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REVIEW |
Medizinische Poliklinik, Klinikum Innenstadt der Ludwig-Maximilians-Universität, Munich, Germany.
Correspondence to Dr. Detlef Schlöndorff, Medizinische Poliklinik, Klinikum Innenstadt der Ludwig-Maximilians-Universität, Pettenkoferstrasse 8a, 80336 Munich, Germany. Phone: +49 89 5160 3500; Fax: +49 89 5160 4439; E-mail: sdorff{at}pk-i.med.uni-muenchen.de
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Abstract |
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 Top Abstract IntroductionChemokines: Classification and...Chemokines, Chemokine Receptors,...Expression of Chemokines and...Other Renal Disease ModelsChemokines in Human Kidney...A Model for Chemokines...Conclusions, Future Directions,...References |
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Introduction |
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TopAbstractIntroductionChemokines: Classification and...Chemokines, Chemokine Receptors,...Expression of Chemokines and...Other Renal Disease ModelsChemokines in Human Kidney...A Model for Chemokines...Conclusions, Future Directions,...References |
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Chemokines are a family of chemotactic cytokines that were first identified on the basis of their ability to induce the migration of different cell types, particularly those of lymphoid origin (7,8,9). A wealth of data has demonstrated that chemokines working in concert with selectins and integrins act as directional signals to sort and direct effector leukocyte migration (4,10,11). In addition, chemokines have also been shown to activate leukocytes, influence hematopoiesis, and modulate angiogenesis (12,13,14).
The receptors for chemokines are expressed in a cell type-specific manner and are restricted primarily to subsets of leukocytes (15). The discovery that some chemokine receptors act as coreceptors for HIV entry into target cells has accelerated research in this field (16,17,18,19,20,21,22). Advances over the past few years have included the discovery of new chemokines, receptors, and antagonists, and a greater appreciation for the diverse biologic functions displayed by this cytokine family (15,23,24,25). Several recent reviews have dealt with the basic biology and the roles of chemokines in various disease processes (2,3,4,9,15,26,27,28). This review will focus on the biology of the chemokine and chemokine receptor families in the context of renal diseases.
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Chemokines: Classification and Mechanisms of Action |
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TopAbstractIntroductionChemokines: Classification and...Chemokines, Chemokine Receptors,...Expression of Chemokines and...Other Renal Disease ModelsChemokines in Human Kidney...A Model for Chemokines...Conclusions, Future Directions,...References |
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Some CXC chemokines display an additional structural designation, namely, the amino acid motif E-L-R-CXC (glutamic acid-leucine-arginine-cysteine-X-cysteine) just proximal to their first two cysteine residues. The E-L-R-CXC chemokines act primarily as neutrophil chemoattractants (30). In contrast, the CXC chemokines that lack the E-L-R motif bind different CXC receptors and are active on lymphocytes (9,30).
Chemokines are involved in more than the control of cell migration.
Melanoma growth stimulating activity/growth-related oncogene-
(GRO-) was originally identified as an autocrine growth factor for
malignant melanoma cells
(30,34).
Interferon-inducible protein-10 (IP-10) has been shown to induce the
proliferation of mesangial cells
(35). Interleukin-8 (IL-8) can
cause release of granules and respiratory burst in neutrophils
(12). Regulated upon
activation, normal T cell expressed and secreted (RANTES) can induce
eosinophil and basophil degranulation, respiratory burst in eosinophils
(36), and has been shown to
augment T cell proliferation
(37). Platelet factor 4 (PF4)
inhibits megakaryopoiesis (38)
and can be bactericidal (39).
In addition, some chemokines are involved in hematopoiesis
(13,40,41,42).
A novel role for some classes of chemokines and their receptors as
anti-inflammatory mediators has recently been suggested
(43). The CXC chemokines IL-8,
epithelial cell-derived neutrophil attractant 78 (ENA-78), and
GRO-,ß,
, which contain the E-L-R-CXC motif, have been shown
to act as angiogenic agents
(44), while PF4, IP-10,
monokine induced by interferon- (MIG), and stromal cell-derived
factor-1 (SDF-1), which lack this motif, can act as angiostatic factors
(14). During embryogenesis,
wound healing, chronic inflammation, and tumor growth, the expression of
chemokines may help to determine the micro-vascularization within the
tissue.
