Osmosis, osmometry, and osmoregulation.

The maintenance of adequate body fluid volume and the correct distribution of this fluid between the body compartments is a critical part of homeostasis. The process of osmosis plays an important role in movement of fluid within the body and the use of osmometry is an important part of the management of many patients. In addition to the application of osmometry to the measurement of body fluids, most commonly plasma and urine, osmotic action plays a part in some therapeutic actions of drugs and its strength needs to be quantified in fluids administered to patients. Unfortunately confusion often exists in the various terms that are used in the field of osmometry. This review aims to explain the different terms used, the laboratory methodology involved in osmometry, and the clinical application and interpretation of the results obtained.

Non-uniform triple helical structure in chick skin type I collagen on thermal denaturation: Raman spectroscopic study.

The individual chains in the triple helix of collagen occur in a conformation related to polyproline II because of the presence of large number of imino peptide bonds. However, these residues are not evenly distributed in the collagen molecule which also contains many non-imino residues. These non-imino regions of collagen may be expected to show preference for other than triple helical conformations. The appearance of several Raman bands in solution phase at 65 degrees C raises the possibility of non-uniform triple helical structure in collagen. Raman spectroscopic studies on collagen in the solid state and in solution at a temperature greater than its denaturation temperature, reported here suggest that denatured collagen may exhibit an ensemble of conformational states with yet unknown implications to the biochemical interactions of this important protein component of connective tissues.

Studies of calmodulin structure: laser raman spectroscopy of biomolecules.

The structure of bovine brain calmodulin was probed by using laser Raman spectroscopy to elucidate cation-induced conformational changes in the protein. Local changes, most likely reflecting metal binding but not rearrangement of the peptide backbone, were observed in the presence of calcium or magnesium. A conformational change involving the peptide backbone and secondary structure content of calmodulin was observed only in the presence of calcium. The calcium-induced conformational change in the peptide backbone involves increased alpha helix and beta sheet. This was the only major calcium-specific change observed in the Raman spectrum, which suggests that the flexibility of the backbone conformation may play a critical role in the physiological activity of calmodulin.

Raman spectroscopic study of the interaction between sulfate anion and an imidazolium ring in ribonuclease A.

Raman spectra of ribonuclease A in D2O solution at various pD values have been studied with special attention to the N-deuterated imidazolium ring vibration at 1408 cm-1, the SO4(2-) symmetric stretching vibration at 984 cm-1, the amide I' band, and the tyrosine doublet. Concomitant decrease and increase in the intensities of the 1408- and 984-cm-1 bands in the pD range between 5 and 7 indicate that a sulfate anion is actually hydrogen bonded to an imidazolium ring of a histidine residue located in the interior of the molecule. The mechanism of the sulfate desorption has been compared with that on heat denaturation.

The high salt form of poly(dG-dC).poly(dG-dC) is left-handed Z-DNA: Raman spectra of crystals and solutions.

The laser-Raman spectra of crystalline d(CpGpCpGpCpG) and of aqueous poly(dG-dC).poly(dG-dC) in high salt (4M NaCl) and low salt (0.1M NaCl) solutions have been measured and compared. The spectra of the crystal and the high-salt solution show a striking congruence, which indicates clearly that the high-salt form of the aqueous polymer has the left-handed Z-DNA structure of the crystalline oligomer. These two spectra differ substantially from that of the low-salt form of the polymer, which has been found previously to have spectral characteristics of the B-form of DNA. The high salt spectrum shows a unique line due to guanine residues at 625 cm-1 which should be useful for qualitative and possibly quantitative assessment of the amount of Z-structure present in a sample of DNA.

Circular dichroism, Raman spectroscopy, and gel filtration of trapped folding intermediates of ribonuclease.

The intermediates of ribonuclease with one to four disulfide bonds trapped during refolding of the reduced protein have been compared to the fully reduced and native forms of the protein by gel filtration, circular dichroism, and Raman spectroscopy. Correctly refolded ribonuclease is indistinguishable from native protein, while a three-disulfide intermediate has a compact conformation which is very similar, but not identical. In contrast, all other intermediates with one to four disulfide bonds are qualitatively similar to fully reduced ribonuclease by their circular dichroism and Raman spectra, although the disulfide cross-links affect the dimensions of the polypeptide chain. The apparent absence of stable partially ordered structures in the initial disulfide intermediates implies that during refolding there are relatively few constraints on formation on disulfide bonds, although their formation is probably not entirely random. The stable conformation appears during refolding only when the three or four disulfide bonds capable of stabilizing a native-like conformation of the entire polypeptide chain occur simultaneously.

