Locomotor deficits in adult rats with moderate to massive retardation of cerebellar development during infancy

Spatial learning and psychomotor performance of C57BL/6 mice: age sensitivity and reliability of individual differences

Two tests often used in aging research, the elevated path test and the Morris water maze test, were examined for their application to the study of brain aging in a large sample of C57BL/6JNia mice. Specifically, these studies assessed: (1) sensitivity to age and the degree of interrelatedness among different behavioral measures derived from these tests, (2) the effect of age on variation in the measurements, and (3) the reliability of individual differences in performance on the tests. Both tests detected age-related deficits in group performance that occurred independently of each other. However, analysis of data obtained on the Morris water maze test revealed three relatively independent components of cognitive performance. Performance in initial acquisition of spatial learning in the Morris maze was not highly correlated with performance during reversal learning (when mice were required to learn a new spatial location), whereas performance in both of those phases was independent of spatial performance assessed during a single probe trial administered at the end of acquisition training. Moreover, impaired performance during initial acquisition could be detected at an earlier age than impairments in reversal learning. There were modest but significant age-related increases in the variance of both elevated path test scores and in several measures of learning in the Morris maze test. Analysis of test scores of mice across repeated testing sessions confirmed reliability of the measurements obtained for cognitive and psychomotor function. Power calculations confirmed that there are sufficiently large age-related differences in elevated path test performance, relative to within age variability, to render this test useful for studies into the ability of an intervention to prevent or reverse age-related deficits in psychomotor performance. Power calculations indicated a need for larger sample sizes for detection of intervention effects on cognitive components of the Morris water maze test, at least when implemented at the ages tested in this study. Variability among old mice in both tests, including each of the various independent measures in the Morris maze, may be useful for elucidating the biological bases of different aspects of dysfunctional brain aging.

Impaired motor performance and learning in glia maturation factor-knockout mice

Glia maturation factor (GMF) is a unique brain protein localized in astrocytes and some neuronal populations. Studies with overexpression of GMF using adenovirus vector have uncovered its regulatory role in intracellular signal transduction and downstream induction of biologically active molecules, including the neurotrophins and cytokines. The current paper deals with the behavior of mice devoid of GMF protein (knockout). GMF-null mice developed normally without gross abnormality. When tested for simple position discrimination using a T-maze and for spatial memory using a Morris water maze, the knockout mice performed as well as the wild-type, showing no defect in maze learning. However, with beam walking, GMF-knockout mice performed poorly and failed to learn. Knockout mice were also defective in learning the eyeblink classical conditioning. Histologically, the knockout mice showed a loss of neurons in the inferior olive, which is a component of the circuitry of eyeblink conditioning, and is also essential for motor performance. The structural abnormality in GMF-null mice explained their impaired ability for both motor performance and motor learning.

GABAA-benzodiazepine receptors in the striatum are involved in the sedation produced by a moderate, but not an intoxicating ethanol dose in outbred Wistar rats

The role of the dorsal striatum in mediating the sedation produced by a moderate (0.75 g/kg) and an intoxicating (1.25 g/kg) EtOH dose was investigated in the open field by determining the capacity of direct intrastriatal injections of RY 008, a partial inverse agonist of the benzodiazepine (BDZ) receptor, to antagonize EtOH's effects. SR 95531, the competitive high-affinity GABAA antagonist was used as a reference compound. Intrastriatal RY 008 (50, 500 ng) and SR 95531 (50 ng) antagonized the sedation produced by the 0.75 g/kg EtOH dose. However, RY 008 did not alter the sedation produced by the 1.25 g/kg dose. RY 008 alone was without effect. RY 008 also failed to negatively modulate GABAergic function at alpha1beta2gamma2 or alpha6beta2gamma2 receptor subtypes expressed in Xenopus oocytes. Intrastriatal modulation of the moderate EtOH dose was site specific: no antagonism by RY 008 after intraaccumbens infusions was observed. The results suggest that central GABAA-BDZ receptors in the dorsal striatum play an important role in mediating the sedation produced by a moderate EtOH dose in the open field.

