Genetic and environmental interactions determine seizure susceptibility in epileptic EL mice.

Gene identification has progressed rapidly for monogenic epilepsies, but complex gene-environmental interactions have hindered progress in gene identification for multifactorial epilepsies. We analyzed the role of environmental risk factors in the inheritance of multifactorial idiopathic generalized epilepsy in the EL mouse. Seizure susceptibility was evaluated in the EL (E) and seizure-resistant ABP/LeJ (A) parental mouse strains and in their AEF1 and AEF2 hybrid offspring using a handling-induced seizure test. The seizure test was administered in three environments (environments I, II and III) that differed with respect to the number of seizure tests administered (one test or four tests) and the age of the mice when tested (young or old). The inheritance of seizure susceptibility appeared dominant after repetitive seizure testing in young or old mice, but recessive after a single test in old mice. Heritability was high (0.67-0.77) in each environment. Significant quantitative trait loci (QTL) that were associated with environments I and III (repetitive testing) were found on chromosomes 2 and 9 and colocalized with previously mapped El2 and El4, respectively. The El2 QTL found in environment I associated only with female susceptibility. A novel QTL, El-N, for age-dependent predisposition to seizures was found on proximal chromosome 9 only in environment II. The findings indicate that environmental risk factors determine the genetic architecture of seizure susceptibility in EL mice and suggest that QTL for complex epilepsies should be defined in terms of the environment in which they are expressed.

Caloric restriction inhibits seizure susceptibility in epileptic EL mice by reducing blood glucose.

PURPOSE: Caloric restriction (CR) involves underfeeding and has long been recognized as a dietary therapy that improves health and increases longevity. In contrast to severe fasting or starvation, CR reduces total food intake without causing nutritional deficiencies. Although fasting has been recognized as an effective antiseizure therapy since the time of the ancient Greeks, the mechanism by which fasting inhibits seizures remains obscure. The influence of CR on seizure susceptibility was investigated at both juvenile (30 days) and adult (70 days) ages in the EL mouse, a genetic model of multifactorial idiopathic epilepsy. METHODS: The juvenile EL mice were separated into two groups and fed standard lab chow either ad libitum (control, n=18) or with a 15% CR diet (treated, n=17). The adult EL mice were separated into three groups; control (n=15), 15% CR (n=6), and 30% CR (n=3). Body weights, seizure susceptibility, and the levels of blood glucose and ketones (beta-hydroxybutyrate) were measured over a 10-week treatment period. Simple linear regression and multiple logistic regression were used to analyze the relations among seizures, glucose, and ketones. RESULTS: CR delayed the onset and reduced the incidence of seizures at both juvenile and adult ages and was devoid of adverse side effects. Furthermore, mild CR (15%) had a greater antiepileptogenic effect than the well-established high-fat ketogenic diet in the juvenile mice. The CR-induced changes in blood glucose levels were predictive of both blood ketone levels and seizure susceptibility. CONCLUSIONS: We propose that CR may reduce seizure susceptibility in EL mice by reducing brain glycolytic energy. Our preclinical findings suggest that CR may be an effective antiseizure dietary therapy for human seizure disorders.

The ketogenic diet inhibits epileptogenesis in EL mice: a genetic model for idiopathic epilepsy.

PURPOSE: The ketogenic diet (KD) is a high-fat, low-carbohydrate and -protein diet that has been used to treat refractory seizures in children for more than 75 years. However, little is known about how the KD inhibits seizures or its effects on epileptogenesis. Several animal models of epilepsy have responded favorably to KD treatment, but the KD has not been studied in animals with a genetic predisposition to seizures. Here we studied the antiepileptogenic effect of the KD in EL mice, an animal model for human idiopathic epilepsy. METHODS: Young male EL mice (postnatal day 30) were randomly separated into two groups fed ad libitum with either the KD (treated, n = 21) or Agway chow (control, n = 19). The mice were weighed and tested for seizures once per week for a total of 10 weeks. The effects of the KD on plasma levels of ketone bodies and glucose were analyzed at several time points throughout the study. Associative learning was compared between treated and control animals using a water maze. RESULTS: KD treatment delayed seizure onset in young male EL mice by 1 month; however, seizure protection was transient, inasmuch as the treated and control mice experienced a similar number and intensity of seizures after 6 weeks on the diet. Plasma glucose levels and associative learning were similar in the treated and control groups, but the plasma beta-hydroxybutyrate levels were significantly higher in mice on the KD. The level of ketosis, however, was not predictive of seizure protection in EL mice. CONCLUSION: The KD delayed seizure onset in EL mice, suggesting a transient protection against epileptogenesis. The KD did not influence plasma glucose levels or associative learning. Therefore, the EL mouse may serve as a good model to study the antiepileptogenic mechanisms of the KD.

Environmental risk factors for multifactorial epilepsy in EL mice.

