Studies of the structure-function correlation of the chlorocatechol 1,2-dioxygenase enzyme from Pseudomonas putida

The intensive use of organic compounds in conjunction with the industrial advances led to a huge accumulation of organic pollutants in the environment. Among these pollutants it has been noticed the presence of aromatic hydrocarbons that are highly toxic and resistant to physical, chemical and biological degradation. Thus, a new way to deal with the presence of this compounds in the environment has been studied: the use of microorganisms, natural or genetically modified, that can turn them into inert substances such as CO2 and water. This methodology is called bioremediation. Among those microorganisms, bacteria from the gender Pseudomonas, Aeromonas, Beijerinckia, among others, have been studied for this purpose. The enzyme chlorocatechol 1,2-dioxygenase (Pp 1,2-CCD) is one of the proteins expressed by Pseudomonas putida bacteria, being responsible for the cleavage of aromatic hydrocarbons through the incorporation of both atoms of a molecule of oxygen into the aromatic ring structure, being the protein chosen for investigation in this work. More specifically, we are interested in studying how the mechanism of action of this enzyme is controlled by extrinsic molecules such as phospholipids. The interest in the interaction between the enzyme and phospholipids arose recently when the first crystal structure of an enzyme of the intradiol dioxygenase family was reported. In this structure it was observed a binding site for a phospholipid per monomer, which raised many issues concerning its influence on the activity of the enzyme. Our goal was to use the techniques of Circular Dichroism (CD), calorimetry and Electron Magnetic Resonance (EMR) to study enzyme conformational changes and kinetics alterations induced by phospholipid molecules, thus gathering information on the structure-function correlation. The results obtained through those experimental techniques in conjunction with the use of protocols for protein delipidation showed that the presence of phospholipids/fatty acids in the structure of the enzyme play a role in enzyme activity. Upon removal of the phospholipid/fatty acids, we observed small changes in the secondary structure of the enzyme, an increase of the enthalpy of reactions as well as an increase in the reaction rate, whereas the affinity of the enzyme for the substrate decreased. We also observed a higher thermal stability of the Pp 1,2-CCD in the absence of the phospholipids/fatty acids, but no interaction was observed between the Pp 1,2-CCD and lysophospholipid micelles. A brief study of the function of ionic strength on the activity and thermal stability of the protein showed that in the absence of NaCl, at pH 8, the enzyme is more active, showing a greater affinity for the substrate and a low interaction was observed between Pp 1,2-CCD and negatively charged micelles. This information along with the data on the inhibition capacity of the reaction product are a new set of data that can be used to achieve the more general goal of controlling Pp 1,2-CCD biological activity. (AU)