Instability development in heated human erythrocytes

Heated human erythrocytes gradually lose their form-maintaining structure as the temperature is increased to 50°C and can behave in some respects as a viscous fluid. We have developed a technique for heating and stressing these cells that is novel, simple and quantitatively precise. We have applied this technique to heated human erythrocytes and have measured instability development in the cells. We have employed instability growth theory to calculate a value for an effective surface tension which, in contrast to other methods of membrane surface tension measurement sought to minimize the effects of membrane supporting structural elements. The value obtained for the surface tension of the heated erythrocyte membrane was 0.9 · 10^?6 N/m with a range of variation from 0.4 · 10^?6 N/m to 1.4 · 10^?6 N/m. The methods described may be useful for determining fundamental physical parameters such as internal viscosity and interfacial tension in other systems.     

Non-coding RNAs turn up the heat: An emerging layer of novel regulators in the mammalian heat shock response

The field of non-coding RNA (ncRNA) has expanded over the last decade following the discoveries of several new classes of regulatory ncRNA. A growing amount of evidence now indicates that ncRNAs are involved even in the most fundamental of cellular processes. The heat shock response is no exception as ncRNAs are being identified as integral components of this process. Although this area of research is only in its infancy, this article focuses on several classes of regulatory ncRNA (i.e., miRNA, lncRNA, and circRNA), while summarizing their activities in mammalian heat shock. We also present an updated model integrating the traditional heat shock response with the activities of regulatory ncRNA. Our model expands on the mechanisms for efficient execution of the stress response, while offering a more comprehensive summary of the major regulators and responders in heat shock signaling. It is our hope that much of what is discussed herein may help researchers in integrating the fields of heat shock and ncRNA in mammals.     

血小板源性生长因子受体α与高温致神经管畸形发生关系的研究

目的探讨PDGFR-α在高温致神经管畸形(NTDs)中的作用.方法在高温致神经管畸形动物模型上,采用免疫组织化学和图像分析技术,研究血小板源性生长因子受体α(PDGFR-α)在发育不同阶段的神经上皮中的表达,并观察高温对其表达的影响.结果在正常对照组,PDGFR-α广泛分布于神经管及其周围组织中;在高温致畸组,神经上皮中PDGFR-α的表达明显减弱,甚至不表达.结论 PDGFR-α的表达与神经管正常发育密切相关,其表达的减少可能是高温致NTDs机制中的重要环节.     

Development of a liposomal delivery system for temperature-triggered release of a tumor targeting agent, Ln(III)-DOTA-phenylboronate

Liposomes, capable of temperature-triggered content release at the site of interest, can be of great importance for imaging and therapy of tumors. The delivery of imaging agents or therapeutics can be improved by application of liposomes with a gel-to-liquid phase-transition temperature suitable for mild hyperthermia (41-43 °C), and by prolonging their circulation time by incorporation of lipids containing polyethyleneglycol moieties. Still, the rapid wash out of the delivered material from the tumor tissue is a major obstacle for both imaging and therapy. In this study, we developed an optimized temperature sensitive liposomal system to be used with mild hyperthermia: highly stable at physiological temperature and with a sharp transition of the bilayer at 41.5 °C, with subsequent rapid release of entrapped compounds such as calcein or tumor cell-targeting contrast agents. Intravital microscopy on calcein/rhodamine containing liposomes was applied to demonstrate the applicability of this system in vivo. The calcein loaded liposomes were injected iv into nude mice with a human BLM melanoma tumor implanted in a dorsal skin-fold window chamber. Arrival of the liposomes at the tumor site and content release after temperature increase were monitored. The results demonstrated not only accumulation of the liposomes at the tumor site, but also a massive release of calcein after increase of the temperature to 41 °C. The versatility of the thermosensitive liposomes was further demonstrated by encapsulation of a tumor cell-targeting DOTA-phenylboronate conjugate and its release at elevated temperatures. The DOTA ligand in this system is able to chelate a variety of metals suitable for both diagnostic and therapeutic applications, whereas the phenylboronate function is able to target specifically to tumor cells through a covalent binding with sialic acid moieties over-expressed on their surface upon heat-triggered release from the liposomal carrier.     

