Absence of the gut microbiota enhances anxiety-like behavior and neuroendocrine response to acute stress in rats.

BACKGROUND AND AIMS: Establishment of the gut microbiota is one of the most important events in early life and emerging evidence indicates that the gut microbiota influences several aspects of brain functioning, including reactivity to stress. To better understand how the gut microbiota contributes to a vulnerability to the stress-related psychiatric disorders, we investigated the relationship between the gut microbiota, anxiety-like behavior and HPA axis activity in stress-sensitive rodents. We also analyzed the monoamine neurotransmitters in the brain upper structures involved in the regulation of stress and anxiety. METHODS: Germfree (GF) and specific pathogen free (SPF) F344 male rats were first subjected to neurological tests to rule out sensorimotor impairments as confounding factors. Then, we examined the behavior responses of rats to social interaction and open-field tests. Serum corticosterone concentrations, CRF mRNA expression levels in the hypothalamus, glucocorticoid receptor (GR) mRNA expression levels in the hippocampus, and monoamine concentrations in the frontal cortex, hippocampus and striatum were compared in rats that were either exposed to the open-field stress or not. RESULTS: GF rats spent less time sniffing an unknown partner than SPF rats in the social interaction test, and displayed a lower number of visits to the aversive central area, and an increase in latency time, time spent in the corners and number of defecations in the open-field test. In response to the open-field stress, serum corticosterone concentrations were 2.8-fold higher in GF than in SPF rats. Compared to that of SPF rats, GF rats showed elevated CRF mRNA expression in the hypothalamus and reduced GR mRNA expression in the hippocampus. GF rats also had a lower dopaminergic turnover rate in the frontal cortex, hippocampus and striatum than SPF rats. CONCLUSIONS: In stress-sensitive F344 rats, absence of the gut microbiota exacerbates the neuroendocrine and behavioral responses to acute stress and the results coexist with alterations of the dopaminergic turnover rate in brain upper structures that are known to regulate reactivity to stress and anxiety-like behavior.

Early stress leads to effects on estrous cycle and differential responses to stress.

Women are more susceptible than men to stress-related mental disorders. However, few animal studies have been conducted on females. Given the interactions between gonadic hormones and the hypothalamo-pituitary-adrenal (HPA) axis, we hypothesized that the effects of early stress may be different between males and females depending on the state of their estrous cycle. Using adult Long-Evans rats of both genders, the effects of maternal deprivation were investigated on the estrous cycle length, corticosterone levels after food deprivation or restraint stress procedures, and the negative feedback efficiency of dexamethasone on the HPA axis. The individual length of the estrous cycle was evaluated using vaginal smears. Non-deprived (AFR) females mainly exhibited regular 5-day cycles (40% of the population) and 4-5-day cycles (26%), with fewer 4-day cycles (18%) and irregular cycles (16%). Comparatively, deprived (D) females displayed a significant decrease of 5-day cycles (24%) and a significant increase of irregular cycles (28%). After the restraint stress procedure, D females exhibited higher corticosterone level than AFR females during proestrous. After the food deprivation procedure, D and AFR females maintained dose-response sensitivity to the negative feedback induced by dexamethasone but only during proestrous. No differences were observed between D and AFR males under these experimental conditions. These data highlight the importance of early environmental factors in regulating the spontaneous pattern of the estrous cycle as well as gender- and stressor-dependent sensitivity of the HPA axis according to steroid levels.

Isatin binding proteins in rat brain: in situ imaging, quantitative characterization of specific [3H]isatin binding, and proteomic profiling.

Isatin (indole-2,3-dione) is an endogenous indole that has a distinct and discontinuous distribution in the brain and in other mammalian tissues and body fluids. Its output is increased under conditions of stress and anxiety. Its biological targets remain poorly characterized, although [(3)H]isatin binding sites have been demonstrated in various brain structures. In this study, by using a real-time beta-imager, [(3)H]isatin radioligand binding analysis, and proteomic identification of proteins specifically bound to the affinity sorbent 5-aminocaproyl-isatin-Sepharose, we have investigated the distribution of [(3)H]isatin specific binding sites in the rat brain, characterized their K(d) and B(max), and identified some individual brain isatin binding proteins. The binding of [(3)H]isatin to rat brain sections was saturable and characterized by K(d) values (of 0.2-0.3 microM) consistent with physiological concentrations. The highest B(max) was found in the hypothalamus, consistent with a role in stress. In most brain regions, the homologous inhibition of [(3)H]isatin binding by increasing concentrations of cold isatin demonstrated complex behavior suggesting involvement of various binding proteins characterized by different affinity to isatin. Affinity chromatography of Triton X-100 lysates of whole-brain homogenates on 5-aminocaproyl-isatin-Sepharose followed by subsequent proteomic analysis resulted in identification of 25 individual proteins, including glyceraldehyde-3-phosphate dehydrogenase, one of few previously reported isatin binding proteins, and a group of cytoskeleton-related proteins. These binding sites may be related to the known antiproliferative and proapoptotic activities of isatin.

5-hydroxyoxindole, an indole metabolite, is present at high concentrations in brain.