Neuroanatomical and functional alterations resulting from early postnatal cerebellar insults in rodents

This review examines neuroanatomical and functional alterations in rodents resulting from postnatal insults during cerebellar development. Treatments such as irradiation and methylazoxymethanol (MAM) administration produced near birth (< postnatal day 8 for irradiation treatment and < postnatal day 4 for MAM administration) result in more severe cerebellar damage than do similar treatments administered several days after birth. Prominent among the more severe alterations are foliation abnormalities, misalignment of Purkinje cells and continued multiple innervation of climbing fibers; few or none of these occur as a result of later treatments (> postnatal day 8 for irradiation treatment and > postnatal day 4 for MAM treatment). The functional alterations also differ: insults produced near birth result in hypoactivity, ataxia, tremor and accompanying learning deficits, whereas those produced later result in hyperactivity and few learning deficits. This hyperactivity may have relevance to human disorders. Brief discussions of cerebellar and functional alterations (e.g., hyperactivity) resulting from neonatal infection with the Borna disease virus and induction of hypo- and hyperthyroidism during the preweaning period are also presented.

Temporal determinants of neonatal alcohol-induced cerebellar damage and motor performance deficits

The timing and duration of alcohol exposure was manipulated in neonatal rats by using a "binge" model of alcohol exposure during the "third trimester equivalent." Groups of Sprague-Dawley rats were exposed to binges via artificial rearing on postnatal days (PD) 4-9, on PD 4-6 or on PD 7-9, which produced peak blood alcohol concentrations representative of human alcohol abusers (approximately 250 mg/dl). Motor performance was assessed using parallel bar traversal on PD 42-44, and total Purkinje cell numbers were determined by using the 3-dimensional stereological optical fractionator method. PD 4-9 binge exposure induced the most severe Purkinje cell loss (to 68% of controls) and PD 4-6 binge exposure also produced significant loss (to 86% of controls), whereas PD 7-9 binge exposure had no significant effect (98% of controls). Unexpectedly, all three alcohol treatments resulted in significant impairments on the parallel bar task. The time of exposure during the early neonatal period in rats strongly influences the degree of Purkinje cell loss, but Purkinje cell loss is not necessary for the alcohol-induced motor performance deficits. Both neuromorphological and neurobehavioral assessments are needed for a full description of alcohol-related neurodevelopmental disorders.

Behavioral deficits induced by bingelike exposure to alcohol in neonatal rats: importance of developmental timing and number of episodes

The importance of the timing and number of episodes of bingelike alcohol exposure in neonatal rats on subsequent behavioral outcomes was evaluated with a parallel bar task and a spatial conditional alternation task. Different groups of Sprague-Dawley rat pups were exposed to alcohol delivered via artificial rearing procedures either on postnatal Days (PD) 4 and 5, on PD 8 and 9, or on both PD 4/5 and 8/9 (Combined), producing daily peak blood alcohol concentrations around 400 mg/dl. Controls included an artificially reared group and a normally reared group. Exposure during PD 4/5 produced significantly more severe motor deficits and significantly more severe reductions in cerebellar and brainstem weights than did exposure on PD 8/9. Combined exposure produced greater deficits on these measures than either of the limited exposures. Significant deficits in the acquisition rates for conditional alternation were found only with the Combined exposure, although both the PD 8/9 and Combined groups committed significantly more within-trial errors. All three alcohol treatments produced significant and comparable reductions in forebrain weight. The type and severity of behavioral and neural deficits induced by neonatal bingelike alcohol exposure depend on the timing and number of exposures.

Age-related losses of cognitive function and motor skills in mice are associated with oxidative protein damage in the brain

The hypothesis that age-associated impairment of cognitive and motor functions is due to oxidative molecular damage was tested in the mouse. In a blind study, senescent mice (aged 22 months) were subjected to a battery of behavioral tests for motor and cognitive functions and subsequently assayed for oxidative molecular damage as assessed by protein carbonyl concentration in different regions of the brain. The degree of age-related impairment in each mouse was determined by comparison to a reference group of young mice (aged 4 months) tested concurrently on the behavioral battery. The age-related loss of ability to perform a spatial swim maze task was found to be positively correlated with oxidative molecular damage in the cerebral cortex, whereas age-related loss of motor coordination was correlated with oxidative molecular damage within the cerebellum. These results support the view that oxidative stress is a causal factor in brain senescence. Furthermore, the findings suggest that age-related declines of cognitive and motor performance progress independently, and involve oxidative molecular damage within different regions of the brain.