PURPOSE: The epileptic EL mouse has been studied extensively as a model of multifactorial epilepsy. Although EL mice have a seizure occasionally during routine handling associated with cage changing, most studies have used vigorous tossing or shaking procedures for seizure induction. A new seizure testing procedure was developed that involved gentle handling and simulated situations associated with emotional stress in rodents. This new testing procedure was used to identify and characterize several environmental risk factors that influence seizure predisposition in EL mice. METHODS: Ten adult EL mice were monitored for 7 days under 24-h light/dark video surveillance to assess the frequency of spontaneous seizures. The development of handling-induced seizures also was studied in EL mice, in nonepileptic ABP and DDY mice, and in reciprocal ABP x EL F1 hybrids from ages 30-180 days. RESULTS: Seizure induction was necessary in EL mice, as spontaneous clinical seizures were not observed. Handling-induced seizure susceptibility was strongly age and gender dependent in naive EL mice (not previously handled) and peaked approximately 90 days, with males significantly more susceptible than females. No seizures were induced by handling in the nonepileptic mouse strains (ABP and DDY) over the testing period. Handling and seizures at young ages in EL and EL x ABP F1 hybrid mice significantly enhanced their seizure susceptibility when they were tested again 1 month later. A significant "Gowers effect" was seen also in EL mice. Furthermore, susceptibility was higher in ABP x EL F1 hybrids than in their reciprocal EL x ABP F1 hybrids at 90-150 days. CONCLUSIONS: Seizure susceptibility in EL mice was significantly influenced by a number of environmental factors including age, gender, maternal/paternal effects, prior handling, and seizure history. The emotional stress/fear response is the likely trigger for seizure induction in EL mice. An early life experience stress-diathesis model, similar to that proposed for major depression in humans, was applicable to the development of seizure susceptibility in EL mice. The new seizure test will be useful for defining gene-environment interactions and in identifying susceptibility genes for multifactorial epilepsy.

Experimental models of multifactorial epilepsies: the EL mouse and mice susceptible to audiogenic seizures.

This chapter reviews two well-characterized mouse epilepsy models with a multifactorial etiology, the epileptic EL mouse and mice susceptible to audiogenic seizures (AGS). Multifactorial disorders are quantitative traits where the action of more than one gene together with environmental factors contributes to the disease phenotype. The EL (epilepsy) mouse has been studied extensively as a genetic model for idiopathic complex partial seizures in humans. EL seizures are associated with an intense hippocampal gliosis in the absence of obvious neuronal loss and an elevated calcium-dependent release of aspartate that is present both before and after seizure onset. The inheritance of epilepsy is complex and several seizure frequency quantitative trait loci (QTL) have been mapped. Much of this genetic complexity may arise from the influence of environmental factors, including the seizure testing procedure, seizure history, and age. AGS, which are violent sound-induced convulsions, are considered a genetic model for generalized brainstem or reflex epilepsies. AGS susceptibility can arise as an inherited trait in some mouse strains or can be induced in genetically resistant strains from environmental factors (e.g., prior acoustic stimulation). AGS susceptibility and long-term potentiation (LTP) may also share common mechanisms. Several Asp genes have been mapped that influence AGS susceptibility. The expression of one of these can be modified by genomic imprinting and another has been identified as the X-linked 5-HT2e serotonin receptor. The genetic dissection of convulsive behavior in EL and AGS susceptible mice could help identify candidate genes for human multifactorial epilepsies.

Environmental influences on epilepsy gene mapping in EL mice.

The epileptic EL mouse has been studied extensively as a genetic model for idiopathic complex partial seizures in humans. The seizures in EL mice occur during routine handling at approximately 90 days of age, but can be induced at younger ages (50 days) by repeated rhythmic vestibular stimulation, e.g., tossing. Six seizure frequency quantitative trait loci (QTLs), El1-El6, were previously mapped in crosses between EL and non-epileptic strains using mechanical tossing procedures beginning at 30 days of age. The presence of these seizure frequency QTLs depended upon genetic background and the type of cross. Here we confirm Chromosome 2 and 9 QTLs in a backcross to the seizure-resistant ABP/LeJ strain with mice tested beginning at 200 days of age. However, the mapping of epilepsy genes was influenced by the seizure testing procedure, i.e., repeated tossing. The maximum Z-score for El1 (Chromosome 9) was 3.7 after 6 tests, but decreased to 2.4 after 15 tests. In contrast, the maximum Z-score for El2 (Chromosome 2) was 2.0 after 6 tests, but increased to 3.9 after 15 tests. In addition to nonallelic interactions (epistasis), our findings indicate that the genetic complexity of tossing-induced seizure susceptibility in EL mice also arises from genotype-environmental interactions involving the seizure test, seizure history, and age.

[Expression of the human alpha-1-antitrypsin gene in Escherichia coli]. / Ekspressiia gena alpha-1-antitripsina cheloveka v kletkakh Escherichia coli.

The cDNA, containing the complete human alpha-1-antitrypsin (AT) sequence starting from codon 2, was used to construct bacterial strains producing AT. The fusion protein was obtained by junction of the AT cDNA to the fragment of an Escherichia coli ompF gene. We have also modified the AT cDNA's 5'-terminal part to construct DNAs containing ATG-codon and cDNA sequences starting from codons 1 or 2. These DNAs were inserted into E. coli expression vectors pBR322/trpII-8 and pKK223-3 that allow transcription from efficient trp- and tac-promoters. This construction resulted in the induction of a 46 kDa protein. The polypeptide produced was recognized by an antiserum raised against human alpha-1-antitrypsin protein. Truncation of the gene at its 5'-end or synthesis as a fusion OmpF-AT protein increases expression up to 10-fold, to a level of approximately 1%. On the contrary, no dependence on the promoter type has been observed. Physical properties of the recombinant proteins are discussed.