Amorphous protein aggregates stimulate plasminogen activation, leading to release of cytotoxic fragments that are clients for extracellular chaperones.

The misfolding of proteins and their accumulation in extracellular tissue compartments as insoluble amyloid or amorphous protein aggregates are a hallmark feature of many debilitating protein deposition diseases such as Alzheimer's disease, prion diseases, and type II diabetes. The plasminogen activation system is best known as an extracellular fibrinolytic system but was previously reported to also be capable of degrading amyloid fibrils. Here we show that amorphous protein aggregates interact with tissue-type plasminogen activator and plasminogen, via an exposed lysine-dependent mechanism, to efficiently generate plasmin. The insoluble aggregate-bound plasmin is shielded from inhibition by α2-antiplasmin and degrades amorphous protein aggregates to release smaller, soluble but relatively hydrophobic fragments of protein (plasmin-generated protein fragments (PGPFs)) that are cytotoxic. In vitro, both endothelial and microglial cells bound and internalized PGPFs before trafficking them to lysosomes. Clusterin and α2-macroglobulin bound to PGPFs to significantly ameliorate their toxicity. On the basis of these findings, we hypothesize that, as part of the in vivo extracellular proteostasis system, the plasminogen activation system may work synergistically with extracellular chaperones to safely clear large and otherwise pathological protein aggregates from the body.

Recombinant Desmodus rotundus salivary plasminogen activator crosses the blood-brain barrier through a low-density lipoprotein receptor-related protein-dependent mechanism without exerting neurotoxic effects.

BACKGROUND AND PURPOSE: Desmoteplase, a recombinant form of the plasminogen activator DSPAalpha1 from Desmodus rotundus, may offer improved clinical benefits for acute ischemic stroke treatment over the current therapy, recombinant tissue plasminogen activator (rtPA). Accumulating evidence suggests that clinical use of rtPA could be limited by unfavorable properties, including its ability to cross the blood-brain barrier (BBB), thus potentially adding to the pro-excitotoxic effect of endogenous tPA in cerebral parenchyma. Here, to investigate whether desmoteplase may display a safer profile than the structurally-related tPA, both agents were compared for their ability to cross the BBB and promote neurotoxicity. METHODS: First, the passage of vascular DSPA and rtPA was investigated in vitro in a model of BBB, subjected or not to oxygen and glucose deprivation. Second, we studied DSPA- and rtPA-mediated effects in an in vivo paradigm of excitotoxic necrosis. RESULTS: The rtPA and desmoteplase cross the intact BBB by LRP-mediated transcytosis. Under conditions of oxygen and glucose deprivation, translocation rates of both compounds increased; however, unlike rtPA, desmoteplase transport remained LRP-dependent. Additionally, neither intracerebral nor intravenous desmoteplase administration enhanced NMDA-induced excitotoxic striatal damage in vivo. Interestingly, intravenous but not intrastriatal coadministration of desmoteplase and rtPA reduced the pro-excitotoxic effect of rtPA. CONCLUSIONS: We show that desmoteplase crosses the BBB but does not promote neuronal death. Moreover, intravenous administration of desmoteplase antagonizes the neurotoxicity induced by vascular rtPA. This action may be caused by competition of desmoteplase with rtPA for LRP binding at the BBB, thus effectively blocking rtPA access to the brain parenchyma.

Safety evaluation of recombinant staphylokinase in rhesus monkeys.

Recombinant staphylokinase (rSTAR) is a profibrinolytic agent of bacterial origin. The objective of this study was to assess the toxicity of rSTAR administered with bolus intravenous infusion in rhesus monkeys (2/sex/group) at the dosages of 0, 4, 14, and 49 mg/kg/day for 2 weeks. The clinical signs were thickening of the skin in all animals and mild hematoma formation in three dosage groups at the injection sites. There were no effects on body weight, absolute or relative organ weights, ophthalmology, or electrocardiogram. Urinalysis indicated that 2 monkeys in 14 or 49 mg/kg/day group developed proteinuria and mild hematuria. Increases in serum BUN levels (14 and 49 mg/kg/day), ALT activity, and bilirubin levels (49 mg/kg/day), and decreases in red blood cell counts, hemoglobin concentrations and Hct values (49 mg/kg/day) were observed at week 2. Significant prolongtion of APTT, PT, and TT (14 and 49 mg/kg/day), and decreases in circulating plasminogen levels (3 treatment groups) were noted. Dose-dependent increases in the titers of anti-rSTAR antibodies and neutralizing rSTAR activity were observed in the three treated groups. Increased neutralizing rSTAR activity diminished the phamacologic effects of rSTAR (ie, prolonged APTT, PT, and TT approaching baseline levels at week 2). Histopathological findings included hemorrhage, and perivascular inflammatory cell infiltration at the injection sites, heptocellular degeneration characterized as cytoplasmic eosinophilia, vacuolation and condensed nuclei (49 mg/kg/day), effusion of RBCs and plasma within some Bowman's capsules and hyaline casts within the lumen of some renal tubules in the kidneys (14 and 49 mg/day/kg), and mild to moderate megakaryocyte hypoplasia with varying levels of pyknotic nuclei at all dose levels. Immune deposits in glomeruli in the kidneys from the three treated groups were detected. These changes were reversible following a 4-week recovery period. In the present preclinical evaluation of toxicity in monkeys, rSTAR is well toleratte at doses up to 49 mg/kg/day. The toxic target organs are the liver, kidney, and bone marrow.

