Richard Bucala

Peripheral Blood Fibrocytes: Differentiation Pathway and Migration to Wound Sites

Fibrocytes are a distinct population of blood-borne cells that display a unique cell surface phenotype (collagen I+/CD11b+/CD13+/CD34+/CD45RO+/MHC class II+/CD86+) and exhibit potent immunostimulatory activities. Circulating fibrocytes rapidly enter sites of tissue injury, suggesting an important role for these cells in wound repair. However, the regulatory processes that govern the differentiation of blood-borne fibrocytes and the mechanisms that underlie the migration of these cells to wound sites are currently not known. We report herein that ex vivo cultured fibrocytes can differentiate from a CD14+-enriched mononuclear cell population and that this process requires contact with T cells. Furthermore, we demonstrate that TGF-β1 (1–10 ng/ml), an important fibrogenic and growth-regulating cytokine involved in wound healing, increases the differentiation and functional activity of cultured fibrocytes. Because fibrocytes home to sites of tissue injury, we examined the role of chemokine/chemokine receptor interactions in fibrocyte trafficking. We show that secondary lymphoid chemokine, a ligand of the CCR7 chemokine receptor, acts as a potent stimulus for fibrocyte chemotaxis in vitro and for the homing of injected fibrocytes to sites of cutaneous tissue injury in vivo. Finally, we demonstrate that differentiated, cultured fibrocytes express α smooth muscle actin and contract collagen gels in vitro, two characteristic features of wound-healing myofibroblasts. These data provide important insight into the control of fibrocyte differentiation and trafficking during tissue repair and significantly expand their potential role during wound healing.

Sustained Mitogen-activated Protein Kinase (MAPK) and Cytoplasmic Phospholipase A2 Activation by Macrophage Migration Inhibitory Factor (MIF) REGULATORY ROLE IN CELL PROLIFERATION AND GLUCOCORTICOID ACTION

Macrophage migration inhibitory factor (MIF) is an important pro-inflammatory mediator with the unique ability to counter-regulate the inhibitory effects of glucocorticoids on immune cell activation. MIF is released from cells in response to glucocorticoids, certain pro-inflammatory stimuli, and mitogens and acts to regulate glucocorticoid action on the ensuing inflammatory response. To gain insight into the molecular mechanism of MIF action, we have examined the role of MIF in the proliferation and intracellular signaling events of the well characterized, NIH/3T3 fibroblast cell line. Both endogenously secreted and exogenously added MIFs stimulate the proliferation of NIH/3T3 cells, and this response is associated with the activation of the p44/p42 extracellular signal-regulated (ERK) mitogen-activated protein kinases (MAP). The MIF-induced activation of these kinases was sustained for a period of at least 24 h and was dependent upon protein kinase A activity. We further show that MIF regulates cytosolic phospholipase A2 activity via a protein kinase A and ERK dependent pathway and that the glucocorticoid suppression of cytokine-induced cytoplasmic phospholipase A2 activity and arachidonic acid release can be reversed by the addition of recombinant MIF. These studies indicate that the sustained activation of p44/p42 MAP kinase and subsequent arachidonate release by cytoplasmic phospholipase A2 are important features of the immunoregulatory and intracellular signaling events initiated by MIF and provide the first insight into the mechanisms that underlie the pro-proliferative and inflammatory properties of this mediator.

Formation of Immunochemical Advanced Glycosylation End Products Precedes and Correlates With Early Manifestations of Renal and Retinal Disease in Diabetes

Elevated levels of advanced glycosylation end products (AGEs) have been found in multiple tissues in association with diabetic vascular complications and during the microalbuminuric phase of diabetic nephropathy. In this study, we have used an AGE-specific enzyme-linked immunosorbent assay (ELISA) to measure skin AGEs to determine whether elevated levels can be detected before the onset of overt microangiopathy. Subjects with type I diabetes (n = 48) were graded for the degree of nephropathy (normal [23], microalbuminuria [12], or macroalbuminuria [12]) and retinopathy (none [13], background [20], or proliferative [15]). Subgroups with a premicroalbuminuric phase of albumin excretion (≤28 mg/24 h, n = 27) or with the earliest stages of retinopathy (n = 27) were identified. A significant increase in tissue AGEs was found as urinary albumin increased during the premicroalbuminuric phase of nephropathy even when the data were adjusted for age and duration of diabetes (P = 0.005). Immunoreactive AGEs also increased as normal renal status advanced to microalbuminuria and macroalbuminuria (P = 0.0001 across groups). Significant elevation of AGEs was also found in association with the earliest stages of clinically evident retinopathy (early background versus minimal grades). In addition, higher AGE levels were found in subjects with proliferative retinopathy when compared with those with less severe retinopathy (P < 0.004 across groups). In contrast, no significant differences were found in tissue AGE levels between groups with or without early retinopathy based on pentosidine or fluorescent AGE measurements, although fluorescent AGEs correlated with albumin excretion. In conclusion, levels of collagen-linked AGEs, when measured by an AGE-specific ELISA, reveal a correlation with preclinical stages of diabetic nephropathy and early retinopathy not indicated by other methods and may prove useful as early markers of microangiopathy in type I diabetes.

