Protein synthesis is defended in the mitochondrial fraction of gill but not heart in cunner (Tautogolabrus adspersus) exposed to acute hypoxia and hypothermia

The cunner, Tautogolabrus adspersus, is a north-temperate teleost which relies upon metabolic depression to survive the extreme low water temperatures of its habitat during the winter. Previous study has demonstrated a decrease in protein synthesis accompanies the metabolic depression observed at the whole animal level during seasonal low temperature exposure. As such, the objective of the current study was to determine: (i) if the response of decreased protein synthesis is conserved across environmental stressors and (ii) if the response of metabolic depression is conserved across levels of cellular organization. This was accomplished through the measurement of in vivo protein synthesis rates in the whole tissue, cytosolic and mitochondrial protein pools (reflective of nuclear encoded proteins imported into mitochondria) of heart and gill in cunner exposed to either acute low temperature (8–4°C) or acute hypoxia (10% O₂ saturation). In both heart and gill, rates of protein synthesis in the whole tissue and cytosolic protein pools were substantially depressed by 80% in response to acute hypothermia. In hypoxic heart, protein synthesis was significantly decreased by 50–60% in the whole tissue, cytosolic and mitochondrial pools; however, in gill there was no significant difference in rates of protein synthesis in any cellular fraction between normoxic and hypoxic groups. Most strikingly the rate of new protein accumulation in the mitochondrial fraction of gill did not change in response to either a decrease in temperature or hypoxia. The defense of protein synthesis in the gill is most likely associated with the importance of maintaining ionic regulation and the oxidative capacity in this front line organ for gas and ion exchange.     

急性低氧/复氧胁迫对克氏原螯虾抗氧化-能量代谢的影响

为研究低氧/复氧胁迫对克氏原螯虾(Procambarus clarkii)抗氧化及能量代谢的影响,将克氏原螯虾暴露于(1.0±0.1) mg/L急性低氧胁迫和后续(6.8±0.2) mg/L复氧环境中,于低氧胁迫1h、6h及复氧1h、12h分别采集肝胰腺、鳃和血淋巴,研究低氧/复氧胁迫下克氏原螯虾抗氧化-能量代谢酶的活力变化,分析鳃和肝胰腺组织的超微结构改变。在低氧胁迫下,肝胰腺和血淋巴中SOD酶活力显著下降(P<0.05);复氧以后,肝胰腺、血淋巴及鳃组织中SOD酶活力均出现了显著上升(P<0.05)。SOD酶活力变化可能与复氧过程中超氧阴离子自由基的过量产生有关。在复氧12h后,血淋巴和鳃组织中MDA含量均出现了显著性增加(P<0.01),提示机体细胞在复氧胁迫下产生了脂质过氧化。在低氧胁迫下,肝胰腺、鳃和血淋巴中ACP、AKP酶活力显著上升(P<0.05);在复氧12h后,肝胰腺和鳃组织中ACP酶活力显著降低(P<0.01)。显示低氧/复氧胁迫影响了机体的非特异性免疫应答。在急性低氧胁迫下,肝胰腺、血淋巴与鳃组织中的LDH含量和总ATPase活力均显...     

Phenotypic plasticity and the possible role of genetic assimilation: Hypoxia-induced trade-offs in the morphological traits of an African cichlid

In this study we investigate the possible role of phenotypic plasticity and genetic assimilation in the process of adaptation and evolutionary change in the cichlid Pseudocrenilabrus multicolor victoriae . In the field we compared a population of a stable hypoxic habitat with one of a stable well-oxygenated habitat. In the laboratory, we compared individuals from the same mother raised under hypoxic or well-oxygenated conditions to examine phenotypic plasticity. Morphological parameters of three categories were measured: (a) the gill apparatus, (b) the surrounding structural elements, and (c) the outer shape of the fish. Swamp-dwelling fish had a 29% greater total gill surface area than fish from the well-oxygenated habitat due to their larger gill filament length and greater lamellar area. In the plasticity experiment, total gill surface area was 18% greater in the hypoxia group due to a larger number of longer filaments. Surrounding elements and outer shape also differed between the field populations and between fish grown under hypoxic and well-oxygenated conditions, but there was disparity between the field results and the plasticity experiment. The disparity between field and experimental fish may be due to: (a) differences in selection pressures between populations, (b) different constraints for genetic and plasticity changes, or (c) selection against plastic responses to hypoxia. Our results suggest that both (a) and (c) are involved.     

Expression levels of genes associated with oxygen utilization,glucose transport and glucose phosphorylation in hypoxia exposed Atlantic cod (Gadus morhua)

Expression level of genes associated with oxygen [cytochrome oxidase 1 (COX1) and myoglobin (Mb)] and glucose utilization [glucose transporters (GLUTs) and hexokinases (HKs)] along with metabolic indices were determined in Atlantic cod (Gadus morhua) subjected to an hypoxic challenge of < 45% oxygen saturation for 24 days. There were two closely related HKs considered to be homologues of mammalian HKIs. HKIa and HKIb share 86% sequence identity and are both ubiquitously expressed. Mb was also expressed in many tissues with highest levels occurring in heart. Over the first 15 days of hypoxia there were transient increases in plasma lactate in hypoxic relative to normoxic fish associated with a significant decrease in liver glycogen. Over days 1–6, there were in ten of eleven cases, increased average (with a number of conditions being statistically significant) expression levels of GLUTs (1, 2, 4) and HKs (1a and b) in gill, heart, liver, and white muscle in hypoxic relative to normoxic fish. There were significant increases in COX1 and Mb expression levels in gill by day 24 but no changes in these aerobic indicators in heart or liver. Overall the data suggest a transient increase in genes associated with glucose utilization during the early part of the hypoxic challenge followed by alterations in gene expression in gill.     

