RESUMO
Many types of shellfish, including shrimp, are sometimes cooked before ingestion. Hence, it is necessary to investigate how cooking (boiling, pressure treatment or none (raw)) affects the structure, digestibility and immunoreactivity of multi-component shrimp muscle. Protein extraction, simulated gastrointestinal digestion, immunoreactivity, immunoglobulin E (IgE)-mediated human mast cell degranulation, morphology, particle size and UV absorbance scanning were used to investigate changes in the shrimp muscle upon treatment. The extractability of proteins and allergens was highest with 0.5 mol L-1 NaCl. Pressure treatment increased the digestibility and reduced the immunoreactivity of shrimp edible portions. Thermal processing induced the production of regular fiber bundles, blue shifts of absorbance peaks and reduction of particle size in the complex food matrix. These changes in macro- and micro-structure can further affect gastrointestinal digestibility and immunoreactivity due to the interactions between multiple components in the whole food. In conclusion, the digestibility, immunoreactivity and structure were altered by thermal processing of the complex food matrix.
Assuntos
Culinária/métodos , Penaeidae/química , Penaeidae/imunologia , Hipersensibilidade a Frutos do Mar/imunologia , Frutos do Mar/análise , Animais , Digestão , Temperatura Alta , Humanos , Imunoglobulina E/imunologia , Mastócitos/imunologia , Penaeidae/metabolismo , Hipersensibilidade a Frutos do Mar/metabolismoRESUMO
To what extent do structural and biophysical features of food allergen proteins distinguish them from other proteins in our diet? Invertebrate tropomyosins (Tpms) as a class are considered "pan-allergens," inducing food allergy to shellfish and respiratory allergy to dust mites. Vertebrate Tpms are not known to elicit allergy or cross-reactivity, despite their high structural similarity and sequence identity to invertebrate homologs. We expect allergens are sufficiently stable against gastrointestinal proteases to survive for immune sensitization in the intestines, and that proteolytic stability will correlate with thermodynamic stability. Thermal denaturation of shrimp Tpm shows that it is more stable than non-allergen vertebrate Tpm. Shrimp Tpm is also more resistant to digestion. Molecular dynamics uncover local dynamics that select epitopes and global differences in flexibility between shrimp and pig Tpm that discriminate allergens from non-allergens. Molecular determinants of allergenicity depend not only on sequence but on contributions of protein structure and dynamics.