Scent Marking, Sexual Behavior and Aggression in Male Gerbils: Comparative Analysis of Endocrine Control

SYNOPSIS. The aggressive, sexual, and scent marking behaviorsof male gerbils (Meriones unguiculatus) are sensitive to gonadalandrogens, but androgens are not equally important in the controlof each behavior. In this species, territorial residency, prioraggressive experience, and unidentified factors that contributeto large individual differences in aggressiveness, influencethe aggressive behavior of males at least as much as androgensdo. To the extent that androgens affect aggression between malegerbils, they act partially by altering aggressiveness and partiallyby altering production of aggression-eliciting cues. The natureof these cues is unknown. Understanding the role of androgensin aggression in this species is further complicated by theobservation that castration can either increase or decreaseaggression depending on the age at which the surgery is performed.In contrast, androgens play aprimary role in the control ofsexual behavior and scent marking. Both behaviors consistentlydecline following castration despite prior experience of themales. Both behaviors are also controlled by the medial preopticarea-anterior hypothalamus, an area of the brain often implicatedin the control of male sociosexual behaviors. It appears, though,that the sites, and possibly the mechanisms, of hormone actionunderlying scent marking and sexual behavior differ. Studyingboth behaviors in the same species, and whenever possible inthe same individuals, is proving to be a useful technique foridentifying such differences between behaviors as their sensitivityto steroids and to brain lesions.     

Characterisation of<Emphasis Type="Italic">fusarium graminearum</Emphasis> and<Emphasis Type="Italic">F. culmorum</Emphasis> isolates by mycotoxin production and aggressiveness to wheat

A total of 27Fusarium culmorum isolates from Germany and 41F. graminearum isolates from Kenya were investigated for aggressiveness and mycotoxin production on wheat ears. In addition, ergosterol content of the kernels from ears inoculated withF. graminearum was determined and theF. culmorum isolates were tested for mycotoxin productionin vitro. For both pathogens, isolates markedly differed in aggressiveness. 59% and 37% of theF. culmorum isolates produced NIV and DON, respectively,in vivo andin vitro. The DON-producing isolates also produced 3-acDONin vitro. The more aggressive isolates produced mainly DON while the less aggressive isolates produced mainly NIV. 12% and 85% of theF. graminearum isolates produced NIV and DON, respectively. The highly aggressive isolates produced higher amounts of DON, aggressiveness being highly correlated to DON content in the kernels. NIV-producing isolates were less aggressive. Ergosterol content of kernels was moderately correlated to aggressiveness but highly correlated to DON content. Disease severity was associated with kernel weight reduction.     

Testosterone supplementation in juvenile Psammodromus algirus lizards: consequences for aggressiveness and body growth

In some species, more aggressive individuals are more successful in resource competition. High testosterone level is associated with increased activity and aggressive behavior, and this may have a direct effect on metabolic rate and cause an increase in energy expenditure. Here, I examined the influence of exogenously administered testosterone on aggressiveness and body growth in juvenile Psammodromus algirus male lizards. Juvenile males were given testosterone-filled (experimental) or empty (control) implants. Testosterone produced an increase in aggressiveness and activity in the experimental males. However, despite being more aggressive, experimental males did not acquire larger home ranges than control males. Experimental males also experienced a significant reduction in growth rate over the 2-month period following implantation. Experimental males also were in poorer condition at the completion of the experiment, compared to control males. These results suggest that although an elevated testosterone level may have positive effects on aggressiveness and activity, it also may have negative effects manifested as reduced growth rate and body condition. Received in revised form: 15 June 2001 Electronic Publication     

Aggressive behavior and radiosensitivity in rats'

