The protein C pathway and pathologic processes.

Alterations in expression of protein C (PC) pathway components have been identified in patients with active inflammatory disease states. While the PC pathway plays a pivotal role in regulating coagulation and fibrinolysis, activated PC (aPC) also exhibits cytoprotective properties. For example, PC-deficient mice challenged in septic/endotoxemic models exhibit phenotypes that include hypotension, disseminated intravascular coagulation, elevated inflammatory mediators, neutrophil adhesion to the microvascular endothelium, and loss of protective endothelial and epithelial cell barriers. Further, inflammatory bowel disease has been correlated with diminished endothelial PC receptor and thrombomodulin levels in the intestinal mucosa. Downregulated expression of the cofactor, protein S, as well as PC, is also associated with ischemic stroke. Studies to elucidate further the structural elements that differentiate the various functions of PC will serve to identify novel therapeutic approaches toward regulating these and other diseases.

Severe deficiency of coagulation Factor VII results in spontaneous cardiac fibrosis in mice.

Mice genetically modified to produce low levels (approximately 1% of wild-type) of coagulation FVII presented with echocardiographic evidence of heart abnormalities. Decreases in ventricular size and reductions in systolic and diastolic functions were found, suggestive of a restrictive cardiomyopathy and consistent with an infiltrative myopathic process. Microscopic analysis of mouse hearts showed severe patchy fibrosis in the low-FVII mice. Haemosiderin deposition was discovered in hearts of these mice, along with increases in inflammatory cell number, ultimately resulting in widespread collagen deposition. Significant increases in mRNA levels of TGFbeta, TNFalpha and several matrix metalloproteinases in low-FVII mice, beginning at early ages, supported a state of cardiac remodelling associated with the fibrotic pathology. Mechanistic time-course studies suggested that cardiac fibrosis in low-FVII mice originated from bleeding in heart tissue, resulting in the recruitment of leukocytes, which released inflammatory mediators and induced collagen synthesis and secretion. These events led to necrosis of cardiomyocytes and collagen deposition, characteristics of cardiac fibrosis. The results of this study demonstrated that haemorrhagic and inflammatory responses to a severe FVII deficiency resulted in the development of cardiac fibrosis, observed echocardiographically as a restrictive cardiomyopathy, with compromised ventricular diastolic and systolic functions.

Targeting plasminogen activator inhibitor-1: role in cell signaling and the biology of domain-specific knock-in mice.

It is well documented that elevated levels of PAI-1 in plasma can decrease the fibrinolytic activity in blood with an associated increased risk of thrombus formation. A diverse range of molecules including bacterial lipopolysaccharide (LPS), the inflammatory mediators tumor necrosis factor alpha (TNFalpha) and interleukins, thrombin, transforming growth factor-beta (TGF-beta), and hormones regulate the synthesis of plasma PAI-1. Therefore, it is of clinical importance to restore the fibrinolytic balance. For a drug to be effective in controlling the synthesis of PAI-1, sufficient insight into the signal transduction pathways that control its regulation is desirable, which could serve as logical targets for the development of pharmaceuticals. Some key signaling pathways have been identified with the aid of pharmacological inhibitors, involved in the up-regulation of PAI-1 in context with several diseases, including obesity, insulin resistance, diabetic nephropathy, glomulonephritis, and pulmonary fibrosis. Furthermore, independent of its inhibitory activity PAI-1 mediates interactions with vitronectin (VN) and low density lipoprotein receptor-related protein (LRP) which modifies basic cell behaviors of proliferation, migration, and attachment. Intriguingly, it has been shown that both anti-fibrinolytic and non-fibrinolytic-related functions of PAI-1 may have overlapping roles in many diseases that are poorly understood. Tailoring knock-in mice with site-specific alterations that diminish the inhibitory activity, VN-binding, and LRP-binding activity of PAI-1 are useful tools for manipulation of biochemical properties, in vivo, and evaluating therapeutics.

A urokinase-type plasminogen activator deficiency diminishes the frequency of intestinal adenomas in ApcMin/+ mice.

