Multiple mechanisms generate the resting activity of filiform sensilla in the firebug (<Emphasis Type="Italic">Pyrrhocoris apterus</Emphasis> L.; Heteroptera)

The resting activity was studied in filiform sensilla of the firebug (Pyrrhocoris apterus). Three functional types (T₁, T₂ and T₃) were detected on the abdomen. A resting discharge of nerve impulses is present in all—always in types T₁ and T₂ and occasionally in type T₃. In T₁ the mean rate is 57, in T₂ 3.3 and in T₃ 0.5 imp/s. Shortening the hair length had a negligible effect on the resting discharge, which indicates an intrinsic origin. The resting activity is highly temperature dependent. In T₁, the activation energy was 56.8, in T₂ 84 and in T₃ 61.4 kJ/mol (Q ₁₀: 2.27, 5.6 and 5.5, respectively). Such values are typical for mechano-transduction, suggesting the involvement of the transduction mechanism itself. The destruction of the hair base in T₁ caused halving of the original discharge rate and shifted the discharge to a regular interval mode. The activation energy decreased to 38 kJ/mol. The destruction of the hair bases in T₂ and T₃ completely abolished the discharge. It appears that at least two mechanisms are involved in the generation of the resting activity in T₁ units while only one can be assumed in case of T₂ and T₃.     

Molecular dynamics simulations of a cyclic-DP-240 amylose fragment in a periodic cell: Glass transition temperature and water diffusion

Molecular dynamics simulations using AMB06C, an in-house carbohydrate force field, (NPT ensembles, 1 atm) were carried out on a periodic cell that contained a cyclic 240 glucose residue amylose fragment (c-DP-240) and TIP3P water molecules. Molecular conformation and movement of the amylose fragment and water molecules at different temperatures were examined. The periodic cell volume, density, and potential energy were determined at temperatures above and below the glass transition temperature (T_g) in 25 K increments_. The amorphous cell is constructed through successive dynamic equilibration steps at temperatures above the assumed T_g value and the temperature successively lowered until several temperature points were obtained below T_g. Molecular dynamics simulations were continued for at least 500 ps or until the volume drift stopped and remained constant for several hundred picoseconds. The T_g values were found by noting the discontinuity in slope of the volume (V), potential energy (PE), or density (ρ) versus 1/T. The changes in flexibility and motion of the amylose chain as well as differences in self diffusion coefficients of water molecules are described. The final average T_g value found (316 K) is in agreement with experimental values, i.e. 320 K.     

Effect of hydration upon the thermal stability of tropocollagen and its dependence on the presence of neutral salts

The endotherm enthalpy changes ΔH_D and temperatures T_D of thermal denaturation of tropocollagen fibers were measured by DSC calorimetry as functions of water content. The denaturation temperatures decrease with increasing water content. The enthalpy change values increase sharply in the range 0–28% of water content, where a maximum of 14.3 cal g^?1 is reached. The effect of water uptake on the enthalpy term is explained by water bridge formation within the collagen triple helix. Evidence is given for the existence of approximately three intercatenary water bridges per triplet at the enthalpy maximum, their H-bond energy amounting to approximately 4000 kcal/mol of protein. In the 30–60% range of water content, ΔH_D decreases by 2 cal^?1 probably due to interactions between secondary water structures and the stabilizing intrahelical water bonds. The influence of two neutral potassium salts, with a structure-stabilizing and a structure-breaking anion (F^? and I^?), on the hydration dependence of ΔH_D and T_D was also studied. It was shown that the primary hydration is not influenced by these ions, but that T_D and ΔH_D are altered in an ion specific way in the presence of interface and bulk water. Hydrophobic interactions do not explain the experimental results. A reaction mechanism of the effects of ions upon the structural stability of collagen is proposed and discussed in terms of interactions of the medium water molecules with the intrahelical water bonds, and in terms of proton-donor/proton-acceptor equilibria between peptide groups, hydrated ions, and intrahelical water molecules.     

