How to quickly predict an individual's behavioral choices is an important issue in the field of human behavior research. Using noninvasive electroencephalography, we aimed to identify neural markers in the prior outcome-evaluation stage and the current option-assessment stage of the chicken game that predict an individual's behavioral choices in the subsequent decision-output stage. Hierarchical linear modeling-based brain-behavior association analyses revealed that midfrontal theta oscillation in the prior outcome-evaluation stage positively predicted subsequent aggressive choices; also, beta oscillation in the current option-assessment stage positively predicted subsequent cooperative choices. These findings provide electrophysiological evidence for the three-stage theory of decision-making and strengthen the feasibility of predicting an individual's behavioral choices using neural oscillations.
Aggression/physiology* ; Brain ; Electroencephalography ; Interpersonal Relations

Nervous systems must not only generate specific adaptive behaviors, such as reproduction, aggression, feeding, and sleep, but also select a single behavior for execution at any given time, depending on both internal states and external environmental conditions. Despite their tremendous biological importance, the neural mechanisms of action selection remain poorly understood. In the past decade, studies in the model animal Drosophila melanogaster have demonstrated valuable neural mechanisms underlying action selection of innate behaviors. In this review, we summarize circuit mechanisms with a particular focus on a small number of sexually dimorphic neurons in controlling action selection among sex, fight, feeding, and sleep behaviors in both sexes of flies. We also discuss potentially conserved circuit configurations and neuromodulation of action selection in both the fly and mouse models, aiming to provide insights into action selection and the sexually dimorphic prioritization of innate behaviors.
Animals ; Mice ; Male ; Female ; Drosophila melanogaster/physiology* ; Sexual Behavior, Animal/physiology* ; Instinct ; Neurons/physiology* ; Aggression/physiology*

Females increase aggression for mating opportunities and for acquiring reproductive resources. Although the close relationship between female aggression and mating status is widely appreciated, whether and how female aggression is regulated by mating-related cues remains poorly understood. Here we report an interesting observation that Drosophila virgin females initiate high-frequency attacks toward mated females. We identify 11-cis-vaccenyl acetate (cVA), a male-derived pheromone transferred to females during mating, which promotes virgin female aggression. We subsequently reveal a cVA-responsive neural circuit consisting of four orders of neurons, including Or67d, DA1, aSP-g, and pC1 neurons, that mediate cVA-induced virgin female aggression. We also determine that aSP-g neurons release acetylcholine (ACh) to excite pC1 neurons via the nicotinic ACh receptor nAChRα7. Together, beyond revealing cVA as a mating-related inducer of virgin female aggression, our results identify a neural circuit linking the chemosensory perception of mating-related cues to aggressive behavior in Drosophila females.
Animals ; Male ; Female ; Drosophila/physiology* ; Drosophila Proteins/physiology* ; Cues ; Sexual Behavior, Animal/physiology* ; Aggression/physiology* ; Drosophila melanogaster/physiology*

OBJECTIVEThis study is purposed to explore the relationship between aggressively driving behavior and functional polymorphism in the promoter region of the monoamine oxidase-A (MAOA) gene.

METHODSA total of 348 automobile drivers were investigated with Deffenbacher's driver anger scale, driving vengeance questionnaire (DVQ) and driver aggression behavior questionnaire. Eighty-eight drivers were selected as more, medium and less aggressive group, each. Polymerase chain reaction (PCR) and 2.5% agarose gel electrophoresisi were adopted to detect the polymorphism of functional 30 bp-uVNTR in the promoter region of the X-chromosomal MAOA gene and their frequencies of varied genotypes were estimated.

RESULTSTwo alleles with 3 and 4 repeats of 30 bp-uVNTR were detected in the drivers. Among the more aggressive group, number of the allele with 3 repeats of 30 bp-uVNTR (63/88) was significantly more than that with 4 repeats (25/88) (chi(2) = 10.21, P < 0.01), and number of the allele with 4 repeats of 30 bp-uVNTR was more in the less aggressive group, indicating that persons with allele of 3 repeats of 30 bp VNTR were more aggressive in their driving than those with 4 repeats.

CONCLUSIONSAggressively driving behavior in drivers possibly related to their functional MAOA-uVNTR polymorphism. Effect of the gene on aggressively driving behavior should be further studied.

Adult ; Aggression ; physiology ; Automobile Driving ; psychology ; Brain ; physiopathology ; Humans ; Impulsive Behavior ; genetics ; physiopathology ; Male ; Monoamine Oxidase ; genetics ; Polymorphism, Genetic ; genetics ; Promoter Regions, Genetic ; Receptors, Serotonin ; genetics ; Serotonin ; physiology ; Surveys and Questionnaires

OBJECTIVE: To explore the correlation between the eicosapentaenoic acid(EPA), docosahexaenoic acid (DHA) and the aggressive behavior in mice. METHODS: Seventy-two male Kunming mice were divided into control group, fish oil group, simvastatin group and aggressive reference group randomly. The control group, fish oil group and simvastatin group were given normal saline, fish oil and simvastatin by irrigation respectively for 3 months consecutively, each mouse was raised isolatedly. The latent period of assault, the frequencies of tail swing and assault, and the cumulative time of assault were recorded at the beginning and the end of the intervention. Finally, the EPA and DHA in brain were analyzed by gas chromatography-mass spectrometry (GC-MS). The aggressive reference group was raised without intervention and was evaluated as aggressive reference only. RESULTS: (1) Before intervention, the latent period of assault, the frequencies of tail swing, the frequencies of assault, and the cumulative time of assault were not significantly different from each other group. After intervention, the differences were significant (P<0.05). (2) After the intervention, the content of EPA and DHA in mice brain was the most in the fish oil group, and the least in the simvastatin group. (3) The content of EPA was negatively related with the four indexes (P<0.05) before and after the intervention. The content of DHA was negatively related with the frequencies of tail swing and assault (P<0.05). CONCLUSION There is a correlation between the EPA, DHA and aggressive behavior in mice under stress.
Aggression/physiology* ; Animals ; Behavior, Animal/physiology* ; Brain/metabolism* ; Docosahexaenoic Acids/metabolism* ; Eicosapentaenoic Acid/metabolism* ; Fatty Acids, Omega-3/metabolism* ; Fish Oils/pharmacology* ; Gas Chromatography-Mass Spectrometry ; Male ; Mice ; Random Allocation ; Simvastatin/pharmacology*

Catechol-O-methyltransferase (COMT) gene encodes catechol-O-methyltransferase, the variant of this gene may affect the expression and metabolic activity of COMT. As the result of the changes of the effective concentration of the catecholamine neurotransmitter in the central nervous system, central nervous system dysfunctions associated with schizophrenia. This review summarizes genetic polymorphism and diversity of COMT gene. It also elaborates the relation between SNP and haplotype of COMT gene and three aspects, which including schizophrenia, attacking and violent tendency, and the frontal cognitive function of the schizophreniac. The correlativity study between genetic variation of the COMT gene and schizophrenia in patients with attacking and violent tendency may be helpful for the assessment of forensic psychiatry.
Aggression/psychology* ; Brain/pathology* ; Catechol O-Methyltransferase/genetics* ; Cognition/physiology* ; Dopamine/metabolism* ; Forensic Genetics ; Gene Expression ; Genetic Predisposition to Disease ; Genetic Variation ; Genotype ; Haplotypes ; Humans ; Polymerase Chain Reaction ; Polymorphism, Genetic ; Prefrontal Cortex/pathology* ; Promoter Regions, Genetic ; Schizophrenia/genetics* ; Violence/psychology*