The interaction of urokinase-type plasminogen activator (uPA) and its receptor, uPAR, on cell surfaces facilitates the generation of cell-bound plasmin, thus allowing cells to establish a proteolytic front that enables their migration through protein barriers. This complex also activates cell signalling pathways that influence cell functions. Clinical studies have identified uPA as an indicator of poor overall survival in patients with colorectal cancer. In the current study, a mouse model of colon cancer, Apc(Min/+), with an additional deficiency of uPA (Apc(Min/+)/Plau-/-) was used to determine the effects of uPA on tumour initiation and growth. Utilizing this model, it was found that the number of tumours was diminished in these mice relative to Apc(Min/+) mice, which correlated with the decreased leukocyte infiltration in the tumours. However, tumour growth was not impeded in Apc(Min/+)/Plau-/- mice, and proliferation and tumour vascularization were, in fact, enhanced in Apc(Min/+)/Plau-/- mice. These latter effects are consistent with a mechanism involving up-regulation of COX-2 expression and Akt pathway activation in Apc(Min/+)/Plau-/- mice. The results from this study suggest that uPA plays dual and opposing roles in regulating lesion development: one early, during the transition from normal epithelia to dysplastic lesions, and another later during tumour growth.

A coagulation factor VII deficiency protects against acute inflammatory responses in mice.

Upregulation of the activated Factor VII (FVIIa)/Tissue Factor complex, downregulation of natural anticoagulation pathways, and inhibition of fibrinolysis, are major contributors to coagulopathies associated with acute inflammation. Provision of FVIIa, and consequent downstream coagulation-related proteases, also stimulates further inflammatory changes, which can result in disseminated intravascular coagulation. Thus, the potential protective effects in vivo of a genetic-based reduction in FVII levels have been investigated in a murine model of acute inflammation, namely lipopolysaccharide (LPS)-induced lethal endotoxaemia. Mice with a total FVII deficiency do not survive the neonatal period. Therefore mice expressing low levels of FVII (FVII(tTA/tTA)), producing sufficient amounts of FVII for survival (approximately 5% of wild-type (WT) FVII), were employed to investigate in vivo pathways involved in the crosstalk between coagulation, inflammation, and survival, consequent to administration of a lethal dose of LPS. The FVII(tTA/tTA) mice presented with reduced mortality, coagulation, and inflammatory responses in comparison with similarly treated WT mice after administration of LPS. The attenuated inflammatory responses in FVII(tTA/tTA) mice were associated with downregulation of Egr-1 signalling. Administration, in vivo, of specific inhibitors of FXa and thrombin demonstrated that the inflammatory responses were unaltered in WT mice, but further reduced in FVII(tTA/tTA) mice. Therefore, a FVII deficiency enhances survival from lethal endotoxaemia both through attenuation of inflammatory responses that result directly from reduced FVIIa levels, and, indirectly, from downregulation of coagulation proteases downstream of the FVII-dependent cascade.

Delayed inflammatory responses to endotoxin in fibrinogen-deficient mice.

Severe inflammation leads to haemostatic abnormalities, such as the development of microvascular thrombi. As a result, ischaemia-related downstream organ damage can occur. The present study demonstrates that mice with a total deficiency of fibrinogen (Fg(-/-)) present with altered responses to challenge with Gram-negative lipopolysaccharide (LPS). Early survival in response to continuous LPS challenge was increased in Fg(-/-) mice and histological findings indicated that this improvement correlated with a lack of fibrin deposition in organs. Neutrophils appeared early in the lungs of challenged wild-type (WT) mice, but occurred in Fg(-/-) mice at later times. This delayed response in Fg(-/-) mice was confirmed by studies that showed a strong dependence on Fg of binding of neutrophils to endothelial cells in the presence of LPS. While cytokines were also elevated in both WT and Fg(-/-) mice, their levels were generally lower at early times in this latter group. The time course of MIP-2 expression correlated with the occurrence of pulmonary leakage after LPS challenge, which was delayed in Fg(-/-) mice. These results suggest that fibrin(ogen) plays a role as an early mediator in the cross-talk between coagulation and inflammation.

A central role for plasminogen in the inflammatory response to biomaterials.

