RESUMEN
Pectinase has been an integral part of commercial food processing, where it is used for degradation of pectin and facilitates different processing steps such as liquefaction, clarification and juice extraction. The industry currently uses pectinases from mesophilic or thermophilic microorganisms which are well established, but recently, there has been is a new trend in the food industry to adopt low-temperature processing. This trend is due to the potential economic and environmental advantages which the industry envisages. In order to achieve this change, an alternative for the existing pectinases, which are mostly mesophilic and temperature-dependent, must be identified, which can function efficiently at low temperatures. Psychrophilic pectinases derived from cold-adapted microorganisms, are known to function at low to freezing temperatures and may be an alternative to address the problem. Psychrophilic pectinases can be obtained from the vast microflora inhabiting various cold regions on earth such as oceans, Polar Regions, snow-covered mountains, and glaciers. This article is intended to study the advantages of cold active pectinases, its sources, and the current state of the research.
Asunto(s)
Manipulación de Alimentos/métodos , Pectinas/química , Poligalacturonasa/química , Aspergillus niger/química , Aspergillus niger/enzimología , Bacillus subtilis/química , Bacillus subtilis/enzimología , Secuencia de Carbohidratos , Clima Frío , Frío , Erwinia/química , Erwinia/enzimología , Humanos , Cubierta de Hielo/microbiología , Isoenzimas/química , Isoenzimas/clasificación , Isoenzimas/metabolismo , Cinética , Modelos Moleculares , Datos de Secuencia Molecular , Poligalacturonasa/clasificación , Poligalacturonasa/metabolismoRESUMEN
BACKGROUND: Determination of the allergen composition of an extract is essential for the improvement of hyposensitization therapy. Surprisingly, although grass pollen extracts have been studied intensively for 20 years, a further major allergen, Phl p 13, was detected recently in timothy grass pollen. OBJECTIVES: We sought to determine the occurrence and importance of group 13 allergens in various grass species and to investigate their proteolytic stability. METHODS: The group 13 allergens were determined by means of 2-dimensional PAGE blotting with patient sera and group 13-specific mAbs. The allergens were isolated chromatographically from several pollen extracts and analyzed by means of microsequencing. Cross-reactivity among various grass species was studied by using Western blots and immunoblot inhibition tests. The stability of the allergens was tested under defined extraction conditions. RESULTS: Group 13 allergens are detectable in all common grasses and show IgE cross-reactivity among them. The allergenic components were identified in the neutral pH range with molecular masses of 50 to 60 kd, and in the case of Phl p 13, maximal binding of the isoforms was observed at 55 kd and at an isoelectric point of 6 to 7.5. Protein sequencing clearly confirms structural identities between different grass species, although individual variations are found. If low-molecular-mass components were depleted by means of gel filtration, a rapid degradation of group 13 allergens was observed. This is in contrast to other pollen allergens described thus far. CONCLUSION: Group 13 allergens are widespread and are major allergens in the grasses. Predicted from their primary structures, these allergens are polygalacturonases. This class of enzymes is already known from microorganisms, and these enzymes are recognized as potential inducers of asthma. Our studies indicate that the group 13 allergens show a considerable microheterogeneity and degradation, especially after depletion of low-molecular-mass components. One has to be aware of this pivotal fact when soluble grass pollen extracts are prepared for diagnostics and hyposensitization therapy.