Investigation of the state and dynamics of water in hydrogels of cellulose ethers by 1H NMR spectroscopy

The aim of this work was to study the effect of the type of substituent of the cellulose ethers and the molecular mass on the state and dynamics of water in the respective hydrogels to specify the quantity of adsorbed water on the polymers or, more explicitly, to calculate the average number of water molecules bound to a polymer repeating unit (PRU).¹H NMR relaxation experiments were performed on equilibrated systems of cellulose ether polymers (HEC, HPC, HPMC K4M, and HPMC K100M) with water. In particular, the water proton spinlattice (T ₁) and spin-spin (T ₂) relaxation times were measured in these systems at room temperature. The observed proton NMRT ₁ andT ₂ of water in hydrogels at different cellulose ether concentrations at room temperature were shown to decrease with increasing polymer concentration. The relaxation rate 1/T ₁ is sensitive to the type of polymer substituent but insensitive to the polymer molecular mass. The rate 1/T ₂ appears much less influenced by the polymer substitution. The procedure developed for calculating the amount of water bound per PRU, based on the analysis of theT ₁ andT ₂ data, shows that this amount is the largest for HPC followed by HEC, HP MC K4M, and HPMC K100M. The results correlate well with the degree of hydrophilic substitution of the polymer chains. This NMR analysis deals with a single molecular layer of adsorbed water for the investigated cellulose ether polymers at all concentrations, while the rest of the water in the hydrogel is bulk-like. Therefore, the mesh size of polymer network in the view of a single molecular layer is not effectively changed.     

Proton Nuclear Magnetic Resonance Relaxation Measurements in Frog Muscle

Proton nuclear magnetic resonance (NMR) relaxation measurements are reported for frog muscle as a function of temperature and Larmor frequency. Each T_1ρ, T₂, and T₁ measurement covered a time domain sufficient to identify the average relaxation time for most intracellular water. Using regression analysis the data were fit with a model where intracellular water molecules are exchanging between a large compartment in which mobility is similar to ordinary water and a small compartment in which motion is restricted. The regression results suggest that: the restricted compartment exhibits a distribution of motions skewed toward that of free water; the residence time of water molecules in the restricted compartment is approximately 1 ms; and, the activation entropy for some water molecules in the restricted compartment is negative.     

The state of water on hydrated collagen as studied by pulsed NMR

The spin-lattice relaxation time (T₁) of water adsorbed on collagen fibers was determined at six frequencies and temperatures varying from 25° to ?80°C. Care was taken to eliminate the contributions to the signal of protons other than those in the adsorbed water. Quantitative calculations were made on T₁ and the results were compared with the experimental data. It is suggested that a maximum of about 0.50–0.55 g water per g collagen forms a hydration layer, which cannot be frozen down to ?90°C and exhibits a distribution of motional correlation times. For collagen samples containing a larger quantity of adsorbed water, the additional water molecules behave like ordinary isotropic water, having a single correlation time and a freezing temperature of about ?10°C.     

Determination of thyroxine in the hair of newborns by radioimmunoassay with high-performance liquid chromatographic confirmation

Hair analysis is often used in forensic toxicology to study, retrospectively, chronic exposure of individuals to drugs, and consequently newborn hair may become an ideal sample to study intrauterine exposure to xenobiotics as well as to endogenous compounds. As a tool to investigate a supposed maternal thyroxine (T₄) supply to the congenital hypothyroid fetus, we devised to use the analysis of T₄ extracted from newborn hair. In the present paper, the analytical method based on T₄ extraction from hair followed by a radioimmunoassay is described. To verify the nature of the T₄-like immunoreactive material present in newborn hair, it was further studied by HPLC fractionation with radioimmunoassay of the eluted fractions. On the basis of a clear correspondence between retention times of T₄ standard and T₄-immunoreactive compound extracted from hair, we assigned this immunoreactive material to T₄. Then, we determined T₄ hair concentrations in 19 control newborns at birth and 12 congenital hypothyroid infants at 22 days of life. Values obtained from hypothyroid infants (31.47±8.8 pg/mg_hair, mean±S.D.) were not significantly lower than those obtained from healthy newborns at birth (36.10±13.2 pg/mg_hair). Such results are in agreement with the hypothesis of a maternal supply of thyroxine to the fetus through placental crossing.     

The effect of deuterium oxide on the stability of the collagen model peptides H‐(Pro‐Pro‐Gly)10‐OH,H‐(Gly‐Pro‐4(R)Hyp)9‐OH,and Type I collagen