The inflammatory response to implanted biomaterials severely limits their deployment in patients. Plasminogen has been shown to play a central role in cell migration, and therefore could regulate this inflammatory response. We sought to determine if plasminogen influences recruitment of inflammatory cells to a biomaterial implanted into plasminogen-deficient (Plg(-/-)) mice. Small disks of polyethylene terephthalate, a material used in vascular grafts, were surgically implanted into the peritoneum of wild-type and Plg(-/-) mice. Recruitment of neutrophils and monocytes/macrophages into the peritoneum and onto the disks was measured, primarily at 18 h. Monocyte/macrophage recruitment was markedly blunted in Plg(-/-) mice compared with wild-type mice. Unexpectedly, neutrophil recruitment was also markedly decreased in the Plg(-/-) mice. While recruitment of leukocytes into the peritoneum was plasminogen-dependent, the adhesion of the emigrating cells to the implants was not. In contrast, adhesion but not recruitment was reduced in fibrinogen-deficient mice. Reconstitution of Plg(-/-) mice with intravenous or intraperitoneal plasminogen differentially restored monocyte/macrophage and neutrophil recruitment. Tranexamic acid, an inhibitor of the lysine binding sites of plasminogen, suppressed leukocyte recruitment in wild-type mice, but aprotinin, a plasmin inhibitor, did not. Plasminogen exerts a marked influence on both neutrophil and monocyte/macrophage recruitment to implanted biomaterials. This role is distinct from that of fibrinogen, and the two inflammatory cell types use plasminogen in different ways. Plasminogen represents a therapeutic target for controlling the inflammatory response to implanted materials.

Accelerated skin wound healing in plasminogen activator inhibitor-1-deficient mice.

Components of the fibrinolytic system have been implicated in cell migratory events associated with tissue remodeling. Studies in plasminogen-deficient mice (PG(-/-)) indicated that skin wound healing is impaired, but is resolved with an additional fibrinogen deficiency. Plasminogen activator inhibitor-1 (PAI-1) expression by keratinocytes has been identified shortly after wound injury. PAI-1 expression could affect wound healing by regulating the fibrinolytic environment of the wounded area, as well as influencing events associated with cell attachment and detachment through interactions with matrix proteins. The present study directly assesses PAI-1 involvement in skin wound healing through analyses of a dermal biopsy punch model in PAI-1-deficient (PAI-1(-/-) mice. While the cellular events associated with the healing process are similar between wild-type (WT) and PAI-1(-/-) mice, the rate of wound closure is significantly accelerated in PAI-1(-/-) mice.

Attenuation of neointima formation following arterial injury in PAI-1 deficient mice.

Atherosclerosis is a chronic inflammatory disease in which the fibrinolytic system has been implicated as playing a major role. In order to directly assess the physiological impact an imbalanced fibrinolytic system has on both early and late stages of this disease, mice deficient for PAI-1 (PAI-1-/-) were used in a model of vascular injury/repair and compared to wildtype mice (WT). Copper-containing cuffs were placed around the carotid arteries of these mice and the injured arteries were removed at either 7 or 21 days for histological analyses. At both times after injury, fibrin was prevalent in WT arteries, whereas only diffuse in PAI-1-/- arteries. At 21 days after injury, a prominent, multilayered neointima was evident in WT arteries, with no evidence of a neointima in PAI-1-/- arteries. Results from this study directly confirm the involvement of the fibrinolytic system in vascular repair processes following injury and indicate that fibrin could potentially play a role in lesion formation by stimulating smooth muscle cell proliferation, collagen synthesis, and intracellular cholesterol accumulation.

Development of pulmonary fibrosis in fibrinogen-deficient mice.