Heat shock proteins as an aid in the treatment and diagnosis of heat stroke

It is now well established that induction of heat shock protein 72 (HSP72) protects the cell or tissue against a second otherwise lethal exposure to heat, a phenomenon known as thermotolerance. Because of this protective role, HSP72 is potentially useful in the treatment of heat illnesses, which range from relatively benign disorders such as heat cramps to heat stroke, which can be life threatening. This review discusses various ways in which HSP72 might be used in the diagnosis and treatment of the heat illnesses. This includes methods to induce HSP72, analysis of HSP72 in the cells and tissues of heat stroke patients, and screening methods to detect individuals who may be heat intolerant.     

A canine thermal model for simulating temperature responses of military working dogs

Military working dogs (MWDs) are often required to operate in dangerous or extreme environments, to include hot and humid climate conditions. These scenarios can put MWD at significant risk of heat injury. To address this concern, a two-compartment (core, skin) rational thermophysiological model was developed to predict the temperature of a MWD during rest, exercise, and recovery. The Canine Thermal Model (CTM) uses inputs of MWD mass and length to determine a basal metabolic rate and body surface area. These calculations are used along with time series inputs of environmental conditions (air temperature, relative humidity, solar radiation and wind velocity) and level of metabolic intensity (MET) to predict MWD thermoregulatory responses. Default initial values of core and skin temperatures are set at neutral values representative of an average MWD; however, these can be adjusted to match known or expected individual temperatures. The rational principles of the CTM describe the heat exchange from the metabolic energy of the core compartment to the skin compartment by passive conduction as well as the application of an active control for skin blood flow and to tongue and lingual tissues. The CTM also mathematically describes heat loss directly to the environment via respiration, including panting. Thermal insulation properties of MWD fur are also used to influence heat loss from skin and gain from the environment. This paper describes the CTM in detail, outlining the equations used to calculate avenues of heat transfer (convective, conductive, radiative and evaporative), overall heat storage, and predicted responses of the MWD. Additionally, this paper outlines examples of how the CTM can be used to predict recovery from exertional heat strain, plan work/rest cycles, and estimate work duration to avoid overheating.     

Methionine protects against hyperthermia-induced cell injury in cultured bovine mammary epithelial cells

The aim of this study was to investigate the effects of methionine on cell proliferation, antioxidant activity, apoptosis, the expression levels of related genes (HSF-1, HSP70, Bax and Bcl-2) and the expression levels of protein (HSP70) in mammary epithelial cells, after heat treatment. Methionine (60 mg/L) increased the viability and attenuated morphological damage in hyperthermia-treated bovine mammary epithelial cells (BMECs). Additionally, methionine significantly reduced lactate dehydrogenase leakage, malondialdehyde formation, nitric oxide, and nitric oxide synthase activity. Superoxide dismutase, catalase, and glutathione peroxidase enzymatic activity was increased significantly in the presence of methionine. Bovine mammary epithelial cells also exhibited a certain amount of HSP70 reserve after methionine pretreatment for 24 h, and the expression level of the HSP70 gene and protein further increased with incubation at 42 °C for 30 min. Compared to the control, the expression of HSF-1 mRNA increased, and there was a significantly reduced expression of Bax/Bcl-2 mRNA and a reduced activity of caspase-3 against heat stress. Methionine also increased survival and decreased early apoptosis of hyperthermia-treated BMECs. Thus, methionine has cytoprotective effects on hyperthermia-induced damage in BMECs.     

