Osmotic effectors in kidneys of xeric and mesic rodents: corticomedullary distributions and changes with water availability

Summary Urea, sodium, the methylamines glycine betaine and glycerophosphorylcholine (GPC), and the polyols sorbitol and myo-inositol are reported to be the major osmolytes in kidneys of laboratory mammals. These were measured (millimoles per kilogram wet weight) in kidney regions and urines of three species of wild rodents with different dehydration tolerances: the pocket mousePerognathus parvus (xeric), voleMicrotus montanus (mesic), and deer mousePeromyscus m. gambeli (intermediate). In animals kept without water for 4–6 days, sodium, urea, betaine and GPC+choline were found in gradients increasing from cortex to outer to inner medulla in all species, withPerognathus having the highest levels. Sorbitol was high in the inner medulla but low in the cortex and outer medulla; inositol was highest in the outer medulla. Totals of methylamines and methylamines plus polyols in the medulla showed high linear correlations (positive) with urea and with sodium values.Whole medullae were analyzed at several time points inMicrotus andPeromyscus subject to water diuresis followed by antidiuresis. In 102 h diuresis inMicrotus, all osmolytes decreased except inositol; however, only urea, sodium and sorbitol reached new steady states within 24 h. Urea returned to initial values in 18 h antidiuresis, while other osmolytes required up to 90 h. InPeromyscus, all osmolytes except the polyols declined in diuresis (max. 78 h test period). During antidiuresis, urea and GPC+choline rose to initial values in 18 h, with sodium and betaine requiring more time. In plots of both species combined, total methylamines+polyols correlated linearly (positive) with sodium, and GPC+choline with urea.Estimates of tissue concentrations suggest that total methylamines+polyols can account for intracellular osmotic balance in all species in antidiuresis and that sufficient concentrations of methylamines may be present to counteract perturbing effects of urea on proteins.Abbrevations GPC Glycero-3-phosphorylcholine - TCA trichloroacetic acid - M+P methylamines plus polyols     

Methanogenesis from Methanol and Methylamines and Acetogenesis from Hydrogen and Carbon Dioxide in the Sediments of a Eutrophic Lake

¹⁴C-tracer techniques were used to examine the metabolism of methanol and methylamines and acetogenesis from hydrogen and carbon dioxide in sediments from the profundal and littoral zones of eutrophic Wintergreen Lake, Michigan. Methanogens were primarily responsible for the metabolism of methanol, monomethylamine, and trimethylamine and maintained the pool size of these substrates below 10 μM in both sediment types. Methanol and methylamines were the precursors for less than 5 and 1%, respectively, of the total methane produced. Methanol and methylamines continued to be metabolized to methane when the sulfate concentration in the sediment was increased to 20 mM. Less than 2% of the total acetate production was derived from carbon dioxide reduction. Hydrogen consumption by hydrogen-oxidizing acetogens was 5% or less of the total hydrogen uptake by acetogens and methanogens. These results, in conjunction with previous studies, emphasize that acetate and hydrogen are the major methane precursors and that methanogens are the predominant hydrogen consumers in the sediments of this eutrophic lake.     

Effects of organic solvents, methylamines, and urea on the affinity for Pi of the Ca2+-ATPase of sarcoplasmic reticulum

The Ca2+-ATPase of sarcoplasmic reticulum can be phosphorylated by Pi, forming an acylphosphate residue at the catalytic site of the enzyme. In a previous report (de Meis, L., Alves, E., and Martins, O.B. (1980) Biochemistry 19, 4252-4261), it was shown that organic solvent such as dimethyl sulfoxide and glycerol cause a decrease in the apparent Km for Pi. In this report it is shown that a similar effect is obtained with the methylamines glycine betaine and trimethylamine N-oxide. The apparent Km value for Pi in totally aqueous medium and in the presence of either 6.4 M glycerol, 1.4 M dimethyl sulfoxide, 0.4 M trimethylamine N-oxide, or 1 M glycine betaine were found to be respectively 2.85, 0.52, 0.52, 0.81, and 0.93 mM at pH 6.2 and greater than 10.0, 1.08, 2.53, 3.05, and 2.05 mM at pH 7.5. In contrast to the effect of methylamines, urea caused an increase in the apparent Km for Pi. When mixed in the appropriate concentration ratio, the effect of either organic solvent or methylamines is cancelled by urea.     