Raman spectra of ten aqueous transfer RNAs and 5S RNA. Conformational comparison with yeast phenylalanine transfer RNA.

Eleven native transfer RNAs have been prepared so as to maintain their Mg2+ content. Their aqueous Raman spectra show a high, relatively constant amount of order in the ribophosphate backbone, as indicated by the ratio 1.73 +/- 0.05 for I814/I1100 in all samples. Variation in the effectiveness of stacking of guanine and adenine bases is seen, though most of the transfer RNAs studied have a comparable degree of stacking to that found in phenylalanine transfer RNA from yeast, whose tertiary structure has been determined by X-ray crystallography. The spectrum of Escherichia coli 5S RNA indicates that the stacking efficiency of the guanine bases is much higher in 5S RNA than in yeast in phenylalanine transfer RNA, while that of the adenine bases is lower.

Laser Raman spectroscopic studies of the thermal unfolding of ribonuclease A.

The reversible thermal denaturation of bovine pancreatic ribonuclease A at pH 5 in 0.1 M NaCl over the range 32-70 degrees C as studied by Raman spectroscopy proceeds in a gradual manner consistent with a stepwise unfolding process rather than as a transition between two states. Conversion of residues from helical or pleated-sheet geometry to some intermediate geometry, as followed by means of the amide I and III lines, reveals that substantial amounts of the helical and pleated-sheet conformations remain at 70 degrees C. Changes in the strength of hydrogen bonding by the tyrosyl residues are indicated by the intensity ratio of the doublet at 830-850 cm(-1) and changes in the geometry of the disulfide bridges by the frequency and half-width of the Raman line near 510 cm(-1) due to the S-S vibration. Vibrations of C-S bonds in the methionines and cystines are used to monitor conformational changes in these residues. While there are small quantitative differences in temperature dependence among these probes, all agree in placing the malting temperature at or near 62 degrees C. The Raman data are quantitatively consistent with the six-stage scheme of unfolding of A.W. Burgess and H.A. Scheraga [(1975), J. Theor, Biol. 53, 403], except that no change in the environment of the tyrosines is seen until 45 degrees C.

Interpretation of the doublet at 850 and 830 cm-1 in the Raman spectra of tyrosyl residues in proteins and certain model compounds.

The doublet at 850 and 830 cm-1 in the Raman spectra of proteins containing tyrosyl residues has been examined as to its origin and the relation of its components to the environment of the phenyl ring, the state of the phenolic hydroxyl group, and the conformation of the amino acid backbone. Raman spectral studies on numerous model molecules related to tyrosine, including certain deuterium derivatives, show that the doublet is due to Fermi resonance between the ring-breathing vibration and the overtone of an out-of-plane ring-bending vibration of the para-substituted benzenes. Further examination of the effects of pH and solvents on the Fermi doublet and of the crystallographic data demonstrates that the intensity ratio of the two components depends on changes in the relative frequencies of the two vibrations. These in turn are found to be sensitive to the nature of the hydrogen bonding of the phenolic hydroxyl group of its ionization, but much less so to the environment of the phenyl ring and the conformation of the amino acid backbone. By use of the relative intensities of the doublet in model systems where the phenolic hydroxyl group is strongly hydrogen-bonded, weakly hydrogen-bonded, free or ionized, the reported Raman intensities of the doublets observed in the Raman spectra of several proteins have been interpreted. The results are compared with those obtained by other techniques.

Raman spectra and structure of yeast phenylalanine transfer RNA in the crystalline state and in solution.

Laser Raman spectra of yeast phenylalanine transfer RNA have been obtained in solution and in orthorhombic and hexagonal crystals. So far as one can tell from the spectra, which are identical in the two crystal forms, the molecular structure of the tRNA is not altered by differences in molecular packing in these two unit cells. In addition, the spectra of the two crystal forms show the same characteristic Raman frequencies and intensities as those of the tRNA in aqueous solution. Thus the structure of the tRNA molecule appears to be the same in the crystals and in aqueous solution. From the spectroscopic changes that result when Mg2+ ions are removed from the native tRNA, it is concluded that the removal of Mg2+ produces a partial disordering of the ribophosphate backbone of the molecule and a lowering of its melting temperature. The melting is shown to be a complex process in that the vibrations specific for adenine indicate a slightly lower melting temperature and those specific for guanine a slightly higher melting temperature than that of the ribophosphate backbone.