Advanced glycosylation end products in diabetic renal and vascular disease

An increasing body of experimental data supports the important, etiologic role of advanced glycosylation end products (AGEs) in the development of the renal and vascular complications of diabetes. Advanced glycosylation end products arise from glucose-derived Amadori products and act to increase vascular permeability, enhance protein and lipoprotein deposition, inactivate nitric oxide, and promote matrix protein synthesis and glomerular sclerosis. Loss of normal renal function increases the level of circulating plasma AGEs and contributes markedly to their ultimate tissue toxicity. Aminoguanidine, a recently developed pharmacologic inhibitor of advanced glycosylation, is presently undergoing phase II/III clinical trials in diabetic nephropathy and may offer a specific therapeutic modality for diminishing the formation and toxicity of AGEs.

Inhibition of macrophage migration inhibitory factor (MIF) tautomerase and biological activities by acetaminophen metabolites

The cytokine macrophage migration inhibitory factor (MIF) has emerged to be an important regulator of the inflammatory response and is critically involved in the development of septic shock, arthritis, and glomerulonephritis. Although the biological activities of MIF are presumed to require a receptor-based mechanism of action, the protein is also a tautomerase and has a catalytically active N-terminal proline that is invariant in structurally homologous bacterial isomerases. This observation raises the possibility that MIF may exert its biological action via an enzymatic reaction. Physiologically relevant substrates for MIF have not been identified, nor have site-directed mutagenesis studies consistently supported the requirement for a functional catalytic site. Small molecule inhibitors of MIFs isomerase activity also have been developed, but none have been shown yet to inhibit MIF biological activity. We report herein that the iminoquinone metabolite of acetaminophen, N-acetyl-p-benzoquinone imine (NAPQI), inhibits both the isomerase and the biological activities of MIF. The reaction between NAPQI and MIF is covalent and produces a NAPQI-modified MIF species with diminished cell binding activity and decreased recognition by anti-MIF mAb. These data are consistent with a model by which the NAPQI reacts with the catalytic Pro-1 of MIF to disrupt the integrity of epitope(s) critical to MIFs biological activity and point to the importance of the catalytic domain, but not the catalytic activity per se, in MIF function. These results also point to a powerful approach for the design of small molecule inhibitors of MIF based on interaction with its catalytic site and constitute an example of a pharmacophore capable of irreversibly inhibiting the action of a proinflammatory cytokine.

Macrophage Migration Inhibitory Factor Release by Macrophages after Ingestion of Plasmodium chabaudi-Infected Erythrocytes: Possible Role in the Pathogenesis of Malarial Anemia

ABSTRACT Human falciparum malaria, caused by Plasmodium falciparum infection, results in 1 to 2 million deaths per year, mostly children under the age of 5 years. The two main causes of death are severe anemia and cerebral malaria. Malarial anemia is characterized by parasite red blood cell (RBC) destruction and suppression of erythropoiesis (the mechanism of which is unknown) in the presence of a robust host erythropoietin response. The production of a host-derived erythropoiesis inhibitor in response to parasite products has been implicated in the pathogenesis of malarial anemia. The identity of this putative host factor is unknown, but antibody neutralization studies have ruled out interleukin-1β, tumor necrosis factor alpha, and gamma interferon while injection of interleukin-12 protects susceptible mice against lethal P. chabaudiinfection. In this study, we report that ingestion of P. chabaudi-infected erythrocytes or malarial pigment (hemozoin) induces the release of macrophage migration inhibitory factor (MIF) from macrophages. MIF, a proinflammatory mediator and counter-regulator of glucocorticoid action, inhibits erythroid (BFU-E), multipotential (CFU-GEMM), and granulocyte-macrophage (CFU-GM) progenitor-derived colony formation. MIF was detected in the sera of P. chabaudi-infected BALB/c mice, and circulating levels correlated with disease severity. Liver MIF immunoreactivity increased concomitant with extensive pigment and parasitized RBC deposition. Finally, MIF was elevated three- to fourfold in the spleen and bone marrow of P. chabaudi-infected mice with active disease, as compared to early disease, or of uninfected controls. In summary, the present results suggest that MIF may be a host-derived factor involved in the pathophysiology of malaria anemia.

