Stimulation of σ1-receptor restores abnormal mitochondrial Ca mobilization and ATP production following cardiac hypertrophy

Background

We previously reported that the σ₁-receptor (σ₁R) is down-regulated following cardiac hypertrophy and dysfunction in transverse aortic constriction (TAC) mice. Here we address how σ₁R stimulation with the selective σ₁R agonist SA4503 restores hypertrophy-induced cardiac dysfunction through σ₁R localized in the sarcoplasmic reticulum (SR).

Methods

We first confirmed anti-hypertrophic effects of SA4503 (0.1–1 μM) in cultured cardiomyocytes exposed to angiotensin II (Ang II). Then, to confirm the ameliorative effects of σ₁R stimulation in vivo, we administered SA4503 (1.0 mg/kg) and the σ₁R antagonist NE-100 (1.0 mg/kg) orally to TAC mice for 4 weeks (once daily).

Results

σ₁R stimulation with SA4503 significantly inhibited Ang II-induced cardiomyocyte hypertrophy. Ang II exposure for 72 h impaired phenylephrine (PE)-induced Ca^2 + mobilization from the SR into both the cytosol and mitochondria. Treatment of cardiomyocytes with SA4503 largely restored PE-induced Ca^2 + mobilization into mitochondria. Exposure of cardiomyocytes to Ang II for 72 h decreased basal ATP content and PE-induced ATP production concomitant with reduced mitochondrial size, while SA4503 treatment completely restored ATP production and mitochondrial size. Pretreatment with NE-100 or siRNA abolished these effects. Chronic SA4503 administration also significantly attenuated myocardial hypertrophy and restored ATP production in TAC mice. SA4503 administration also decreased hypertrophy-induced impairments in LV contractile function.

Conclusions

σ₁R stimulation with the specific agonist SA4503 ameliorates cardiac hypertrophy and dysfunction by restoring both mitochondrial Ca^2 + mobilization and ATP production via σ₁R stimulation.

General significance

Our observations suggest that σ₁R stimulation represents a new therapeutic strategy to rescue the heart from hypertrophic dysfunction.     

Seasonal acclimatization to the hot summer over 60 days in the Republic of Korea suppresses sweating sensitivity during passive heating

The main objective of this study was to determine the central mechanisms involved in suppression of thermal sweating after seasonal acclimatization (SA) during passive heating (immersing the legs in 43 °C hot water for 30 min). Testing was performed in July (before-SA) and August (after-SA) [25.2±2.2 °C, 73.9±10.3% relative humidity (RH), Cheonan (Chungnam,126° 52′N, 33.38′E), in the Republic of Korea. All experiments were carried out in an automated climatic chamber (25.0±0.5 °C and RH 60.0±3.00%). Twelve healthy men (height, 174.6±5.40 cm; weight, 65.4±5.71 kg; age, 22.7±2.90 yr) participated. The local sweat onset time was delayed in the after-SA compared to that in the before-SA (p<0.001). The local sweat rate and whole body sweat loss volume decreased in the after-SA compared to those in the before-SA (p<0.001). In addition, evaporative loss volume decreased significantly in the after-SA compared to that in the before-SA [chest, upper-back, thigh and forearm (p<0.001)]. Changes in tympanic temperature and mean body temperature were significantly lower (p<0.05) and the basal metabolic rate decreased significantly in the after-SA compared to those in the before-SA (p<0.001). These results suggest that maintenance of a lower body temperature and basal metabolic rate can occur and blunt the central sudomotor mechanisms following seasonal acclimatization, which suppresses sweating sensitivity.     

Comparing methods for metabolic network analysis and an application to metabolic engineering

Bioinformatics tools have facilitated the reconstruction and analysis of cellular metabolism of various organisms based on information encoded in their genomes. Characterization of cellular metabolism is useful to understand the phenotypic capabilities of these organisms. It has been done quantitatively through the analysis of pathway operations. There are several in silico approaches for analyzing metabolic networks, including structural and stoichiometric analysis, metabolic flux analysis, metabolic control analysis, and several kinetic modeling based analyses. They can serve as a virtual laboratory to give insights into basic principles of cellular functions. This article summarizes the progress and advances in software and algorithm development for metabolic network analysis, along with their applications relevant to cellular physiology, and metabolic engineering with an emphasis on microbial strain optimization. Moreover, it provides a detailed comparative analysis of existing approaches under different categories.     

Chronic morphine exposure and its abstinence alters dendritic spine morphology and upregulates Shank1

Exposure to chronic drugs of abuse has been reported to produce significant changes in postsynaptic protein profile, dendritic spine morphology and synaptic transmission. In the present study we demonstrate alterations in dendritic spine morphology in the frontal cortex and nucleus accumbens of mice following chronic morphine treatment as well as during abstinence for two months. Such alterations were accompanied with significant upregulation of the postsynaptic protein Shank1 in synaptosomal enriched fractions. mRNA levels of Shank1 was also markedly increased during morphine treatment and during withdrawal. Studies of the different postsynaptic proteins at the protein and mRNA levels showed significant alterations in the morphine treated groups compared to that of saline treated controls. Taken together, these observations suggest that Shank1 may have an important role in the regulation of spine morphology induced by chronic morphine leading to addiction.     