Regulation of Chemokine Expression
Chemokines are regulated at transcriptional, posttranscriptional,
translational, and posttranslational levels
(2). Many, but not all, of the
proinflammatory chemokines are induced by IL-1ß or tumor necrosis
factor- (TNF-). Some CXC chemokines (MIG, IP-10) were initially
identified on the basis of their specific upregulation by interferon-
(IFN-) (45). Other
chemokines, especially those that play a role in normal leukocyte trafficking,
appear to be constitutively expressed (SDF-1, B cell attracting chemokine-1,
thymus-expressed chemokine, secondary lymphoid tissue chemokine, EBI1 ligand
chemokine, hemofiltrate CC chemokine-1, liver and activation-regulated
chemokine) (28).
Some of the best-studied proinflammatory chemokines (e.g., IL-8,
RANTES, monocyte chemoattractant protein-1 [MCP-1]) are controlled at the
transcriptional level by the transcription factors nuclear factor-
B
(NF-B), CAAT enhancer binding protein, and activator protein-1
(21,46,47).
Their activation requires a complex cascade of steps including phosphorylation
by multiple kinases and phosphatases, degradation of transcriptional
inhibitors, translocation of transcription factors from cytoplasm to nucleus,
etc. (4). These signaling
pathways can be different for each stimulus and transcription factor and are
further complicated by "cross-talk" between the various pathways
(48). Although at first glance
this may appear to be an unnecessarily complicated system, it allows the
fine-tuning and integration of the multiple signals required for a complex
signal- and tissue-specific biologic response. These biochemical events are
potential targets for therapeutic intervention. For example, glucocorticoids
interfere with NF-B activation
(49,50).
Similarly, agents that influence cAMP levels often modulate the stimulatory
signals for chemokine expression
(51,52,53).
The inhibition of chemokine expression seen after treatment with free radical
scavengers may be due to interference with NF-B activation, but may
also involve other redox-related steps
(54).
Selective Expression of Chemokine Receptors Contributes to Cell
Specificity of Chemokine Action
The biologic actions of chemokines
(Table 3) are mediated through
a family of G protein-coupled receptors with seven transmembrane domains
(4,25,55,56).
The nomenclature used to describe these receptors is based on the class of
chemokine ligands that interact with the receptor (i.e., C, CC, CXC,
and CX3C receptors)
(27). Many chemokines bind to
several different receptors (Tables
1 and
2)
(57). The differential
expression of the receptors by distinct leukocyte subsets is an important
component of the specificity of chemokine action
(27,58).
The complexity and apparent redundancy of the system is thought to provide a
high degree of effectiveness and flexibility in vivo
(57).
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Binding of a chemokine to its receptor activates a signal transduction
cascade leading to activation of phospholipase C1 and 2, and the
production of inositol
(1,4,5)-trisphosphate
and diacylglycerol
(2,4).
In addition, a rapid and transient increase in intracellular calcium, and the
activation of protein kinase C are observed
(59,60,61).
A variety of kinases may be involved in signal transduction, including
serine/threonine kinases (e.g., members of the mitogen-activated
protein kinase cascade) as well as tyrosine protein kinases
(59). The various stimulatory
and inhibitory pathways involved in these activation cascades are providing
insight into the design of potential pharmacologic agents.
The Duffy Antigen Receptor for Chemokines
The Duffy antigen receptor for chemokines (DARC) is a
"promiscuous" receptor-like structure that binds the CXC family
proteins IL-8
(62,63),
GRO (63), PF4
(64), neutrophil activating
peptide-2, as well as the CC chemokines MCP-1
(62,63)
and RANTES (63). DARC, first
identified as the Duffy blood group antigen, is expressed on erythrocytes and
endothelial cells of postcapillary venules of the kidney
(64,65,66).
DARC mediates Plasmodium vivax entry into red blood cells, and
DARC-"negative" individuals (generally of central African lineage)
are resistant to this form of malaria but still express DARC on their
endothelial cells (67). At
present, a function for the erythroid-expressed form of DARC is not known.
Chemokine-induced signal transduction through DARC has not been demonstrated,
and DARC is not coupled to G proteins. One hypothesis is that DARC may act as
a scavenger that helps to clear chemokines from the circulation
(62). DARC protein expressed
on postcapillary venules may act as a presentation-like structure for
chemokines on these surfaces, and hypothetically could contribute to induced
leukocyte adhesion and transmigration at these sites.