Determination of trimethylamine and related aliphatic amines in human urine by head-space gas chromatography

A rapid and simple assay procedure employing head-space gas chromatography has been developed for the routine quantification of volatile methylamines and stable trimethylamine N-oxide present in human urine. This assay will enable the rapid screening of patients and aid the diagnosis of fish odour syndrome.     

Testing the paradigm that the denaturing effect of urea on protein stability is offset by methylamines at the physiological concentration ratio of 2:1 (urea:methylamines)

The intra- and extracellular urea concentration in many organisms is sufficiently high to destabilize (inhibit) many proteins, yet organisms survive and function. The generally accepted explanation is the counteracting hypothesis, which holds that methylamines stabilize proteins and oppose the deleterious effect of urea. The two osmolytes are typically found at 2:1 concentration ratio (urea:methylamine) under physiological conditions. Does this mean that this ratio holds for all proteins in a cell? The present study tests the counteracting hypothesis by determining the effects of urea and methylamines (trimethylamine N-oxide and sarcosine), singly and in combination at a concentration ratio of 2:1 (urea:methylamine) on the thermal denaturation equilibrium, native state<-->denatured state of three different proteins (alpha-lactalbumin, lysozyme and Ribonuclease-A). We show here that the molar concentration of a methylamine required to offset the denaturing effect of urea at a given concentration is different for different proteins.     

Isolation and characterization of "Methanosphaera cuniculi" sp. nov

A nonmotile, gram-positive, spherical organism was isolated from the intestinal tracts of rabbits. Both hydrogen and methanol were required for growth. No methane was produced from hydrogen-carbon dioxide, formate, acetate, methylamines, ethanol, or isopropanol. The optimum pH was 6.8, and the optimum temperature was 35 to 40 degrees C. The DNA G+C content is 23 mol%. The pseudomurein cell wall contained serine. These characteristics and the immunological fingerprinting results are consistent with its placement in the genus Methanosphaera as a new species.     

Living with urea stress

Intracellular organic osmolytes are present in certain organisms adapted to harsh environments. These osmolytes protect intracellular macromolecules against denaturing environmental stress. In contrast to the usually benign effects of most organic osmolytes, the waste product urea is a well-known perturbant of macromolecules. Although urea is a perturbing solute which inhibits enzyme activity and stability, it is employed by some species as a major osmolyte. The answer to this paradox was believed to be the discovery of protective osmolytes (methylamines). We review the current state of knowledge on the various ways of counteracting the harmful effects of urea in nature and the mechanisms for this. This review ends with the mechanistic idea that cellular salt (KCl/NaCl) plays a crucial role in counteracting the effects of urea, either by inducing required chaperones or methylamines, or by thermodynamic interactions with urea-destabilised proteins. We also propose future opportunities and challenges in the field.     

Salt Potentiates Methylamine Counteraction System to Offset the Deleterious Effects of Urea on Protein Stability and Function

Cellular methylamines are osmolytes (low molecular weight organic compounds) believed to offset the urea’s harmful effects on the stability and function of proteins in mammalian kidney and marine invertebrates. Although urea and methylamines are found at 2:1 molar ratio in tissues, their opposing effects on protein structure and function have been questioned on several grounds including failure to counteraction or partial counteraction. Here we investigated the possible involvement of cellular salt, NaCl, in urea-methylamine counteraction on protein stability and function. We found that NaCl mediates methylamine counteracting system from no or partial counteraction to complete counteraction of urea’s effect on protein stability and function. These conclusions were drawn from the systematic thermodynamic stability and functional activity measurements of lysozyme and RNase-A. Our results revealed that salts might be involved in protein interaction with charged osmolytes and hence in the urea-methylamine counteraction.     

Moving known libraries to an addressable array: a site-selective hetero-Michael reaction

A two-step, Michael reaction-based strategy for site-selectively placing molecules by unique electrodes in an addressable microelectrode array has been developed. The strategy is compatible with the use of polypeptide nucleophiles and works with microelectrode arrays having either 1024 electrodes/cm (2) or 12,544 electrodes/cm (2). The chemistry should allow for the transfer of existing molecular libraries to microelectrode array devices for analysis.     

Oxidation of hydrogen and reduction of methanol to methane is the sole energy source for a methanogen isolated from human feces.

A methanogenic coccus isolated from human feces requires H2 and CH3OH for growth and uses H2 to reduce CH3OH to CH4. Growth does not occur with CH3OH alone. The organism does not grow or produce CH4 from acetate or methylamines without or with H2 or from H2 and CO2 or formate. In a complex medium. CO2 is required for formation of approximately 50% of cell carbon, whereas the methyl carbon from methanol is not incorporated into cell carbon.     