Bleomycin is an antineoplastic drug commonly used for the treatment of many carcinomas and lymphomas. Its toxic side effect on lung tissue is a major limitation to its use, with approximately 3-5% of patients affected. Although the number of affected patients is small, the damage incurred by bleomycin in these patients is often irreversible and, at times, fatal. A number of therapies have been shown to be effective in animal studies to minimize damage, but to date no "magic bullet" has been identified. Many proteins of the fibrinolytic system have been implicated as playing a role in the progression of the disease, one of which is fibrinogen (Fg) acting in the context of a fibroproliferative agent. Its presence correlates with an upregulation of plasminogen activator inhibitor-1 and tissue factor in alveolar cells surrounding the lesion area. It is believed that Fg participates in the activation and migration of fibroblasts and provides a scaffold, in the form of fibrin, for cell migration following induction of acute lung injury. To further understand the mechanism of injury following bleomycin treatment and the possible role of fibrinogen therein, mice have been generated with a targeted deletion of the gamma-chain of Fg, which resulted in the absence of detectable circulating Fg. The offsprings of Fg heterozygous mice (FG+/-) mice follow Mendelian distributions indicating no embryonic lethality with this deletion. Approximately one-half of the Fg-deficient (FG-/-) neonates exhibited bleeding episodes, approximately one-half of which were fatal. For the pulmonary fibrosis study, FG-/- mice and wildtype littermates were administered a bleomycin solution intratracheally and the disease was allowed to progress for two weeks. The mice were then sacrificed, the left lung was excised for hydroxyproline analysis, the right lung was processed for histologic profiling. Examination of trichrome stained sections, surprisingly, revealed no qualitative difference between wildtype and FG-/- animals. The extent and pattern of the deposition of collagen were also similar. These results were quantitatively confirmed by hydroxyproline analysis, which revealed equivalent increases in collagen content between wildtype and FG-/- animals when compared to appropriate saline controls. Analysis of the early acute inflammatory stage of the disease showed a difference in the neutrophil population between days three and five of the disease. These studies suggest that, although fibrinogen is not required for collagen deposition at the later stage of the disease, it may play a role in the early acute inflammation stage.

Gene targeting in hemostasis. plasminogen.

A number of in vitro and in vivo observations have implicated plasminogen in contributing to events associated with diverse physiological and pathophysiological processes. The development of gene knockout technology has led to the generation of plasminogen deficient mice. These mice survive to adulthood and are thus a valuable resource for directly assessing its role in these processes. As a result, fibrinolytic and nonfibrinolytic functions have been identified from studies in which these mice were challenged utilizing a number of models that mimic both normal biological and pathological events.

The characterization of mice with a targeted combined deficiency of protein c and factor XI.

Activated protein C functions directly as an anticoagulant and indirectly as a profibrinolytic enzyme. To determine whether the fibrin deposition previously observed in PC(-/-) murine embryos and neonates was mediated through the FXI pathway, PC(+/-)/FXI(-/-) mice were generated and crossbred to produce double-deficient progeny (PC(-/-)/FXI(-/-)). PC(-/-)/FXI(-/-) mice survived the early lethality observed in the PC(-/-)/FXI(+/+) neonates, with the oldest PC(-/-)/FXI(-/-) animal living to 3 months of age. However, the majority of these animals was sedentary and significantly growth-retarded. On sacrifice or natural death, all of these PC(-/-)/FXI(-/-) mice demonstrated massive systemic fibrin deposition with concomitant hemorrhage and fibrosis, as confirmed through histological analyses. Several of these animals also presented with enlarged lymph nodes and extensive lymphatic fluid in the thoracic cavity. Thus, although a number of the PC(-/-)/FXI(-/-) mice survived the lethal perinatal coagulopathy seen in the PC(-/-) neonates, they nonetheless succumbed to overwhelming thrombotic disease in later life. This combined deficiency state provided the first clear indication that the course of a severe thrombotic disorder could be manipulated by blocking the intrinsic pathway and provided the first opportunity to study a total protein C deficiency in an adult animal.

Remodeling of the vessel wall after copper-induced injury is highly attenuated in mice with a total deficiency of plasminogen activator inhibitor-1.

