Enzyme activity in the aestivating Green-striped burrowing frog (Cyclorana alboguttata)

Green-striped burrowing frogs (Cyclorana alboguttata) can depress their resting metabolism by more than 80% during aestivation. Previous studies have shown that this species is able to withstand long periods of immobilisation during aestivation while apparently maintaining whole muscle mass and contractile performance. The aim of this study was to determine the effect of prolonged aestivation on the levels of metabolic enzymes (CCO, LDH and CS) in functionally distinct skeletal muscles (cruralis, gastrocnemius, sartorius, iliofibularis and rectus abdominus) and liver of C. alboguttata. CS activity was significantly reduced in all tissues except for the cruralis, gastrocnemius and the liver. LDH activity was significantly reduced in the sartorius and rectus abdominus, but remained at control (active) levels in the other tissues. CCO activity was significantly reduced in the gastrocnemius and rectus abdominus, and unchanged in the remaining tissues. Muscle protein was significantly reduced in the sartorius and iliofibularis during aestivation, and unchanged in the remaining muscles. The results suggest that the energy pathways involved in the production and consumption of ATP are remodelled during prolonged aestivation but selective. Remodelling and subsequent down-regulation of metabolic activity seem to target the smaller non-jumping muscles, while the jumping muscles retain enzyme activities at control levels during aestivation. These results suggest a mechanism by which aestivating C. alboguttata are able to maintain metabolic depression while ensuring that the functional capacity of critical muscles is not compromised upon emergence from aestivation.     

Metabolic depression during aestivation in Cyclorana alboguttata

The green striped burrowing frog, Cyclorana alboguttata, spends, on average, nine to ten months of every year in aestivation. Recently, C. alboguttata has been the focus of much investigation regarding the physiological processes involved in aestivation, yet our understanding of this frog's capacity to metabolically depress remains limited. This study aimed to extend our current knowledge of metabolic depression during aestivation in C. alboguttata. C. alboguttata reduced whole animal metabolism by 82% within 5 weeks of aestivation. The effects of aestivation on mass specific in vitro tissue metabolic rate (VO₂) varied among individual organs, with muscle and liver slices showing significant reductions in metabolism; kidney VO₂ was elevated and there was no change in the VO₂ of small intestine tissue slices. Organ size was also affected by aestivation, with significant reductions in the mass of all tissues, except the gastrocnemius. These reductions in organ size, combined with changes in mass specific VO₂ of tissue slices, resulted in further energy savings to aestivating animals. This study shows that C. alboguttata is capable of selectively down- or up-regulating individual tissues, using both changes in metabolic rate and morphology. This strategy allows maximal energy savings during aestivation without compromising organ functionality and survival at arousal.     

Metabolic depression during aestivation does not involve remodelling of membrane fatty acids in two Australian frogs

Changes in membrane lipid composition (membrane remodelling) have been associated with metabolic depression in some aestivating snails but has not been studied in aestivating frogs. This study examined the membrane phospholipid composition of two Australian aestivating frog species Cyclorana alboguttata and Cyclorana australis. The results showed no major membrane remodelling of tissue in either frog species, or in mitochondria of C. alboguttata due to aestivation. Mitochondrial membrane remodelling was not investigated in C. australis. Where investigated in C. alboguttata, total protein and phospholipid content, and citrate synthase (CS) and cytochrome c oxidase (CCO) activities in tissues and mitochondria mostly did not change with aestivation in liver. In skeletal muscle, however, CS and CCO activities, mitochondrial and tissue phospholipids, and mitochondrial protein decreased with aestivation. These decreases in muscle indicate that skeletal muscle mitochondrial content may decrease during aestivation. Na⁺K⁺ATPase activity of both frog species showed no effect of aestivation. In C. alboguttata different fat diets had a major effect on both tissue and mitochondrial phospholipid composition indicating an ability to remodel membrane composition that is not utilised in aestivation. Therefore, changes in lipid composition associated with some aestivating snails do not occur during aestivation in these Australian frogs.     

