Effect of temperature reduction on the reactivity of the mouse vas deferens to adrenergic drugs

1. Dose-response curves for noradrenaline, phenylephrine and clonicline were determined isometrically on the mouse vas deferens at 26°C, 15°C and compared to the one obtained at 37°C.2. In the presence of noradrenaline, reducing temperature induced an increase of both maximal developed tension and sensitivity to the drug. Reduction by 50% of the extracellular calcium concentration abolished the maximal contraction potentiation.3. When reducing temperature to 26°C, the maximal contraction was increased and depressed in the presence of phenylephrine and clonicline respectively.4. The results suggest (a) that cooling increases the reactivity of mouse vas deferens by activation of α₁ adrenoceptors and depresses it by activation of α₂ adrenoceptors (b) that calcium ions could play an important role in the potentiation of the maximal contraction.     

Phase diagram relationships in cryobiology

The reactions which occur during freezing in biological systems employing DMSO as a cryoprotective agent may well involve information given by a near equilibrium ternary H₂O-DMSO-NaCl phase diagram. The initial freezing point depressions for solutions with three different DMSO-NaCl initial ratios (R) have been determined over the onefold surface of ice saturation. DMSO has been shown to be more effective in reducing NaCl concentration in the residual liquid than had been previously predicted. The temperature and the fraction solid which must be reached for the occurrence of second phase coprecipitation with ice have been shown to be a strong function of initial R value. Ternary invariant reactions have been identified at ?35 °C, and tentatively identified at ?115 and ?105 °C for solutions having DMSO/NaCl ratios of R = 9, 5, and 1, respectively. Metastable nonequilibrium phase formation has been observed for slow cooling of a solution with R = 1. This metastable condition results in different phase relationships upon thawing than upon the initial freezing. By quenching the system after partial rewarming, it has been demonstrated that this metastable condition can be eliminated.     

Optimizing conditions for cryopreservation of an insect cell line

A cell line (UM-BGE-2) derived from embryos of the cockroach Blattella germanica was frozen to ?196 °C under a variety of conditions and cell viability was assayed after warming. It was found that cell viability was affected by the cooling rate, the warming rate, the controlled cooling endpoint temperature, and the type and concentration of cryoprotectant. The best survival for cells suspended in Grace's tissue culture medium containing 1 M Me₂SO was obtained when cells were cooled at 1 °C/ min to at least ?90 °C before being placed in liquid nitrogen and warmed at more than 900 °C/min. Cultures initiated from these frozen cells produce typical growth curves and appear normal after several passages.     

Interaction of the regulatory gene product with the operator site in the l-arabinose operon of Escherichia coli

The DNA binding properties of the araC protein in the absence of l-arabinose have been studied in Escherichia coli using the nitrocellulose membrane filter technique. Equilibrium competition experiments demonstrate that the araC protein binds specifically to the ara operator. The apparent K_m of the interaction is 1 × 10^?12m at 20 °C. The rates of association and dissociation of the complex have also been determined. A k_a of 2 × 10⁹m^?1 s^?1at 20 °C is calculated assuming binding to a single site. The half-life of the complex is three minutes. The equilibrium constant calculated from the ratio of k_a to k_d is 2.8 × 10^?12m at 20 °C. The good agreement between the equilibrium and kinetic determinations of the equilibrium constant suggest that the kinetic studies are providing true rate constants. It is calculated that about 1% of the purified araC protein is active with respect to operator binding activity.     

Measurement of cooling and warming rates in vitrification‐based plant cryopreservation protocols

Cryopreservation protocols include the use of additives and pretreatments aimed to reduce the probability of ice nucleation at all temperatures, mainly through micro‐viscosity increase. Still, there is a risk of ice formation in the temperature region comprised between the equilibrium freezing (T_f) and the glass transition (T_G) temperatures. Consequently, fast cooling and warming, especially in this region, is a must to avoid ice‐derived damage. Vitrification and droplet‐vitrification techniques, frequently used cryopreservation protocols based in fast cooling, were studied, alongside with the corresponding warming procedures. A very fast data acquisition system, able to read very low temperatures, down to that of liquid nitrogen, was employed. Cooling rates, measured between ?20°C and ?120°C, ranged from ca. 5°C s^?1 to 400°C s^?1, while warming rates spanned from ca. 2°C s^?1 to 280°C s^?1, for the different protocols and conditions studied. A wider measuring window (0°C to ?150°C) produced lower rates for all cases. The cooling and warming rates were also related to the survival observed after the different procedures. Those protocols with the faster rates yielded the highest survival percentages. © 2014 American Institute of Chemical Engineers Biotechnol. Prog., 30:1177–1184, 2014     

