藏羚羊与藏绵羊心肌、骨骼肌中肌红蛋白含量和乳酸脱氢酶活性的比较

为了探讨藏羚羊(Pantholops hodgsonii)对低氧环境的适应机制。以生活在同海拔(4 300 m)的藏绵羊(Tibetan Sheep)为对照,用分光光度法测定2种动物心肌、骨骼肌中肌红蛋白(myoglobin,Mb)含量、乳酸(lactic acid,LD)含量及乳酸脱氢酶(lactate dehydrogenase,LDH)活力。结果显示,藏羚羊心肌和骨骼肌中Mb含量明显高于藏绵羊(P0.05),但心肌和骨骼肌的Mb含量无差别(P0.05),而藏绵羊心肌Mb含量明显高于骨骼肌(P0.05);藏羚羊心肌和骨骼肌中LD含量及LDH活力明显低于藏绵羊(P0.05),且2种动物心肌中的LDH活力均明显低于其骨骼肌(P0.01)。结果表明,藏羚羊尽管生活在高寒缺氧地区,其心肌和骨骼肌细胞仍然能得到丰富的氧供应,并非处于缺氧状态,这可能是通过增加心肌和骨骼肌中Mb的含量,提高其在低氧环境获取和储存氧的能力,从而提高有氧获能水平。与之相反,藏绵羊尽管也生活在高寒缺氧地区,但其心肌和骨骼肌中Mb含量相对于藏羚羊较低,且LD含量和LDH活力较高,说明其心肌和骨骼肌细胞内氧供不如藏羚羊丰富,提示藏绵羊可能主要以糖酵解获能。我们推测这种差异可能与两种动物不同的运动习性密切相关,且认为藏羚羊较高的Mb含量可能是其适应高原缺氧条件的分子基础之一。     

Cardiorespiratory performance in salmonids during exercise at high temperature: insights into cardiovascular design limitations in fishes

Studies in the laboratory with salmonids and now in the field with wild salmon clearly show that critical swimming performance has an optimum temperature. This temperature optimum is coincident with maximum aerobic scope and maximum cardiac scope. At a temperature that is higher than this optimum, however, whole animal performance declines abruptly. Evidence is presented here to suggest that this is directly associated with a decline in cardiac scope which limits oxygen supply to tissues. It is further suggested that the decline in maximum cardiac performance could reflect problems with the heart's own oxygen supply. The reasoning behind this suggestion is that, at temperatures at or below the optimum and probably because of a limitation on oxygen diffusion in skeletal muscle during exercise, venous oxygen does not fall below a threshold level during exercise, and so the heart receives just enough oxygen for its own muscular activity via the cardiac circulation (i.e. the venous return to the heart). However, because high temperature favours increased oxygen extraction by skeletal muscle, which consequently lowers venous oxygen, cardiac oxygen supply may become insufficient to meet cardiac oxygen demand. The hypoxic myocardium then cannot maintain cardiac scope and internal oxygen delivery to tissue declines.     

Phenotypic and genetic correlations of pork myoglobin content with meat colour and other traits in an eight breed-crossed heterogeneous population

Meat colour is one of the most important meat quality traits affecting consumption desire. Genetic improvement for meat colour traits is not so easy because pigs can be phenotyped only after slaughter. Besides the parameters from the optical instrument, other indexes that reflect the material basis of meat colour should be measured accurately and used in the genomic analysis. Myoglobin (Mb) is the main chemical component determining meat colour. However, to what extent the Mb content contributes to meat colour, and whether it can be used as a trait for pig breeding to improve meat colour, and the correlations of Mb content with complex porcine traits are largely unknown. To address these questions, we measured the muscle Mb content in 624 pigs from the 7th generation of a specially designed eight breed-crossed pig heterogeneous population, evaluated its phenotypic and genetic correlations with longissimus thoracis colour score at 24 h after slaughter. More than that, we also systematically phenotyped more than 100 traits on these animals to evaluate the potential correlations between muscle Mb content and economically important traits. Our results showed that the average muscle Mb content in the 624 pigs was 1.00 mg/g, ranging from 0.51 to 2.17 mg/g. We found that higher Mb content usually correlated with favourable meat colour, higher marbling score, less moisture content, and less drip loss. Genetic correlation analysis between muscle Mb content and 101 traits measured in this study shows that Mb content is also significantly correlated with 31 traits, including marbling, shear force, firmness, and juiciness. To our knowledge, this is one of the largest studies about the correlations of muscle Mb content with as many as 100 various traits in a large-scale genetically diversified population. Our results showed that the Mb content could be a selection parameter for the genetic improvement of meat colour. The selection for higher Mb content will also benefit marbling, shear force, firmness, and overall liking but might not affect the growth, carcass, and fat deposition traits.     