Effect of prolonged inactivity on skeletal motor nerve terminals during aestivation in the burrowing frog, <Emphasis Type="Italic">Cyclorana alboguttata</Emphasis>

This study examined the effect of prolonged inactivity, associated with aestivation, on neuromuscular transmission in the green-striped burrowing frog, Cyclorana alboguttata. We compared the structure and function of the neuromuscular junctions on the iliofibularis muscle from active C. alboguttata and from C. alboguttata that had been aestivating for 6 months. Despite the prolonged period of immobility, there was no significant difference in the shape of the terminals (primary, secondary or tertiary branches) or the length of primary terminal branches between aestivators and non-aestivators. Furthermore, there was no significant difference in the membrane potentials of muscle fibres or in miniature end plate potential (EPP) frequency and amplitude. However, there was a significant decrease in evoked transmitter release characterised by a 56% decrease in mean EPP amplitude, and a 29% increase in the failure rate of nerve terminal action potentials to evoke transmitter release. The impact of this suite of neuromuscular characteristics on the locomotor performance of emergent frogs is discussed.     

Effect of aestivation on muscle characteristics and locomotor performance in the Green-striped burrowing frog, Cyclorana alboguttata

The Green-striped burrowing frog, Cyclorana alboguttata survives extended drought periods by burrowing underground and aestivating. These frogs remain immobile within cocoons of shed skin and mucus during aestivation and emerge from their burrows upon heavy rains to feed and reproduce. Extended periods of immobilisation in mammals typically result in muscle atrophy and a decrease in muscle performance. We examined the effect of aestivation and hence prolonged immobilisation, on skeletal muscle mass, in vitro muscle performance, and locomotor performance in C. alboguttata. Frogs were aestivated in soil for 3 months and were compared with control animals that remained active, were fed, and had a continual supply of water. Compared to the controls, the wet mass of the gastrocnemius, sartorius, gracilus major, semimembranosus, peroneus, extensor cruris, tibialis posticus and tibialis anticus longus of aestivators remained unchanged indicating no muscle atrophy. The in-vitro performance characteristics of the gastrocnemius muscle were maintained and burst swimming speed was unaffected, requiring no recovery from the extended period of immobilisation associated with aestivation. This preservation of muscle size, contractile condition and locomotor performance through aestivation enables C. alboguttata to compress their life history into unpredictable windows of opportunity, whenever heavy rains occur.     

The impact of prolonged fasting during aestivation on the structure of the small intestine in the green-striped burrowing frog, Cyclorana alboguttata

The effects of short‐term fasting and prolonged fasting during aestivation on the morphology of the proximal small intestine and associated organs were investigated in the green‐striped burrowing frog, Cyclorana alboguttata (Anura: Hylidae). Animals were fasted for 1 week while active or for 3–9 months during aestivation. Short‐duration fasting (1 week) had little effect on the morphology of the small intestine, whilst prolonged fasting during aestivation induced marked enteropathy including reductions in intestinal mass, length and diameter, longitudinal fold height and tunica muscularis thickness. Enterocyte morphology was also affected markedly by prolonged fasting: enterocyte cross‐sectional area and microvillous height were reduced during aestivation, intercellular spaces were visibly reduced and the prevalence of lymphocytes amongst enterocytes was increased. Mitochondria and nuclei were also affected by 9 months of aestivation with major disruptions to mitochondrial cristae and increased clumping of nuclear material and increased infolding of the nuclear envelope. The present study demonstrates that the intestine of an aestivating frog responds to prolonged food deprivation during aestivation by reducing in size, presumably to reduce the energy expenditure of the organ.     

