Your search keyword '"Charles L. Apel"' showing total 3 results

1. The Formation Of Glycerol Monodecanoate By A Dehydration Condensation Reaction: Increasing The Chemical Complexity Of Amphiphiles On The Early Earth

Author

David W. Deamer and Charles L. Apel

Subjects

Glycerol, Water activity, Origin of Life, Surface-Active Agents, Hydrolysis, chemistry.chemical_compound, Amphiphile, medicine, Organic chemistry, Dehydration, Ecology, Evolution, Behavior and Systematics, Evolution, Chemical, Chemistry, Decanoates, Temperature, Water, General Medicine, Decanoic acid, Condensation reaction, medicine.disease, Kinetics, Models, Chemical, Space and Planetary Science, Thermodynamics, Chromatography, Thin Layer, Wetting

Abstract

Dehydration/condensation reactions between organic molecules in the prebiotic environment increased the inventory and complexity of organic compounds available for self-assembly into primitive cellular organisms. As a model of such reactions and to demonstrate this principle, we have investigated the esterification reaction between glycerol and decanoic acid that forms glycerol monodecanoate (GMD). This amphiphile enhances robustness of self-assembled membranous structures of carboxylic acids to the potentially disruptive effects of pH, divalent cation binding and osmotic stress. Experimental variables included temperature, water activity and hydrolysis of the resulting ester product, providing insights into the environmental conditions that would favor the formation and stability of this more evolved amphiphile. At temperatures exceeding 50 degrees C, the ester product formed even in the presence of bulk water, suggesting that the reaction occurs at the liquid interface of the two reactants and that the products segregate in the two immiscible layers, thereby reducing hydrolytic back reactions. This implies that esterification reactions were likely to be common in the prebiotic environment as reactants underwent cycles of wetting and drying on rare early landmasses at elevated temperatures.

Published

2005

2. Influence of ionic inorganic solutes on self-assembly and polymerization processes related to early forms of life: implications for a prebiotic aqueous medium

Author

Pierre-Alain Monnard, David W. Deamer, Charles L. Apel, and Anastassia Kanavarioti

Subjects

Polymers, Iron, Inorganic chemistry, Origin of Life, Ionic bonding, Fatty Acids, Nonesterified, Chloride, Divalent, chemistry.chemical_compound, Chlorides, medicine, Magnesium, chemistry.chemical_classification, Aqueous solution, Sodium, Water, Membranes, Artificial, Agricultural and Biological Sciences (miscellaneous), Solutions, Monomer, Membrane, chemistry, Polymerization, Space and Planetary Science, Ionic strength, Inorganic Chemicals, Calcium, Salts, medicine.drug

Abstract

A commonly accepted view is that life began in a marine environment, which would imply the presence of inorganic ions such as Na+, Cl-, Mg2+, Ca2+, and Fe2+. We have investigated two processes relevant to the origin of life--membrane self-assembly and RNA polymerization--and established that both are adversely affected by ionic solute concentrations much lower than those of contemporary oceans. In particular, monocarboxylic acid vesicles, which are plausible models of primitive membrane systems, are completely disrupted by low concentrations of divalent cations, such as magnesium and calcium, and by high sodium chloride concentrations as well. Similarly, a nonenzymatic, nontemplated polymerization of activated RNA monomers in ice/eutectic phases (in a solution of low initial ionic strength) yields oligomers with80% of the original monomers incorporated, but polymerization in initially higher ionic strength aqueous solutions is markedly inhibited. These observations suggest that cellular life may not have begun in a marine environment because the abundance of ionic inorganic solutes would have significantly inhibited the chemical and physical processes that lead to self-assembly of more complex molecular systems.

Published

2002

3. Self-assembled vesicles of monocarboxylic acids and alcohols: conditions for stability and for the encapsulation of biopolymers

Author

Michael Mautner, David W. Deamer, and Charles L. Apel

Subjects

Lipid Bilayers, Nonanoic acid, Biophysics, Carboxylic Acids, Micelle, Biochemistry, Permeability, chemistry.chemical_compound, Biopolymers, Polymer chemistry, Organic chemistry, Microscopy, Phase-Contrast, Semipermeable membrane, Hydrogen peroxide, Micelles, Hydrogen bond, Vesicle, Fatty Acids, Hydrogen Bonding, Decanoic acid, Self-assembly, Cell Biology, DNA, Hydrogen-Ion Concentration, Catalase, Membrane, Lipid vesicle, chemistry, Spectrophotometry, Alcohols, Encapsulation, Caprylates

Abstract

We tested the ability of saturated n-monocarboxylic acids ranging from eight to 12 carbons in length to self-assemble into vesicles, and determined the minimal concentrations and chain lengths necessary to form stable bilayer membranes. Under defined conditions of pH and concentrations exceeding 150 mM, an unbranched monocarboxylic acid as short as eight carbons in length (n-octanoic acid) assembled into vesicular structures. Nonanoic acid (85 mM) formed stable vesicles at pH 7.0, the pK of the acid in bilayers, and was chosen for further testing. At pH 6 and below, the vesicles were unstable and the acid was present as droplets. At pH ranges of 8 and above clear solutions of micelles formed. However, addition of small amounts of an alcohol (nonanol) markedly stabilized the bilayers, and vesicles were present at significantly lower concentrations (approximately 20 mM) at pH ranges up to 11. The formation of vesicles near the pK(a) of the acids can be explained by the formation of stable RCOO(-)...HOOCR hydrogen bond networks in the presence of both ionized and neutral acid functions. Similarly, the effects of alcohols at high pH suggests the formation of stable RCOO(-)...HOR hydrogen bond networks when neutral RCOOH groups are absent. The vesicles provided a selective permeability barrier, as indicated by osmotic activity and ionic dye capture, and could encapsulate macromolecules such as DNA and a protein. When catalase was encapsulated in vesicles of decanoic acid and decanol, the enzyme was protected from degradation by protease, and could act as a catalyst for its substrate, hydrogen peroxide, which readily diffused across the membrane. We conclude that membranous vesicles produced by mixed short chain monocarboxylic acids and alcohols are useful models for testing the limits of stabilizing hydrophobic effects in membranes and for prebiotic membrane formation.

Published

2002