Voltage associated with spontaneous embryonic motility in the developing chicken: an automated characterization during mid-late embryogenesis.

Movement of developing chicken embryos and their associated membranes generates voltage detectable with electrodes inserted just beneath the eggshell. Use of such voltages as a motility indicator offers an embryonic behavioral assessment method less subjective and invasive than observational methods using windows that disrupt substantial portions of the eggshell. We used a computerized signal recording and processing procedure to compare voltages from embryonic Day 12 (E12), E15, and E18 chicken eggs with embryos, assessed on the same day. Larger voltages were recorded from E18 subjects than from E12 or E15 subjects. Because this could have been due to embryonic size (mass) and/or proximity to the electrodes, making age comparisons uninterpretable, we used standard deviation-normalized and Z-score-based data transformations, comparing groups for relative deviations from basal voltages. E18 subjects still appeared more active than E12 subjects, with E15 a transitional age, in contrast to results from earlier window-based studies. The automated assessment method we used could enhance behavioral teratology studies of avian species.

Relationships between midembryonic 5-HT2 agonist and/or antagonist exposure and detour learning by chickens.

The importance of serotonin (5-HT) as both a transmitter and a regulatory signal during development of many species is well established. The availability of 5-HT receptor subtype agonists and antagonists will enable pharmacological dissection of the importance of one or more of the 5-HT receptors for their involvement in the mediation of developmental insults by drugs that are less selective but include actions upon serotonergic function. Such insults include exposure to cocaine or opiate withdrawal, both of which are blocked or attenuated by 5-HT2 antagonists. The 5-HT2 receptor agonist dimethoxyiodophenylaminopropane (DOI), like cocaine, causes vasoconstriction during embryogenesis, herniated umbilici in hatchlings, and altered detour learning by young chickens after injection into eggs at late stages of embryogenesis. The 5-HT2 antagonist ritanserin (RIT) blocks or significantly attenuates these effects. This study describes an effect of DOI on posthatch detour learning when injected earlier during embryogenesis (i.e., on embryonic day 12, E12) which is opposite its effect when injected later (i.e., on E15). Both effects are blocked by an inactive dose of RIT (0.3 mg/kg egg) and by a higher dose of RIT (0.9 mg/kg egg), which itself retards posthatch detour learning following E12 injection. Thus, excessive stimulation or blockade of 5-HT2 receptors around midembryogenesis can cause a similar behavioral teratogenic outcome. The data are discussed in relation to the likelihood that potential use of 5-HT2 antagonists for treating pregnant women and their fetuses who are not at risk is nil.

Behavioral and neuroendocrine assessment of ritanserin exposure in the developing chicken: lack of toxicity at effective doses.

The 5-HT2 antagonist ritanserin (RIT) is undergoing Phase III clinical trials for the treatment of substance abuse disorders. RIT has also shown preclinical therapeutic potential for attenuating or blocking lethal and/or toxic effects of exposure to cocaine or the selective 5-HT2 agonist dimethoxyiodophenyl-aminopropane (DOI) in the developing chicken. To assess the potential toxicity ("side effects") of RIT itself during development, we exposed chicken embryos to 0, 0.1, 0.3, 0.9, or 2.7 mg RIT/kg egg by injecting the drug into eggs with 14-day-old embryos (E14). Voltage generated by spontaneous embryonic activity (motility) was measured on E15 to assess short-term effects of RIT; none were observed. There was no overall effect of these RIT doses on hatchability, though sample sizes were small (n = 13-15 per group). One to 2 weeks after hatching, chicks' acquisition of a detour learning response was tested. There were no observable effects of any RIT dose on detour learning. To assess potential effects of RIT on responsiveness to stress, some chicks were exposed to isolation stress approximately 3 weeks after hatching and killed 15 min later. Blood was assayed for serum corticosterone. There was no effect of any embryonic RIT dose on corticosterone concentrations in nonstressed subjects. Although corticosterone was elevated in all stressed groups, the group exposed to the highest embryonic RIT dose (2.7 mg/kg egg) showed a stress-induced elevation greater than other groups. Thus, except for the highest RIT dose (six to seven times greater than a therapeutically effective dose used in earlier work), embryonic RIT exposure on E14 had no effect on embryonic behavior, hatchability, posthatch learned behavior, and basal serum corticosterone concentrations. At a supraefficacious dose it appears to have modified the responsiveness of the neuroendocrine axis to mild stress.

Ritanserin blocks DOI-altered embryonic motility and posthatch learning in the developing chicken.

Developing chicken embryos exposed to cocaine show altered motility, hatchability, and posthatch detour learning. Pretreating such subjects with the serotonin2 (5-HT2) antagonist ritanserin (RIT) can block the motility suppression and reduced hatchability, indicating 5-HT2 receptor involvement in these cocaine effects. To study behavioral consequences of more selective 5-HT2 receptor stimulation and its blockade during development and to compare such exposure with that of cocaine, we injected eggs with 15-day-old chicken embryos with the 5-HT2 agonist dimethoxyiodophenylaminopropane (DOI, 1.0 mg/kg egg) and 1 h later, with RIT (0.3 and 0.9 mg/kg egg). Motility was recorded 2.5 or 24 h after DOI. This DOI dose suppressed motility 2.5 h but not 24 h after administration. Both RIT doses blocked DOI's motility suppression. No treatment affected hatchability. Subjects were tested on posthatch days 6-9 for detour learning acquisition. DOI "enhanced" learning (i.e., reduced latency), a cocaine-like effect observed in prior work, which was also blocked by both RIT doses. Thus, some consequences of DOI exposure late during embryonic development resemble cocaine's and are blocked by RIT, suggesting a therapeutic role for RIT-like drugs against cocaine's potential developmental toxicity.