This paper aims to present the study of rats' individual radiosensitivity dependence on their individual aggressiveness. On total irradiation in sublethal doses (1.0, 1.5 and 3.5 Gy) and in doses close to LD50/30 (6, 7 and 8 Gy) there was investigated comparative radiosensitivity of non-aggressive and aggressive rats of Wistar line, as well as that of non-aggressive individuals during provoked aggressiveness by means of blocking serotonin synthesis with intraperitoneal (i/p) injection of 400 mg/kg of parachlorphenylalanine (pCPA). Muricidity served as a criterion for aggressiveness and as a criterion of radiosensitivity--cumulative function of survival, the changes of behavior in "Open feald", serotonine and catecholamine content in various brain structures and the dose dependence on the radiation modification of muricidity. It has been found that after 1 Gy total X-irradiation the rats do not lose aggressiveness. Nevertheless the ethalogical parameters change in considerable degree. In the doses of 1.5 and 3.5 Gy muricidity is eluminated in 15-18 and 5-9 days, correspondingly. I/p injection of pCPA after the elimination of aggressiveness provokes transient muricidity in the same terms and duration as it is in case of non-aggressive rats. The elimination of muricidity is associated with changes in content and distribution of biogenic amines in various structures of brain, as well as with reduction of locomotor and reference-research activity, on the one hand and with an increase of emotionality and stereotype activity, on the other hand. After X-irradiation in 6, 7 and 8 Gy the regression coefficients of the dependence of functions type of survival on irradiation dose in aggressive rats is significantly reliable both in comparison with non-aggressive rats and animals with provoked aggressiveness. The change of mortality-rate per unit of changing irradiation dose not depend on blocking of serotonin synthesis, which deficit is one of the distinct determinant of aggressiveness, on the one hand, and higher radiosensitivity, on the other hand. The obtained data allow to suppose that elimination of muricidity after the irradiation of rats in the sublethal doses is conditioned not only by the consequenses of radiation damage of neurobiological structures responsible for the organization of aggressive behavior but the activation of serotonergic system in the process of restitution after radiation trauma. On the other hand, higher radiosensitivity of aggressive rats compared with non-aggressive ones is connected with low serotonin content, thiols and some other biologically active substances which are endogenous radioprotectors determining individual radioresistance.     

The involvement of brain 5-HT(1A)-receptors in genetically determined aggressive behavior

The hypothesis was tested that one of the critical mechanisms underlying genetically determined aggressiveness involves brain serotonin 5-HT(1A)-receptors. The expression of 5-HT(1A)-receptor mRNA in brain structures and functional correlate for 5-HT(1A)-receptors identified as 8-OH-DPAT-induced hypothermia were studied in Norway rats bred over the course of 59 generations for the low and high affective (defensive) aggressiveness with respect to man and in highly aggressive (offensive) MAO A-knockout mice (Tg8 strain). Considerable differences between the aggressive and the nonaggressive animals were shown. Agonist of 5-HT(1A)-receptor 8-OH-DPAT (0.5 mg/kg for rats and 2.0 mg/kg for mice, i.p.) produced a distinct hypothermic reaction in nonaggressive rats and mice and did not affect significantly the body temperature in aggressive animals. In aggressive rats, a significant reduction of the expression of 5-HT(1A)-receptor mRNA was found in the midbrain. In Tg8 mice, 5-HT(1A)-receptor mRNA level was increased in the frontal cortex and amygdala and not changed in the hypothalamus and the midbrain. The results provide support for the idea that brain 5-HT(1A)-receptors contribute to the genetically determined individual differences in aggressiveness.     

Specialized predation on plataspid heteropterans in a coccinellid beetle: adaptive behavior and responses of prey attended or not by ants

Two plataspid hemipteran species proliferated on Bridelia micrantha(Euphorbiaceae). Colonies of Libyaspis sp., never attendedby ants, developed on branches, while Caternaultiella rugosa lived at the base of the trunks, mostly in association withCamponotus brutus that attends them in carton shelters. Bothplataspid species are prey of the coccinellid beetle Anisolemniatetrasticta, whose larvae always detected them by contact.When attacked the Libyaspis nymphs cowered, so that the hypertrophiedlateral sides of their tergits made contact with the substrate,but the ladybirds slid their long forelegs under these nymphs,lifted them, and bit them on the ventral face. The Caternaultiellanymphs, which do not have hypertrophied extremities of thetergits, tried to escape at contact with the ladybirds, butwere rarely successful. To capture them, the ladybirds eitheradopted the previous behavior or directly grasped then bitthem. We noted a graded aggressiveness in the ants toward theladybirds according to the situation: no aggressiveness onthe tree branches; stopping the ladybirds that approached theshelters where the ants attended Caternaultiella; and fullattack of ladybirds that tried to capture Caternaultiella nymphssituated outside shelters. The latter behavior can emit analarm pheromone that triggers the dispersion of their congenerswhile attracting attending C. brutus workers. Naive workersare not attracted, so we deduce that this behavior is the resultof a kind of learning.     

