Functional properties of flours and protein concentrates of 3 strains of the edible mushroom Pleurotus ostreatus.

Pleurotus ostreatus is an edible mushroom with significant nutritional properties and highly valuable protein concentrates can be obtained from its fruit bodies. Functional properties of flours and protein concentrates derived from 3 Pleurotus ostreatus strains (PCM, POS and hybrid PCM × POS) were evaluated in this investigation. Fruit bodies were produced on wheat straw substrate, flours were obtained from dried and grinded fruit bodies and protein concentrates were extracted from flours by alkaline solubilization. For all 3 strains, pale yellow flours were obtained and protein concentrates showed a grayish brown color. Flour bulk densities ranged from 0.52 to 0.64 g/mL, a higher value than those for protein concentrates, i.e. 0.30-0.35 g/mL. The highest water absorption capacities (WAC) were observed for flours (300-418.8%) while protein concentrates presented higher oil absorption capacity (OAC) (173.3-214.1%). Flours and protein concentrates presented a minimal gelation concentration of 2%. Protein concentrates showed a higher foam capacity formation (FC) at pH 8. Likewise, flours and protein concentrates presented higher foam stability (FS) at alkaline pH (8 and 10). Emulsion activity index (EAI) for flours ranged from 3.96 to 26.68 m2 g-1 whereas for protein concentrates ranged from 1.55 to 10.28 m2 g-1. These results indicate that flours and protein concentrates from P. ostreatus have remarkable functional properties, valuable in food industry where foaming and emulsifying properties are required.

Intense aversive training protects memory from the amnestic effects of hippocampal inactivation.

There is extensive evidence that amnestic treatments are less effective, or ineffective when administered to subjects that have been overtrained or subjected to high foot-shock intensities in aversively motivated learning. This protective effect has been found with a variety of learning tasks and with treatments that disrupt activity in several regions of the brain, including the hippocampus, amygdala, striatum, and substantia nigra. Such findings have been interpreted as suggesting that the brain regions disrupted are not critical sites for the memory processes induced by these types of training. In most experiments investigating this issue the amnestic treatments were administered after training. Thus, it might be less amnesia was induced because the training accelerated memory consolidation and, thus, the maximum effect of the amnestic treatment occurred after memory of the learning experience was consolidated. This study investigated this issue by inactivating the hippocampus of rats bilaterally with tetrodotoxin (TTX) (10 ng/side) 30 min before one-trial inhibitory avoidance training using relatively low (1.0 mA), medium (2.0 mA), or high (3.0 mA) foot-shock intensities. Retention of the task was measured 48 h after training. TTX produced a profound retention deficit, a mild deficit, and no deficit at all in the 1.0, 2.0, and 3.0 mA groups, respectively. These data confirm the protective effect of training with relatively high foot-shock intensity against experimentally induced amnesia, and suggests that this protection is not due to accelerated consolidation. Rather, the findings suggest that strong training activates brain systems other than those typically involved in mediating memory consolidation.

Spasmolytic effect of Alternanthera repens on isolated rat ileum.

Abstract Context: Alternanthera repens (L.) Kuntze (Amaranthaceae) is widely used in Mexican traditional medicine for the treatment of gastrointestinal disorders that are mainly related to diarrhea. Objective: The aim of the present study was to investigate the spasmolytic effect of hexane (Hx), methanol (Me) and aqueous (Aq) extracts as well as chromatographic Me fractions (F1-F6) of A. repens in rat ileum. Materials and methods: Dried and powdered aerial parts were used to obtain the extracts. The rat ileum preparations were incubated in Tyrode's solution gassed (95% O2-5% CO2) at 37 °C. The effect on the contractile response of isolated ileum was evaluated by obtaining cumulative concentration-response curves to CaCl2, KCl, 5-HT and acetylcholine in the absence and presence of different doses of Aq (0.56-2.09 mg/mL), Me (0.24-0.91 mg/mL) and Hx (0.24-0.91 mg/mL) extracts, as well as six Me fractions of 0.66 mg/mL (F1 to F6). Results: The A. repens Me (0.24 mg/mL) caused an inhibitory response of the Ca2+-induced contractions, with IC50 values of 0.18 ± 0.061 and 0.67 ± 0.061 mM in the presence and absence of the Me, respectively. Me fractions F2 to F4 presented a significant inhibitory effect (F(3,8) = 60.17, p = 0.0001), causing a reduction in the CaCl2-induced contractions and shifting the Ca2+ (0.39 to 1.81 mM) concentration-response curves to the right. With respect to the effect on 5-HT-induced contractions, IC50 values Hx extract (0.24 mg/mL) were 5.44 ± 0.08 × 10-6 M and 3.38 ± 0.07 × 10-6 M in the presence and absence of the Hx, respectively. Discussion and conclusion: The spasmolytic effects induced by Me and Me fractions of A. repens may involve a serotonergic and Ca2+ influx blockade mechanisms, which may justify the use of A. repens extracts as an effective traditional treatment against diarrhea.

Extinction procedure induces pruning of dendritic spines in CA1 hippocampal field depending on strength of training in rats.

Numerous reports indicate that learning and memory of conditioned responses are accompanied by genesis of dendritic spines in the hippocampus, although there is a conspicuous lack of information regarding spine modifications after behavioral extinction. There is ample evidence that treatments that typically produce amnesia become innocuous when animals are submitted to a procedure of enhanced training. We now report that extinction of inhibitory avoidance (IA), trained with relatively low foot-shock intensities, induces pruning of dendritic spines along the length of the apical dendrites of hippocampal CA1 neurons. When animals are trained with a relatively high foot-shock there is a high resistance to extinction, and pruning in the proximal and medial segments of the apical dendrite are seen, while spine count in the distal dendrite remains normal. These results indicate that pruning is involved in behavioral extinction, while maintenance of spines is a probable mechanism that mediates the protecting effect against amnesic treatments produced by enhanced training.

Amygdala or hippocampus inactivation after retrieval induces temporary memory deficit.

The hypothesis that memory is stored through a single stage of consolidation that results in a stable and lasting long-term memory has been challenged by the proposition that reactivation of a memory induces reconsolidation of the memory. The reconsolidation hypothesis is supported by evidence that, under some conditions, post-retrieval treatments affecting amygdala and hippocampus functioning impair subsequent retention performance. We now report that repeated retention testing attenuates the performance impairment induced by post-retrieval reversible inactivation of the amygdala and hippocampus of rats induced by tetrodotoxin. These findings challenge the reconsolidation hypothesis and suggest that the post-retrieval retention performance impairment is best explained as due to temporary retrieval failure.