The development of swimming behavior in the neurological mutant weaver mouse

Weaver (wv/wv) mice have well-specified ontogenetic defects in both the cerebellum and striatum, but have not previously been evaluated systematically for patterns of motor development. In this study, the effects of the weaver mutation were evaluated through an examination of swimming behavior over the first 3 postnatal weeks. Detailed movement analyses of individual limb movements as well as interlimb coordination were used to evaluate the effects of the weaver mutation. Weaver mutant mice displayed a developmental lag in terms of swimming style relative to controls. They also displayed a generalized slowness in limb movements during the swim, which correlated with the developmental onset of use of a particular limb during the swim. However, basic motor patterns in weaver swimming continue to exhibit good overall coordination through the 3rd postnatal week, even though locomotor ataxia has become pronounced by this time. Our results indicate that specific and limited alterations in movement can be traced to very early in development (postnatal Day 3) in weaver mutant mice, a time at which the earliest biochemical and neuroanatomical deficits in these animals have been established. Our results also emphasize the need for systematic contextual analyses of movement to understand interlocking processes both in movement ontogeny and its disorders.

Permanent neuronal cell loss in the inferior olive of adult rats exposed to alcohol during the brain growth spurt: a stereological investigation

The purpose of this study was to examine whether exposure of rat pups to alcohol postnatally over a period of brain development similar to that of the human 3rd trimester results in a permanent loss of cells in the inferior olivary nucleus. It was hypothesized that a deficit of neurons in the inferior olive, the sole source of climbing fibers, may contribute to the cerebellar dysfunction observed following exposure to alcohol during development. Sprague-Dawley rat pups were artificially reared and administered alcohol over postnatal days 4-9. One artificially reared group received a daily alcohol dose of 4.5 g/kg, administered as a 10.2% solution in 2 of 12 daily feedings (10.2% group). This pattern of alcohol administration resulted in high peak blood alcohol concentrations with near total clearance. The other artificially reared group was fed a diet made isocaloric to the alcohol-containing diet (gastrostomy control group). Pups were allowed to grow to adulthood and killed on postnatal day 115. The total number of neurons in the inferior olivary nucleus was estimated using unbiased stereological methods. Exposure to alcohol resulted in a significant deficit in the number of neurons in the inferior olive at 115 days of age. The total number of neurons in the alcohol-exposed group was 40.12 +/- 8.7 x 10(3), compared with 53.37 +/- 3.7 x 10(3) in the artificially reared controls. These results indicate that there is a permanent deficit of neurons in the inferior olive after postnatal exposure to alcohol.(ABSTRACT TRUNCATED AT 250 WORDS)

Neonatal alcohol exposure and early development of motor skills in alcohol preferring and nonpreferring rats

It has been suggested that differential sensitivity to alcohol might influence the severity of effects seen in offspring following gestational alcohol exposure and data exist to support this contention. Previously, we found that neonatal alcohol treatment produced greater increases in activity at the time of weaning in alcohol preferring (P) than by alcohol nonpreferring (NP) rat lines. Whereas these lines were genetically selected for extremes in alcohol preference they also differ on "sensitivity" to alcohol. Neonatal exposure in rats is used to model human third trimester alcohol exposure and the present study examined motor skills in P and NP rats following such exposure. On postnatal days 4 through 7, P and NP rats received a daily dose of 6 g/kg in four administrations 2 h apart. The alcohol was delivered in a milk solution through an indwelling intragastric cannula. Artificially reared and normally reared controls were included in the study. At 21 and 43 days of age, rats were tested for abnormalities in gait by walking an inclined runway and for dysfunction in balance using the parallel bar test. Neonatal alcohol exposure increased falling from the bars and altered gait and these effects were similar in the P and NP lines. The parallel bar test was generally too difficult for the NP rats, limiting the utility of this test in trying to determine the effects of differential alcohol sensitivity. Thus, the present results suggest that neonatal alcohol exposure had equivalent effects on gait and balance, as measured by falling from parallel bars, in P and NP rats.(ABSTRACT TRUNCATED AT 250 WORDS)

Early and persistent abnormalities in rats with neonatally acquired Borna disease virus infection

Newborn rats inoculated with Borna disease virus (BDV) develop a persistent, tolerant nervous system infection (PTI-NB), with no signs of encephalitis or Borna disease. We measured body weight, body length, taste preferences, and spontaneous locomotor activity over a 4-month period in PTI-NB and control rats. PTI-NB rats had decreased weight and length but not detectable disturbances in growth hormone and insulin-like growth factor-1 biosynthesis as compared to control rats. In single bottle taste acceptance tests, PTI-NB rats did not differ from controls and drank normal amounts of all solutions. When offered a choice of solutions in two-bottle taste preference tests, PTI-NB rats exhibited a normal preference for saccharin and a normal aversion for quinine, but an exaggerated preference for saline. At 1 and 4 months of age, PTI-NB rats were significantly more active than normal rats, although only 1-month-old PTI-NB rats had increased daytime activity. Thus, even in the absence of encephalitis, BDV infection of the PTI-NB rat is associated with a number of physiological and behavioral abnormalities.