Chemokines, Chemokine Receptors, and Th1, Th2 Immune Responses
The immune system mounts distinct and selective immune responses to
different types of infection or antigenic challenge. These responses have been
termed Th1-like and Th2-like after the two classes of T helper cells (Th)
involved
(68,69,70).
Th1 and Th2 responses appear to represent the extremes of a spectrum of immune
responses. Th1 responses are stimulated by pathogens that invade and inhabit
cells and result in activation of cytotoxic T lymphocytes and delayed-type
hypersensitivity. The Th1 subtype produces cytokines that stimulate strong
cellular immune responses (IFN-, IL-2, leukotriene A, granulocyte
macrophage colony-stimulating factor). The Th2 subtypes produce cytokines that
evoke strong antibody responses (IL-3, -4, -5, -6, -10, and -13). In addition,
Th2 cytokines can inhibit the inflmmatory reactions induced by Th1 cytokines.
A third subtype called Th0 secretes cytokines of both types and is believed to
give rise to the "polarized" Th1 and Th2 lineages. The recently
characterized Th3/T-regulatory-1 T cell subset is thought to downregulate
antigen-presenting cells, possibly via transforming growth factor-ß
(TGF-ß) (71).
Growing evidence suggests that differential chemokine receptor expression may be crucial for the generation of a Th1- or Th2-type immune response, because specific chemokine receptor expression has been shown to characterize these T helper cell subtypes (72). Th1 cells appear to preferentially express the chemokine receptors CXCR3 and CCR5, while Th2 cells display CCR4, CCR8, and some CCR3 (28,72,73). The chemokine receptors expressed by different populations of T cells may thus dictate to a significant degree the tissue infiltration of Th1 and Th2 cells and the direction of the eventual immune response.
This is an important issue in the interpretation of results obtained from animal models. For example, different inbred mouse strains often demonstrate a more pronounced Th1- or Th2-like response. After an immunologic insult, C57BL/6 mice show a more Th1-like bias compared with Balb/C mice, which show a more Th2-like response (74,75). This can influence the composition of the cellular infiltrate and subsequently the course of the renal disease model (75).
Chemokines Control Important Aspects of Acute and Chronic
Inflammation
Inflammation is a process involving changes in hemodynamics, vascular
reaction of endothelial cells, leukocyte adhesion, activation, and migration
(76). The nature of the
inflammatory response is dictated by the pathogenic insult. The process of
leukocyte trafficking from the peripheral circulation into tissue spaces
involves a series of interactions between soluble mediators and surface
molecules expressed by the endothelium and leukocyte, as well as subsequent
interactions with the extra-cellular matrix
(77). Chemokines mediate
events at multiple stages in this process
(78,79).
The early events in this process entail the rolling of leukocytes along the
microvascular surface through transient interactions between vascular
addressins and selectins (80).
The addressin/selectin-dependent cell-cell interaction is essential in
leukocyte homing and promotes transient surface contact between the rolling
leukocyte and the endothelial surface. The endothelium provides a selective
interface between the peripheral circulation and extravascular space and
ultimately acts as a discriminator of leukocyte infiltration.
During inflammation, the endothelium upregulates chemokine presentation structures (such as specific glucosaminoglycans), selectin ligands (addressins), selectins, and the Ig partners of leukocyte-expressed integrins (11,81). Thus, inflamed microvascular endothelium increases its capacity to bind chemokines and upregulates the expression of molecules required for the efficient rolling and firm adhesion of leukocytes.
Early in inflammation, as the microvascular endothelium becomes activated, chemokines generated by endothelial cells, subendothelial tissue, or released after platelet activation bind to the "activated" endothelial surface (78,82). Thus situated chemokines act as directional signals for leukocytes as they roll across the endothelium. A notable exception appears to be fractalkine, which is a membrane-bound chemokine that also enables direct leukocyte adhesion via its receptor CX3CR1 (33). Chemokines can trigger activation of leukocyte-expressed integrins, resulting in the arrest and firm adhesion of leukocytes to the activated endothelial surface. Important adhesion molecule pairs in this process include the selectins (E, L, and P), the Ig-like molecules intercellular adhesion molecule-1 and vascular cell adhesion molecule-1, and the ß2 and ß1 integrins (e.g., leukocyte function-associated antigen-1 and very late antigen-4) (80). (Note: The nomenclature of these factors is often confusing as it reflects the manner in which the proteins were first identified rather than their structural characteristics.)