Expression patterns and adaptive functional diversity of vertebrate myoglobins

Recent years have witnessed a new round of research on one of the most studied proteins - myoglobin (Mb), the oxygen (O₂) carrier of skeletal and heart muscle. Two major discoveries have stimulated research in this field: 1) that Mb has additional protecting functions, such as the regulation of in vivo levels of the signaling molecule nitric oxide (NO) by scavenging and generating NO during normoxia and hypoxia, respectively; and 2) that Mb in vertebrates (particularly fish) is expressed as tissue-specific isoforms in other tissues than heart and skeletal muscle, such as vessel endothelium, liver and brain, as found in cyprinid fish. Furthermore, Mb has also been found to protect against oxidative stress after hypoxia and reoxygenation and to undergo allosteric, O₂-linked S-nitrosation, as in rainbow trout. Overall, the emerging evidence, particularly from fish species, indicates that Mb fulfills a broader array of physiological functions in a wider range of different tissues than hitherto appreciated. This new knowledge helps to better understand how variations in Mb structure and function may correlate with differences in animals' lifestyles and hypoxia-tolerance. This review integrates old and new results on Mb expression patterns and functional properties amongst vertebrates and discusses how these may relate to adaptive variations in different species. This article is part of a special issue entitled: Oxygen Binding and Sensing Proteins.     

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.     

Nitric oxide moves myoglobin centre stage

It has been proposed that myoglobin (Mb), besides being an oxygen carrier, plays the role of a nitric oxide (NO) scavenger in heart and skeletal muscle. A paper reporting data obtained using perfused hearts isolated from either wild-type or Mb-knockout mice provides the first experimental evidence for this novel function of Mb. The biochemical basis underlying the effects of NO on cardiac function is outlined in this article, beginning with the idea that this gas is an inhibitor of cytochrome-c oxidase. Some of the consequences of this new role of Mb and a molecular mechanism to account for the high reactivity of oxymyoglobin with NO are also briefly discussed.     

Directed sequencing and annotation of three Dicentrarchus labrax L. chromosomes by applying Sanger- and pyrosequencing technologies on pooled DNA of comparatively mapped BAC clones

Dicentrarchus labrax is one of the major marine aquaculture species in the European Union. In this study, we have developed a directed-sequencing strategy to sequence three sea bass chromosomes and compared results with other teleosts.Three BAC DNA pools were created from sea bass BAC clones that mapped to stickleback chromosomes/groups V, XVII and XXI. The pools were sequenced to 17-39x coverage by pyrosequencing. Data assembly was supported by Sanger reads and mate pair data and resulted in superscaffolds of 13.2 Mb, 17.5 Mb and 13.7 Mb respectively. Annotation features of the superscaffolds include 1477 genes. We analyzed size change of exon, intron and intergenic sequence between teleost species and deduced a simple model for the evolution of genome composition in teleost lineage.Combination of second generation sequencing technologies, Sanger sequencing and genome partitioning strategies allows “high-quality draft assemblies” of chromosome-sized superscaffolds, which are crucial for the prediction and annotation of complete genes.     

Temperature effects on aerobic scope and cardiac performance of European perch (Perca fluviatilis)

Several recent studies have highlighted how impaired cardiac performance at high temperatures and in hypoxia may compromise the capacity for oxygen transport. Thus, at high temperatures impaired cardiac capacity is proposed to reduce oxygen transport to a degree that lowers aerobic scope and compromises thermal tolerance (the oxygen- and capacity-limited thermal tolerance (OCLTT) hypothesis). To investigate this hypothesis, we measured aerobic and cardiac performance of a eurythermal freshwater teleost, the European perch (Perca fluviatilis). Rates of oxygen consumption were measured during rest and activity at temperatures between 5 °C and 27 °C, and we evaluated cardiac function by in vivo measurements of heart rate and in vitro studies to determine contractility of myocardial strips. Aerobic scope increased progressively from 5 °C to 21 °C, after which it levelled off. Heart rate showed a similar response. We found little difference between resting and active heart rate at high temperature suggesting that increased cardiac scope during activity is primarily related to changes in stroke volume. To examine the effects of temperature on cardiac capacity, we measured isometric force development in electrically paced myocardial preparations during different combinations of temperature, pacing frequency, oxygenation and adrenergic stimulation. The force-frequency product increased markedly upon adrenergic stimulation at 21 and 27 °C (with higher effects at 21 °C) and the cardiac preparations were highly sensitive to hypoxia. These findings suggest that at (critically) high temperatures, cardiac output may diminish due to a decreased effect of adrenergic stimulation and that this effect may be further exacerbated if the heart becomes hypoxic. Hence cardiac limitations may contribute to the inability to increase aerobic scope at high temperatures in the European perch (Perca fluviatilis).     