Sonochemically fabricated microelectrode arrays for biosensors--part II. Modification with a polysiloxane coating

A polymer-modified sonochemically fabricated glucose oxidase microelectrode array with microelectrode population densities of up to 2.5 x 10(5) microelectrodes per square centimetres is reported. These microelectrode sensors were formed by first depositing an insulating film on commercial screen printed electrodes which was subsequently sonicated to form cavities of regular sizes in the film. Electropolymerisation of aniline at the microelectrode cavities formed polyaniline protrusions containing entrapped glucose oxidase. Chemical deposition of polysiloxane from dichlorodimethysilane was used to deposit a thin protective and diffusion mass transport controlling coating over the electrodes. The physical and electrochemical properties of these films were studied. The performance of the final glucose oxidase based microelectrode sensor array is reported.     

Printed circuit microelectrodes and their application to honeybee brain.

The application of printed circuit technology to the production of a new type of multi-channel microelectrode is described. 2. Recordings have been obtained from the the protocerebrum of the honeybee Apis mellifera L. using printed circuit microelectrodes in both restrained and free-moving preparations. 3. These recordings are compared with those previously obtained from conventional probe microelectrodes and are found to have similar characteristics of transient voltage changes superimposed on an undifferentiated high frequency background. 4. A wide range of development possibilities for the printed circuit microelectrode are discussed.     

Demethylation of dimethylsulfoniopropionate to 3-mercaptopropionate by an aerobic marine bacterium.

A bacterium, strain BIS-6, that grew aerobically on dimethylsulfoniopropionate (DMSP) was isolated from an intertidal mud sample. Strain BIS-6 quantitatively demethylated DMSP and 3-methiolpropionate to 3-mercaptopropionate. Strain BIS-6 was a versatile methylotroph growing on the osmolytes DMSP and glycine betaine and their methylated degradation products (dimethyl glycine, sarcosine, methylamines, and dimethyl sulfide.     

Water Stress, Osmolytes and Proteins

Organic osmolytes are small solutes used by cells of numerouswater-stressed organisms and tissues to maintain cell volume.All known osmolytes are amino acids and derivatives, polyolsand sugars, methylamines, and urea; unlike salt ions, most are"compatible," i.e., do not perturb macromolecules. In addition,some stabilize macromolecules and are "counteracting" towardsperturbants, e.g., methylamines can stabilize proteins and ligandbinding against perturbations by urea in elasmobranchs and mammaliankidney, and (our latest findings) high hydrostatic pressurein deep-sea animals. Methylamines appear to coordinate watermolecules tightly, resulting in osmolyte exclusion from hydrationlayers of peptide backbones. This makes unfolded protein conformationsentropically unfavorable (work of Timasheff, Galinski, Bolenand coworkers). These properties have led to proposed uses inbiotechnology, agriculture and medicine, including improvedbiochemical methods, in vitro rescue of misfolded proteins incystic fibrosis and prion diseases (work of Welch and others),and plants engineered for drought and salt tolerance. Theseproperties also explain some but not all of the considerablevariation in osmolyte composition among species with differentmetabolisms and habitats, and among and within mammalian tissuesin development.     

Comparing cardiac action potentials recorded with metal and glass microelectrodes

Machine-pulled high-impedance glass capillary microelectrode is standard for transmembrane potential (TMP) recordings. However, it is fragile and difficult to impale, especially in beating myocardial tissues. We hypothesize that a high-impedance pure iridium metal electrode can be used as an alternative to the glass microelectrode for TMP recording. The TMPs were simultaneously recorded from isolated perfused swine right ventricles with a metal microelectrode and a standard glass microelectrode during pacing and during ventricular fibrillation. The basic morphology of TMP recorded with these electrodes was comparable. The action potential duration (APD) at 90% repolarization was 241 +/- 29 ms for the metal microelectrode and 236 +/- 31 ms for the glass microelectrode with a good correlation (r = 0.99, P < 0.0001). The maximum slope value of the APD restitution curves during pacing was also significantly correlated. One metal microelectrode and >20 glass microelectrodes were needed per study. We conclude that, in isolated perfused swine right ventricles, the TMP recorded by the metal microelectrode is comparable with that recorded by the glass microelectrode. Because the metal microelectrode is more durable than the glass microelectrode, it can serve as an alternative for APD recording and for restitution analyses.     