After firm adhesion, leukocytes undergo spreading, diapedesis, extravasation, and migration into interstitial spaces. Although some chemokines are important for the control of leukocyte arrest, other chemokines appear to influence the subsequent events associated with leukocyte emigration. Leukocyte emigration in vivo occurs in a complex background of chemotactic signals where several receptors may be activated simultaneously or successively. Thus, the migrating leukocyte must distinguish among the various chemotactic signals within the three-dimensional environment of the tissue to move both up and down gradients to eventually reach the site of inflammation (21,83)
Chemokines May Play a Role in the Resolution or Progression of
Inflammatory Processes
As leukocytes reach the site of inflammation and undergo activation, they
can produce additional proinflammatory factors resulting in propagation and
amplification of the inflammatory response. The accumulation of specific
leukocytes at the site of injury normally results in removal of the initiating
insult (e.g., phagocytosis of bacteria, immune complexes, apoptotic
cells, cell debris, etc.) and tissue repair. Inactivation and removal of
inflammatory effector cells once their goal has been accomplished are
important to prevent chronic inflammation and progressive tissue destruction.
Factors that govern the termination of the inflammatory response are thought
to involve the downregulation of chemokine synthesis by local factors
(e.g., prostaglandins, TGF-ß) or a specific combination of
inflammatory mediators leading to local apoptosis of the leukocytes involved
(84).
During renal diseases, the infiltration of monocytes/macrophages and T cells into kidneys is thought to play a central role in progressive interstitial fibrosis and the progression of chronic renal failure (85). During this process, a cross-talk between cytokines, vasoactive substances, chemokines, and their respective target cells takes place. This interaction contributes to the outcome, i.e., healing or progression of the renal disorder. Chemokines appear to be integral players in this complex and dynamic process.
Transgenic and Knockout Mice: Models of Chemokine and Chemokine
Receptor Action
The targeted disruption of chemokine and chemokine receptor genes as well
as the expression of chemokines as transgenes has identified important roles
for these molecules in specific aspects of the inflammatory response.
The ability of chemokines to direct leukocyte infiltration depends on a low regional expression level. In studies with MCP-1 transgenic mice, the systemic overexpression of a mouse mammary tumor virus long terminal repeat-MCP-1 transgene led to a general paralysis of the response to this chemokine (86). Only the local production as seen in insulin promoter-MCP-1 transgenic mice was shown to be effective in selectively recruiting monocytes (86). Besides persistent MCP-1 expression and insulitis, the macrophage infiltrate did not result in progressive tissue destruction. Therefore, additional costimulatory signals are required for the activation of macrophages.
Knockout mice with a targeted disruption for either MCP-1 or the MCP-1 receptor CCR2 gene show a reduced capacity to recruit monocytes and have suggested a fundamental role for these molecules in the generation of atherosclerotic lesions (87,88,89). In addition, CCR2(-/-) mice show significant defects in delayed-type hypersensitivity responses and in the production of Th1-type cytokines (89). Mice deficient for CCR5 show an increased humoral response to T cell-dependent antigenic challenge, suggesting a novel role for CCR5 in downmodulating T cell-dependent immune responses (90). Targeted disruption of the eotaxin gene demonstrated that eotaxin enhances the magnitude of early but not late eosinophil recruitment after antigen challenge (91). CXCR4 is broadly expressed by cells of the immune and central nervous system and mediates the migration of resting leukocytes and hematopoietic progenitors in response to its ligand SDF-1 (92). Essentially identical lethal defects were seen in mice deficient for either CXCR4 or SDF-1 (93,94,95). These include severely reduced B lymphopoiesis, reduced myelopoiesis in bone marrow, defective formation of the large vessels supplying the gastrointestinal tract, as well as cardiac defects and abnormal cerebellar development (93,94,95). In normal mice, CXCR5 is expressed on mature B cells and a subpopulation of T helper cells. CXCR5 knockout mice lack inguinal lymph nodes and possessed little or no normal Peyer's patches. Lymphocyte migration into splenic follicles of these mice were significantly impaired (96). Information obtained with chemokine and chemokine receptor knockout in models of renal diseases is discussed in later sections.