Biotic and abiotic factors affecting stability of Beauveria bassiana conidia in soil

Beauveria bassiana conidia were stored in sterile and nonsterile soil under various temperature, relative humidity, soil water content, and pH regimes. Survival of the conidia was primarily dependent on temperature and soil water content. Conidia half-lives ranged from 14 days at 25°C and 75% water saturation to 276 days at 10°C and 25% water saturation. Conidia held at ?15°C exhibited little or no loss in viability regardless of water content, relative humidity, or pH. Conidia were not recoverable after 10 days from soils held at 55°C. Conidia survival in nonsterile soil that was amended with carbon sources, nitrogen sources, or combinations of carbon and nitrogen was greatly decreased and loss was often complete in less than 22 days whereas sterile soil treated in the same manner showed dramatic increases in number, demonstrating that B. bassiana is capable of growth in sterile soil. The obvious fungistatic effect in amended nonsterile soils was possibly related to Penicillium urticae which was routinely isolated from the soils and is shown to produce a water-soluble inhibitor of B. bassiana. The fungistatic effect was shown to be an active inhibition rather than due to competition.     

Binding of [3H]batrachotoxinin A-20-α-benzoate and [3h]saxitoxin to receptor sites associated with sodium channels in trout brain synaptoneurosomes

1. [³H]Batrachotoxinin A-20-α-benzoate ([³H]BTX-b) and [³H]saxitoxin ([³H]STX), radioligands that bind to distinct sites on the voltage-sensitive sodium channel, were bound specifically to saturable sites in rainbow trout (Oncorhynchus mykiss) brain synaptoneurosomes.2. Specific [³H]BTX-B binding was temperature dependent with highest levels of specific [³H]BTX-B binding observed at 7°C. Specific binding was inversely correlated with assay temperature at temperatures above 7°C.3. Saturating concentrations of scorpion (Leiurus quinquestriatus) venom (ScV) stimulated specific [³H]BTX-B binding at 27°C, but not at 7°C. The dihydropyrazole insecticide RH 3421 inhibited specific [³H]BTX-B binding at 7°C but had no effect on specific binding at 27°C. The sodium channel activators veratridine and aconitine and the local anesthetic dibucaine inhibited specific [³H]BTX-B binding at both 7°C and 27°C.4. Displacement experiments in the presence of ScV at 27°C gave an equilibrium dissociation constant (K_d) for [³H]BTX-B of 710 nM and a maximal binding capacity (B_max) of 11.3 pmol/mg protein. Kinetic experiments established the rates of association (1.17 × 10⁵min⁻¹ nM⁻¹) and dissociation (0.0514min⁻¹) of the ligand-receptor complex.5. The binding of [³H]STX reached apparent saturation at 7.5 nM. Scatchard analysis of the saturation data indicated a K_d of 3.8nM and a B_max of 1.9 pmol/mg protein.6. These studies provide evidence for high affinity, saturable binding sites for [³H]BTX-B and [³H]STX in trout brain preparations. Whereas certain neurotoxins modified the specific binding of [³H]BTX-B in trout brain synaptoneurosomes in a predictable fashion, other compounds known to affect specific [³H]BTX-B binding in mammalian brain preparations had no effect on specific [³H]BTX-B binding in the trout.     