Potential efficacy and toxicity of GM1 ganglioside against trimethyltin-induced brain lesions in rats: comparison with protracted food restriction.

GM1 ganglioside (one week each at 10, 5, and 2.5 mg GM1/kg per day, ip) or gradual food restriction leading to a reduction in body weight to 75% of control were tested for their ability to block or reverse histopathologic and behavioral effects of trimethyltin (TMT) poisoning in rats. TMT (a single oral gavage of 6.0 mg TMT HCI/kg body weight) reduced hippocampal weight, decreased hippocampal cell counts, decreased autoshaped learning measures, and suppressed progressive fixed ratio (PFR) lever pressing without affecting stable lever pressing. Neither GM1 nor greater food restriction affected hippocampal weight. Greater food restriction prevented TMT's effects on autoshaping but not on PFR behavior, was without behavioral effects in animals not treated with TMT, and did not affect hippocampal histology. GM1 prevented certain TMT-induced decrements in autoshaping and PFR behavior but also suppressed autoshaping and stimulated stable fixed ratio behavior in animals not treated with TMT. GM1 also reduced hippocampal serotonin concentration, another "lesion-like" change. GM1 blocked TMT-induced hippocampal CA3b cell loss, but did not protect CA3c cells, the main locus of TMT hippocampal damage. The results support the idea that exogenous GM1 is a potent neuroactive agent with complex actions in intact organisms, potentially beneficial and potentially toxic. Like GM1, food restriction induces complex and potentially beneficial effects, but it lacked GM1's biochemical and behavioral "side effects" (i.e. toxicity) in these experiments.

Food deprivation enhances both autoshaping and autoshaping impairment by a latent inhibition procedure.

The influence of food deprivation on acquisition of autoshaped operant behavior was measured. In one study separate groups of young, male rats that were deprived to 75%, 80%, 85%, 90%, and 95% of ad lib weight were subjected to an autoshaping procedure in which a 6 s delay was interposed between lever retraction (which occurred when rats made a lever touch, or automatically after 15 s) and food pellet delivery. In a second study, groups of rats were deprived to 80% or 90% of ad lib weight prior to testing in a latent inhibition variation of the same autoshaping procedure. This was done to determine if greater food deprivation would enhance learning which, because of the latent inhibition manipulation, is manifest as less lever-directed behavior. Greater food deprivation was associated both with fast acquisition of autoshaped lever responding and with more reliable failure to increase lever responding in the latent inhibition paradigm. Thus, increasing food deprivation was associated with enhanced acquisition regardless of whether the required performance was an increase or a failure to increase the same behavior, indicating a specific effect on learning.

Dose-specific effects of trimethyltin poisoning on learning and hippocampal corticosterone binding.

The organometal neurotoxin trimethyltin (TMT) damages limbic forebrain, and impairs acquisition of lever-directed behaviors in an autoshaping task, in which a lever is presented according to a random time schedule, and rats learn to associate its presentation/retraction with food delivery (Cohen et al., 1987). This impairment is evident only if a sufficiently long delay of reinforcement is interposed between lever retraction (which occurs either automatically after 15 sec, or immediately upon a touch response) and food pellet delivery. Paradoxically, rats given a higher (7.5 mg/kg) dose show a smaller acquisition impairment, perhaps because they are generally more reactive to the lever than controls. These rats sustain a larger hippocampal lesion (measured by wet weight of the structure). The experiment reported here was done to investigate (1) an autoshaping deficit related to hippocampal weight loss, and (2) biochemical changes in hippocampus which might be related to behavioral impairments. Rats were treated with water vehicle or TMT four weeks before autoshaping using a 6 sec reinforcement delay. In addition to lever touching, touches of the food trough were measured. The timing of trough-touching behaviors within a trial was used as an indication of the strength of the association formed between the lever and the site of food delivery. Following autoshaping rats were adrenalectomized and killed for measurement of cytosolic [3H]corticosterone binding in hippocampus. As before, rats treated with 6.0 mg TMT/kg showed a deficit in acquisition of lever-directed behaviors. Also, as hypothesized, the proportion of total trough-directed behaviors made during the 6 sec reinforcement delay intervals (when reinforcement probability was high) diverged significantly from control values as learning progressed. These rats also showed a reduction in hippocampal weight compared with controls, but significant decreases in hippocampal steroid binding were observed only in groups given the low and median dose of TMT. Further, steroid binding was correlated with lever-directed behaviors. It thus appears that lever and trough behaviors can be used to simultaneously assess different aspects of impairment in associative learning which are accompanied by differential cell loss and biochemical deficit.

Lactose digestion by yogurt beta-galactosidase: influence of pH and microbial cell integrity.

Lactase-deficient subjects more effectively digest lactose in yogurt than lactose in other dairy products, apparently due to yogurt microbial beta-galactosidase (beta-gal) which is active in the GI tract. We evaluated the effects of buffering capacity of yogurt, gastric pH, and microbial cell disruption on beta-gal activity and lactose digestion. Three times more acid was required to acidify yogurt than to acidify milk. Yogurt beta-gal was stable at pH 4.0 but inactivated at lower pH. When yogurt was sonicated to disrupt microbial cell structure, only 20% activity remained after incubation at pH 4.0 for 60 min. In vivo gastric pH remained greater than 2.7 for 3 h after ingestion of yogurt. Acidified milk alone or with disrupted yogurt microorganisms caused twice as much lactose malabsorption as did acidified milk containing intact yogurt microorganisms. The results provide a possible explanation for the survival of beta-gal activity from yogurt in the GI tract.