Chemokines, Chemokine Receptors, and Viral Biology
Given the important roles of chemokines in diverse immune processes, it is
not surprising that viruses have exploited chemokine biology through the
course of evolution. This phenomenon is emphasized by the large number of
chemokine receptors, chemokines, and general inhibitors or modulators of
chemokine action that are encoded by different viral genomes
(21,60,97,98,99,100,101).
One of the most dramatic developments in the viral/chemokine connection is
the observation that select chemokine receptors act as coreceptors for HIV
entry into target cells
(16,17,18,19,20).
The chemokine ligands for these receptors can suppress infection by some
strains of HIV-1 and may act as important moderators of HIV replication in
vivo (21). CCR5
represents the major coreceptor for macrophage-tropic strains of HIV-1,
whereas CXCR4 acts as a coreceptor for T celltropic strains. CCR5 appears to
play a unique role in viral pathogenesis, as individuals homozygous for a
nonfunctional allele of CCR5 (CCR5
32) are highly protected from HIV-1
infection (21). These results
have opened new avenues of research into the pathogenesis of HIV and have led
to the development of new strategies to block viral fusion.
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Chemokines, Chemokine Receptors, and the Kidney |
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TopAbstractIntroductionChemokines: Classification and...Chemokines, Chemokine Receptors,...Expression of Chemokines and...Other Renal Disease ModelsChemokines in Human Kidney...A Model for Chemokines...Conclusions, Future Directions,...References |
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, IL-1ß,
IFN-, and lipopolysaccharide (LPS), especially when used in
combination, rapidly (within a few hours) induce MCP-1, IL-8, and IP-10
(53,
104,
111,112,113).
The induction of RANTES occurs in a more delayed manner (12 to 48 h). IgG and
IgA immune complexes can also induce upregulation of MCP-1, RANTES, IL-8, and
IP-10 expression by mesangial cells (Tables
4 and
5). Reactive oxygen species are
able to upregulate chemokine expression and may represent a common mechanism
of injury-induced chemokine generation
(106).
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Growth factors such as platelet-derived growth factor and basic fibroblast growth factor can induce MCP-1 and RANTES expression by mesangial cells (114,115). This expression may be related to the macrophage influx seen during proliferative responses related to tissue repair, regeneration, and remodeling (114). MCP-1 expression by proximal tubular cells is seen after exposure to hyaluronan, a glucosaminoglycan degradation product of extracellular matrix that accumulates in the interstitium during kidney diseases (116). The interaction of CD40 with its ligand (CD154), together with IL-4 and IL-13, results in MCP-1, RANTES, and IL-8 generation by cultured proximal tubular cells (117), observations that may be relevant for tubulointerstitial inflammatory cell infiltrates in transplant rejection and other forms of interstitial diseases.
The generation of chemokines by proximal tubular cells can be induced by
albumin, which is thought to mimic the effects of proteinuria and may be
related to the tubulointerstitial damage seen in glomerular disease
(118,119,120).
Wang et al. described an increase of MCP-1 mRNA expression in
proximal tubular cells in response to delipidated bovine serum albumin (BSA),
holotransferrin, and apotransferrin, which was mediated by NF-B
(118,120).
Lysine, an inhibitor of protein uptake, reduced the MCP-1 expression
(118). Zoja et al.
found a dose-dependent increase of RANTES expression by proximal tubular
epithelial cells exposed to BSA
(119). However, this effect
required very high albumin concentrations (i.e., 10 to 30 mg/ml),
probably not achieved in proximal tubular fluids. Although the significance of
these in vitro effects of albumin on tubular epithelial cell
chemokine production for the nephrotic syndrome remains hypothetical, it does
suggest that the prolonged proteinuria and proximal tubular epithelial
overload of proteins ("nephrosis") may lead to tubular cell
activation and chemokine induction. Furthermore, the role of lipids in the
nephrotic syndrome and of lipid droplets in proximal tubules deserves
attention in this context, as lipid oxidation may occur and oxidized lipids
can stimulate chemokine production
(121).
Vasoactive Agents Can Stimulate Chemokine Expression
Vasoactive agents and chemokines may directly interact. Wolf et
al. found that angiotensin II via the AT2 receptor could
stimulate RANTES production by glomerular endothelial cells
(122). Moreover, the infusion
of angiotensin II into rats led to an influx of macrophages into the
glomerulus, which was attenuated by the administration of an AT2
receptor antagonist (122).
