The significance of the aprotic solvent in monomer studies related to the primary subunit environment in the macromolecule

An advantage of aprotic polar solvent systems in the study of monomer interactions relevant to the macromolecular state is demonstrated with the measurement of nucleoside amino proton exchange rates in DMSO/water mixtures. The DMSO/water solvent provides the first unequivocal observation of general acid catalysis of nucleic acid amino proton exchange, which is undetectable in aqueous solution due to the formation of the endocyclic protonated nucleobase. Suppression of nucleobase protonation in the presence of buffer acid is a consequence of anion desolvation in the aprotic solvent. The detected route of general acid catalysis is demonstrated as a consequence of Watson-Crick H-bonding, leading to the implication that amino chemistry is modulated in the helical state to decrease amino proton lifetime in the closed macromolecular context of conformational information obtained by hydrogen exchange methods. This useful property of the aprotic solvent can be extended to monomeric studies pertaining to specific local site interactions affecting the function and conformation of proteins and nucleic acids.     

The possession of coli surface antigen CS6 by enterotoxigenicEscherichia coli of serogroups O25, O27, O148, and O159: a possible colonization factor?

A total of 134 enterotoxigenicEscherichia coli (ETEC) of serogroups O25, O27, O148, and O159 were tested in the enzyme-linked immunosorbent assays for the colonization factor antigens I (CFA/I), CFA/II (coli surface antigens CS1, 2 and 3) and putative colonization factor (PCF) 8775 (CS4, 5 and 6). CS6 was detected without CS4 or CS5 in 94% of the strains of serogroup O25, 86% of strains of serogroup O27, 87% of strains of serogroup O148, and 29% of strains of serogroup, O159. The frequency with which CS6 occurs in ETEC of common serotypes without the antigens CS4 or CS5 suggests that it might be a colonization factor.     

General acid-base catalysis in nucleobase amino proton exchange: cytidine

A useful property of DMSO solvent has been exploited to reveal a new catalytic route for cytidine amino proton exchange, relevant to exchange in the macromolecular state, but hidden in aqueous solution. Additional exchange mechanisms in aqueous monomeric cytidine (and adenosine) are obscured by the formation of a fast-exchanging endocyclic-protonated intermediate, which dominates the kinetics. Endocyclic nucleobase protonation could be circumvented in the presence of buffer conjugate acid by the use of DMSO/water solvent, permitting the first unequivocal observation buffer acid-catalyzed exchange from the neutral, unprotonated nucleobase, i.e., general acid catalysis. Because buffer ionization is greatly reduced in DMSO through anion desolvation, nucleobase protonation is suppressed in the presence of buffer acid. Evidence is presented to describe this catalytic route as one involving hydrogen bond formation between the buffer acid and the endocyclic protonation site, C(N-3). Since this same configuration is found in Watson-Crick hydrogen bonding, experiments are presented to demonstrate faster cytidine amino proton exchange with the formation of the G-C base pair in DMSO. The importance of this mechanism in past aqueous monomer studies and in the interpretation of macromolecular (DNA) hydrogen exchange is discussed.     

Exceptional characteristics of amino proton exchange in guanosine compounds

Amino 1H NMR line width as a measure of amino proton exchange in guanosine compounds is completely unaffected by the addition of ca. 1 M tris(hydroxymethyl)-aminomethane, imidazole, 2-(N-morpholino)ethanesulfonic acid, glycine, or cacodylate, all shown to be effective buffer catalysts in adenosine and cytidine proton exchange. Line broadening, seen only with phosphate and acetate, is established by intermolecular interactions, as well as by amino to water proton exchange. This absence of buffer catalysis of exchange is accounted for by the relatively small implied effect of G(N-7) protonation on amino acidity, based on similar observations with 7-methylguanosine as a model for endocyclic protonation. The requirement for diffusion-controlled proton transfer in buffer catalysis is achieved by nucleobase protonation in adenine and cytosine, but not in guanine.     

ARAGONITE IN HALIMED A AND TYDEMANIA (ORDER SIPHON ALES)12

The mineral component of the marine green algal genus Halimeda is the orthorhombic calcium carbonate (aragonite); its presence appears to be a generic characteristic. Tydemania expeditionis also precipitates aragonite in contradistinction to species of the red alga Corallina wliich precipitate calcium carbonate of the hexagonal form (calcite). The analyses are based on x-ray diffraction methods. Although other inorganic substances arc present, the amounts are minor and probably represent contaminants. Specimens that are to be studied for mineral components should not be stored in formalin.