电刺激大鼠尾核头部镇痛的中枢效应—[^3H]—2脱氧...

Sokoloff's 2-deoxyglucose (2-DG) autoradiographic technique was used to identify changes of glucose metabolic rate in the rat brain following unilateral stimulation of the head of the caudate nucleus. The results were as follows. The local glucose metabolic rate after noxious stimulation was increased in the somatosensory cortex, cingulate cortex, ventroposterior and parafascicular nucleus of the thalamus, septal area, habenular nucleus, head of caudate nucleus, periaqueductal gray (PAG) and dorsal raphe nucleus (P < 0.05). After stimulating the head of the caudate nucleus, the local glucose metabolic rate of nucleus raphe magnus (rm) and nucleus paragigantocellularis (pgcl) was increased significantly and that of the PAG and dorsal raphe nucleus had a tendency to increase, while stimulation of the head of caudate nucleus could partially abolish the increased glucose metabolic rate in the somatosensory cortex, cingulate cortex, ventroposterior and parafascicular nucleus of the thalamus, septal area and habenular nucleus as induced by noxious stimulation. These results suggest that caudate stimulation is able to depress the activation of some brain structures related to nociception and to activate those related to antinociception. The pgcl, rm, PAG and dorsal raphe nucleus might be the key structures participating in the caudate stimulation produced analgesia.     

Octopaminergic system in the brain controls aggressive motivation in the ant, Formica japonica

The ant, Formica japonica, is polyphagous and workers hunt other insects as foods. In this study, interspecific aggression was examined in the workers and queens. Behavior experiments demonstrated that interspecific aggressiveness was significantly higher in workers than queens. Workers showed predatory aggressive behavior towards crickets, on the other hand, queens elicited threat behavior but they didn't attack crickets. In order to investigate neuronal mechanisms underlying regulation of aggressive motivation, the role of biogenic amine in the brain in evoking aggressive behavior was examined by measuring biogenic amine using high-performance liquid chromatography (HPLC) with electrochemical detection (ECD). No significant difference in the octopamine (OA) level was found between workers and queens, but the level of N-acetyloctopamine (NacOA) in the brain of queens was significantly higher than that of workers. This study suggests that OAergic system in the brain must involve in controlling aggressive motivation in the ants.     

Change in certain forms of aggressive behavior and the concentration of monoamines in the brain during selection of wild rats for taming

Norway rats have been selected during 20 generations by the absence of aggressive reaction to man (tamed rats). From 7 up to 20th generations of selection, different forms of aggressive behaviour (reaction to glove, intermale, shock-induced aggression and predatory aggression) were studied, and the level of noradrenaline, serotonin and its metabolite 5-hydroxyindoleacetic acid was determined in the brain. In the absence of aggressive reaction to glove in tamed rats, the shock-induced aggression considerably decreased while the predatory aggressiveness (mouse-killing behaviour) and intermale aggressiveness did not change. Beginning from 15-16th generation of selection, a higher level of the 5-hydroxyindoleacetic acid in the hypothalamus was established, in the 20th generation an increased content of serotonin was revealed in the hypothalamus and the midbrain. In some generations of selection an increased level of noradrenaline in the hypothalamus in comparison to wild rats was observed. A conclusion is made that the selection of animals by taming unequally influences different kinds of aggressiveness and is accompanied by inherited consolidated reorganization of the monoamine brain systems.     