Metabolic depression and Na+/K+ gradients in the aestivating Australian goldfields frog,Neobatrachus wilsmorei

During aestivation the metabolic rate of the Australian goldfields frog Neobatrachus wilsmorei was reduced by 80% from its standard metabolic rate. The in vitro rate of oxygen consumption of isolated muscle and skin from aestivating frogs was up to 50% lower than that of the non-aestivating frogs. This in vitro rate of oxygen consumption was maintained for 6–12 h, indicating an intrinsic metabolic depression of tissues during aestivation. Frogs became dehydrated during aestivation. Muscle, skin and liver also became dehydrated during aestivation, but brain and kidney did not. Na⁺ and K⁺ contents and extracellular space measurement for muscle indicated that ion gradients were maintained across the muscle cell membrane during aestivation. Increases in plasma concentrations of Na⁺ and K⁺ were matched with similar increases in muscle intracellular ion concentrations. Extracellular space measurements were unsuccessful in the other tissues, but K⁺ content in all tissues (per dry weight) was maintained during aestivation, and the concentration of plasma K⁺ did not increase above that which can be accounted for by dehydration, indicating that K⁺ gradients were maintained.Abbreviations bm body mass - DPM disintegrations per minute - dw dry weight - MR metabolic rate - vO₂ rate of oxygen consumption - ww wet weight     

Metabolic depression and sodium-potassium ATPase in the aestivating frog, Neobatrachus kunapalari

In aestivation the metabolic rate of the Australian desert frog Neobatrachus kunapalari was 50–67% lower than in the non-aestivating state. The rate of O₂ consumption of isolated muscle, skin and brain was measured in both metabolic states. The average rate of O₂ consumption of muscle was 30% lower and brain 50% lower in aestivating frogs, while the rate of O₂ consumption of skin was the same. The reduction in muscle could account for a large proportion of whole animal metabolic depression. To look for evidence of a reduction in energy demand in the tissues we measured the ouabain-sensitive fraction of tissue rate of O₂ consumption, which is considered to be the proportion of metabolism used for transmembrane Na⁺/K⁺ pumping. Ouabain inhibited the in vitro rate of O₂ consumption of skin by a average of 20% and of brain by an average of 30%. However, in muscle, ouabain stimulated in vitro O₂ consumption. Despite the 50% reduction in the in vitro rate of O₂ consumption of brain during aestivation, neither the ouabain-sensitive nor ouabain-insensitive fractions were found be statistically different, possibly because of the large individual variation in the degree of ouabain inhibition. A reduction in the level of ion pumping during aestivation was therefore not demonstrated in any tissue. Measurement of the level of the enzyme Na⁺K⁺-ATPase in skeletal muscle, ventricle, kidney and brain showed that there was no change in the amount of this enzyme in the aestivating frogs. Measurement of the levels of adenylates in muscle and liver showed that the adenylate energy charge was maintained in aestivation, but that there was a reduction in ATP in liver and a reduction in the level of total adenylates in both tissues, which could be an adaptation of the tissues to a lower energy turnover. Accepted: 22 July 1996     

Morpho-functional modifications of human syncytiotrophoblast plasma membrane during Pregnancy Induced Hypertension

Changes in [³⁵S]methionine protein labeling patterns were examined by following incorporation into the acid precipitate protein fraction of land snails,Otala lactea (Müller) (Pulmonata, Helicidae). Labeled proteins were analyzed by SDS polyacrylamide gel electrophoresis and isoelectric focusing columns. Snails in four different physiological states were compared: active controls, short term aestivating snails (injected and allowed to enter aestivation), long term aestivating snails (aestivated for 14 days, injected, and maintained in the aestivating state), and snails aroused after aestivation (aestivated, injected, and aroused). Protein associated radioactivity was measured over a 7 day time course post injection. Autoradiographic analysis of SDS-polyacrylamide gels showed increases in the radioactivity of four proteins: 91 kDa (hepatopancreas, day 1 in long term aestivating animals), 50 kDa (hepatopancreas, day 2 in short term aestivating snails), 70 kDa and 30 kDa (foot, day 2 in short term aestivating animals). Hepatopancreas and foot from day 1 long term aestivating and day 2 short term aestivating animals were also analyzed by isoelectric focusing columns. Several pH-specific differences were apparent when controls and aestivating animals were analyzed. In particular a peak of radioactivity was observed at pH 5.05 in 1 d long term aestivating hepatopancreas and at pH 4.30 in 2d short term aestivating animals. Several differences were noted in foot with no specific pattern emerging. SDS-polyacrylamide gel electrophoresis analysis of the hepatopancreas peaks showed the appearance of several bands with increased radioactivity, including the 91 kDa and 50 kDa proteins described above. These results suggest thatO. lactea aestivation specific proteins may be involved in the transition to a depressed metabolic state.Abbreviations dpm radioactive disintegrations per minute - PAGE polyacrylamide gel electrophoresis - SDS sodium dodecyl sulphate - SRP stress related protein     