Hypoxia and interdemic variation in Poecilia latipinna

Variation in respiratory traits was quantified between two populations of the sailfin molly Poecilia latipinna (one from a periodically hypoxic salt marsh, Cedar Key, and one from a chronically normoxic river site, Santa Fe River). Two suites of characters were selected: traits that may show both short‐term acclimation response and interdemic variation in acclimation response (metabolic rate, critical oxygen tension and respiratory behaviour), and those that are not likely to respond to short‐term acclimation but may vary among populations (gill morphometric characters). Sailfin mollies from the salt marsh, acclimated to hypoxia (1 mg l⁻¹, c . 20 mmHg) for 6 weeks, spent less time conducting aquatic surface respiration and had lower gill ventilation rates than hypoxia‐acclimated conspecifics from the well‐oxygenated river site. Poecilia latipinna acclimated to hypoxia exhibited a lower critical oxygen tension ( P _c) than fish acclimated to normoxia; however, there was also a significant population effect. Poecilia latipinna from Cedar Key exhibited a lower P _c than fish from the Santa Fe River, regardless of acclimation. Cedar Key fish had a 14% higher mean gill surface area relative to fish from the Santa Fe River, a character that could account, at least in part, for their greater tolerance to hypoxia.     

Decreased genetic variation in metabolic variables of Litopenaeus vannamei shrimp after exposure to acute hypoxia

Concentration of proteins, carbohydrates, lactate, total lipids, acylglycerides, and carotenoids in shrimp were evaluated for their changes under acute hypoxia, and for their genetic variation under normoxic and hypoxic conditions. Proteins and lactate concentrations in muscle and hepatopancreas were significantly higher and carbohydrates in hepatopancreas were decreased in the hypoxic group. Family variances were significantly different only for proteins and carbohydrates in hepatopancreas in the normoxic group, indicating the existence of genetic variation for these traits. When family variances for each biochemical component were compared between normoxic and hypoxic groups, it was seen that most decreased. However, total variance was not significantly changed in response to hypoxia except for lactate (increased) and carotenoids (decreased) in hepatopancreas. The decrease in genetic variance without an increase in phenotypic variances in an acute response to hypoxia might be related to the known suppression of metabolic pathways that either use or produce ATP, which could result in a decreased expression of additive genes.     

低氧胁迫和恢复对杂交黄颡鱼“黄优1号”肠道组织的影响

为探究低氧胁迫和恢复对杂交黄颡鱼(Pelteobagrus fulvidraco) “黄优1号”肠道组织的影响, 研究运用酶活测定、HE染色、qRT-PCR、TUNEL检测及16S rRNA测序技术等方法, 分析低氧胁迫[(1.0±0.1) mg/L]和恢复下[(7.0±0.5) mg/L]该鱼肠道氧化应激指标、组织结构形态、细胞凋亡及微生物组成变化。结果显示: (1)在低氧胁迫下肠道中抗氧化酶活性(SOD、CAT、GSH-Px)、能量代谢酶活性(LDH)、丙二醛(MDA)和脂质过氧化物(LPO)含量显著升高, 恢复溶氧后氧化应激反应也比较剧烈。(2)低氧胁迫阶段, 肠道组织受损现象逐渐加剧, 杯状细胞肿胀、黏膜层被侵蚀, 恢复溶氧24h后, 缺氧引起的生理变化并未得到明显改善。(3)肠道组织细胞凋亡程度随着低氧时间的延长而加剧, 凋亡相关基因(bax、caspase9和p53)的表达量显著升高, bcl-2基因的表达量则减少。(4)低氧胁迫阶段肠道微生物相对丰度降低, 低氧胁迫72h的处理组中以厚壁菌门(Firmicutes)(47.8%)和拟杆菌门(Bacteroidetes)(40.6%)的丰度最为优势, 恢复溶氧后肠道菌群数量有所增加; KEGG功能预测显示, 多数肠道微生物与代谢通路相关。研究结果可为解析低氧和恢复下杂交黄颡鱼“黄优1号”肠道组织内环境稳态调控机制提供理论依据。     

A Genome-Wide Analysis of the Gene Expression and Alternative Splicing Events in a Whole-Body Hypoxic Preconditioning Mouse Model

Exposure to specific doses of hypoxia can trigger endogenous neuroprotective and neuroplastic mechanisms of the central nervous system. These molecular mechanisms, together referred to as hypoxic preconditioning (HPC), remain poorly understood. In the present study, we applied RNA sequencing and bioinformatics analyses to study HPC in a whole-body HPC mouse model. The preconditioned (H4) and control (H0) groups showed 605 differentially expressed genes (DEGs), of which 263 were upregulated and 342 were downregulated. Gene Ontology enrichment analysis indicated that these DEGs were enriched in several biological processes, including metabolic stress and angiogenesis. The Kyoto Encyclopedia of Genes and Genomes enrichment analysis showed that the FOXO and Notch signaling pathways were involved in hypoxic tolerance and protection during HPC. Furthermore, 117 differential alternative splicing events (DASEs) were identified, with exon skipping being the dominant one (48.51%). Repeated exposure to systemic hypoxia promoted skipping of exon 7 in Edrf1 and exon 9 or 13 in Lrrc45. This study expands the understanding of the endogenous protective mechanisms of HPC and the DASEs that occur during HPC.