Comprehending renin inhibitor’s binding affinity using structure-based approaches

The performance of several structure-based design (SBD) approaches in predicting the binding affinity of diverse small molecule inhibitors co-crystallized to human renin was assessed to ascertain the modeling tool and method of choice required when dealing with structure-based lead optimization projects. Most of the SBD approaches investigated here were able to provide qualitative guidance, but quantitative accuracy as well as decisive discrimination between [in]actives is still not within reach. Such an outcome suggests that the current methods need improvement to capture the overall physics of the binding phenomenon for consistent applications in a lead optimization setting.     

Discovery of a new type of scaffold for the creation of novel tyrosinase inhibitors

Tyrosinase is known as the key enzyme for melanin biosynthesis, which is effective in preventing skin injury by ultra violet (UV). In past decades, tyrosinase has been well studied in the field of cosmetics, medicine, agriculture and environmental sciences, and a lot of tyrosinase inhibitors have been developed for their needs. Here, we searched for new types of tyrosinase inhibitors and found phenylbenzoic acid (PBA) as a unique scaffold. Among three isomers of PBA, 3-phenylbenzoic acid (3-PBA) was revealed to be the most potent inhibitor against mushroom tyrosinase (IC₅₀ = 6.97 μM, monophenolase activity; IC₅₀ = 36.3 μM, diphenolase activity). The kinetic studies suggested that the apparent inhibition modes for the monophenolase and diphenolase activities were noncompetitive and mixed type inhibition, respectively. Analyses by in silico docking studies using the crystallographic structure of mushroom tyrosinase indicated that the carboxylic acid group of the 3-PBA could adequately bind to two cupric ions in the tyrosinase. To prove this hypothesis, we examined the effect of modification of the carboxylic acid group of the 3-PBA on its inhibitory activity. As expected, the esterification abrogated the inhibitory activity. These observations suggest that 3-PBA is a useful lead compound for the generation of novel tyrosinase inhibitors and provides a new insight into the molecular basis of tyrosinase catalytic mechanisms.     

水杨酸对大花三色堇幼苗耐热性的影响

大花三色堇性喜冷凉、忌酷热。该研究以大花三色堇3个自交系08H 、HAR 和 E01为材料,分别测定了40℃高温处理4、8和12 h 时不同基因型大花三色堇幼苗的生理指标,以及不同浓度(0.1、1、2 mmol?L-1)水杨酸预处理对热胁迫下大花三色堇幼苗耐热性的影响。结果表明：在高温胁迫下大花三色堇电解质外渗量增加,随着处理时间的延长,电解质外渗更多,可溶性糖含量先增加后降低,POD 酶活性先提高后降低;与其他2个自交系相比,HAR 表现出较好的耐热性,其可溶性糖含量、POD 酶活性的增加均较高,而电解质外渗率偏低;与对照相比,3种浓度 SA 预处理均显著降低了大花三色堇幼苗的电解质外渗率,增加了幼苗体内可溶性糖含量,提高了大花三色堇的幼苗体内脯氨酸含量和 POD 酶活性;其中1 mmol?L-1的 SA 预处理对高温胁迫下大花三色堇幼苗体内可溶性糖的含量增加最高,最大程度减缓幼苗体内的电解质外渗量,08H 和 HAR 的脯氨酸含量和 POD 酶活性达到最大值。而对 E01而言,0.1 mmol?L-1的水杨酸预处理的脯氨酸含量和 POD 酶活性最高。该研究结果探讨了高温胁迫下不同基因型大花三色堇幼苗的生理表现,以及外施水杨酸对增强大花三色堇幼苗耐热性的效果,为大花三色堇抗热栽培提供重要的基础资料。     

玉米SAUR基因家族的鉴定与生物信息学分析

为研究玉米早期应答生长素基因SAUR(Small auxin-up RNA)家族,本研究采用全基因组信息鉴定出91个玉米SAUR基因,命名为ZmSAUR。SAUR家族成员基因结构、氨基酸特点、染色体定位及基因进化分析表明,SAUR基因家族在染色体上呈现不均匀分布,其中2号染色体上数量最多为22个,基因的扩增模式为分散复制与片段复制。SAUR基因家族具有相对保守的结构,即包含1个保守的Rna DNA结构,SAUR蛋白的3D结构含有3个α螺旋和3个β折叠。根据多物种SAUR蛋白进化树分析将其分为9个分支,并分析发现玉米与物种相近的谷子聚在一起。这些信息为玉米SAUR基因家族功能分析奠定了一定的工作基础。