Physiology of drought tolerance and cold hardiness of the Mediterranean tiger moth Cymbalophora pudica during summer diapause

Prepupae of the arctiid moth Cymbalophora pudica spend spring and summer months in a summer diapause (aestivation), the duration of which is photoperiodically controlled. Cold hardiness, drought tolerance and some physiological and biochemical parameters were measured in aestivating prepupae. Large amounts of metabolic reserves, in the form of lipids and glycogen, accumulated prior to aestivation. Glycogen served as the main metabolic fuel for aestivating prepupae. Metabolic rate decreased rapidly after the onset of the inactive prepupal stage and remained low (5-15% of the level in active larva) during aestivation. A spontaneous increase of the respiration rate occurred before pupation. Neither low mol. wt sugars or alcohols (polyols) accumulated nor the haemolymph osmotic pressure changed during aestivation. Drought tolerance of aestivating prepupae was high (no decrease in survival after exposure to r.h.<10% at a temperature of 23 degrees C for a substantial part of diapause) owing to their extensive capacity to stabilize the relative body water content irrespective of the r.h. of surrounding air. Cold hardiness was low (>90% decrease in survival after exposure to -7 degrees C for 24h). Cold and drought acclimations did not lead to significant changes in the measured physiological and biochemical parameters but cold (not drought) acclimation caused a significant increase in cold hardiness. Neither drought tolerance nor the increase in cold hardiness after cold acclimation appear to be related to presence/accumulation of polyols in aestivating C. pudica prepupae.     

废用条件下大鼠和达乌尔黄鼠骨骼肌氧化应激和抗氧化防御能力与肌萎缩的比较研究

有鳞类(蛇和蜥蜴)具有较发达的嗅器和犁鼻器,对其不同种类嗅觉结构的认识有助于阐明爬行动物化学感觉的进化。本文采用组织学方法比较了草原沙蜥(Phrynocephalus frontalis)、荒漠沙蜥(P. przewalskii)、密点麻蜥(Eremias multiocellata)和秦岭滑蜥(Scincella tsinlingensis)的嗅器及犁鼻器。结果发现,草原沙蜥的鼻腔较为狭长,秦岭滑蜥呈梨形,其他两种蜥蜴的鼻腔略成圆形。秦岭滑蜥的嗅上皮最厚,其次是密点麻蜥和草原沙蜥,荒漠沙蜥最薄。犁鼻器主要由犁鼻腔、犁鼻感觉上皮、犁鼻神经及蘑菇体等组成,没有腺体。草原沙蜥和荒漠沙蜥的犁鼻腔较为宽阔,密点麻蜥和秦岭滑蜥的较窄。4种蜥蜴的犁鼻感觉上皮均较嗅上皮厚,蘑菇体向后逐渐缩小至消失,犁鼻感觉上皮成闭环状,包围犁鼻腔。密点麻蜥和秦岭滑蜥的犁鼻感觉上皮位于犁鼻器的背侧,蘑菇体位于腹侧;与此不同,两种沙蜥的犁鼻感觉上皮偏向于犁鼻器的腹内侧,蘑菇体位于背外侧。密点麻蜥的犁鼻感觉上皮最厚,其次为秦岭滑蜥,两种沙蜥最薄;秦岭滑蜥犁鼻感觉上皮的感觉细胞密度最高,其次是密点麻蜥,两种沙蜥最低。这些结果提示,密点麻蜥和秦岭滑蜥对嗅觉信号的依赖和投入较两种沙蜥多;4种蜥蜴犁鼻器的结构差异间接地佐证了有鳞类犁鼻器系统发生的特异性。     