Permeability of the 17-day fetal rat pancreas to glycerol and dimethylsulfoxide

Experimentally induced diabetes in rats can be reversed by the transplantation of several fresh or frozen-thawed fetal pancreases. An important question to both the mechanistic and practical aspects of cryobiology is the role played by the permeation of protective additives during freezing, thawing, and subsequent dilution. Answers require knowledge of the kinetics of permeation of the specific additive into the cell or tissue. In this paper, we report isotopic measurements of the rate of permeation of 2 M glycerol and 1 and 2 M dimethylsulfoxide (Me₂SO) into 17-day fetal pancreases at 0 and 22 °C. In Me₂SO, equilibrium was achieved in about 10–15 min at 0 °C and in less than 10 min at 22 °C. In glycerol, equilibrium was attained in about 60 min at 22 °C; but at 0 °C permeation was only 65% complete after 180 min. In general, Me₂SO permeated 10–30 times more rapidly than glycerol at 0 °C, and glycerol permeated about 10 times more rapidly at 22 than at 0 °C.The kinetics of permeation were more characteristic of a two-compartment than a single-compartment system. In all probability, the two compartments are the intercellular space and the intracellular space. The permeability data suggest that each compartment occupies about half the total volume.     

Cryopreservation of some useful microalgae species for biotechnological exploitation

Culture collections of microalgae represent a biological resource for scientific research and biotechnological applications. When compared to the current methods of maintenance and sub-culturing, cryopreservation minimizes labor costs and is an effective method for maintaining a large range of species over long periods with high stability. In order to determine the best cryopreservation method for microalgae species with great biotechnological potential, three freezing protocols were employed using different cryoprotectants (dimethyl sulfoxide—Me₂SO; methanol—MeOH). Three marine microalgae species (Thalassiosira weissflogii; Nannochloropsis oculata, and Skeletonema sp.) were cooled by directly plunging into liquid nitrogen (?196°C) and with two-step controlled cooling protocols (?18°C and ?80°C pre-treatments). After storage periods ranging from 10 to 120 days, viability was determined by the ability of cells to actively grow again. Results obtained for T. weissflogii showed that this species could be preserved at ultra-low temperature (?196°C) for 10 and 30 days with 10?% Me₂SO and 5?% MeOH when employed a controlled cooling protocol (?80°C). N. oculata was successfully cryopreserved either by direct freezing or with controlled cooling protocols. N. oculata samples presented good responses when treated with 5?% Me₂SO, 10?% Me₂SO, 5?% MeOH and even without any cryoprotectant. Skeletonema sp. did not survive cryopreservation in any of the tested conditions. The results indicate the difficulty in establishing common protocols for different microalgae species, being necessary further studies for a better understanding of cell damages during freezing and thawing conditions for each species.     

Properties of human growth hormone binding sites solubilized from female rabbit kidney

Human growth hormone binding sites from female rabbit kidney microsomes were solubilized by treatment with the nonionic detergent Triton X-100. The binding of ¹²⁵I-labelled human growth hormone to the solubilized sites retains many of the properties observed in the particulate fraction, such as saturability, reversibility, high affinity and structural specificity. The association and the dissociation process are time- and temperature-dependent. The association rate constant, k₁, is 1.6·10⁷ mol^?1·l·min^?1 at 25°C, and the dissociation rate constant, k_?1, is 2.8·10^?4 min^?1 at 25°C. Solubilization causes an increase in affinity as well as in binding capacity. Scatchard plots from saturation curves suggest the presence of a single class of binding site with a dissociation equilibrium constant, K_d, of 1.3·10^?11 M and a binding capacity of 133 fmol/mg of protein. Similar results were obtained from competition experiments. Specificity studies revealed the lactogenic characteristics of the solubilized sites. The Stokes radii of the free binding sites and of the ¹²⁵I-labelled human growth hormone-binding site complex, determined on a Sepharose CL-6B column, are 57 and 53 Å, respectively.     