The differential regulation of RANTES and MCP-1 could explain the apparent
divergent reports from other groups implicating the AT1 rather than
the AT2 receptor in "chemokine" stimulation
(122,123,124,125).
The Production of Proinflammatory Chemokines Is Transitory
Some chemokines appear to be constitutively expressed (i.e., those
that control normal leukocyte trafficking). The proinflammatory chemokines
appear to be kept under tight regulatory control and are expressed only in
response to specific stimuli (Tables
4 and
5). The basal expression of
chemokines often seen in cultured renal cells may represent a tissue-culture
artifact, as serum and endotoxin (a common contaminant of growth media) are
potent stimuli for chemokine induction
(112).
It is thought that the expression of proinflammatory chemokines normally
follows a self-limited course. Interestingly, different time frames for the
expression of various chemokines in response to the same stimulus have been
reported
(112,126).
In general, chemokines that are rapidly induced (e.g., MCP-1) return
to "baseline" within a day. Stimulation with a combination of
cytokines (e.g., TNF-, IL-1ß, and IFN-) often
results in a more prolonged expression
(114,115).
RANTES expression can be slower with an increase seen after 12 to 24 h, but
the levels may remain elevated for days
(114). The different time
courses suggest different signal transduction events used for the individual
chemokines.
Inhibition of Chemokine Expression
The expression of inflammatory chemokine genes can be inhibited by
glucocorticoids
(127,128),
cytokines such as TGF-ß
(129), and prostaglandins
(e.g., PGE2)
(53). The inhibitory effect of
prostaglandin appears to involve modulation of the second messenger cAMP
(51,52,53,130).
Because TGF-ß and prostaglandins are generated at sites of tissue injury,
the net effect on local chemokine generation may depend on the balance between
proinflammatory and anti-inflammatory agents. The dual character of TGF-ß
is again illustrated by the report that this cytokine can inhibit MCP-1
expression by proximal tubular cells and at the same time enhanced synthesis
of the neutrophil-specific chemokine IL-8
(129).
Renal Cells May Also be Targets for Chemokines
Renal cells also express chemokine receptors. Thymus-derived chemotactic
agent-4 (TCA4), a mouse chemokine, can bind to mouse mesangial cells and
mediate chemotaxis and proliferation
(131). The TCA4-specific
receptor expressed by mesangial cells has not yet been identified
(131,132).
In a human mesangial cell line, stimulation with IFN- led to induction
of functional CCR1 expression
(112). The activated
mesangial cells were found to migrate in response to RANTES
(112). In these experiments,
no expression of CCR3, CCR4, CCR5, and CCR8 could be detected
(112).
Romagnani et al. demonstrated the expression of CXCR3 both in cultured human mesangial cells and renal biopsies (35). The mesangial cells were shown to flux Ca2+, migrate in response to IP-10, and proliferate in response to MIG (35). The overall function of chemokine receptor expression by intrinsic renal cells remains to be defined, but could play a role in mesangial cell migration-proliferation during mesangial repair and could even function as local immune modulator. It is hoped that these questions can be addressed with receptor knockout models.
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Expression of Chemokines and Chemokine Receptors in Experimental Models of Renal Diseases |
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Nephrotoxic Serum Nephritis
Many groups have used the classic model of nephrotoxic serum nephritis
(NTS-GN) induced by the injection of antibodies against glomerular basement
membranes for the study of chemokine expression and action
(138,139,140,141).
Mice with accelerated NTS-GN show increased expression of RANTES
(138,139,141,142),
MCP-1
(138,139,140,141,142),
IP-10
(141,142),
and MCP-3 (140) mRNA, whereas
no change was seen in macrophage inflammatory protein-1 (MIP-1)
expression (139).