超排处理对雌兔生殖器官中表皮生长因子表达的影响

本研究采用免疫荧光组织化学染色法和蛋白免疫印迹法比较研究了后肢去负荷大鼠(Rattus norvegicus)和冬眠不活动达乌尔黄鼠(Spermophilus dauricus)不同类型骨骼肌氧化应激水平和抗氧化防御能力及与肌萎缩之间的关系。结果显示,后肢去负荷14 d后,大鼠比目鱼肌和趾长伸肌肌萎缩程度显著升高,过氧化氢和丙二醛水平增加,Nrf2介导的抗氧化信号通路及下游抗氧化酶蛋白表达及活性显著下降;而冬眠不活动达乌尔黄鼠骨骼肌中肌萎缩指标并未出现变化,氧化应激水平维持夏季组水平,抗氧化酶和调控因子出现不同程度升高。研究表明,后肢去负荷导致非冬眠大鼠骨骼肌氧化应激水平升高,抗氧化防御能力减弱,可能是导致大鼠废用性肌萎缩的重要机制之一;而冬眠动物达乌尔黄鼠骨骼肌在自然废用状态下,抗氧化防御能力增强可能是防止自然冬眠不活动引起的废用性肌萎缩的重要机制。     

Of bears, frogs, meat, mice and men: complexity of factors affecting skeletal muscle mass and fat

Extreme loss of skeletal muscle mass (atrophy) occurs in human muscles that are not used. In striking contrast, skeletal muscles do not rapidly waste away in hibernating mammals such as bears, or aestivating frogs, subjected to many months of inactivity and starvation. What factors regulate skeletal muscle mass and what mechanisms protect against muscle atrophy in some species? Severe atrophy also occurs with ageing and there is much clinical interest in reducing such loss of muscle mass and strength (sarcopenia). In the meat industry, a key aim is optimizing the control of skeletal muscle growth and meat quality. The impaired response of muscle to insulin resulting in diabetes, that is a consequence of the metabolic impact of increasing obesity and fat deposition in humans, is also of increasing clinical concern. Intensive research in these fields, combined with mouse models, is reviewed with respect to the molecular control of muscle growth (myogenesis) and atrophy/hypertrophy and fat deposition (adipogenesis) in skeletal muscle, with a focus on IGF‐1/insulin signaling. BioEssays 28: 994–1009, 2006. © 2006 Wiley Periodicals, Inc.     

Increased urea synthesis and/or suppressed ammonia production in the African lungfish, Protopterus annectens, during aestivation in air or mud

The objective of this study was to elucidate how the African lungfish, Protopterus annectens, ameliorated ammonia toxicity during 12 or 46 days of aestivation in air or in mud. Twelve days of aestivation in air led to significant increases in contents of urea, but not ammonia, in tissues of P. annectens. The estimated rate of urea synthesis increased 2.7-fold despite the lack of changes in the activities of hepatic ornithine–urea cycle enzymes, but there was only a minor change in the estimated rate of ammonia production. After 46 days of aestivation in air, the ammonia content in the liver decreased significantly and contents of urea in all tissues studied increased significantly, indicating that the fish shifted to a combination of increased urea synthesis (1.4-fold of the day 0 value) and decreased ammonia production (56% of the day 0 value) to defend against ammonia toxicity. By contrast, 12 days of aestivation in mud produced only minor increases in tissue urea contents, with ammonia contents remained unchanged. This was apparently achieved through decreases in urea synthesis and ammonia production (40 and 15%, respectively, of the corresponding day 0 value). Surprisingly, 46 days of aestivation in mud resulted in no changes in tissue urea contents, indicating that profound suppressions of urea synthesis and ammonia production (2.6 and 1.2%, respectively, of the corresponding day 0 value) had occurred. This is the first report on such a phenomenon, and the reduction in ammonia production was so profound that it could be the greatest reduction known among animals. Since fish aestivated in mud had relatively low blood pO₂ and muscle ATP content, they could have been exposed to hypoxia, which induced reductions in metabolic rate and ammonia production. Consequently, fish aestivating in mud had a lower dependency on increased urea synthesis to detoxify ammonia, which is energy intensive, than fish aestivating in air.     

