a prevalence of FHS of 10-30% in infants of women ingesting 100-800 mg/kg of phenytoin during the first trimester or beyond. Unfortunately, data on neurobehavioral development in FHS children is limited. Animal models of FHS have been developed and those focusing on neurobehavioral effects are reviewed. Phenytoin produces multiple behavioral dysfunctions in rat offspring at subteratogenic and nongrowth retarding doses. These behaviorally teratogenic doses produce maternal serum phenytoin concentrations in rats comparable to those found in humans. The dysfunctions in rats are dose-dependent and exposure-period-dependent, but independent of nutritional, maternal rearing, or seizure disorder confounds. Effects include vestibular dysfunction, hyperactivity and deficits in learning and memory. General comparability between the human and animal findings for phenytoin are apparent, however, difficulties with existing studies prevent precise comparisons. Animal studies have not dealt satisfactorily with the potential contribution of epileptic disease state to the FHS, with fetal brain drug concentration determinations, a complete dose-effect range, effects in multiple species (although limited nonhuman primate data exist), site of CNS injury, and the comparability of end points assessed. Human studies have not dealt satisfactorily with issues of the need for prospective study designs, separation of the effects of different anticonvulsants, or adequate long-term follow-up of cases, especially with attention to neuropsychological assessment.