5-Hydroxyoxindole has been identified as a urinary metabolite of indole, which is produced from tryptophane via the tryptophanase activity of gut bacteria. We have demonstrated recently that 5-hydroxyoxindole is an endogenous compound in blood and tissues of mammals, including humans. To date, 5-hydroxyoxindole's role is unknown. The aim of this study was to compare 5-hydroxyoxindole levels in plasma and cerebrospinal fluid (CSF) during day-night and seasonal changes, as a common approach to pilot physiological characterization of any compound. Simultaneous blood and CSF sampling was performed in the ewe, because its size allows collection in quantities suitable for 5-hydroxyoxindole assay (HPLC-ED) in awake animals, without obvious physiological or behavioral disturbance. 5-Hydroxyoxindole concentration was quite stable in plasma (2-6 nM range), whereas, in CSF, it displayed marked day-night and photoperiodic variations (4-116 nM range). 5-Hydroxyoxindole levels in CSF were twofold higher at night than during the day and at least one order of magnitude higher during the long compared with the short photoperiod. These day/night and photoperiodic variations persisted after pinealectomy, indicating that 5-hydroxyoxindole rhythms in CSF are independent of melatonin formation. In conclusion, high levels of 5-hydroxyoxindole in the CSF during long photoperiod and its daily modulation suggest physiological involvement of 5-hydroxyoxindole in rhythmic adjustments in the brain, independently of the pineal gland.

Isatin: role in stress and anxiety.

(Indoledione 2,3) isatin is an endogenous indole found both in mammalian brain and peripheral tissues. Isatin concentration in blood can exceed 1 microM and tissue concentrations vary from < 0.1 to 10 microM. Its level in the brain and periphery is increased by stress. Isatin has a wide spectrum of behavioural and metabolic effects. It is anxiogenic at lower doses and sedative at higher doses. Its most potent known in vitro actions are as an antagonist of atrial natriuretic peptide (ANP) function and NO signaling. In this review, we discuss isatin and stress in animal models, the few human studies, and also what it is known to date about the molecular mechanisms of its action. We suggest the possibility that isatin and its analogues may be interesting new pharmacological agents; Isatin antagonists may be anxiolytic, and isatin agonists may activate the HPA axis.

Natriuretic peptide interaction with [3H]isatin binding sites in rat brain.

Isatin is an endogenous indole, which has a distinct and discontinuous distribution in the brain and exhibits a wide range of physiological and pharmacological effects. In the present study, we have demonstrated that atrial natriuretic peptide (ANP) and C-type natriuretic peptide (CNP) inhibited [3H]isatin binding to rat brain sections and isolated membrane fractions. Isatin itself antagonised not only natriuretic peptide receptor type A (NPR-A) (ANP-stimulation of guanylyl cyclase) but also NPR-C (ANP and CNP mediated inhibition of adenylyl cyclase) signalling. These results suggest that some [3H]isatin binding in the brain may be to NPR-A and NPR-C. Competitive interactions between isatin and natriuretic peptides and their receptors give a possible explanation of the known anxiogenic effect of low doses of isatin, interacting at NPR-A, and the sedative effects of higher doses, antagonising respectively the anxiolytic effect of ANP and the anxiogenic effect of CNP.

Inhibition of brain mitochondrial monoamine oxidases by the endogenous compound 5-hydroxyoxindole.

5-Hydroxyoxindole is a recently identified endogenous compound. Its physiological role remains unclear but certain evidence exists, that it may share some regulatory properties with isatin, a known endogenous inhibitor of monoamine oxidase (MAO) type B (MAO-B). In this study several oxidized indoles were tested for their in vitro inhibition of MAO type A (MAO-A) and B of rat brain non-synaptic mitochondria. 5-Hydroxyoxindole was less potent MAO-A inhibitor (IC50 56.8 microM) than isatin (31.8 microM) and especially 5-hydroxyisatin (6.5 microM), but it was the only highly selective MAO-A inhibitor among the all compounds studied (IC50 MAO-A:IC50 MAO-B = 0.044). Thus, the in vitro data suggest that MAO-A may represent potential target for 5-hydroxyoxindole.

Detection and quantification of 5-hydroxyoxindole in mammalian sera and tissues by high performance liquid chromatography with multi-electrode electrochemical detection.

OBJECTIVE: Since 5-hydroxyoxindole structurally related indole metabolites play different roles in some hepatic and neurologic disorders we found necessary to develop an assay to further investigate the physiologic relevance of this compound. METHODS: We have designed a convenient assay to determine 5-hydroxyoxindole in serum using solid phase extraction and a highly selective High Performance Liquid Chromatography system with multi-Electro Chemical Detection (HPLC-ECD). RESULTS: We have identified and quantified 5-hydroxyoxindole in various mammalian species. Its distribution in tissues showed that the molecule is also present in brain, liver, kidney and spleen, but not in skeletal muscle. CONCLUSIONS: 5-hydroxyoxindole is an endogenous tryptophan metabolite present in circulating blood and in some tissues at the nmol level, its determination using HPLC-ECD will be useful for elucidating the role of this molecule in normal and disease conditions.

In situ imaging of specific binding of [3H]isatin in rat brain.

Isatin is an endogenous indole that influences a range of processes both in vivo and in vitro. It has a distinct and discontinuous distribution in the brain, as well as in other mammalian tissues and body fluids. However, the distribution of isatin binding sites in the brain is not known. Using a real-time beta-imager we have investigated the distribution of [3H]isatin-specific binding in rat brain sections. The highest labeling was found in hypothalamic nuclei and in the cortex, hippocampus, and cerebellum. Administration of the mechanism based monoamine oxidase inhibitor, pargyline, reduced but did not abolish the specific binding of [3H]isatin in the rat brain. The distribution became cortex, cerebellum, hypothalamus > hippocampus > brain stem > thalamus approximately striatum.