Induction of metallothionein by superantigenic bacterial exotoxin: probable involvement of the immune system

Metallothionein (MT) can be induced in mouse liver by a bacterial exotoxin, toxic shock syndrome toxin-1 (TSST-1). Hepatic MT was induced by TSST-1 in a dose-dependent manner from 100 μg/kg through 3 mg/kg in CF-1 mice, and by 6 h the induction was almost maximal. The increase of hepatic MT occurred at the mRNA level, also, and both MT-I and II mRNAs increased coordinately. Because TSST-1 is a superantigen, it was investigated whether TSST-1 induces MT through cytokines as a consequences of immunostimulation. In low-cytokine-producing mice (C3H/HeJ), up to a dose of 1 mg/kg of TSST-1, there was only 2- to 3-fold increase of hepatic MT. In contrast, in normal-cytokine-producing mice (C3Heb/FeJ), TSST-1 increased MT in a dose-dependent manner, and at a dose of 1 mg/kg, there was a 25-fold increase in hepatic MT. This suggests that activation of the immune system is probably involved in the induction of MT by TSST-1. Studies on the role of specific hepatic cytokines (IL-1, TNF-α, and IL-6) in TSST-mediated hepatic MT induction showed that TSST-1 did not increase hepatic IL-1 or TNF-α significantly over controls in any of the mouse strains studied. In contrast, TSST-1 induced hepatic IL-6 in all three strains of mice. However, in CF-1 and C3Heb/FeJ mice (normal-cytokine-producing) IL-6 induction preceded MT mRNA induction, but in C3H/HeJ mice (low-cytokine-producing), IL-6 induction did not precede MT and mRNA induction.     

Effects of exogenous abscisic acid on some physiological responses in a popular aromatic indica rice compared with those from two traditional non-aromatic indica rice cultivars

The poor productivity and local confinement of indigenous aromatic rice varieties are mostly due to their susceptibility to salinity/drought/abscisic acid (ABA)-mediated abiotic stresses. It is thus essential to study the effects of several stress factors on their physiological parameters so as to improve their tolerance mechanism and enhance their global demand. Previously, we studied the effect of salinity stress on the physiological and molecular responses of the common aromatic rice Gobindobhog. The objective of this study was to understand the influence of exogenous ABA on some biochemical parameters in Gobindobhog, and comparison with those from non-aromatic M-1-48 and Nonabokra rice. The highest endogenous hydrogen peroxide content and membrane lipid peroxidation (increased malondialdehyde and lipoxygenase activity) were found in ABA-treated Gobindobhog leaves. While the catalase activity was down regulated the most in ABA-treated Gobindobhog leaves, the guaiacol peroxidase activity was induced maximally, indicating the protective role of peroxidase rather than catalase, during ABA-induced oxidative damages. The antioxidant, anthocyanin, showed the highest level in ABA-treated Nonabokra. Enhanced cysteine, following ABA exposure and the highest levels of reducing sugars, total amino acids, proline, and polyamines (putrescine and spermidine) recorded in Gobindobhog, probably served to shield from ABA-induced stress injuries, whereas the spermine levels were comparable in ABA-treated Nonabokra and Gobindobhog. The aroma content, intensified after ABA treatment, was markedly noted in Gobindobhog. Thus, the systematic examination of ABA-mediated stress revealed the most prominent oxidative damages in Gobindobhog, even higher than M-1-48, with a concomitant enhancement in peroxidase system and particularly osmolyte or polyamine levels to ensure its sustenance.     

Strength of Gamma Rhythm Depends on Normalization

Neuronal assemblies often exhibit stimulus-induced rhythmic activity in the gamma range (30–80 Hz), whose magnitude depends on the attentional load. This has led to the suggestion that gamma rhythms form dynamic communication channels across cortical areas processing the features of behaviorally relevant stimuli. Recently, attention has been linked to a normalization mechanism, in which the response of a neuron is suppressed (normalized) by the overall activity of a large pool of neighboring neurons. In this model, attention increases the excitatory drive received by the neuron, which in turn also increases the strength of normalization, thereby changing the balance of excitation and inhibition. Recent studies have shown that gamma power also depends on such excitatory–inhibitory interactions. Could modulation in gamma power during an attention task be a reflection of the changes in the underlying excitation–inhibition interactions? By manipulating the normalization strength independent of attentional load in macaque monkeys, we show that gamma power increases with increasing normalization, even when the attentional load is fixed. Further, manipulations of attention that increase normalization increase gamma power, even when they decrease the firing rate. Thus, gamma rhythms could be a reflection of changes in the relative strengths of excitation and normalization rather than playing a functional role in communication or control.