Vasoconstrictor-mediated thermogenesis present in perfused skeletal muscle but absent from perfused heart

Resting muscle thermogenesis as controlled by vasocontrictors was compared in rat hindlimb and cardiac muscle. An α-adrenergic agonist combination of phenylephrine+atenolol increased oxygen uptake and perfusion pressure in the constant flow hindlimb and neither increase was blocked by 10 μM tetrodotoxin. The same adrenergic combination also increased oxygen uptake and perfusion pressure in the perfused heart but the former along with beating was completely blocked by tetrodotoxin. Vasoconstriction by phenylephrine occurs in the heart but is not linked to thermogenic increases as in hindlimb, implying that all metabolic energy in heart is conserved for contractile activity. The findings highlight a fundamental difference between skeletal and cardiac muscle.     

High-Throughput Tissue Bioenergetics Analysis Reveals Identical Metabolic Allometric Scaling for Teleost Hearts and Whole Organisms

Organismal metabolic rate, a fundamental metric in biology, demonstrates an allometric scaling relationship with body size. Fractal-like vascular distribution networks of biological systems are proposed to underlie metabolic rate allometric scaling laws from individual organisms to cells, mitochondria, and enzymes. Tissue-specific metabolic scaling is notably absent from this paradigm. In the current study, metabolic scaling relationships of hearts and brains with body size were examined by improving on a high-throughput whole-organ oxygen consumption rate (OCR) analysis method in five biomedically and environmentally relevant teleost model species. Tissue-specific metabolic scaling was compared with organismal routine metabolism (RMO₂), which was measured using whole organismal respirometry. Basal heart OCR and organismal RMO₂ scaled identically with body mass in a species-specific fashion across all five species tested. However, organismal maximum metabolic rates (MMO₂) and pharmacologically-induced maximum cardiac metabolic rates in zebrafish Danio rerio did not show a similar relationship with body mass. Brain metabolic rates did not scale with body size. The identical allometric scaling of heart and organismal metabolic rates with body size suggests that hearts, the power generator of an organism’s vascular distribution network, might be crucial in determining teleost metabolic rate scaling under routine conditions. Furthermore, these findings indicate the possibility of measuring heart OCR utilizing the high-throughput approach presented here as a proxy for organismal metabolic rate—a useful metric in characterizing organismal fitness. In addition to heart and brain OCR, the current approach was also used to measure whole liver OCR, partition cardiac mitochondrial bioenergetic parameters using pharmacological agents, and estimate heart and brain glycolytic rates. This high-throughput whole-organ bioenergetic analysis method has important applications in toxicology, evolutionary physiology, and biomedical sciences, particularly in the context of investigating pathogenesis of mitochondrial diseases.     

Mechanistic Drivers of Flexibility in Summit Metabolic Rates of Small Birds

Flexible metabolic phenotypes allow animals to adjust physiology to better fit ecological or environmental demands, thereby influencing fitness. Summit metabolic rate (M_sum = maximal thermogenic capacity) is one such flexible trait. Skeletal muscle and heart masses and myocyte metabolic intensity are potential drivers of M_sum flexibility in birds. We examined correlations of skeletal muscle and heart masses and pectoralis muscle citrate synthase (CS) activity (an indicator of cellular metabolic intensity) with M_sum in house sparrows (Passer domesticus) and dark-eyed juncos (Junco hyemalis) to determine whether these traits are associated with M_sum variation. Pectoralis mass was positively correlated with M_sum for both species, but no significant correlation remained for either species after accounting for body mass (M_b) variation. Combined flight and leg muscle masses were also not significantly correlated with M_sum for either species. In contrast, heart mass was significantly positively correlated with M_sum for juncos and nearly so (P = 0.054) for sparrows. Mass-specific and total pectoralis CS activities were significantly positively correlated with M_sum for sparrows, but not for juncos. Thus, myocyte metabolic intensity influences M_sum variation in house sparrows, although the stronger correlation of total (r = 0.495) than mass-specific (r = 0.378) CS activity with M_sum suggests that both pectoralis mass and metabolic intensity impact M_sum. In contrast, neither skeletal muscle masses nor pectoralis metabolic intensity varied with M_sum in juncos. However, heart mass was associated with M_sum variation in both species. These data suggest that drivers of metabolic flexibility are not uniform among bird species.     

