Patterns of Metabolism and Growth in Avian Embryos

Metabolic rates of embryos of precocial birds increase rapidlyuntil about 80% through incubation, then increase slowly remainconstant or even decline. In altricial species, embryo metabolicrates increase continuously and at an accelerating rate throughout incubation. Total energy cost of development is higher inprecocial than in altricial species. Growth patterns of altricialand precocial embryos differ in the same way as does metabolicrate. Embryo growth rates decline late in incubation in precocialspecies, but increase continuously in altricial species. Embryometabolic rate in cal/hr (P) is related to embryo mass in grams(M) and growth rate in grams/day (GR) by the equation P = 12.17GR+ 1.66M + 1.81. The energy cost of growth in avian embryos is292 cal/g. The energy cost of maintenance is 1.66 cal/g hr andappeals to be independent of embryo mass. Differences in growthpatterns account for the observed differences in metabolic ratesand total energy costs of development. High energy costs ofmaintenance account for high total developmental costs in piecocialspecies and in species that have unusually long incubation periods.     

Responses of Peanut Somatic Embryos to Thidiazuron

Induction of both somatic embryogenesis and organogenesis in presence of thidiazuron is reported in peanut tissues. However the histological evidence of thidiazuron induced somatic embryogenesis was unclear. Thidiazuron triggered multiple shoot differentiation in the plumule of the embryos. Keeping in view the ability of thidiazuron to induce both organogenesis and embryogenesis in peanut tissues, experiments were conducted to define the pathway of morphogenesis in the plumule of rooted somatic embryos. On exposure to thidiazuron, projections appeared from the plumule. These projections closely resemble the somatic embryos. However histological examination revealed that these are caulogenic buds and not somatic embryos. In concurrence with the earlier reports on thidiazuron induced organogenesis it is concluded that this growth regulator induces organogenic response in peanut tissues. This revised version was published online in July 2006 with corrections to the Cover Date.     

Analysis of Oxidative Stress in Zebrafish Embryos

High levels of reactive oxygen species (ROS) may cause a change of cellular redox state towards oxidative stress condition. This situation causes oxidation of molecules (lipid, DNA, protein) and leads to cell death. Oxidative stress also impacts the progression of several pathological conditions such as diabetes, retinopathies, neurodegeneration, and cancer. Thus, it is important to define tools to investigate oxidative stress conditions not only at the level of single cells but also in the context of whole organisms. Here, we consider the zebrafish embryo as a useful in vivo system to perform such studies and present a protocol to measure in vivo oxidative stress. Taking advantage of fluorescent ROS probes and zebrafish transgenic fluorescent lines, we develop two different methods to measure oxidative stress in vivo: i) a “whole embryo ROS-detection method” for qualitative measurement of oxidative stress and ii) a “single-cell ROS detection method” for quantitative measurements of oxidative stress. Herein, we demonstrate the efficacy of these procedures by increasing oxidative stress in tissues by oxidant agents and physiological or genetic methods. This protocol is amenable for forward genetic screens and it will help address cause-effect relationships of ROS in animal models of oxidative stress-related pathologies such as neurological disorders and cancer.     