The effect of hyperthermia on cell viability,oxidative damage,and heat shock protein expression in hepatic cells of grass carp (Ctenopharyngodon idellus)

The purpose of the study was to investigate the effects of mild hyperthermia on cell viability, release of lactate dehydrogenase (LDH), superoxide dismutase (SOD) activity, malondialdehyde (MDA) formation, total antioxidant capacity (T-AOC), and the relative mRNA levels of heat shock protein (HSP60, 70, and 90) in hepatic cells of grass carp (Ctenopharyngodon idellus) before and after temperature stress. Cultured cells were exposed to thermal stress (32 °C) for 0.5, 1, 2, 4, and 8 h. The results showed that hyperthermia stress significantly reduced cell viability (P<0.01) and increased LDH release at 0.5 and 1 h (P<0.05). Additionally, hyperthermia stress led to oxidative stress as evidenced by significantly decreased T-AOC after treating cells for 0.5 and 8 h (P<0.05). SOD activity also significantly decreased after 1 h of stress (P<0.05), but MDA formation increased after 8 h of stress (P<0.05). This may be partly responsible for the lower cell viability and higher LDH release we observed. The differences between SOD activity, MDA formation, and T-AOC between the 2 h treatment group and the control were smaller than that of other groups. This indicated that cellular antioxidant enzyme systems play an important role in the defense against oxidative stress. Further tests showed that the expression of HSP60 at 1, 2, and 4 h (P<0.05), HSP70 at 0.5 and 1 h (P<0.01), and HSP90 at all time points after stress were higher (P<0.01) than pre-stress levels. This suggested that HSPs possess the ability to modulate cellular anti-stress responses and play key roles in protecting organisms from heat stress. In conclusion, hyperthermia inhibits cell proliferation, induces cell oxidative stress, and enhances HSP expression in hepatic cells of grass carp.     

An Energy Analysis of Extracellular Hyperthermia

The classical hyperthermia effect is based on well‐focused energy absorption targeting the malignant tissue. The treatment temperature has been considered as the main technical parameter. There are discussions about the mechanism and control of the process because of some doubts about the micro‐mechanisms. The main idea of the extracellular hyperthermia is to heat up the targeted tissue by means of electric field, keeping the energy absorption in the extracellular liquid. This produces a temperature gradient and connected heat flow through the cell membrane, which initializes numerous nonequilibrium thermal microprocesses to destroy the cell membrane. Furthermore, before the heat shock activates the intracellular heat shock protein (HSP) mechanisms, thecell membrane has been already compromised, therefore the HSP synthesis in the cells starts secondarily only after the membrane damage. The process could explain why the nonuniform and basically unsatisfactorily high temperature locoregional hyperthermia could be effective.     

Effects of Amphetamine on Protein Synthesis and Energy Metabolism in Mouse Brain: Role of Drug-Induced Hyperthermia

Abstract: Changes in brain protein synthesis activity, and in brain levels of glucose, glycogen, and several high-energy phosphate metabolites, were evaluated under conditions of amphetamine-induced hyperthermia in mice. Protein synthesis showed a striking dependence on rectal temperature ( T _R), falling abruptly at T _R above 40°C. A similar result was obtained following direct heating of the animals. Protein synthesis activity in liver showed the same temperature dependence observed for brain. Increased synthesis of a protein with characteristics of the major mammalian stress protein, hsp 70, was demonstrated in both brain and liver following amphetamine administration. Brain protein synthesis showed significant recovery within 2 h after amphetamine administration whereas that of liver remained below 30% of control activity, suggesting significant temporal and quantitative differences in the response of individual tissues to elevated temperatures. Brain glycogen levels after amphetamine administration were significantly lower under conditions of ambient temperature which resulted in more severe drug-induced hyperthermia but did not correlate as strikingly as protein synthesis with the temperatures of individual animals. Brain glycogen also fell in animals whose temperatures were increased by brief exposure at high ambient temperature. Brain glucose levels did not consistently change with hyperthermia. Slight decreases in high-energy phosphates with increasing T _R were likely the result of fixation artifact. These results demonstrate the fundamental role of hyperthermia in the reduction of protein synthesis in brain and other tissues by amphetamine, and suggest that temperature also constitutes a significant source of variability in the effects of this drug on brain energy metabolism, in particular glycogenolysis.