Long-term deficits in cerebellar growth and rotarod performance of rats following "binge-like" alcohol exposure during the neonatal brain growth spurt

The cerebellum is vulnerable to growth restriction and neuronal depletion induced by alcohol exposure during the brain growth spurt of neonatal rats. This study examined whether neonatal alcohol exposure permanently restricted brain growth and induced motor performance deficits in adults. Two groups of rats were given 4.5 g/kg of alcohol per day during postnatal days 4 through 9, using artificial-rearing procedures. One group was given the alcohol as a 10.2% (v/v) solution in two of the 12 daily feedings, producing peak BACs of 361 mg/dl. The second group was given the alcohol as a 5.1% (v/v) solution in four of the feedings, producing peak BACs of 187 mg/dl. Controls included an artificially reared group and a normally reared group. All rats were tested on a rotarod at approximately 405 days of age, then perfused 1-2 weeks later. The 10.2% group was significantly impaired in acquiring the task and had significant reductions in whole brain and cerebellar weight, compared to controls. The 5.1% treatment also significantly restricted whole brain and cerebellar growth, and rotarod performance of that group was intermediate between the control groups and the 10.2% group. The cerebellar reductions and deficits in motor performance in adulthood demonstrate permanent structural and functional consequences of binge-like alcohol exposure during the brain growth spurt.

Neonatal ethanol exposure: functional alterations associated with cerebellar growth retardation

The effects of alcohol exposure during the brain growth spurt on development and on behavioral assessments of functional alterations in the cerebellum were examined in the rat. Rat pups were exposed via an artificial rearing technique to either a 2.50% w/v or 2.15% w/v EtOH-milk formula during a period encompassing the brain growth spurt. An artificially reared control group and a suckle control group were also included. Peak blood alcohol concentrations for animals in the high and low dose alcohol exposure groups were approximately 300 mg/dl and 180 mg/dl, respectively. Reductions in brain minus cerebellum to body weight (BR-C/BD) and cerebellum to body weight (C/BD) ratios were noted in animals from each of the alcohol-treated groups. Some catch-up growth in terms of brain mass was noted in animals from each of the alcohol-exposed groups. Animals exposed to alcohol during the neonatal period displayed deficits on several tests of balance and motor ability. Alcohol-exposed animals performed more poorly than controls when traversing two parallel horizontal rods and on tests of hindlimb and head elevation. No differences were noted in the ability to remain on a rotating drum. These results suggest that some of the behavioral consequences of neonatal ethanol exposure might be due to ethanol's actions on the cerebellum.

Chronology of neuron development: animal studies and their clinical implications

Because different parts of the central nervous system form at different stages of development, there is not one critical period but many critical periods. Some neurons are formed around the time of closure of the neural tube: these include the motor horn cells of the spinal cord and some motor nuclei of the brain stem. Other neurons, most notably the granule cells of the cerebellum, olfactory bulb and hippocampus, are produced in great numbers after birth. This review focuses on the mouse, the species for which the most data on neurogenesis are available, and draws parallels with other species. The clinical significance of the chronology of neuron formation is discussed in the context of recent studies of experimentally-induced congenital brain damage.

Effects of low-level x-irradiation on cat cerebella at different postnatal intervals. I. Quantitative evaluation of morphological changes