An experimental study on the freezing of red blood cells with and without hydroxyethyl starch

Red blood cells were frozen in small capillaries down to ?196 °C at different linear cooling rates with or without the cryoadditive HES; the thawing rate was 3000 or 6500 °C/min. Hematocrit and hydroxyethyl starch concentration varied independently. The hemolysis of red blood cells was determined photometrically after 250-fold dilution and compared to totally hemolyzed samples. The typical U-shaped curves for hemolysis as a function of the cooling rate were obtained for all cell suspensions investigated. Relative optimum cooling rates were determined for the respective combinations of HES and hct. The results show that increasing hct causes an increased hemolysis; increased HES concentration C_HES reduces the optimum cooling rate B_opt; increased hct results in higher optimal cooling rates. The findings allow one to establish a linear correlation of the HES concentration and the optimum cooling rates when the dilution of the extracellular medium by the cell water efflux during freezing is taken into account. A comparison with results from larger volumes frozen (25 ml) shows that the established relationship between hematocrit, HES concentration, and optimal cooling rate remains valid.     

Spectral changes in membrane fragments and artificial liposomes of Anacystis induced by chilling.

Isolated membrane fragments from Anacystis nidulans grown at 39 °C undergo visible spectral changes on chilling, suggesting a carotenoid component is altered. No such changes are seen when cells are grown at 25 °C. The magnitude of the decreased absorbance is a function of the chilling temperature and the media in which membrane fragments are suspended. The spectral decrease following chilling develops relatively slowly and is a function of the cooling rate and final temperature. The absorbance change is reversed if the fragments are heated to near 50 °C subsequent to chilling. Liposomes prepared from a total lipid extract of Anacystis undergo a spectral change on chilling which closely resembles that occurring in whole cells or isolated membrane fragments. Liposomes prepared from an extract of cells grown at 25 °C show only about 30% as great a spectral change as those from cells grown at 39 °C. The spectral bleaching is freely reversible when the liposomes are reheated, but shows a pronounced hysteresis. It is suggested that specific phase changes occur in Anacystis membranes and artificial liposomes on cooling which alter the environment of carotenoid. These changes may relate to previous observations that cells grown at 39 °C cannot survive a cold shock while those grown at 25 °C do.     

Interspecific variation in thermoregulation among three sympatric bats inhabiting a hot, semi-arid environment

Bats in hot roosts experience some of the most thermally challenging environments of any endotherms, but little is known about how heat tolerance and evaporative cooling capacity vary among species. We investigated thermoregulation in three sympatric species (Nycteris thebaica, Taphozous mauritianus and Sauromys petrophilus) in a hot, semi-arid environment by measuring body temperature (T _b), metabolic rate and evaporative water loss (EWL) at air temperatures (T _a) of 10?C42?°C. S. petrophilus was highly heterothermic with no clear thermoneutral zone, and exhibited rapid increases in EWL at high T _a to a maximum of 23.7?±?7.4?mg?g^?1?h^?1 at T _a????42?°C, with a concomitant maximum T _b of 43.7?±?1.0?°C. T. mauritianus remained largely normothermic at T _as below thermoneutrality and increased EWL to 14.7?±?1.3?mg?g^?1?h^?1 at T _a????42?°C, with a maximum T _b of 42.9?±?1.6?°C. In N. thebaica, EWL began increasing at lower T _a than in either of the other species and reached a maximum of 18.6?±?2.1?mg?g^?1?h^?1 at T _a?=?39.4?°C, with comparatively high maximum T _b values of 45.0?±?0.9?°C. Under the conditions of our study, N. thebaica was considerably less heat tolerant than the other two species. Among seven species of bats for which data on T _b as well as roost temperatures in comparison to outside T _a are available, we found limited evidence for a correlation between overall heat tolerance and the extent to which roosts are buffered from high T _a.     

Preservation of mouse embryos by two-step freezing

Eight-cell mouse embryos in 1.5 M DMSO were preserved in LN₂ by a two-step procedure. Fifteen minutes exposure at ?20 °C protected the embryos against damage during rapid cooling to -196 °C and during rapid warming and rapid dilution. Since survival was poor on slow warming it is suggested that the method permits the formation of some intracellular ice.     