Energy loss in an aestivating population of the tropical snail pila globosa

The dried peripheral area of pond Idumban (62 ha) increased from 3.2 ha in January to 3 1.9 ha in April. Pila globosa, which were abundant in the littoral area, did not commence aestivation during this period, perhaps due to low temperature and/or high dissolved oxygen content. The number of aestivating snails averaged 0.5/m² in May, 1973 (3.6% of the total population) and it increased to 1.1/M² in September (26.2%). Biomass of the snail increased from 3.5 to 19.9 g dry weight (including shell)/M². Number of aestivating snails increased from 0.4/m² (5.2% of the total population) in May 1974 to 0.8/m² (11.1%) in July and the biomass from 4.1 g/m² to 10.7 g/m². Availability of dried area for aestivation increased from 5.3 to 23.7 ha in 1973 and from 13.5 to 30.2 ha in 1974.Monthly observations made on the marked snails forced to aestivate at 7.5, 15.0, 22.5 and 30.0 cm depth in the pond during May, revealed that temperature above 35°C and moisture below 5% were critical. Mortality and weight loss decreased in the snails forced to aestivate at increasing depth. Random observations indicated that 83% of the aestivating snails buried themselves at 15 cm depth in the pond. On the whole, 98,480 snails (592 Kg) and 115,270 (758 Kg) died during aestivation in 1973 and 1974 respectively. Of the total weight loss, the energy lost via metabolism contributed only a small fraction of 2.2% (12 Kg) and 2.1% (15 Kg) during these years. Considering the total aestivation area, the snails which succumbed averaged only 0.4/m²/year (2.5 g/m²/year). On an average, dry substance equivalent to about 2.6 mg dry weight/ g dry weight of snail/ day (3.7 gcal/ g live snail/ day) was lost on metabolism by the aestivating snails, i.e. the metabolic level of the aestivating snail was about 1 / 18th of that of the actively feeding snail.     

Molecular mechanism underlying muscle mass retention in hibernating bats: Role of periodic arousal

Hibernators like bats show only marginal muscle atrophy during prolonged hibernation. The current study was designed to test the hypothesis that hibernators use periodic arousal to increase protein anabolism that compensates for the continuous muscle proteolysis during disuse. To test this hypothesis, we investigated the effects of 3‐month hibernation (HB) and 7‐day post‐arousal torpor (TP) followed by re‐arousal (RA) on signaling activities in the pectoral muscles of summer‐active (SA) and dormant Murina leucogaster bats. The bats did not lose muscle mass relative to body mass during the HB or TP‐to‐RA period. For the first 30‐min following arousal, the peak amplitude and frequency of electromyographic spikes increased 3.1‐ and 1.4‐fold, respectively, indicating massive myofiber recruitment and elevated motor signaling during shivering. Immunoblot analyses of whole‐tissue lysates revealed several principal outcomes: (1) for the 3‐month HB, the phosphorylation levels of Akt1 (p‐Akt1) and p‐mTOR decreased significantly compared to SA bats, but p‐FoxO1 levels remained unaltered; (2) for the TP‐to‐RA period, p‐Akt1 and p‐FoxO1 varied little, while p‐mTOR showed biphasic oscillation; (3) proteolytic signals (i.e., atrogin‐1, MuRF1, Skp2 and calpain‐1) remained constant during the HB and TP‐to‐RA period. These results suggest that the resistive properties of torpid bat muscle against atrophy might be attained primarily by relatively constant proteolysis in combination with oscillatory anabolic activity (e.g., p‐mTOR) corresponding to the frequency of arousals occurring throughout hibernation. J. Cell. Physiol. 222: 313–319, 2010. © 2009 Wiley‐Liss, Inc.