The effect of intra- and interspecific aggression on patch residence time in Negev Desert gerbils: a competing risk analysis

We observed patch-use behavior by two gerbil species in a fieldsetting and investigated how aggression and intrinsic decision-makinginteract to influence patch residence times. Results were interpretedby using a competing risk analysis model, which uniquely enabledus to estimate the intrinsic patch-leaving decisions independentlyof external interruptions of foraging bouts by aggression. Theexperiment was conducted in two 1-ha field enclosures completelysurrounded by rodent-proof fences and included allopatric (onlyGerbillus andersoni allenbyi) and sympatric (G. a. allenbyiand G. pyramidum) treatments. We predicted that increased foodpatch quality (i.e., habitat quality) should decrease intrinsicpatch-leaving rates and increase rates of aggressive interactionsinvolving the forager feeding in the patch (i.e., the occupantindividual). We also anticipated that increasing populationdensity should result in an increase in the rate of aggressiveinteractions involving the occupant individual. Our resultssupported the first two predictions, indicating a trade-offbetween foraging and aggression. However, the third predictionwas realized only for G. a. allenbyi in allopatry. Furthermore,in allopatry, occupant G. a. allenbyi individuals with highcompetitive ranks were involved in aggressive interactions atlower rates than those with low competitive ranks. However,in sympatry, patch-use behavior of occupant G. a. allenbyi individualswas mainly influenced by aggressive behavior of G. pyramidum,which did not respond to their competitive rank. Thus, it shouldpay less for G. a. allenbyi to be aggressive in sympatric populations.The observed reduction in intraspecific aggression among individualG. a. allenbyi in the presence of G. pyramidum supports thisassertion. We suggest that this reduction likely weakens thenegative effect of intra- and interspecific density on the percapita growth rate of G. a. allenbyi. Because this would changethe slope of the isocline of G. a. allenbyi, it could be animportant mechanism promoting coexistence when habitat selectionis constrained.     

Enhanced Activity of DNA Polymerase Iota in Mouse Brain Cells Is Associated with Aggressiveness

Recent studies performed with crude extracts of mouse tissues showed that the activity of DNA-polymerase iota (Pol iota) can be detected only in brain and testis extracts. To assess whether the activity of Pol iota is associated with animal behavior, we determined Pol iota activity in brain extracts of mice of two lines sharply differing in aggressiveness (RSB and RLB). We found that Pol iota activity in the mice with aggressive behavior was three times higher than in the less aggressive mice. The possible relationship between the activity of Pol iota and animal behavior is discussed.     

Lorenz was right, or does aggressive energy accumulate?

Evidence supporting the fact that inherited mechanisms of regulation of aggressive behavior as a result of a repeated experience of aggression ending in victories are transformed into pathological mechanisms based on accumulation of neurochemical shifts in the brain, enhancing aggressiveness, and forming aggressive motivation in aggressive winners. This confirms the concept by Lorenz on the existence of a mechanism (but not instinct) of a spontaneous accumulation of aggressive energy that needs a discharge and formation of permanent attraction to manifestation of aggression.     

Lorenz Was Right! Or Does Aggressive Energy Accumulate?

Evidence supporting the fact that innate mechanisms of regulation of aggressive behavior as a result of a repeated experience of aggression ending in victories are transformed into pathological mechanisms based on accumulation of neurochemical shifts in the brain, enhancing aggressiveness, and forming aggressive motivation in aggressive winners. This confirms the concept by Lorenz on the existence of a mechanism (but not instinct) of a spontaneous accumulation of aggressive energy that needs a discharge and formation of permanent attraction to manifestation of aggression.     

EEG correlates of aggression and anxiety in a social interaction model

Aggressiveness- and anxiety-related behavioral and oscillatory patterns were investigated in 49 18-30 year old subjects during virtual social interactions. The subjects were presented with pictures of "angry", "happy", and "neutral" faces and had to choose one out of three options: "attack", "avoid", or "make friends". Sources of cortical EEG were localized with sLORETA software. Subjects with high aggressiveness chose attack more frequently and this behavior was accompanied by a stronger induced delta and theta synchronization in the right orbitofrontal cortex. In subjects with high anxiety, delta and theta responses were stronger induced in the right temporal cortex during their more frequent avoidance behavior. Thus, both in anxious and in aggressive subjects, typical behavior was accompanied by increased induced low-frequency synchronization whose localization implies that it is associated with motivational and emotional processes.     