Clinical studies have indicated that high plasma levels of fibrinogen, or decreased fibrinolytic potential, are conducive to an increased risk of cardiovascular disease. Other investigations have shown that insoluble fibrin promotes atherosclerotic lesion formation by affecting smooth muscle cell proliferation, collagen deposition, and cholesterol accumulation. To directly assess the physiological impact of an imbalanced fibrinolytic system on both early and late stages of this disease, mice deficient for plasminogen activator inhibitor-1 (PAI-1(-/-)) were used in a model of vascular injury/repair, and the resulting phenotype compared to that of wild-type (WT) mice. A copper-induced arterial injury was found to generate a lesion with characteristics similar to many of the clinical features of atherosclerosis. Fibrin deposition in the injured arterial wall at early (7 days) and late (21 days) times after copper cuff placement was prevalent in WT mice, but was greatly diminished in PAI-1(-/-) mice. A multilayered neointima with enhanced collagen deposition was evident at day 21 in WT mice. In contrast, only diffuse fibrin was identified in the adventitial compartments of arteries from PAI-1(-/-) mice, with no evidence of a neointima. Neovascularization was observed in the adventitia and was more extensive in WT arteries, relative to PAI-1(-/-) arteries. Additionally, enhanced PAI-1 expression and fat deposition were seen only in the arterial walls of WT mice. The results of this study emphasize the involvement of the fibrinolytic system in vascular repair processes after injury and indicate that alterations in the fibrinolytic balance in the vessel wall have a profound effect on the development and progression of vascular lesion formation.

Tumor development is retarded in mice lacking the gene for urokinase-type plasminogen activator or its inhibitor, plasminogen activator inhibitor-1.

In vivo tumor progression in mice with targeted deficiencies in urokinase-type plasminogen activator (UPA-/-) and its inhibitor, plasminogen activator inhibitor-1 (PAI-1-/-), was studied using a fibrosarcoma tumor model. Murine T241 fibrosarcoma cells were s.c. implanted into three groups of mice with the following genotypes, wild-type (WT), UPA-/-, and PAI-1-/-. A significantly diminished primary tumor growth in UPA-/- and PAI-1-/- mice occurred, relative to WT mice. Tumors in UPA-/- and PAI-1-/- mice displayed lower proliferative and higher apoptotic indices and displayed a different neovascular morphology, as compared with WT mice. These results are consistent with the decreased growth rates of this tumor in these gene-deleted mice. Immunohistochemical analyses of the tumors revealed a decrease in vascularity and vascular endothelial growth factor expression only in tumors in PAI-1-/- mice. Analyses of the relative extents of corneal angiogenesis in these same animals, induced by basic fibroblast growth factor, corroborated the resistance of PAI-1-/- mice to neovascularization. The results obtained suggest that the host fibrinolytic system plays an important role in tumor growth in this model. Alterations in host expression of components of this system may alter tumor growth and dissemination by affecting the balance between tumor cell death and proliferation, as well as extracellular matrix changes needed for invasiveness and angiogenesis.

A total fibrinogen deficiency is compatible with the development of pulmonary fibrosis in mice.

In addition to their well-known roles in hemostasis, fibrinogen (Fg) and fibrin (Fn) have been implicated in a number of other physiological and pathophysiological events. One of these involves the fibroproliferative response after acute lung injury, which is the focus of the current study. Mice with a total Fg deficiency (FG(-/-)) were generated by breeding heterozygous (FG(+/-)) pairs, each of which contained an allele with a targeted deletion of its Fg-gamma-chain gene. The resulting FG(-/-) animals did not possess detectable plasma Fg. FG(-/-) mice were then used to assess the roles of Fg and Fn in a bleomycin-induced acute lung injury model. Intratracheal administration of bleomycin in wild-type and FG(-/-) mice resulted in equivalent deposition of interstitial collagen and fibrotic lesions at days 7 and 14 after administration. This indicates that Fg and/or Fn are not essential for the development of bleomycin-induced pulmonary fibrosis.

The development of bleomycin-induced pulmonary fibrosis in mice deficient for components of the fibrinolytic system.