Gene expression and tissue distribution of cytoglobin and myoglobin in the Amphibia and Reptilia: possible compensation of myoglobin with cytoglobin in skeletal muscle cells of anurans that lack the myoglobin gene

Cytoglobin (Cygb), a recently discovered vertebrate cytoplasmic heme-binding globin, is considered to be in a clade with vertebrate myoglobin (Mb), which is exclusively distributed in the cytoplasm of cardiac and skeletal muscles as an oxygen storage protein. GenBank databases (NCBI and JGI) and gene synteny analyses showed the absence of the Mb gene (mb) in two anuran amphibians, Xenopus laevis and X. tropicalis. Here we conducted comparative studies on the gene expression and tissue distribution of Cygb and Mb in anuran and reptilian tissues. Cygb and Mb genes were cloned from a reptile, iguana (Iguana iguana). Two types of cygb (cygb-1 and -2) were cloned, with lengths of 1066 and 1034 bp, and 196 and 193 amino acid residues, respectively. Their nucleotide and amino acid sequence identities were 90 and 87%, respectively. The Mb gene covered 1416 bp with an open reading frame of 465 bp, giving rise to a 154 amino acid protein. The distal ligand-binding histidine at E7, the proximal heme-binding histidine at F8, and the phenylalanine residue at CD1 were conserved in Mb and Cygb. The nucleotide and amino acid sequence identity of I. iguana cygb-1 and cygb-2 against X. laevis cygb were approximately 67% and 65%, respectively. RT-PCR demonstrated that X. laevis cygb was uniquely expressed in the heart and skeletal muscles, and faintly in the liver and spleen, which was quite contrasted with Iguana and the other vertebrates, where mb is exclusively expressed in the heart and skeletal muscles. Immunohistochemical analyses showed the distribution of Cygb in the cytoplasm of skeletal muscle cells. Interestingly, Cygb in the heart was localized in the nuclei. Considering the absence of mb in the Anura, we hypothesize that Cygb in muscle cells of anurans compensates for the lack of Mb for the storage and intracellular transportation of oxygen.     

Circulation during hypoxia in birds

The effects of hypoxia on the avian cardiovascular system are reviewed. The avian cardiovascular system seems well adapted to deal with the stress of hypoxia. In general, birds are remarkably tolerant of hypoxia, with some species being capable of performing vigorous exercise at extreme altitude. During hypoxia at rest, the circulation maintains arterial pressure, increases cardiac output, and redistributes blood flow so oxygen delivery to the heart and brain is maintained. During exercise, further adjustments are required, since exercising muscle has large oxygen requirements. The mechanisms responsible for producing these circulatory changes are largely unknown. The transport steps that limit O2 delivery during hypoxia are also poorly understood.     

Gizzard myoglobin contents and feeding habits in avian species

In an attempt to consider physiological function of myoglobin (Mb), we determined Mb contents of gizzard smooth muscles with special reference to feeding habits in 85 avian species of 19 orders. The Mb content in 44 species of herbivorous birds was 7.52+/-3.81 mg/g wet muscle, which was significantly higher than the value of 2.34+/-1.74 mg/g in 41 species of carnivorous ones (P<0.001). Buffering capacity, as determined by in vitro titration method, was 37.3+/-5.5 slykes/g in gizzard smooth muscles of 75 species and 60.7+/-10.5 slykes in breast skeletal muscles of 77 species (P<0.001), which suggests a significantly higher dependence, almost comparable to cardiac muscles, of the gizzard muscular function on aerobic metabolism. Together with the fact that blood circulation in the gizzard is very low at resting, and might be further limited during activity, we conclude that the higher Mb content in gizzards of herbivorous birds is an adaptation, to allow storage and/or facilitated diffusion of oxygen, during process of high mechanical work required to grind down hard and fibrous vegetable food under the conditions of limited circulatory supply.     

Genome-wide association and pathway analysis of carcass and meat quality traits in Piemontese young bulls