Social isolation increases male aggression toward females in the field cricket Gryllus bimaculatus

Social isolation has often been reported to facilitate male aggressiveness in various animal species. If social isolation also escalates male aggressive behavior towards females, the mating success of the aggressive males will be low. This study evaluated the effect of social isolation on mating behavior in the field cricket Gryllus bimaculatus, which has traditionally been considered to be an asocial species. The results showed that social isolation from same-sex individuals enhanced male aggressiveness to females, and the mating success of aggressive males was reduced under the experimental conditions. More aggressive males exhibited a longer latency to court than less aggressive males. These results suggest that because male aggressiveness causes a delay in courtship, aggressive males may have reduced mating success. This demonstrated that social relationships are a critical factor affecting male mating success, even if the species is normally considered solitary.     

Imbalance Between Nitric Oxide and Dopamine May Underly Aggression in Acute Neurological Patients

The neurochemical basis of aggressive behavior in humans is not fully understood. In this study we explored the relationship between aggressiveness (as measured by the Overt Aggression Scale), cognitive performance (as measured by the Mini Mental State Examination), and biochemical markers of dopamine neurotransmission (homovanillic acid, HVA) and nitric oxide synthesis (nitrite plus nitrate, NO _x ) in cerebrospinal fluid from 70 patients with acute brain disorders, mainly brain infections. Aggressive behavior and cognitive performance showed an inverse correlation. NO _x /HVA ratio was inversely correlated to aggressive behavior, and positively correlated to cognitive performance. A subanalysis with antipsychotic-naïve patients confirmed those results. The balance between nitric oxide and dopamine could be related to the cognitive control of aggressive impulse.     

The influence of sex, line, and fight experience on aggressiveness of the Siamese fighting fish in intrasexual competition

We examined the influence of sex, line, i.e., broods from different parents, and previous fight experience on the aggressiveness of the Siamese fighting fish Betta splendens in intrasexual competition. The innate aggressiveness of the fish against their mirror images was measured on the day prior to the direct fight with other individuals, and it was found to be influenced by the line type but not by the sex. In the direct fight with other individuals, the males invested more effort in the fight than the females. In addition, the individuals of a particular line that exhibited a lower innate aggressiveness spent less time in the direct fight and were often losers when compared with those of other lines. After the direct fight with other individuals, the aggressiveness of the fish against their mirror images was remarkably influenced by the outcome of the direct fight, i.e., the winners exhibited more aggressive behavior, whereas the losers exhibited a lesser degree of aggressive behavior. This influence of the previous fight experience on subsequent aggressiveness was the greatest in the individuals of the line that have exhibited the lowest innate aggressiveness. However, the positive effect of the winning experience or the negative effect of the losing experience on subsequent aggressiveness decreased following several days after the previous fight increased.     

Effects of prolonged estrogen-progesterone treatment and hypophysectomy on the stimulation of short-latency maternal behavior and aggression in female rats

Two experiments were undertaken to examine the stimulation of home-cage and/or maternal aggressiveness by a hormonal treatment stimulating short-latency maternal behavior. Nonpregnant ovariectomized rats were treated with a 16-day regimen providing pregnancy levels of estrogen (E, 5-mm Silastic capsule) and progesterone (P, daily injection of 4 mg) followed by E and P withdrawal, with or without a terminal injection of estradiol benzoate (EB, 5 micrograms/kg). In Experiment 1, hormonally treated and control females were exposed continuously to pups and tested for aggression toward male intruders on the fifth day of pup exposure. Females receiving E/P/Oil and E/P/EB were highly aggressive whether or not they had yet shown maternal behavior, whereas vehicle-treated females were nonaggressive. In Experiment 2, hypophysectomized (HYPX) and Sham-HYPX females received either E/P/EB or a control treatment and were tested with male intruders (a) immediately preceding and (b) on the fifth day of continuous pup exposure. HYPX and Sham-HYPX females treated with E/P/EB were almost equally aggressive both preceding and following pup exposure (during which they initiated maternal care), whereas HYPX and Sham-HYPX vehicle-treated females were nonaggressive at both tests. In contrast, maternal behavior latencies were reduced by E/P/EB only among Sham-HYPX females. The results establish that an E/P/EB-treatment which elicits short-latency maternal responses also increases aggressiveness toward intruders. Pituitary products, although involved in the mediation of maternal responsiveness, do not contribute significantly to the stimulation of female aggressiveness by ovarian hormones.