Involvement of a Novel TetR-Like Regulator (BdtR) of Bradyrhizobium diazoefficiens in the Efflux of Isoflavonoid Genistein.

A wide variety of leguminous plant-released (iso)flavonoids, such as genistein, are potential inducers of the nodulation (nod) genes of endosymbiotic rhizobia for the production of Nod factors, which are vital signaling molecules for triggering the symbiotic process. However, these (iso)flavonoids are generally thought to be toxic to the bacterial partner to varying degrees. Here, a novel TetR-like regulator gene of the soybean symbiont Bradyrhizobium diazoefficiens USDA110, bdtR (systematic designation blr7023), was characterized. It was found to be rapidly and preferentially induced by genistein, and its mutation resulted in significantly increased expression of the neighboring bll7019-bll7021 genes, encoding a multidrug resistance efflux pump system, in the absence of this isoflavonoid. Then, the transcriptional start site of BdtR was determined, and it was revealed that BdtR acted as a transcriptional repressor of the above efflux system through the binding of an AT-rich operator, which could be completely prevented by genistein. In addition, the ΔbdtR deletion mutant strain showed higher accumulation of extracellular genistein and became less susceptible to the isoflavonoid. In contrast, the inactivation of BdtR led to the significantly decreased induction of a nodulation gene (nodY) independent of the expression of nodD1 and nodW and to much weaker nodulation competitiveness. Taken together, the results show that BdtR plays an early sensing role in maintaining the intracellular homeostasis of genistein, helping to alleviate its toxic effect on this bacterium by negatively regulating neighboring genes encoding an efflux pump system while being essentially required for nodule occupancy competitiveness.[Formula: see text] Copyright © 2020 The Author(s). This is an open access article distributed under the CC BY-NC-ND 4.0 International license.

Effect of the timing of ice slurry ingestion for precooling on endurance exercise capacity in a warm environment.

It has been demonstrated that precooling with ice slurry ingestion enhances endurance exercise capacity in the heat. However, no studies have yet evaluated the optimal timing of ice slurry ingestion for precooling. This study aimed to investigate the effects of varying the timing of ice slurry ingestion for precooling on endurance exercise capacity in a warm environment. Ten active male participants completed 3 experimental cycling trials to exhaustion at 55% peak power output (PPO) after 15min of warm-up at 30% PPO at 30°C and 80% relative humidity. Three experimental conditions were set: no ice slurry ingestion (CON), pre-warm-up ice slurry ingestion (-1°C; 7.5gkg-1) (PRE), and post-warm-up ice slurry ingestion (POST). Rectal and mean skin temperatures at the beginning of exercise in the POST condition (37.1±0.2°C, 33.8±0.9°C, respectively) were lower than those in the CON (37.5±0.3°C; P<0.001, 34.8±0.8°C; P<0.01, respectively) and PRE (37.4±0.2°C; P<0.01, 34.6±0.7°C; P<0.01, respectively) conditions. These reductions increased heat storage capacity and resulted in improved exercise capacity in the POST condition (60.2±8.7min) compared to that in the CON (52.0±11.9min; effect size [ES]=0.78) and PRE (56.9±10.4min; ES=0.34) conditions. Ice slurry ingestion after warm-up effectively reduced both rectal and skin temperatures and increased cycling time to exhaustion in a warm environment. Timing ice slurry ingestion to occur after warm-up may be effective for precooling in a warm environment.

Involvement of a novel genistein-inducible multidrug efflux pump of Bradyrhizobium japonicum early in the interaction with Glycine max (L.) Merr.

The early molecular dialogue between soybean and the bacterium Bradyrhizobium japonicum is crucial for triggering their symbiotic interaction. Here we found a single large genomic locus that is widely separated from the symbiosis island and was conspicuously induced within minutes after the addition of genistein. This locus (named BjG30) contains genes for the multidrug efflux pump, TetR family transcriptional regulator, and polyhydroxybutyrate (PHB) metabolism. The induction of BjG30 by genistein was competitively inhibited by daidzein, although both genistein and daidzein are soybean-derived inducers of nodulation (nod) genes. Such a differential expression pattern is also observed in some legume-derived flavonoids, which structurally differ in the hydroxy/deoxy group at the 5-position. In addition, not only did the induction start far in advance of nodW and nodD1 after the addition of genistein, but the levels showed distinct concentration dependence, indicating that the induction pattern of BjG30 is completely different from that of nod genes. The deletion of genes encoding either the multidrug efflux pump or PHB metabolism, especially the former, resulted in defective nodulation performance and nitrogen-fixing capability. Taken together, these results indicate that BjG30, and especially its multidrug efflux pump, may play a key role in the early stage of symbiosis by balancing the dual functions of genistein as both a nod gene inducer and toxicant.

Temperature-dependent expression of type III secretion system genes and its regulation in Bradyrhizobium japonicum.

The genome-wide expression profiles of Bradyrhizobium japonicum in response to soybean (Glycine max (L.) Merr.) seed extract (SSE) and genistein were monitored with time at a low temperature (15 degrees C). A comparison with the expression profiles of the B. japonicum genome previously captured at the common growth temperature (30 degrees C) revealed that the expression of SSE preferentially induced genomic loci, including a large gene cluster encoding the type III secretion system (T3SS), were considerably delayed at 15 degrees C, whereas most nodulation (nod) gene loci, including nodD1 and nodW, were rapidly and strongly induced by both SSE and genistein. Induction of the T3SS genes was progressively activated upon the elevation of temperature to 30 degrees C and positively responded to culture population density. In addition, genes nolA and nodD2 were dramatically induced by SSE, concomitantly with the expression of T3SS genes. However, the deletion mutation of nodD2 but not nolA led to elimination of the T3SS genes expression. These results indicate that the expression of the T3SS gene cluster is tightly regulated with integration of environmental cues such as temperature and that NodD2 may be involved in its efficient induction in B. japonicum.