Increased TIMP-3 expression alters the cellular secretome through dual inhibition of the metalloprotease ADAM10 and ligand-binding of the LRP-1 receptor

The tissue inhibitor of metalloproteinases-3 (TIMP-3) is a major regulator of extracellular matrix turnover and protein shedding by inhibiting different classes of metalloproteinases, including disintegrin metalloproteinases (ADAMs). Tissue bioavailability of TIMP-3 is regulated by the endocytic receptor low-density-lipoprotein receptor-related protein-1 (LRP-1). TIMP-3 plays protective roles in disease. Thus, different approaches have been developed aiming to increase TIMP-3 bioavailability, yet overall effects of increased TIMP-3 in vivo have not been investigated. Herein, by using unbiased mass-spectrometry we demonstrate that TIMP-3-overexpression in HEK293 cells has a dual effect on shedding of transmembrane proteins and turnover of soluble proteins. Several membrane proteins showing reduced shedding are known as ADAM10 substrates, suggesting that exogenous TIMP-3 preferentially inhibits ADAM10 in HEK293 cells. Additionally identified shed membrane proteins may be novel ADAM10 substrate candidates. TIMP-3-overexpression also increased extracellular levels of several soluble proteins, including TIMP-1, MIF and SPARC. Levels of these proteins similarly increased upon LRP-1 inactivation, suggesting that TIMP-3 increases soluble protein levels by competing for their binding to LRP-1 and their subsequent internalization. In conclusion, our study reveals that increased levels of TIMP-3 induce substantial modifications in the cellular secretome and that TIMP-3-based therapies may potentially provoke undesired, dysregulated functions of ADAM10 and LRP-1

[15] Synthesis of atp from Ca2+ gradient by sarcoplasmic reticulum Ca2+ transport ATPase

This chapter focuses on the synthesis of ATP from Ca2+ gradient by sarcoplasmic reticulum Ca2+ transport ATPase. Sarcoplasmic reticulum vesicles isolated from rabbit skeletal muscle consist of tightly sealed membranes, which only allow a slow passive back-diffusion of Ca2+ taken up previously by a pathway not yet identified. The driving force for ATP formation is the Ca2+ gradient existing between the vesicular volume and the external medium. Conditions are chosen in such a way that nearly all Ca2+ that was released could contribute to ATP synthesis. Loading of the vesicles is usually performed in the presence of acetyl phosphate (AcP) as energy-yielding substrate, and inorganic phosphate (Pi) serving as precipitating anion and substrate for the backward reaction. Ca2+ loads obtained by slow passive diffusion of millimolar concentrations (<100 nmol/mg protein) or by active transport in the absence of a precipitating anion (100–200 nmol/mg protein) set limits to the duration of the two fast-occurring processes, and to the accuracy of the results obtained

The dependence on internal pH of Ca2+ ‐fluxes across sarcoplasmic reticulum vesicular membranes

The interdependence of the competition between Ca2+ and hydrogen ions for the internally located low‐affinity Ca2+ binding sites of sarcoplasmic reticulum vesicles and the pH‐dependent splitting rate of phosphoenzyme was investigated. Sarcoplasmic reticulum vesicles were preincubated at a selected pH and passive Ca2+ loading, active Ca2+ uptake at the same pH as well as active Ca2+ uptake at a distinct pH (pH‐jump method) were observed. In addition, Cai‐Cao exchange in the absence and presence of ADP and ATP‐ADP exchange were measured. The overall ATP splitting rate was assayed with leaky vesicles in the presence of varied Ca2+ concentration and four different pH. All experiments were carried out at Ca2+ concentrations sufficient to saturate the externally located activating high‐affinity binding sites at all pH and in the absence of affecting concentrations of monovalent cations. Active Ca2+ transport (particularly evident applying the pH‐jump method) is facilitated at low intravesicular pH, reflecting the favoured Ca2+ release to the intravesicular space, in contrast to the reverse pH‐dependence of passive Ca2+ accumulation and the initial rate of Cai‐Cao exchange, both favoured by elevated internal Ca2+ binding capacity. The rates of ATP splitting, the continuing slow rate of Cai‐Cao exchange, and the ATP‐ADP exchange are optimal at an intermediate proton concentration, reflecting the influence of protons on partial reaction steps occurring later in the reaction cycle and the accelerated exchange of Ca2+ at the internal low‐affinity sites as well as the establishment of a new pseudo equilibrium between the possible reaction intermediates. The pool of rapidly exchangeable Ca2+ is enlarged whereas the rate of slow exchange is unaltered or diminished (pH 7.8) by ADP

Effect of non-solubilizing SDS concentrations on high affinity Ca2+ binding and steady state phosphorylation by inorganic phosphate of the sarcoplasmic reticulum ATPase