Substrate Temperature Effect on Microstructure,Optical, and Glucose Sensing Characteristics of Pulsed Laser Deposited Silver Nanoparticles

This work reports the substrate temperature-influenced change in the structural, morphological, optical, and glucose sensing properties of silver (Ag) nanoparticles (NPs) deposited on p-type Si (100) wafers. AgNP films grown at temperatures ranging from RT to 600 °C clearly show a dependence of orientation texture and surface morphology on substrate temperature (T _s). As T _s increases from RT towards 600 °C, the preferred orientation of AgNP film changes from (111) to (200). The AgNPs size, that is T _s-dependent, reaches the maximum value at T _s = 300 °C. This result is attributed to restructuring of AgNPs texture. Moreover, the AgNP shape also changes from ellipsoid to sphere as T _s increases from RT to 600 °C. Surface plasmon enhancement in photoluminescence intensity is observed with increase in T _s. It is found also that the AgNP film deposited at 300 °C has considerable reflectance reduction relative to the silicon substrate, in wavelength range of 300–800 nm and a progressive red shift of localized surface plasmon resonances caused by the adding of increasing quantities of glucose has been observed. As a proof of concept, we also demonstrate the capability of grown AgNP substrates for glucose detection based on surface enhanced Raman spectroscopy in physiological concentration range with short integration time 10 s, varying with T _s.     

Effect of temperature on the in vitro assembly of bacterial flagella

The temperature dependence for the rate of reconstitution or polymerization (k₊) at neutral pH of the protein, flagellin, to flagella was measured using Ostwald-type viscometers. Similarly, the kinetics for the reverse process, the thermally-induced depolymerization of flagella filaments to the flagellin monomer (k_?) was measured. The temperature at which k_? equals zero was used to define the thermal dissociation temperature or melting point of flagella filaments. The remarkable similarity of melting points obtained (36.8 ± 0.2 deg. C) for flagella isolated from three Salmonella strains (SJ670, SJ25 and SJ30 bearing H-antigen types i, 1.2 and e, n, x, respectively) suggests that the structural stability of these different protein filaments is also similar.On increasing the temperature between 12 and 28°C, k₊ increased smoothly and had a Q₁₀ of 1.8. Above 28.0, k₊ decreased rapidly and fell to zero at a temperature near 37°C, its precise value varying with the bacterial strain. This result supports the prior hypothesis (Gerber &; Noguchi, 1967) that on heating, a reversible co-operative transconformation occurs between different states of the protein; in one state, flagellin (M) can polymerize to flagella, whereas its conformational isomer(s) may do so with difficulty or not at all.For strains SJ25 and SJ30 the rates of polymerization and depolymerization both fall to zero near 37°C. Therefore, mixtures of monomer and flagella fragments (short polymers or “seeds”), in all ratios, appear to be in equilibrium at temperatures near this critical temperature, and neither polymerization of flagellin to flagella nor melting of polymers is apparent.Measurements made on flagella from strain SJ670 showed that k₊ and k_? approached zero at 45 and 37°C, respectively. Within this temperature range the conc entration of monomer in equilibrium with filaments was determined. By a null -point type experiment, solutions of monomer and seed were mixed to find the ratio that showed neither increases (polymerization) nor decreases (depolyme rization) in viscosity with time. An unexpected finding was that the temperature defines a critical monomer concentration, which exists in equilibrium with any concentration of filaments (and not the ratio of monomer-to-filament concentrations). Thus, the polymerization of fiagellin to flagella corresponds to a phase change akin to either crystallization or condensation.Application, of the Clapeyron-Clausius equation to the results obtained yields a heat of condensation of 70 kcal/mol of monomeric protein. The enthalpy change associated with M ? M_i is estimated as 110 kcal/mol of protein. Since the heat content of these various forms of flagella protein lies in the order M_i > F > M, by difference we estimate the enthalpy change for the conversion of monomers to polymers to be 40 kcal/mol of monomer.     

