Tartrate-resistant acid phosphatase (TRAP) is highly expressed in bone-resorbing osteoclasts and activated macrophages. It has been suggested that a redox-active iron in the binuclear iron center of TRAP could have the capacity to react with hydrogen peroxide to produce highly destructive reactive oxygen species (ROS). Here we show that TRAP can generate ROS in vitro and that cells over-expressing TRAP produce higher amounts of intracellular ROS than their parent cells. We further demonstrate that these ROS can be targeted to destroy collagen and other proteins. In resorbing osteoclasts, TRAP was found in transcytotic vesicles transporting matrix degradation products through the cell, suggesting that TRAP-facilitated fragmentation of endocytosed material takes place in a specific cellular compartment. These results suggest that bone matrix degradation occurs not only extracellularly in the resorption lacunae but also intracellularly in the transcytotic vesicles. We propose that proteins containing redox-active iron could represent a novel mechanism of physiological fragmentation of organic molecules. This mechanism could be important in tissue remodeling and as a defense mechanism of phagocytosing cells.
Abstract TRACP is an enzyme with unknown biological function. It is expressed primarily in bone-resorbing osteoclasts and activated macrophages. In addition to its phosphatase activity, TRACP is capable of generating reactive oxygen species (ROS). In resorbing osteoclasts, TRACP is localized in transcytotic vesicles transporting bone matrix degradation products from the resorption lacuna to a functional secretory domain in the basolateral membrane. ROS generated by TRACP are capable of destroying organic bone matrix components, suggesting that they may be targeted to further destroy initial matrix degradation products in the transcytotic vesicles. The transcytotic route of osteoclasts is analogous with the antigen presentation route of macrophages transporting endocytosed foreign material into cell surface for presentation to other cells of the immune system. Macrophages overexpressing TRACP have elevated levels of intracellular ROS. In alveolar macrophages, TRACP is colocalized with endocytosed Staphylococcus aureus, a pathogen whose clearance is reduced in TRACP-deficient mice, suggesting that ROS generated by TRACP may be targeted to destroy foreign material in the antigen presentation route of macrophages. These data suggest that the ROS generating activity of TRACP may have an important role both in bone resorption and in the immune defense system.
Prolyl 4-hydroxylase (EC 1.14.11.2) catalyses the formation of 4-hydroxyproline in collagens. The vertebrate enzymes are α2β2 tetramers while the Caenorhabditis elegans enzyme is an αβ dimer. The β-subunit is identical to protein disulphide isomerase (PDI), a multifunctional endoplasmic reticulum luminal polypeptide. ERp60 is a PDI isoform that was initially misidentified as a phosphatidylinositol-specific phospholipase C. We report here on the cloning and expression of the human and Drosophila ERp60 polypeptides. The overall amino acid sequence identity and similarity between the processed human ERp60 and PDI polypeptides are 29% and 56% respectively, and those between the Drosophila ERp60 and human PDI polypeptides 29% and 55%. The two ERp60 polypeptides were found to be similar to human PDI within almost all their domains, the only exception being the extreme C-terminal region. Nevertheless, when the human or Drosophila ERp60 was expressed in insect cells together with an α-subunit of human prolyl 4-hydroxylase, no tetramer was formed and no prolyl 4-hydroxylase activity was generated in the cells. Additional experiments with hybrid polypeptides in which the C-terminal regions had been exchanged between the human ERp60 and PDI polypeptides demonstrated that the differences in the C-terminal region are not the only reason for the lack of prolyl 4-hydroxylase tetramer formation by ERp60.
Carbonic anhydrase III (CA III; EC 4.2.1.1) is a cytoplasmic enzyme that exhibits a relatively low carbon dioxide hydratase activity. It is expressed at a very high level in skeletal muscle, where physical exercise has been shown to increase free radical production. In this work we show the effect of overexpression of CA III on cellular response to oxidative stress. Rat CA III cDNA was transfected to NIH/3T3 cells, which have no endogenous CA III expression. The isolated clones expressed CA III mRNA and protein. The protein was localized to cytoplasm and nuclei. Compared to parental cells, transfected cells showed lower basal oxidized state as judged by measurement of intracellular reactive oxygen species (ROS) using fluorescent dye and an image analysis system. Addition of exogenous H2O2 to cells induced a rapid increase of ROS in control but not in CA III overexpressing cells. Association of this phenomenon with CA III expression was further confirmed by showing that overexpression of CA II could not prevent H2O2-stimulated increase of ROS. In proliferation assays, CA III overexpressing cells grew faster and were more resistant to cytotoxic concentrations of H2O2 than control cells. After a 16 h exposure to oxidative stress, the number of apoptotic cells was also reduced in transfectants. Our results suggest that CA III functions as an oxyradical scavenger and thus protects cells from oxidative damage. A lower level of free radicals in CA III overexpressing cells may also affect growth signaling pathways.—Räisänen, S. R., Lehenkari, P., Tasanen, M., Rahkila, P., Härkönen, P. L., Väänänen, H. K. Carbonic anhydrase III protects cells from hydrogen peroxide-induced apoptosis. FASEB J. 13, 513–522 (1999)