Avian Community Responses to Variability in River Hydrology

River flow is a major driver of morphological structure and community dynamics in riverine-floodplain ecosystems. Flow influences in-stream communities through changes in water velocity, depth, temperature, turbidity and nutrient fluxes, and perturbations in the organisation of lower trophic levels are cascaded through the food web, resulting in shifts in food availability for consumer species. River birds are sensitive to spatial and phenological mismatches with aquatic prey following flow disturbances; however, the role of flow as a determinant of riparian ecological structure remains poorly known. This knowledge is crucial to help to predict if, and how, riparian communities will be influenced by climate-induced changes in river flow characterised by more extreme high (i.e. flood) and/or low (i.e. drought) flow events. Here, we combine national-scale datasets of river bird surveys and river flow archives to understand how hydrological disturbance has affected the distribution of riparian species at higher trophic levels. Data were analysed for 71 river locations using a Generalized Additive Model framework and a model averaging procedure. Species had complex but biologically interpretable associations with hydrological indices, with species’ responses consistent with their ecology, indicating that hydrological-disturbance has implications for higher trophic levels in riparian food webs. Our quantitative analysis of river flow-bird relationships demonstrates the potential vulnerability of riparian species to the impacts of changing flow variability and represents an important contribution in helping to understand how bird communities might respond to a climate change-induced increase in the intensity of floods and droughts. Moreover, the success in relating parameters of river flow variability to species’ distributions highlights the need to include river flow data in climate change impact models of species’ distributions.     

Brassinosteroid-Mediated Stress Responses

Brassinosteroids (BRs) are a group of naturally occurring plant steroidal compounds with wide-ranging biological activity that offer the unique possibility of increasing crop yields through both changing plant metabolism and protecting plants from environmental stresses. In recent years, genetic and biochemical studies have established an essential role for BRs in plant development, and on this basis BRs have been given the stature of a phytohormone. A remarkable feature of BRs is their potential to increase resistance in plants to a wide spectrum of stresses, such as low and high temperatures, drought, high salt, and pathogen attack. Despite this, only a few studies aimed at understanding the mechanism by which BRs promote stress resistance have been undertaken. Studies of the BR signaling pathway and BR gene-regulating properties indicate that there is cross-talk between BRs and other hormones, including those with established roles in plant defense responses such as abscisic acid, jasmonic acid, and ethylene. Recent studies aimed at understanding how BRs modulate stress responses suggest that complex molecular changes underlie BR-induced stress tolerance in plants. Analyses of these changes should generate exciting results in the future and clarify whether the ability of BRs to increase plant resistance to a range of stresses lies in the complex interactions of BRs with other hormones. Future studies should also elucidate if BRI1, an essential component of the BR receptor, directly participates in stress response signaling through interactions with ligands and proteins involved in plant defense responses.     

Cofilin-Mediated Actin Stress Response Is Maladaptive in Heat-Stressed Embryos

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Adrenal Responses to Stress

Based on concepts proposed by Langley, Cannon, and Selye, adrenal responses to stress occur in a syndrome that reflects activation of the sympathoadrenal system and hypothalamic–pituitary–adrenocortical (HPA) axis; and a “stress syndrome” maintains homeostasis in emergencies such as “fight or flight” situations, but if the stress response is excessive or prolonged then any of a variety of clinical disorders can arise. The idea of a unitary sympathoadrenal system does not account for evidence that different stressors elicit different patterns of autonomic responses, with exposure to some stressors differentially affecting sympathetic noradrenergic and adrenomedullary hormonal activities. Instead, adrenomedullary responses to stressors are more closely tied to adrenocortical than to sympathetic noradrenergic responses. Distress involves concurrent activation of the HPA and adrenomedullary neuroendocrine systems.     

Plant Responses to Water Stress

This Special Issue comprises a series of papers that developsthe theme of plant responses to water stress, encompassing recentdevelopments at the molecular level, through responses of photosynthesisand metabolism, to their application in crop selection and yield.The consideration of water deficits is particularly timely,given the huge developments in this area in the past decade.This issue specifically sets out to place molecular and physiologicalprocesses and their agronomic applications in an environmentalcontext.     