Retinal toxicity of commercial intravitreal tissue plasminogen activator solution in cat eyes.

BACKGROUND: We previously reported retinal toxic reactions in rabbit eyes receiving intravitreal injections of commercial tissue plasminogen activator (tPA) in concentrations greater than or equal to 50 microg/0.1 mL, and recent clinical experience suggests that intravitreal tPA solution may produce toxic effects in human eyes. We therefore investigated the dose-dependent retinal toxicity of intravitreal commercial recombinant tPA solution in cat eyes, which have a vascularized inner retina and vitreous volume similar to that of human eyes. METHODS: Commercial tPA in L-arginine solution was injected into the mid vitreous cavity of normal cat eyes in doses of 25, 50, 75, and 100 microg/0.1 mL and 200 microg/0.2 mL. Control (fellow) eyes received an equal volume of sterile saline solution. After injection, eyes were evaluated by ophthalmoscopy and electroretinography for 14 days and then enucleated for histopathological evaluation. RESULTS: Fundus pigmentary alterations were observed in eyes receiving doses greater than or equal to 50 microg/0.1 mL. Changes were centered in the area around the injection site, and the area's size increased in proportion to the dosage. Mean electroretinography B-wave amplitude measured at 14 days was significantly reduced in eyes receiving greater than or equal to 50 microg of tPA in a dose-dependent fashion. Light microscopy of the involved areas showed loss of photoreceptor elements with necrosis and proliferation of the retinal pigment epithelium. CONCLUSION: Intravitreal injection of commercial tPA solution results in dose-dependent retinal toxicity in cat eyes. CLINICAL RELEVANCE: Because cat eyes are similar to human eyes regarding retinal vascularity and vitreous volume, intravitreal injections of commercial tPA (with L-arginine vehicle) in concentrations greater than 25 microg/0.1 mL are potentially unsafe in human eyes.

The efficacy of plasminogen-urokinase combination in inducing posterior vitreous detachment.

PURPOSE: To investigate the toxicity of intravitreal plasminogen, urokinase, and their combination, and to evaluate their efficacy in the production of posterior vitreous detachment (PVD) in the rabbit eye. METHODS: Fifty-six albino New Zealand rabbits were examined before and after injection using the indirect ophthalmoscope, slit-lamp biomicroscopy, and electroretinography. Various concentrations of urokinase or recombinant plasminogen or a combination were injected intravitreally into the right eyes of four rabbits for each concentration. The left eyes of the animals served as controls and received 0.1 mL balanced salt solution. Group 1 was injected with pure urokinase (1,000, 5,000, or 10,000 IU); Group 2 with recombinant plasminogen (0.1, 0.4, 1.0, 2.0, 4.0, 8.0, or 16.0 caseinolytic units [CU]); and Group 3 with a combination of 1,000 IU urokinase (highest nontoxic dose) and nontoxic concentrations of plasminogen (0.1, 0.4, 1.0, or 2.0 CU). The animals were killed and the eyes enucleated 15 days after injection. Electron and light microscopy were performed. RESULTS: A concentration of 1,000 IU of urokinase was found to be nontoxic to the retina. Plasminogen concentrations of 2.0 CU or less did not produce retinal toxicity, whereas 4.0, 8.0, and 16.0 CU of plasminogen caused minimal-to-severe inflammatory response in the vitreous without histologic or electroretinographic changes. Neither plasminogen nor urokinase alone was successful in producing PVD. The combination of 1,000 IU of urokinase and 1.0 to 2.0 CU of plasminogen was effective without causing retinal toxicity. CONCLUSION: Posterior vitreous detachment can be produced in the rabbit eye using a combination of plasminogen and urokinase.

Comparison of the bleeding potential of vampire bat salivary plasminogen activator versus tissue plasminogen activator in an experimental rabbit model.