A key concern in beef production is how to improve carcass and meat quality traits. Identifying the genomic regions and biological pathways that contribute to explaining variability in these traits is of great importance for selection purposes. In this study, genome wide-association (GWAS) and pathway-based analyses of carcass traits (age at slaughter (AS), carcass weight (CW), carcass daily gain (CDG), conformation score and rib-eye muscle area) and meat quality traits (pH, Warner-Bratzler shear force, purge loss, cooking loss and colour parameters (lightness, redness, yellowness, chroma, hue)) were conducted using genotype data from the ‘GeneSeek Genomic Profiler Bovine LD’ array in a cohort of 1166 double-muscled Piemontese beef cattle. The genome wide-association analysis was based on the GRAMMAR-GC approach and identified 37 significant single nucleotide polymorphisms (SNPs), which were associated with 12 traits (P<5 × 10⁻⁵). In particular, 14 SNPs associated with CW, CDG and AS were located at 38.57 to 38.94 Mb on Bos taurus autosome 6 and mapped within four genes, that is, Leucine Aminopeptidase 3, Family with Sequence Similarity 184 Member B, Non-SMC Condensin I Complex Subunit G and Ligand-Dependent Nuclear Receptor Corepressor-Like. Strong pairwise linkage disequilibrium was found in this region. For meat quality traits, most associations were 1 SNP per trait, except for a signal on BTA25 (at ~11.96 Mb), which was significant for four of the five meat colour parameters assessed. Gene-set enrichment analyses yielded significant results for six traits (right-sided hypergeometric test, false discovery rate <0.05). In particular, several pathways related to transmembrane transport (i.e., oxygen, calcium, ion and cation) were overrepresented for meat colour parameters. The results obtained provide useful information for genomic selection for beef production and quality in the Piemontese breed.     

Comparison of hypoxia-inducible factor-1 alpha in hypoxia-sensitive and hypoxia-tolerant fish species

Levels of oxygen can vary dramatically in aquatic environments. Aquatic organisms, including fishes, have adapted accordingly to survive. As there are both phylogenetically closely related fish species with differing oxygen requirements and distantly related species with similar oxygen requirements, fishes are good candidates for examining oxygen-related functions in vertebrates. We set out to investigate if sequence variation in the hypoxia-inducible factor-1 alpha (HIF-1α) gene is associated with variations in oxygen requirements. Since the teleost HIF-1α sequences available in databases represent a very limited dataset both phylogenetically and with regard to oxygen requirements, we have sequenced the protein coding sequence for HIF-1α from an additional 9 fish species. Our results indicate that the deduced HIF-1α proteins of teleost fishes are somewhat shorter than those of tetrapods. Additionally, the results suggest that tetrapod sequences more closely resemble the ancestral form of the protein than do teleost sequences. No clear signatures which could be associated with the oxygen requirements of the species were found. This study suggests that if species-specific differences in HIF-1α function with regards to oxygen dependence have evolved, they do not occur in the protein coding sequence but at other levels of the HIF-1α pathway.     

Performance of AAV8 vectors expressing human factor IX from a hepatic-selective promoter following intravenous injection into rats

The AAV9 capsid displays a high natural affinity for the heart following a single intravenous (IV) administration in both newborn and adult mice. It also results in substantial albeit relatively lower expression levels in many other tissues. To increase the overall safety of this gene delivery method we sought to identify which one of a group of promoters is able to confer the highest level of cardiac specific expression and concurrently, which is able to provide a broad biodistribution of expression across both cardiac and skeletal muscle. The in vivo behavior of five different promoters was compared: CMV, desmin (Des), alpha-myosin heavy chain (α-MHC), myosin light chain 2 (MLC-2) and cardiac troponin C (cTnC). Following IV administration to newborn mice, LacZ expression was measured by enzyme activity assays. Results showed that rAAV2/9-mediated gene delivery using the α-MHC promoter is effective for focal transgene expression in the heart and the Des promoter is highly suitable for achieving gene expression in cardiac and skeletal muscle following systemic vector administration. Importantly, these promoters provide an added layer of control over transgene activity following systemic gene delivery.     

Cardiac metabolism in high performance fish

In aerobic tissues, such as cardiac and skeletal muscle, short term increases in energy demand are met primarily by acute regulation of mitochondrial pathways. Chronic increases in time-average metabolic rate of an individual or tissue can lead to modest “physiological adaptations” that may result in increased metabolic capacities and more efficient energy production and utilization. These physiological adaptations differ fundamentally from those which alter metabolic rate acutely. Analysis of the metabolic strategies used by an individual to chronically elevate cardiac metabolic rates may help identify the components of cardiac metabolism which may be constrained or malleable over evolutionary time. While pronounced physiological differences in cardiac energy transduction are apparent across species, the evolutionary origins of such differences are difficult to assess. However, the functional consequences of such differences in homologous tissues across species can be discussed with more certainty. Both chronic hypermetabolic challenges and interspecies comparisons suggest highly oxidative tissues such as heart are restricted to strategies which a) elevate the functional mass b) make more efficient use of intracellular space devoted to mitochondria and c) shift toward more efficient metabolic fuels, primarily fatty acids if oxygen delivery is not a factor.