Generation of Digital Responses in Stress Sensors

Ultrasensitivity, hysteresis (a form of biochemical memory), and all-or-none (digital) responses are important signaling properties for the control of irreversible processes and are well characterized in the c-Jun N-terminal kinase (JNK) system using Xenopus oocytes. Our aim was to study these properties in the AMP-activated protein kinase (AMPK) signaling system under stress conditions that could engage a cell death program, and compare them to the JNK responses. After characterization of Xenopus AMPK, we show here that the response to antimycin (nonapoptotic) was slightly cooperative and graded (analog) in individual oocytes, whereas the response to sorbitol (which induced cytochrome c release and caspase activation) was ultrasensitive, digital in single cells, and without hysteresis, hallmarks of a monostable system. Moreover, initial graded responses of AMPK and JNK turned into digital during a critical period for the execution of the cell death program, although single cell analysis did not show complete correlation between AMPK or JNK activation and cytochrome c release. We propose a model where the life or death decision in the cell is made by integration of multiple digital signals from stress sensors.The energy level in a cell/organism is probably the most remarkable vital constant and must be tightly regulated or cell death programs will otherwise be engaged. The AMP-activated protein kinase (AMPK)² is an energy sensor (activated by a high AMP/ATP ratio) and a homeostatic regulator of cellular ATP levels, taking central stage in orchestrating cell metabolism (1).Stress sensors should have, to function efficiently, ultrasensitive properties to respond to small changes in the important parameters of cell survival. In addition, all-or-none (digital) responses, at a single cell level, and sustained activation when the stimulus has disappeared (also named hysteresis) may be important properties of stress sensors in regulating cell death (2).Mammalian AMPK is a heterotrimeric complex consisting of a catalytic α-subunit and regulatory β- and γ-subunits. AMPK is activated by AMP in two ways, both antagonized by high concentrations of ATP. Binding of AMP to the γ-subunit induces: 1) allosteric activation that can account for a 5-fold increase in the activity, and 2) phosphorylation of the α-subunit at Thr-172 (in human), which is essential for activity and causes a much marked activation (3). The combination of the two effects causes a >1000-fold increase in kinase activity (4). The protein kinases LKB1 and CaMKKα/β have been reported to phosphorylate the AMPK α-subunit at Thr-172 (1, 5). This signaling system is a clear example of multistep sensitivity, which arises when a signal molecule (AMP) affects more than one step in a cascade (allosteric activation and phosphorylation). In addition, the AMPK upstream kinases have a very low K_m for AMPK (6), a phenomenon referred to as zero-order ultrasensitivity (7). In practice, the ultrasensitivity of a system is reflected in a stimulus/response curve with a very steep upstroke. These properties of the AMPK signaling system may be very important to maintain energy levels in the cell within narrow limits and can be useful for filtering noise. Although there is one report supporting that AMPK is an ultrasensitive system (6), no further research has considered its significance in the control of cell death as well as other important signaling properties associated with ultrasensitivity, such as hysteresis and all-or-none responses.It is well known that ultrasensitive systems embedded in a positive feedback loop have the potential to exhibit bistable behavior, switching between discrete stable steady states without being able to rest in intermediate states (8, 9). The three hallmarks of a bistable system are: 1) strong ultrasensitivity, 2) digital response at the individual cell level, and 3) hysteresis. Examples of such systems are JNK and the mitogen-activated protein kinase (MAPK) cascades, implicated in oocyte maturation and maybe in apoptosis (2, 10). The hallmarks of a monostable system are the same, but without hysteresis.Because AMPK is an energy sensor, it seems reasonable that the AMPK cascade would transmit at the individual cell level graded (analog) information about the energy status of the cell. In fact, AMPK can be considered part of a negative feedback loop because AMPK activation (by a high AMP/ATP ratio) regulates multiple steps in metabolism to restore ATP levels in the cell, which in turn down-regulates AMPK activity. However, sustained activation of AMPK by some stimuli has been considered a pro-apoptotic signal (11, 12). Because cell death is an all-or-none irreversible process, it may be more appropriate for the AMPK cascade in this situation to exhibit a digital (all-or-none) response to trigger cell death.Here, we analyze the sensitivity, the grade of hysteresis, and the single cell response of the AMPK system under different stress conditions that could engage a cell death program. We performed experiments with Xenopus oocytes, a suitable model for discerning the character of a signaling response, as has been previously reported for JNK and MAPK cascades. Based on our results, we propose that commitment to cell death will occur after integration of multiple digital responses from stress protein kinases.     