The collagen triple helix has a larger accessible surface area per molecular mass than globular proteins, and therefore potentially more water interaction sites. The effect of deuterium oxide on the stability of collagen model peptides and Type I collagen molecules was analyzed by circular dichroism and differential scanning calorimetry. The transition temperatures (T_m) of the protonated peptide (Pro‐Pro‐Gly)₁₀ were 25.4 and 28.7°C in H₂O and D₂O, respectively. The increase of the T_m of (Pro‐Pro‐Gly)₁₀ measured calorimetrically at 1.0°C min^?1 in a low pH solution from the protonated to the deuterated solvent was 5.1°C. The increases of the T_m for (Gly‐Pro‐4(R)Hyp)₉ and pepsin‐extracted Type I collagen were measured as 4.2 and 2.2°C, respectively. These results indicated that the increase in the T_m in the presence of D₂O is comparable to that of globular proteins, and much less than reported previously for collagen model peptides [Gough and Bhatnagar, J Biomol Struct Dyn 1999, 17, 481–491]. These experimental results suggest that the interaction of water molecules with collagen is similar to the interaction of water with globular proteins, when the ratio of collagen to water is very small and collagen is monomerically dispersed in the solvent. © 2009 Wiley Periodicals, Inc. Biopolymers 93: 93–101, 2010. This article was originally published online as an accepted preprint. The “Published Online” date corresponds to the preprint version. You can request a copy of the preprint by emailing the Biopolymers editorial office at biopolymers@wiley.com     

Co-composting of hair waste from the tanning industry with de-inking and municipal wastewater sludges

Production of waste hair in the leather manufacturing industry is increasing every year due to the adoption of hair-save unhairing techniques, leaving the tanners with the problem of coping with yet another solid by-product. Numerous potential strategies for hair utilisation have been proposed. However, the use of hair waste as agricultural fertiliser is one of its most promising applications due to the high nitrogen content of hair. Agricultural value of hair can be increased by composting. This paper deals with the composting of hair from the unhairing of bovine hide. Results indicated that hair cannot be either composted on its own or co-composted with de-inking sludge, a chemical complementary co-substrate. However, good results were obtained when co-composted with raw sludge from a municipal wastewater treatment plant at hair:raw sludge weight ratios 1:1, 1:2 and, 1:4 in lab scale and pilot plant scale composters. In all cases, a more stable product was achieved at the end of the process. Composting in the pilot plant composter was effectively monitored using Static Respiration Indices determined at process temperature at sampling (SRI _T ) and at 37°C (SRI₃₇). Notably, SRI _T values were more sensitive to changes in the biological activity. In contrast, Respiratory Quotient (RQ) values were not adequate to follow the development of the process.     

Flocculation Effects on Bound Water in Sludges as Measured by Nuclear Magnetic Resonance Spectroscopy

Nuclear magnetic resonance relaxation times (T₁ and T₂) were measured for flocculated and unflocculated samples of activated sludge. The weight of water and solids in the sludge samples was found and related to T₁ to find the relative percentage of bound water. The results suggest that the amount of bound water increases as the samples become more unflocculated. The values of T₁ and T₂ also indicate that unflocculated individual particles are characterized by loose packing of shorter molecules and that the addition of larger molecules may induce flocculation.     

Detection of dynamic water molecules in a microcrystalline sample of the SH3 domain of α-spectrin by MAS solid-state NMR

Water molecules are a major determinant of protein stability and are important for understanding protein–protein interactions. We present two experiments which allow to measure first the effective T₂ decay rate of individual amide proton, and second the magnetization build-up rates for a selective transfer from H₂O to H^N using spin diffusion as a mixing element. The experiments are demonstrated for a uniformly ²H, ¹⁵N labeled sample of a microcrystalline SH3 domain in which exchangeable deuterons were back-substituted with protons. In order to evaluate the NMR experimental data, as X-ray structure of the protein was determined using the same crystallization protocol as for the solid-state NMR sample. The NMR experimental data are correlated with the dipolar couplings calculated from H₂O–H^N distances which were extracted from the X-ray structure of the protein. We find that the H^N T₂ decay rates and H₂O–H^N build-up rates are sensitive to distance and dynamics of the detected water molecules with respect to the protein. We show that qualitative information about localization and dynamics of internal water molecules can be obtained in the solid-state by interpretation of the spin dynamics of a reporter amide proton.     

The crystal structure of D-glucaro-1,4-lactone monohydrate

In the crystal structure of D-glucaro-1,4-lactone monohydrate, C₆H₈O₇·H₂O, the molecules have the E₃ lactone-ring conformation, with a small distortion of the ring to ₃T². The α-hydroxycarboxylic acid side-chain is axial, with the HO---C---C=O torsion angle within 6° of cis-planar. The orientation of the side-chain is such that the hydroxyl group lies over the lactone ring, which is the same conformation as is reported to preponderate in solution. Calculations of non-bonding repulsion energy show that this conformation corresponds to an energy minimum, although comparable minima can also be obtained with the ring in the alternative ³E conformation. The lactone and water molecules are hydrogen-bonded to form layers two molecules,wide, separated by Van der Waals interactions. One of the water hydrogen atoms is involved in a weak, bifurcated hydrogen-bond.     

