Effect of redox potential on activity of hydrogenase 1 and hydrogenase 2 in Escherichia coli.

This report elucidates the distinctions of redox properties between two uptake hydrogenases in Escherichia coli. Hydrogen uptake in the presence of mediators with different redox potential was studied in cell-free extracts of E. coli mutants HDK103 and HDK203 synthesizing hydrogenase 2 or hydrogenase 1, respectively. Both hydrogenases mediated H(2) uptake in the presence of high-potential acceptors (ferricyanide and phenazine methosulfate). H(2) uptake in the presence of low-potential acceptors (methyl and benzyl viologen) was mediated mainly by hydrogenase 2. To explore the dependence of hydrogen consumption on redox potential of media in cell-free extracts, a chamber with hydrogen and redox ( E(h)) electrodes was used. The mutants HDK103 and HDK203 exhibited significant distinctions in their redox behavior. During the redox titration, maximal hydrogenase 2 activity was observed at the E(h) below -80 mV. Hydrogenase 1 had maximum activity in the E(h) range from +30 mV to +110 mV. Unlike hydrogenase 2, the activated hydrogenase 1 retained activity after a fast shift of redox potential up to +500 mV by ferricyanide titration and was more tolerant to O(2). Thus, two hydrogenases in E. coli are complementary in their redox properties, hydrogenase 1 functioning at higher redox potentials and/or at higher O(2) concentrations than hydrogenase 2.

Binding of alpha2-macroglobulin to collagen type I: modification of collagen matrix by alpha2-macroglobulin induces the enhancement of macrophage migration.

Alpha2-macroglobulin (a2M) secreted by tissue macrophages and fibroblasts functions in the environment of extracellular matrix macromolecules. We supposed that it may interact with these molecules and change the properties of extracellular matrix. Modified variant of ELISA was used to prove the direct binding of human a2M to collagen. Native and transformed by plasmin a2M, as well as plasmin, used as the control, were labeled by biotin. It has been found that the transformed, but not the native a2M form binds to type I collagen molecules: K(d)=(1.168 +/- 1.14) x 10(-11) M. The data obtained give a strong evidence of high power of the interaction between a2M and type I collagen: practically no reverse dissociation may be seen for such a binding. The modification of three-dimensional collagen matrix by binding to the transformed a2M resulted in the enhancement of migration of macrophages, carrying the receptors for a2M, but not splenocytes that lack for such receptors. Our results allow to suggest that a2M may be one of the components of extracellular matrix, and may change the properties of microenvironment for immunocompetent cells during the processes of inflammation, reparation and tumor invasion.