The biologic action of different chemokines has been studied through the use of neutralizing antibodies and specific chemokine antagonists. Lloyd et al. blocked RANTES-associated events in NTS-GN in CD1 mice (an outbred mouse strain) by the use of the antagonist Met-RANTES. Animals treated with Met-RANTES showed reduced proteinuria, reduced T cell infiltration, and mononuclear cell infiltration. However, glomerular crescent formation was not significantly reduced. Treatment with a neutralizing MCP-1 antibody led to a reduction in proteinuria, infiltrating macrophages, and a striking decrease in crescent formation and collagen production, suggesting that MCP-1, and not RANTES, is involved in crescent formation and early interstitial fibrosis (139). This issue was also examined in MCP-1 knockout mice. Tesch et al. induced NTS-GN in F1 generation littermates of MCP-1 knockout 129SV/J and wild-type C57BL/6 (i.e., a mixed genetic background). The animals developed a glomerular injury consisting of hyalinosis, capillary dilation and thickening, focal segmental sclerosis, and crescents (140). Glomerular hypertrophy or hypercellularity was not present (140). The lack of glomerular chemokine expression in this model is consistent with the lack of glomerular leukocyte infiltration, while the predominant tubular MCP-1 expression was associated with tubulointerstitial cell infiltrate (140). In the MCP-1-deficient F1 generation (129SV/JXC57BL/6), a reduced macrophage infiltrate adjacent to tubules was seen. The authors suggest that tubular epithelial cells represent the primary source of MCP-1 protein in this model. MCP-1 so positioned could act to recruit peritubular macrophages that could then promote tubular interstitial injury (140). Hisada et al. used the NTS-GN model in mice to evaluate the role of angiotensin II type 1a receptor (AT1a) by use of AT1a receptor-deficient mice (AT1a(-/-)) (125). AT1a-deficient mice were backcrossed with C57BL/6 for five generations (representing adequate backcrossing) (125). In these animals, a peak of MCP-1 mRNA expression was seen after 6 h. An additional increase in MCP-1 after 14 d, which was stronger in the AT1a(+/+) than in the AT1a(-/-) mice, was also seen (125). The higher expression of MCP-1 in wild-type mice was associated with a more severe disease course (125). The authors propose that angiotensin II via the AT1a receptor mediates the late MCP-1 expression and may play a role in progression of immune-mediated renal injury.
NTS-GN results in induction of CCR1, CCR2, and CCR5 that is associated with the expression of corresponding chemokine mRNA for MCP-1, RANTES in CD1 mice (142). Another recent abstract indicates that mice deficient in CCR1 show more severe renal impairment and proteinuria than the wildtype mice, suggesting a novel immune modulatory role for CCR1 (141).
In Wistar-Kyoto rats, the injection of NTS-GN antibodies leads to
crescentic glomerulonephritis in which CD8+ T cells are thought to play a
major role (143). In this
model, an upregulation of MCP-1
(143,144,145,146,147,148,149,150,151,152),
MIP-1
(143,148,149,151),
MIP-1ß
(143,148,151),
RANTES
(145,150,151),
MCP-3 (151), CINC
(148,149),
MIP-2
(148,149,153),
PF4 (149), TCA3
(151), fractalkine
(154), lymphotactin
(155), and IP-10 mRNA
(149) was detected
(Table 6).
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A correlation between the expression of neutrophil-attracting chemokines
and an early neutrophil influx and the later expression of
macrophage-attracting chemokines followed by a macrophage influx was described
(148,149).
The MCP-1 mRNA was localized to intrinsic glomerular cells after 3 h. After 24
h, the predominant source of MCP-1 was from infiltrating monocytes/macrophages
(156). MCP-1 protein
(156) was demonstrated in
glomeruli
(144,150,152,157),
vascular endothelial cells
(157), and tubular epithelial
cells (157). Expression of
RANTES (150), MIP-1
(148), MIP-1ß
(150), and MIP-2
(153) protein was also
demonstrated. Recently, the upregulation of fractalkine mRNA, as well as an
induction of the fractalkine receptor (CX3CR1) mRNA, was described
in NTS-GN. Fractalkine protein was localized to glomerular endothelium
(154). Antibodies against
CX3CR1 markedly attenuated the crescentic nephritis
(154). A neutralizing
antibody against MCP-1 decreased macrophage infiltration of the glomeruli and
reduced proteinuria
(146,156,157).
This beneficial effect was shown to persist to day 56 after induction of the
disease, with lower proteinuria and blood urea nitrogen seen compared with
untreated rats (157).