Estimation of Differently Bound Water Molecules for the Gel Phase of Dimyristoylphosphatidylethanolamine-Water System as Studied by DSC and 2H-NMR Spectroscopy

A measurement of ²H spin-lattice relaxation time, T ₁, forD₂O was performed with a high resolution liquid NMR apparatus fortwo samples of dimyristoylphosphatidylethanolamine (DMPE)-D₂Osystem in a full hydration at varying temperatures of –20, –10, and 5 ^°C, and both components and compositions of differently boundfreezable water molecules were estimated from a best-fitted curve toexperimental inversion recovery data. A choice of the best-fitted curve wasbased on a distribution of weighted residuals for the experimental data. Asingle component was found for a temperature of –20 ^°C. At 5 ^°C, where all the freezable water exists in the liquid state, threecomponents were observed to be characterized by T ₁ values ofapproximately 20, 100, and 200 ms, respectively. By comparingcompositions of these individual components with those obtained in ourprevious DSC study, it was revealed that the first and secondarycomponents are members of freezable interlamellar water and the last oneis comparable to bulk water.     

The mobility of PSI and PQ molecules in <Emphasis Type="Italic">Spirulina platensis</Emphasis> cells during state transition

Monomerization and trimerization of photosystem I (PSI) in cyanobacteria are reversible to response to light switched off and on, which leads to “energy spillover” to regulate excitation of the two photosystems in balance. Considering that PSI is a trans-membrane protein embedded in thylakoid membranes, the monomerization or trimerization must involve a movement of PSI in the membranes. In this work, the mobility of PSI was demonstrated by dependence of the monomerization and trimerization on temperature for intact Spirulina platensis cells undergoing a light-to-dark or a dark-to-light transition. Based on the characteristic absorbance of monomers and trimmers, it confirms that both monomerization and trimerization are temperature-sensitive. The relative populations of the monomers and trimmers are invariable above the phase transition temperature (T _PT) while directly proportional to temperature below T _PT. On the other hand, the rate to reach the equilibrium population is proportional to temperature above T _PT but invariable below T _PT. The PSI mobility and the temperature-dependent population are contrary to those of plastoquinone (PQ) molecules because PSI is a trans-membrane protein while PQ molecules are small diffusive electron carriers in thylakoid membranes as well as their distinctive sizes and environments. The less monomerization of PSI but the invariable time constant at lower temperature below T _PT may be due to that accumulation of the reduced PQ molecules results in decrease of the stromal-side H⁺ concentration which is a driving force of PSI monomerization.     

NMR relaxation study of water protons in Syrian hamster fetal cells at 300 MHz

TheT ₁ andT ₂ relaxation times of water protons in two cell types in culture derived from Syrian hamster fetuses (normal primary or secondary fetal cells vs BP6T tumor cells derived from the normal cells transformed by carcinogens) were measured at 7.05 Tesla magnetic field (proton frequency =300 MHz). TheT ₁/T ₂ ratios and the correlation time, τ _c , calculated from theT ₁/T ₂ ratio of cellular water protons, are significantly different in these two fibroblastic cell types of the same biological origin and with similar morphologies and growth rates in culture.     

Physical properties of insect cuticular hydrocarbons: Model mixtures and lipid interactions

Cuticular lipids include a diverse array of hydrophobic molecules that play an important role in the water economy of terrestrial arthropods. Their waterproofing abilities are believed to depend largely on their physical properties, but little is known about interactions between different surface lipids to determine the phase behavior of the total lipid mixture. I examined the biophysical properties of binary hydrocarbon mixtures, as a model for interactions between different epicuticular lipids of insects. The midpoint of the solid/liquid phase transition (T_m) for mixtures of n-alkanes differing in chain length equaled the weighted average of the T_ms of the component lipids. This was also true for n-alkane-methylalkane mixtures. However, alkane-alkene mixtures melted at temperatures up to 17°C above the temperature predicted from the weighted average of component lipid T_m values. Hydrocarbon mixtures did not exhibit biphasic melting transitions indicative of independent phase behavior of the component lipids. Instead, melting occurred continuously, over a broader temperature range than pure hydrocarbons.     