In this investigation low, non-solubilizing concentrations of the strong anionic detergent SDS were used to perturbate the interaction of Ca2+ and P, with their respective binding domains on the sarcoplasmic reticulum Ca-transport ATPase. Rising SDS concentrations produce a two-step decline of Ca2+-dependent ATP hydrolysis. At pH 6.15, SDS differently affects high affinity Ca2+ binding and phosphorylation by inorganic phosphate and releases the “mutual exclusion” of these two ligand binding steps. The degree of uncoupling is considerably more pronounced in the presence of 20% Me2SO.The reduction of Ca2+ binding by SDS is demonstrated to be a result of decreased affinity of one of the two specific high affinity binding sites and of perturbation of their cooperative interaction. Higher SDS partially restores the original high Ca2f affinity but not the cooperativity of binding. Phosphorylation exhibits a higher SDS sensitivity than Ca2+ binding: Increasing SDS competitively inhibits and then completely abolishes phosphoenzyme formation. Thus. SDS binds to the phosphorylation domain, evidently involving the Lys352 residue of the ATPase molecule; this is accompanied by a more unspecific concentration-dependent SDS effect, probably mediated by hydrophobic force, which, finally, suppresses phosphorylation. Me2SO does neither qualitatively affect the SDS-dependent chemical properties of the vesicular material nor the SDS-dependent perturbation of the investigated reaction steps

Variable Ca2+ Transport: Phosphoprotein Ratios in the Early Part of the GTP‐Driven Calcium‐Transport Reaction of the Sarcoplasmic Reticulum

Initial Ca2+ transport and phosphoprotein formation of the sarcoplasmic reticulum membrane with GTP were investigated in a comparative study. While saturation of the high-affinity sites for Ca2+ binding and transporting as well as for GTP binding on the external surface of the membrane resulted in Ca2+ transport and phosphoprotein formation in a molar ratio of 2, the variation of the concentrations of the two reactants yielded ratios between 1.7 and 5.7. The ratios varied with a similar dependence on the concentrations of Ca2+ and GTP, except at 500 microM Ca2+, if the reaction was started by Ca2+ instead of GTP but the overall rates decreased. 1 mM DL-propranolol in the preincubation medium selectively inhibited Ca2+ transport but had no effect on initial phosphoprotein formation. These observations indicate that:L (a) phosphorylation of one enzyme molecule induces Ca2+ transport by a variable but limited number of neighbouring molecules, (b) not all Ca2+ bound is essential for phosphorylation but can be transported in parallel, (c) Ca2+ bound to low-affinity sites occupied at 500 microM Ca2+ in the reaction medium is also transported initially, (d) the accessibility of the high-affinity Ca2+ binding sites for DL-propranolol differs, (e) DL-propranolol interacts with Ca2+ binding and transporting sites only in that conformation of the enzyme that can be phosphorylated by the nucleotide

The effect of monovalent and divalent cations on the ATP-dependent Ca2+-binding and phosphorylation during the reaction cycle of the sarcoplasmic reticulum Ca2+-transport ATPase

The coupling of Ca2+ movements and phosphate fluxes as well as the time-dependent occurrence of sequential reaction intermediates in the forward mode of the Ca,Mg-dependent ATPase reaction have been investigated using leaky vesicles (A23187) in the presence of varying Ca2+, Mg2+, and K+ concentrations. The employed ATP concentration of 2 microM does not allow more than one reaction cycle to occur. The respective fractions of ADP-sensitive and ADP-insensitive phosphoenzyme have been determined. The chosen experimental conditions (0-1 degree C, pH 6.0, absence of solubilizers) allow a prolonged time of observation and exclude interfering alterations of coupling and binding parameters, respectively. It is shown that under the experimental conditions K+ interacts with at least four different reaction steps (phosphoenzyme formation, E1P----E2P transition, E2P hydrolysis, and E2----E1 transformation). Mg2+ represents the sole ionic co-factor for the formation of the substrate MgATP if it is present in high concentrations (5 mM). Additional Ca2+ is bound to the substrate as well as to unspecific sites otherwise occupied by Mg2+ if Mg2+ is reduced to 0.1 mM. In this case the E1P----E2P transition rate (including Ca2+ translocation and Ca2+ release from low-affinity sites) is little diminished. If, in the absence of K+, both Mg2+ and Ca2+ are deficient E2P hydrolysis is vastly retarded. We find Ca2+ release to occur time-coincidently with E1P formation and not concomitantly with the comparably slow appearance of E2P; the molar amount of Ca2+ released, however, rather agreed with that of E2P formed. This suggests that under the prevailing conditions of a high proton concentration, phosphoenzyme states containing occluded Ca2+ or Ca2+ bound to low-affinity sites are transitional and not detectable. Preliminary findings on this subject have been published by us and colleagues from this laboratory [Hasselbach, W., Agostini, B., Medda, P., Migala, A. & Waas, W. (1985) in The sarcoplasmic reticulum calcium pump: Early and recent developments critically overviewed (Fleischer, S. & Tonomura, Y., eds) pp. 19-49, Academic Press, Orlando]