Acute and chronic pulmonary diseases are characterized by impaired fibrinolytic activity within the lung. To determine the role of the fibrinolytic system in regulating the pathologies associated with lung injury, we examined the effect of bleomycin, an agent that induces the development of pulmonary fibrosis, in mice deficient for plasminogen (Pg(-)(/-)), urokinase (u-PA(-)(/-)), urokinase receptor (u-PAR(-)(/-)), or tissue plasminogen activator (t-PA(-)(/-)), and in control wild-type (WT) mice. Pg(-)(/-) and t-PA(-)(/-) mice demonstrated an enhanced increase in lung collagen content relative to that observed in WT mice. Levels in u-PA(-)(/-) and u-PAR(-)(/-) mice were similar to those in WT mice. Histological analysis 14 days after lung injury confirmed enhanced interstitial fibrosis in Pg(-)(/-), u-PA(-)(/-), and t-PA(-)(/-) mice relative to WT and u-PAR(-)(/-) mice. Areas of pulmonary hemorrhage were observed in bleomycin-treated WT mice and not in Pg(-)(/-), u-PA(-)(/-), and u-PAR(-)(/-) mice or saline controls. Instead, extensive areas of fibrosis were present throughout the lungs of bleomycin-treated Pg(-)(/-) and u-PA(-)(/-) mice. A mixed phenotype (hemorrhage and fibrosis) was observed in t-PA(-)(/-) and Pg(+/-) mice. Hemosiderin-laden macrophages were abundant in the lungs of mice exhibiting hemorrhage and these mice were prone to an early death. Enhanced macrophage levels in the lungs and activation of matrix metalloelastase (MMP-12) were found in mice with a hemorrhage phenotype. The results of these studies indicate a role for the fibrinolytic system in acute lung injury and suggests that intra-alveolar hemorrhage is the result of basement membrane degradation through cell-mediated u-PA activation of Pg with possible involvement of matrix metalloproteinases. Absence of these two components of the fibrinolytic system, either urokinase or plasminogen, results in accelerated fibrosis.

Endoluminal arterial injury in plasminogen-deficient mice.

BACKGROUND: Vascular remodeling following arterial injury is characterized by an initial inflammatory reaction. Prior experiments using peritoneal inflammatory models have shown that the plasminogen system plays a role in the intensity of the inflammatory response. This study was undertaken to test the hypothesis that an absence of plasminogen would lead to a decrease in vascular remodeling. METHODS: A left carotid artery injury was created with a flexible guidewire in both wild-type [Plg(+/+)] and plasminogen deficient [Plg(-/-)] mice. The right carotid artery was uninjured and used as a control. Three weeks postinjury, the mice were sacrificed and perfusion fixed, and the bilateral carotid arteries were sectioned for histological examination and collection of morphometric data. RESULTS: After arterial injury, electron microscopy of the acutely injured artery revealed that the endothelium was denuded, that there were breaks in the internal elastic membrane, and that there was disruption of the medial layer of smooth muscle cells. The intimal and medial areas were significantly increased between the uninjured and injured carotid arteries of both Plg(+/+) (+80% intimal, +41% medial, P < 0. 05) and Plg(-/-) [+48% intimal, +24% medial, P < 0.05) mice. However, although there was a significant increase in the adventitial area of Plg(+/+) mice (+18%, P < 0.05), there was no difference in Plg(-/-) mice (-6%). Interestingly, even after 3 weeks, four of six injured arteries in Plg(-/-) mice had persistent thrombus within the medial layer, whereas this was not found in any of the nine Plg(+/+) mouse arteries. DISCUSSION: Plasminogen deficiency inhibited the increase in adventitial area seen after injury in Plg(+/+) mice, but not the increase in intimal or medial areas. Not surprisingly, plasminogen-deficient mice also demonstrated a severe alteration in intramural thrombus clearance. Thus, specific aspects of the vascular remodeling response are dependent on plasminogen.

Nonfibrinolytic functions of plasminogen.

Although the roles of plasminogen and plasmin in mediating blood clot dissolution are well known, the availability of mice deficient for components of the fibrinolytic system has allowed direct approaches to be made toward elucidating the role of these proteins in other diverse physiological and pathophysiological processes. A number of these studies have identified plasminogen as playing an important role in inflammation and other cell migratory processes. With the identification of receptors for plasminogen on a number of pathogens, and the ability to activate plasminogen through either endogenous production of plasminogen activators or utilization of host activators, mice deficient for components of the fibrinolytic system offer a unique approach toward further elucidating the importance of this system in pathogen infection and dissemination.