Oxygen consumption and body temperature in yellow-bellied marmot populations from montane-mesic and lowland-xeric environments

Summary Yellow-bellied marmots characteristically live in montane-mesic environments, but in several areas in western North America, this species extended its range into lowland-xeric habitats. Body mass was significantly smaller in the lowland-xeric population from eastern Washington at 393 m than in the montane-mesic population from western Colorado at 2900 m. Oxygen consumption of marmots from montane-mesic and lowland-xeric environments was signiflcantly affected by ambient temperature (T_A) water regimen, population, and a population x water regimen x temperature interaction. Lowland-xeric animals had a higher metabolic rate at low T_As, but a lower metabolic rate at higher T_As than the montane-mesic aminals. Oxygen consumption was lower on a restricted-water regimen than on ad libitum water in both populations. Coefficients relating oxygen consumption to body mass were affected by T_A, water regimen, and population. These intraspecific coefficients are larger than the interspecific coefficients for all mammals. Body temperature (T_B) was affected significantly by T_A, water regimen, and population. T_A body mass, and a population x water regimen interaction significantly affected conductance. Conductance generally was higher in the lowland-xeric than in the montane-mesic marmots. Both populations increased conductance at high T_A, but the lowland-xeric population dissipated a much higher proportion of the heat by evaporative water loss (EWL) than did the montane-mesic population. Metabolic water production exceeded or equaled EWL at 5–20°C. Smaller body size, reduced metabolism at high T_A, and increased EWL at high T_A characterized the lowland-xeric population.Metabolic rates of yellow-bellied marmots were higher than predicted from body size during the reproductive season but decreased to 67% of that predicted from the Kleiber curve by late summer. Marmots minimize thermoregulatory costs by concentrating activity at times when the microclimate is favorable, by tolerating hyperthermia at high T_A in the field, and by having a conductance lower than that predicted from body size.Abbreviations DHC dry-heat conductance - EHL evaporative heat loss - EWL evaporative water loss - HP heat produced - T _A ambient temperature - T _n body temperature - M body mass     

300 MHz proton NMR study of the differentiation of diploid human epidermal keratinocytes

The nuclear magnetic resonance spin-lattice (T₁) and spin-spin (T₂) relaxation times are closely related to the molecular motions of the molecules in a liquid sample. T₁ and T₂ of human epidermal cells were measured at 300 MHz as functions of harvesting methods (i.e., scraping vs trypsinization) and age in culture. It was found that T₁ and T₂ values have smaller variances when the cell is harvested by trypsinization rather than scraping. The correlation coefficients for both T₁ and T₂, obtained from cells harvested by trypsinization, are much higher than those obtained from cells harvested by scraping. More importantly, this is the first report to monitor in vitro aging through relaxation times measurement. There is a significant increase in the values of T₁ and T₂ from the third to seventh passages. Human keratinocytes slowed down and even ceased to grow the seventh passage. Therefore, the cellular water molecules of human keratinocytes have higher mobility in a more differentiated state. The factors contributing to the change in relaxation times as cells progress toward senescence are discussed.     

Relationship between leaf water spin-lattice relaxation time and water relation parameters in three wheat cultivars

Pot culture studies were conducted using two drought-tolerant and one susceptible cultivar of wheat (Triticum aestivum L.) under three different moisture regimes. Proton spin-lattice relaxation time, T₁, leaf water content, LWC, leaf water potential, Ψ, solute potential, Ψ_s and turgor potential, Ψ_p were measured from 45 to 75 d after sowing at weekly intervals. The three cultivars did not differ significantly in their values of LWC, leaf water potential, and their components in the stressed and unstressed plants; but they did differ significantly in their T₁ values both under stressed and unstressed conditions on all days of measurement, with the drought tolerant cultivars having a higher T₁ compared to the susceptible cultivar. This suggests that leaf water T₁ is a better parameter for describing plant water status than the traditional water relation indices. The relation between Ψ and T₁ was logarithmic, indicating the similarity between T₁ and water activity of the cellular water.     

Intrinsic proton relaxation parameters of hydrated polyglycine from two‐dimensional time domain NMR

Proton two‐dimensional time domain nmr involving T₁, T_1ρ, T_1D, and T₂ measurements was applied to hydrated polyglycine powders. The results were analyzed for magnetization exchange and found to be consistent with a general three‐site (glycine–water–glycine) exchange model. The intrinsic glycine and water proton relaxation parameters as well as the three exchange rates were obtained. Estimates of correlation times for water molecule motion at hydration sites are presented. © 1999 John Wiley & Sons, Inc. Biopoly 50: 630–640, 1999