Glycation and microglial reaction in lesions of Alzheimer's disease

Single, double, and triple immunostaining of cryostat sections of elderly normal and Alzheimer disease (AD) brain was performed with monoclonal and polyclonal antibodies to advanced glycation end products (AGE). The sections were counterstained with thioflavin-S or with immunocytochemistry for A beta and also stained with markers for microglia. AGE-immunoreactivity was detected in senile plaques and neurofibrillary tangles (NFT). AGE immunoreactivity was most intense in dense or reticular amyloid deposits and extracellular NFT, while intracellular NFT and diffuse amyloid had less AGE immunoreactivity. This pattern of immunoreactivity was similar to that noted in previous studies with antibodies to apolipoprotein-E (apo-E). Therefore, double labeling with antibodies to apo-E and AGE was performed. AGE immunoreactivity colocalized to a very high degree with apo-E immunoreactivity, except that relatively more intense apo-E immunoreactivity was detected in amyloid deposits and more intense AGE immunoreactivity in NFT. The lesions that were immunostained with antibodies to AGE and apo-E were often, but not always, associated with a local microglial reaction. The results raise the possibility that apo-E or a fragment of apo-E may be glycated. Biochemical studies are needed to determine the extent of possible apo-E glycation in AD. The present results raise the possibility that glycation may serve as one of the signals for activation of microglia associated with amyloid deposits and extracellular NFT.

Up-regulation of macrophage colony-stimulating factor (M-CSF) and migration inhibitory factor (MIF) expression and monocyte recruitment during lipid-induced glomerular injury in the exogenous hypercholesterolaemic (ExHC) rat

Although macrophages play an important role in lipid‐induced glomerular injury, we know little of the mechanisms by which hyperlipidaemia induces monocyte recruitment. This study investigated the role of M‐CSF and macrophage MIF in monocyte recruitment during the development of lipid‐induced glomerular injury in the susceptible ExHC rat strain. Groups of five ExHC rats were fed a high cholesterol diet (HCD) containing 3% cholesterol, 0.6% sodium cholate and 15% olive oil, and killed after 3 days, 1, 2 or 6 weeks. Control animals were killed on day 0 or after 6 weeks on a normal diet. Animals were hypercholesterolaemic 3 days after the induction of the HCD, but showed no change in plasma triglycerides over the 6‐week period. Glomerular macrophage accumulation was first evident at 1–2 weeks and increased up to week 6, when macrophage‐derived foam cells were seen in almost all glomeruli, and segmental lesions and mild proteinuria were also evident. Combined in situ hybridization and immunohistochemistry staining demonstrated that, coincident with the induction of hypercholesterolaemia on day 3, there was marked up‐regulation of M‐CSF and MIF mRNA expression by intrinsic glomerular cells (mostly mesangial cells and podocytes) which preceded monocyte recruitment. There was a highly significant correlation between the number of M‐CSF and MIF‐positive cells and glomerular macrophage accumulation over the 6‐week period. Although some glomerular macrophages and foam cells exhibited M‐CSF and MIF expression, the major source of these molecules was intrinsic glomerular cells. No local macrophage proliferation was observed during the development of glomerular lesions. In conclusion, hypercholesterolaemia caused marked up‐regulation of M‐CSF and MIF expression by intrinsic glomerular cells, which correlated with monocyte recruitment and the development of lipid‐induced glomerular injury. This is the first study to implicate local synthesis of MIF in the pathogenesis of lipid‐induced lesions.

Macaque blood-derived antigen-presenting cells elicit SIV-specific immune responses

Natural blood‐borne antigen‐presenting cells (APCs) were tested for their ability to augment antigen presentation for SIV vaccines. Fibrocytes and monocyte‐derived dendritic cells (DCs) were isolated from multiple Macaca fascicularis. Macaque fibrocytes displayed the characteristic cellular morphology and stained positive for CD34 and collagen, as observed in human and murine fibrocytes. Macaque DCs were generated from monocytes by culturing in granulocyte–macrophage colony stimulating factor and interleukin‐4 (IL‐4). Two days after maturation, cells were enriched for the DC marker CD83. Fibrocytes and DCs were each transfected with green fluorescence protein expression plasmids or DNA expression vectors encoding all of the SIVmne structural and regulatory genes. Autologous DCs were re‐infused into macaques subcutaneously (sc) following transfection; mixing with recombinant SIV antigens or inactivated whole SIV in vitro; or mock‐treatment. Autologous monocyte‐derived DCs pulsed with whole inactivated SIV were re‐infused and elicited cellular and/or humoral responses in vivo in eight of ten vaccinated macaques.