Whole head fractionated doses of 200 r and 150 r were initiated postnatally in five experimental age groups (birth, 1-week, 2-week, 3-week and 4-week) and continued over a period of 14 or 20 days to prevent reconstitution of the external granular layer. Animals irradiated at birth displayed minor deficits in behavior, which included ataxia, tremor, hypertonus and dysmetria, while animals irradiated at 1-week showed only mild symptoms of hypermetria. All other animals displayed no motor deficits. Animals irradiated at birth had smaller eyes and ears, a reduction in the size of the entire head and were susceptible to seizures. All animals were sacrified at 70 days of age. The cerebellum was found to be reduced in size and weight, the greatest deficit being seen in animals x-irradiated at the very early ages. Newborn condition animals were found to have large compliments of interneurons in the molecular layer, an established internal granular layer, and Purkinje cells were found to have a normal orientation, position, and to be unreduced in number or size. Total granule cell deficits were found to range from 83% at birth to 29% at four weeks. Quantitative changes for the molecular layer, internal granular layer, medullary layer, Purkinje cell to granule cell ratio, and granule cell density, all depicted the greatest changes in the newborn, 1-week and 2-week conditions. This experiment confirmed that the critical period in the development at which damage would result in behavioral abnormalities was from birth to five days, while for neuroanatomical abnormalities, this critical period was from birth to 18 days.

Effects of cyclophosphamide treatment of newborn mice on the development of swimming and reflex behavior and on adult behavioral performance

Cyclophosphamide (CP), an antineoplastic agent, was administered subcutaneously to Swiss-Webster mice on the day of birth and the mice were later tested for developmental or adult behavioral abnormalities. The CP dosages of 20, 30, or 45 mg/kg of body weight retarded maturation of swimming ability and 45 mg/kg retarded maturation of the righting reflex. At 7 weeks of age mice treated neonatally with 30 or 45 mg/kg of CP had reduced locomotor activity and were more emotionally reactive than controls in an open field. Mice treated with 30 but not 20 mg/kg of CP tended to avoid shock less than controls and those treated with 20 mg/kg fell more frequently when crossing a rotating rod for food. Rotorod performance was improved by treatment with 45 but not 30 mg/kg of CP. All dosages examined decreased body weight gains but only 30 or 45 mg/kg resulted in gross body malformations. The results indicate that CP can functionally impair the development of mice and that some of these impairments are independent of gross body malformations.

Postnatal development of locomotion in the laboratory rat

In laboratory rats (Rattus norvegicus) aged 1 to 21 days emergence of postural and locomotor skills was studied in the open field and in experimental situations with homing used as motivation. Righting is mediated initially by curving and rocking of the trunk, later head and shoulder are rotated, and lastly the hindlimbs turn and provide co-ordinated support. Pivoting prodominates during the second half of the first week, crawling during most of the second week, and walking or running by the end of the second week. Balancing on narrow paths and compensating for lateral displacement on rotating rods mature later, as do various skills (climbing up or down on inclined surfaces, rods and ropes, and jumping across gaps) that require substantial hindlimb co-ordiantion.

Purkinje cell dendritic alterations after transient developmental injury of theexternal granular layer

To examine the influence of granule cell axons on morphogenesis of their major synaptic target, the Purkinje cell dendrites, a transient injury of the external granular layer of developing rat cerebellum was induced by injecting 10 mg/kg methylazoxymethanol acetate on postnatal days 1, 2, 3 and 4. The antiproliferative action of the drug resulted in a diminution of the mitotic population which slowed the expansion of the internal granular and molecular layers. This was followed by a reconstitution of a thicker than normal external granular layer and a late phase of extensive growth. Perturbations of Purkinje cell dendritic morphology induced by this altered timing of granule cell accumulation were studied with Golgi-Cox impregnation techniques. Systematic observation were made of a number of defined abnormalities of Purkinje cells which included somas positioned below the normal monolayer; elongated dendrites; multiple somatic dendrites; S-shaped dendrites; dendrites disoriented away from the radial direction; and portions of dendrites below the soma of origin. The results indicated that most of these 'abnormalities' occur to a small extent in normal cerebellum but that these experimental conditions induced a bias in favor of their appearance. Some dendritic abnormalities, i.e., dendrites tilted out of the sagittal plane, dendrites directed toward the white matter, and apical dendrites growing vertically between cells of the external granular layer, were not noted in normal cerebellum and we attribute these particular changes to unique developmental possibilities occuring only after a more or less severe injury. This analysis of bias in dendritic morphology subsequent to subtle developmental injury provides informat on on processes of normal development and on the genesis of phylogenetic variants of Purkinje cell morphology.

The level of GABA in the brain and locomotor behavior

GABA content was measured in the brains of animals injected with AOAA, DPA or Saline. Significant increases in GABA were found in the motor cortex and cerebellum after treatment with both drugs as compared to saline injected controls. Increased GABA levels were associated with interference with the smooth execution of locomotor acts, especially where balancing and coordination of the hind limbs were necessary.