Diamond-like carbon (DLC) microelectrode for electrochemical ELISA

A diamond-like carbon (DLC) microelectrode was applied to commercial ELISA kits for medical diagnosis of HIV (human immunodeficiency virus), HBV (human hepatitis B virus), HCV (human hepatitis C virus). In this work, quantification of oxidized 3,3',5,5'-tetramethylbenzidine (TMB) was carried out by using a microelectrode made of boron-doped DLC and cyclic voltammetric analysis method without the conventional quenching step which uses sulfuric acid. The microelectrode provided well-known step-shaped graphs, and limit of detection could be improved by clear determination of electrochemical oxidative and reductive peaks. To demonstrate the applicability of DLC microelectrode to conventional ELISA kits, commercial ELISA kits for detection of HIV antigen, HBV antigen and HCV antigen were also tested. These results proved that the applicability of DLC microelectrode to practical detection is feasible.     

Distribution of cytochromes in methanogenic bacteria

Abstract Various methanogenic bacteria belonging to the orders Methanobacteriales, Methanococcales , and Methanomicrobiales were examined for the presence of cytochromes. Those methanogens which are capable of growing only on H ₂+ CO ₂ or formate were found to lack cytochromes. However, membrane-bound cytochromes were detected in species able to utilize methanol, methylamines or acetate.     

Stable membrane potentials and mechanical K+ responses activated by internal Ca2+ in HeLa cells

Stable membrane potentials have been measured with microelectrodes in HeLa cells and their average value (-38 mV) compares well with the Cl- electrochemical potential (-34 mV). A hyperpolarizing response is observed upon microelectrode penetrations and following a mechanical or electrical shock; this response is due to a large increase in the K+ permeability, which can also be triggered by Ca2+ injection or blocked by EGTA injection through the microelectrode. Stable hyperpolarizations are obtained with the Ca2+ ionophore A 23187.     

Measurement of Extracellular Ion Fluxes Using the Ion-selective Self-referencing Microelectrode Technique

Cells from animals, plants and single cells are enclosed by a barrier called the cell membrane that separates the cytoplasm from the outside. Cell layers such as epithelia also form a barrier that separates the inside from the outside or different compartments of multicellular organisms. A key feature of these barriers is the differential distribution of ions across cell membranes or cell layers. Two properties allow this distribution: 1) membranes and epithelia display selective permeability to specific ions; 2) ions are transported through pumps across cell membranes and cell layers. These properties play crucial roles in maintaining tissue physiology and act as signaling cues after damage, during repair, or under pathological condition. The ion-selective self-referencing microelectrode allows measurements of specific fluxes of ions such as calcium, potassium or sodium at single cell and tissue levels. The microelectrode contains an ionophore cocktail which is selectively permeable to a specific ion. The internal filling solution contains a set concentration of the ion of interest. The electric potential of the microelectrode is determined by the outside concentration of the ion. As the ion concentration varies, the potential of the microelectrode changes as a function of the log of the ion activity. When moved back and forth near a source or sink of the ion (i.e. in a concentration gradient due to ion flux) the microelectrode potential fluctuates at an amplitude proportional to the ion flux/gradient. The amplifier amplifies the microelectrode signal and the output is recorded on computer. The ion flux can then be calculated by Fick’s law of diffusion using the electrode potential fluctuation, the excursion of microelectrode, and other parameters such as the specific ion mobility. In this paper, we describe in detail the methodology to measure extracellular ion fluxes using the ion-selective self-referencing microelectrode and present some representative results.     

Methylamines and polyols in kidney, urinary bladder, urine, liver, brain, and plasma. An analysis using 1H nuclear magnetic resonance spectroscopy

Methylamines and polyols are known to behave as organic osmolytes in the adaptation of many cells to hyperosmolar conditions. Using 1H nuclear magnetic resonance spectroscopy to analyze perchloric acid extracts we have examined several tissues in the rat for the presence of these compounds. Methylamines such as glycerophosphorylcholine, choline and betaine were observed in the renal inner medulla, urinary bladder, urine, liver, brain, and plasma. Myoinositol was relatively abundant in the renal inner medulla and brain whereas sorbitol was detected only in the inner medulla. A variety of unidentified compounds was also detected in each tissue. Although these methylamines and polyols are known to respond to osmotic changes in the renal inner medulla, their responses in other tissues remain to be investigated.