1a.Objectives (from AD-416):
Purify and characterize pectin methylesterase isoforms from papaya. Use them to modify a model homogalacturonan, introducing demethylated block structure which will be characterized for average block size, number of blocks per molecule and their intermolecular distribution within the population of molecules. These data will be used to mathematically model enzyme mode of action. Introduced structural features will be correlated to measured functional properties for predictive modeling of food product quality.
1b.Approach (from AD-416):
Pectin methylesterases (PME) present in commercial papaya fruit (Carica papaya) extracts, used industrially in the formulation of food ingredients for their inherent PME activity, will be purified with a multi-dimensional strategy incorporating affinity chromatography. The hypothesis that these enzymes can be used to rationally design functional polysaccharide food ingredients will be tested. They will be characterized for biochemical, physical and kinetic properties, and their ability to manipulate pectin nano-structure. Mass spectrometry and N-terminal amino acid sequencing will be used to establish identity tags and relatedness of individual PME forms, establishing a basis for subsequent cloning. A recently defined model homogalacturonan will be demethylated with purified papaya PME(s) to pectins with predetermined degrees of methylation. Introduced demethylated block sequence will be characterized by limited digestion with endo polygalacturonase to release demethylated fragments. Released oligomers of galacturonic acid will be visualized and quantified using HPAEC coupled to an evaporative light scattering detector, allowing for the estimation of average demethylated block size and number per pectin molecule. Capillary electrophoresis will be used to probe the intermolecular distribution of introduced demethylated blocks. These data will be used to mathematically model the enzyme mode of action/degree of processivity. Modified homogalacturonans will be submitted to functional testing (rheology, calcium sensitivity and suspension properties) to enable comparison of nano-structure features to functional properties. The relationship between block size/number and influence of reaction conditions on enzyme mode of action and pectin functionality will allow for predictive modeling of food product quality related to the listed variables.
This project is related to Objective 4 of this in-house project: Develop value-added food materials from polysaccharide constituents of citrus byproduct waste streams.
All objectives of the planned research and travel have been accomplished. Pectin modifying esterases present in a commercial papaya extract have been purified and characterized. The commercial extract was used to modify pectin nanostructure. Introduced nanostructural modifications have been characterized and their affect on pectin functionality has been determined. Two manuscripts have been published and others are in preparation.