鸟类应激反应的诱发和影响因素

应激反应是动物应对环境变化或社会压力的重要机制,表现为下丘脑-垂体-肾上腺轴(HPA轴)被激活并产生糖皮质激素。鸟类的糖皮质激素主要是皮质酮。通过检测鸟类体内的皮质酮水平,可以了解鸟类的应激状态水平,进而了解诱发和影响鸟类应激反应的因素,这有助于理解鸟类如何适应环境、如何权衡生活史各阶段的能量分配等。而通过长期监测动物个体的生存和应激状况,对濒危鸟类的保育工作也具有重要参考价值。本文综述了诱发鸟类应激反应的因素,包括天气、捕食压力、食物可获得性、人为干扰和城市化以及社会压力等。归纳出影响鸟类应激反应程度的主要因素,包括光周期、生境、性别、年龄、社会等级和早期经历等8个方面。提出了应激反应在个性、认知、系统发育等领域的应用,以及慢性应激、羽毛皮质酮检测等值得关注的内容。     

Ten Years on: Generating Innovative Responses to Avian Influenza

Since 2006, the number of recorded H5N1 avian influenza outbreaks has declined globally, but at mid-2012 the disease was enzootic in six countries in Asia and Africa, and sporadic outbreaks continue over a wide area. It is now accepted that it will take decades to eliminate the H5N1 virus in poultry and ‘unconventional’ response approaches have been called for. Drawing on increased understandings of the epizoosis over the last 10 years, this paper investigates what conditions are required if such innovative approaches are to be generated. It argues that addressing the spread and persistence of avian influenza is primarily a political matter, and if approaches appropriate for enzooticity are to be devised, the social, political, and economic dynamics of the disease and responses to it need to be identified and prioritised. A dominant response strategy focused on outbreak events, containment and eradication has obscured these important dynamics. If innovative ‘unconventional’ responses are to be generated, a wider range of perspectives and expertise needs to be engaged. This will result in political processes of negotiation, which the technically led, development-orientated institutions directing and funding the global response are ill-equipped to facilitate.     

Integrating Insulin Signaling and Stress Responses

Drosophila embryonic hemocytes have emerged as a potent system to analyze the roles of key regulators of the actin and microtubule cytoskeletons live and in an in vivo context (see Table I and references therein). The relative ease with which live imaging can be used to visualize the invasive migrations of these highly motile macrophages and their responses to wound and chemoattractant signals make them a particularly appropriate and genetically tractable cell type to study in relation to pathological conditions such as cancer metastasis and inflammation.^1-3 In order to understand how signaling pathways are integrated for a coordinated response, a question with direct relevance to autoimmune dysfunction, we have sought to more fully characterize the inputs these cells receive in vivo over the course of their developmental dispersal. These studies have recently revealed that hemocyte migration is intimately associated with the development of the ventral nerve cord (VNC), a structure used by hemocytes to disperse over the embryo that itself requires this association for its correct morphogenesis. Crucially the VNC must separate from the epidermis to create a channel for hemocyte migration, revealing how constriction of extracellular space can be used to control cell migration in vivo.⁴     

三角梅对盐胁迫的响应研究

长期盐胁迫处理实验表明,随着NaCl浓度增加,不同三角梅品种的地上部和地下部生物量均呈下降趋势。与对照相比,盐浓度为5%时,勤花三角梅生物量下降幅度最小,为27.94%;樱花三角梅下降最大,为67.03%。当盐浓度为4%时,樱花三角梅、白苞三角梅和勤花三角梅的光量子产量分别为0.36、0.30和0.36,分别为对照的78.23%、79.64%和74.82%;金心鸳鸯三角梅的光量子产量为0.05,仅为对照的15.53%。白苞三角梅的光化学猝灭系数qP值随着盐浓度的升高无明显变化;金心鸳鸯三角梅、勤花三角梅和樱花三角梅的qP值随着盐浓度的升高而降低。4个三角梅品种的抗盐胁迫能力为：白苞三角梅>樱花三角梅>勤花三角梅>金心鸳鸯三角梅。     