BACKGROUND: Vampire bat salivary plasminogen activator (Bat-PA) has significantly greater fibrin specificity than any of the fibrinolytic agents currently in clinical use. This study tests the hypothesis that avoiding fibrinogen depletion may protect against the hemorrhage induced by plasminogen activator treatment. METHODS AND RESULTS: Bat-PA was compared with tissue-type plasminogen activator (TPA) in a randomized, prospective, and blinded study using a rabbit ear puncture model of fibrinolytic bleeding. The two agents were used at equimolar dosages (42 nmol/kg) that yielded similar thrombolytic efficacies in a rabbit femoral artery thrombosis model. Both Bat-PA and TPA prolong primary bleeding to double the baseline values, from between 2.1 and 2.3 minutes to between 4.8 and 5.2 minutes. Rebleeding from hemostatically stable sites during the 3-hour observation period occurred equally often with Bat-PA and TPA, 31% from preinjection sites and 23% to 25% from postinjection sites. The lag time between the time of plasminogen activator injection and the onset of rebleeding was likewise the same for both agents, most occurring at 41 to 57 minutes. However, a greater number of prolonged primary or rebleeding occurrences continued for longer than 10 minutes (63% versus 36%) or longer than 30 minutes (30% versus 10%) after Bat-PA than TPA injection. Animals treated with TPA showed a dramatic decrease in plasma fibrinogen and factor VIII concentrations, but those in the Bat-PA treatment group showed only a slight decrease from control values. CONCLUSIONS: The results indicate that fibrinolytic bleeding after plasminogen activator infusion into rabbits did not correlate with the intensity of the plasma proteolytic state. If anything, Bat-PA usage was associated with a higher proportion of more protracted fibrinolytic bleeding episodes, despite the relatively mild lytic state in comparison with that induced by TPA.

Vampire bat salivary plasminogen activator evokes minimal bleeding relative to tissue-type plasminogen activator as assessed by a rabbit cuticle bleeding time model.

Cuticle bleeding time (CBT) measurements in anesthetized rabbits were performed to assess the potential bleeding risks which may accompany the administration of tissue-type plasminogen activator (tPA) or vampire bat salivary plasminogen activator (BatPA). The dose of BatPA or tPA used in this study, 42 nmol/kg, was previously shown to be efficacious using a rabbit femoral artery thrombosis model (Gardell et al, Circulation 84:244, 1991). CBT was determined by severing the apex of the nail cuticle and monitoring the time to cessation of blood flow. CBT was minimally elevated (1.6-fold, p = NS) following bolus intravenous administration of BatPA; in contrast, bolus intravenous administration of tPA dramatically elevated CBT (6.2-fold, p < 0.05). Rabbits treated with tPA, but not BatPA, displayed profound activation of systemic plasminogen and consequent degradation of Factor VIII and fibrinogen. Elevations in CBT after the administration of tPA were reversed by the replenishment of plasma Factor VIII activity to 40% of control, but were unaffected by complete replenishment of plasma fibrinogen. The results of this study suggest that the administration of BatPA, at a dose that promotes thrombolysis, may evoke a minimal bleeding risk, relative to an equi-efficacious dose of tPA. In addition, the tPA-provoked proteolytic consumption of Factor VIII may be a key contributor to the heightened bleeding risk.

Effect of intravitreal tissue plasminogen activator on experimental subretinal hemorrhage.

PURPOSE: To study the effect of intravitreally injected tissue plasminogen activator (tPA) in an experimental model of subretinal hemorrhage. METHODS: Autologous blood was transsclerally injected into the subretinal space in 34 albino rabbits. One day later tPA was injected into the posterior vitreous in 24 eyes and saline was injected into 10 control eyes. Lysis of the subretinal blood was assessed ophthalmoscopically and retinal function was evaluated electroretinographically. RESULTS: In all eyes in which tPA was injected intravitreally 1 day after subretinal injection of blood, the formed subretinal clots was not visible within 24 hours of treatment. Liquefied subretinal blood that formed from clot lysis disappeared within 6 days. Conversely, in all saline-injected control animals, the subretinal clots were unchanged at 24 hours and were observed for at least 3 days after injection. As a result of the presence of subretinal blood, scotopic electroretinogram amplitudes were markedly reduced in the tPA and saline-injected groups. In many eyes, blood migrated from the subretinal space into the vitreous, but it was detected later, was less severe, and cleared more rapidly after tPA injection. CONCLUSION: Intravitreal injection of tPA 1 day after subretinal injection of blood in rabbits facilitated more rapid lysis of the clotted blood, however, retinal damage was not prevented.

Toxic ocular effects of two fibrinolytic drugs. An experimental electroretinographic study on albino rabbits.

The toxic effects on rabbit eyes of 2 intravitreally injected fibrinolytic substances at different concentrations were studied with repeated clinical observations and registrations of the DC ERG. The fellow, control eye of each animal was injected with saline. Urokinase (Ukidan, Serono) (13 rabbits) initially produced aqueous flare (64%), iris hyperaemia (36%) vitreous opacities (27%) and small retinal haemorrhages (18%). 2-3 months after the injection cataract (50%), vitreous opacities (25%) and retinal changes (13%) were observed. The highest dose (10 000 Ploug units) caused reduction of the ERG b-wave, as a sign of retinal toxicity. Tissue activator (D-44, Centre d'immunologie et de biologie Pierre Fabre) (10 rabbits) produced marked aqueous flare (initially 100%, after 2 weeks 50%) and pronounced, persistent vitreous opacities (25% after 2-3 months). At the late stage corneal blood vessels (38%) and cataract (38%) were also found, but only in eyes injected with the highest dose (1000 units), which was retinotoxic as judged by the ERG (reduced b- and c-waves).