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Production and biochemical and biophysical characterization of fibrinolytic protease of a Mucor subtilissimus strain isolated from the caatinga biome.

Amanda Emmanuelle S ConniffThiago Pajeú NascimentoRomero Marcos Pedrosa Brandão CostaLeonid BreydoCamila Souza PortoAttilio ConvertiJoyce G W SiqueiraJosé António TeixeiraGalba Maria de Campos TakakiVladimir N UverskyAna Lucia Figueiredo PortoTatiana Souza Porto
Published in: Anais da Academia Brasileira de Ciencias (2024)
Cardiovascular diseases, resulting from the deposition of clots in blood vessels, are the leading cause of death worldwide. Fibrinolytic enzymatic activity can catalyze blood clot degradation. Findings show that 36 fungal isolates recovered from Caatinga soils have the potential to produce fibrinolytic protease under submerged conditions. About 58 % of the isolates displayed fibrinolytic activity above 100 U/mL, with Mucor subtilissimus UCP 1262 being the most active. The protease was biochemically and biophysically characterized, showing that the enzyme had a high affinity for SAApNA substrate and was significantly inhibited by fluoride methyl phenyl sulfonyl-C7H7FO2S, suggesting that it is a chymotrypsin-like serine protease. The highest enzyme activity was detected at pH 5.0 and 28 °C. This fibrinolytic protease's far-UV circular dichroism (CD) showed that its secondary structure was primarily α-helical. The purified fibrinolytic enzyme may represent a novel therapeutic agent for treating thrombosis. At temperatures above 65 °C, the enzyme lost all its secondary structure. Its melting temperature was 58.1 °C, the denaturation enthalpy 85.1 kcal/mol, and the denaturation entropy 0.26 kcal/K∙mol.
Keyphrases
  • cardiovascular disease
  • high resolution
  • human health
  • type diabetes
  • hydrogen peroxide
  • risk assessment
  • drinking water
  • mass spectrometry