Permeability of the human erythrocyte to glycerol in 1 and 2 m solutions at 0 or 20 °C

There are increasing numbers of exceptions to a central tenet in cryobiology that low-molecular-weight protective solutes such as glycerol must permeate cells in high concentration in order to protect them from freezing injury. To test this supposition, it is necessary to determine the amount of solute that has permeated a cell prior to freezing. The amount in human red cells was estimated from the flux equation $\text{ds}\text{dt}\text{= P}{}_{\mathrm{<mtext>\gamma </mtext>}}\text{A}$[(activity external solute) — (activity internal solute)]. Solving the equation required knowledge of P_γ the permeability constant for the solute. Estimates of P_γ for glycerol were made in two ways: (i) by measuring the time to 50% hemolysis of human red cells suspended in 1 or 2 m solutions of glycerol that were hypotonic with respect to NaCl, and (ii) by measuring the time required for red cells in 1 or 2 m solutions of glycerol in isotonic saline-buffer to undergo osmotic shock upon tenfold dilution with isotonic saline-buffer. The measurements were made at 0 and 20 °C. The values of P_γ were about 2.5 × 10^?4 cm/min at 20 °C and about 0.9 × 10^?4 cm/min at 0 °C. The difference corresponds to an activation energy of 7.2 kcal/mole. These values of P_γ are 100 to 600 times higher than those for glycerol permeation in the bovine erythrocyte. The values of P were relatively unaffected by whether calculations were based on classical or irreversible thermodynamics and by the choice of concentration units in the flux equations. Calculations of the kinetics of glycerol entry using these P values showed that the concentration of intracellular glycerol reaches 90% of equilibrium in 1.2 min at 0 °C and in 0.6 min at 20 °C. The osmolal ratio of intracellular glycerol to intracellular nonpermeating solutes reaches 90% of equilibrium in 7 min at 0 °C and in 3.2 min at 20 °C.     

The gelation of deoxyhemoglobin S in erythrocytes as detected by transverse water proton relazation measurements

At 37 °C, when samples of blood, washed erythrocytes, or isolated hemoglobin from individuals with sickle cell disease are deoxygenated, the transverse water proton relaxation time is sharply decreased. In similar samples from normal adults homozygous for hemoglobin A, only a slight decrease in t₂ is observed upon deoxygenation at 37 °C. In samples containing deoxyhemoglobin S the value of t₂ increases as the temperature is decreased from 37 °C to 4 °C, in contrast to samples containing oxyhemoglobin S, oxyhemoglobin A, or deoxyhemoglobin A where t₂ decreases as the temperature decreases. It is suggested that this decrease in t₂ observed in samples of deoxyhemoglobin S at 37 °C is the result of an increase in the amount of preferentially oriented water at macromolecular interfaces which occurs under conditions known to produce deoxyhemoglobin S gelation. Conditions which reverse deoxyhemoglobin S gelation such as lowering the temperature to 4 °C decrease the amount of preferentially oriented water which results in an increase in the value of t₂. Thus, measurement of the transverse water proton relaxation time can be used to monitor the gelation of deoxyhemoglobin S inside the erythrocyte.     

The effect of ice formation on the function of smooth muscle tissue stored at −21 or −60 °C

The mechanisms by which single cells are injured during freezing are relatively well understood, but it is likely that additional factors apply to tissues and organs, factors that may be responsible for the poor suecess of attempts to cryopreserve complex multicellular systems. One such factor may be the formation of extracellular ice.

This study was designed to discover whether ice formation as such is detrimental to the contractile recovery of pieces of mammalian smooth muscle after storage at subzero temperatures. Strips of taenia coli muscle were equilibrated with 2.56 M Me₂SO in a buffered solution, cooled at either 0.3 or 2 °C/min to ?21 °C and then held at this temperature in the frozen state. Other muscle strips were bathed in a solution the composition of which mimicked that of the unfrozen phase of the previous solution at ?21 °C; it contained 4.49 M Me₂SO and 1.75 times the normal concentration of salts, and muscles equilibrated with this solution were also cooled at either 0.3 or 2 °C/min to ?21 °C, and then held unfrozen for the same length of time.It was shown that exposure to ?21 °C and the increased concentration of solutes had little effect on the contractile recovery of the muscles, whereas ice formation was damaging. Furthermore, the rate of cooling had a marked effect upon functional recovery in the frozen muscles, and this could be correlated with the known effect of these cooling rates on the pattern of ice formation in the tissue. The effect was also seen in muscles frozen at ?60 °C. Improved buffering increased the functional recovery of all groups, but the effect of ice, and of cooling rate in the presence of ice, was confirmed. These findings may have significant implications for attempts to cryopreserve complex tissues and organs.