Monitoring Plant Hormones During Stress Responses

Plant hormones and related signaling compounds play an important role in the regulation of plant responses to various environmental stimuli and stresses. Among the most severe stresses are insect herbivory, pathogen infection, and drought stress. For each of these stresses a specific set of hormones and/or combinations thereof are known to fine-tune the responses, thereby ensuring the plant''s survival. The major hormones involved in the regulation of these responses are jasmonic acid (JA), salicylic acid (SA), and abscisic acid (ABA). To better understand the role of individual hormones as well as their potential interaction during these responses it is necessary to monitor changes in their abundance in a temporal as well as in a spatial fashion. For the easy, sensitive, and reproducible quantification of these and other signaling compounds we developed a method based on vapor phase extraction and gas chromatography/mass spectrometry (GC/MS) analysis (1, 2, 3, 4). After extracting these compounds from the plant tissue by acidic aqueous 1-propanol mixed with dichloromethane the carboxylic acid-containing compounds are methylated, volatilized under heat, and collected on a polymeric absorbent. After elution into a sample vial the analytes are separated by gas chromatography and detected by chemical ionization mass spectrometry. The use of appropriate internal standards then allows for the simple quantification by relating the peak areas of analyte and internal standard.Download video file.^{(121M, mp4)}     

一氧化氮(NO)在植物逆境响应中的作用

简要介绍了有关一氧化氮(NO)在植物非生物胁迫响应中生理作用的研究现状,并对与这一问题相关的研究趋势作了分析和讨论.     

植物逆境胁迫相关miRNA研究进展

MicroRNAs(mi RNAs)是一类内源性小分子的非编码RNA,它通过对其靶基因mRNA的降解或抑制翻译来调控基因表达,进而参与调控植物相关生理活动。在逆境胁迫下,植物中的一些miRNA通过迅速表达并作用于某些与逆境相关的基因,以启动植物的某些抗逆信号系统,进而提高植物对不良环境的适应能力。就miRNA的产生、作用方式、研究方法及其在植物在逆境胁迫中的抗逆作用机制研究进行了综述,并对植物miRNA的研究发展趋势进行了展望。     

哺乳动物冷应激的主要神经内分泌反应

为便于了解哺乳动物冷应激生理变化的调节机理,介绍了冷应激的主要神经内分泌反应。控制冷应激反应的主要中枢位于下丘脑。冷应激激活交感神经系统,激活下丘脑－垂体－甲状腺轴和下丘脑－垂体－肾上腺轴激素的合成和分泌,引起肾上腺髓质儿茶酚胺分泌增加;同时抑制促生长激素轴、促性腺轴、催乳激素轴的激素分泌。神经肽Y、瘦素、褪黑激素等多种神经肽和激素参与冷应激反应。     

Autophagy in Development and Stress Responses of Plants

The uptake and degradation of cytoplasmic material by vacuolar autophagy in plants has been studied extensively by electron microscopy and shown to be involved in developmental processes such as vacuole formation, deposition of seed storage proteins and senescence, and in the response of plants to nutrient starvation and to pathogens. The isolation of genes required for autophagy in yeast has allowed the identification of many of the corresponding Arabidopsis genes based on sequence similarity. Knockout mutations in some of these Arabidopsis genes have revealed physiological roles for autophagy in nutrient recycling during nitrogen deficiency and in senescence. Recently, markers for monitoring autophagy in whole plants have been developed, opening the way for future studies to decipher the mechanisms and pathways of autophagy, and the function of these pathways in plant development and stress responses.