Neutralizing antibodies against other chemokines have also shown partial
"positive" effects. Blocking MIP-1 and MIP-1ß resulted
in a 60% reduction in proteinuria after 24 h, but the animals did not show a
corresponding reduction in leukocyte influx
(148). Blocking CINC (the rat
homologue of GRO) also resulted in decreased proteinuria and reduced early
glomerular cell infiltration by polymorphonuclear neutrophils
(148). The combination of
anti-CINC and anti-MIP treatment did not show an additive beneficial effect
(148). A single injection of
an anti-MIP-2 (CXC chemokine) antibody resulted in a reduced neutrophil influx
and a significant decrease in proteinuria
(153).
A natural and broadly acting chemokine receptor antagonist of viral origin, vMIP-II, can block both CC and CXC receptors (99,150). Treatment with vMIP-II decreased infiltration with CD8+ T cells, macrophages and reduced proteinuria to onethird of the control group (150).
Agents that modulate expression of chemokines have beneficial effects on
the outcome of the disease. Treatment with dexamethasone can limit glomerular
MCP-1 expression, as well as polymorphonuclear neutrophil and
monocyte/macrophage infiltration
(149). MCP-1 mRNA expression
is controlled to a significant extent by the transcription factor NF-B
(147). Treatment of rats with
the NF-B inhibitor pyrrolidine dithiocarbamate led to a decrease in
MCP-1 expression, reduced proteinuria, and preserved renal function
(147). Treatment of animals
with a nonselective cyclo-oxygenase (COX) inhibitor (indomethacin) or
selective COX-2 inhibitors (meloxicam, SC 58125) resulted in an upregulation
of MCP-1 and RANTES (145).
The nonselective COX inhibitor led to a stronger induction of chemokines
compared with the group treated with the COX-2 inhibitor. COX products
(i.e., prostaglandins) may serve as endogenous chemokine repressors
(Table 6)
(53,145).
In summary, the animal models of nephrotoxic serum glomerulonephritis suggest a role for chemokines in the initiation and propagation of this disease. The blockade of select chemokines, or their receptors, can lead to a partial improvement of the disease. Surprisingly, recent abstracts indicate that interference with lymphotactin (43), or the elimination of CCR1 (141), may worsen the disease, suggesting "anti-inflammatory" functions for some chemokines.
Anti-Thy-1 Nephritis
In rats the injection of anti-thymocyte antiserum can lead to
complement-dependent mesangiolysis followed by monocyte influx and a mesangial
proliferative glomerulonephritis
(107,158).
These lesions heal spontaneously over several weeks. The type of renal disease
is dependent on the rat strain used. Wistar and Lewis rats develop a transient
influx of macrophages (159).
By contrast, F344 rats do not show an influx of macrophages, but have a
pronounced proliferative glomerulopathy
(159).
MCP-1 (107,123,145,160,161,162) and RANTES (145,162) are upregulated in this model, and MCP-1 protein localizes to glomeruli (107,159). An important role for MCP-1 in this disease process was suggested in blocking experiments using MCP-1 neutralizing antibodies, which led to a decreased infiltration of monocytes/macrophages after 24 h (160). Treatment with AOP-RANTES (a partially "blocking" RANTES derivative) as described in a recent abstract showed a 60% decrease of glomerular macrophage infiltration and ameliorated collagen type IV deposition (Table 6) (162).
Prostaglandin E (PGE) infusion (161), depletion of complement (107), and AT1 antagonists have been shown to significantly decrease MCP-1 expression and glomerular macrophage infiltration (123). As seen in the NTS-GN model, COX inhibitors enhance production of MCP-1 and RANTES (Table 6) (145).
Models of Systemic Lupus Erythematosus
New Zealand black mice crossed with New Zealand white (NZB/W) mice serve as
a model for lupus nephritis. The F1 hybrid develops circulating antibodies to
nucleic acid, renal immune deposits, and proteinuria
(163). MCP-1 mRNA expression
is upregulated during the initial 6 mo of the disease
(163). In situ
hybridization localized MCP-1 mRNA to intrinsic glomerular cells, infiltrating
mononuclear cells, and tubular epithelium
(163). At later stages of the
disease, MCP-1 expression in tubuli corresponded to an "adjacent"
leukocyte infiltration (163).
Mice treated with cyclophosphamide showed better survival, lower proteinuria,
as well as less severe glomerular and interstitial changes, and reduced MCP-1
expression (163). Bindarit, a
novel immunosuppressive drug, was recently tested in this model at different
time points and in combination with low-dose steroids
(164). Starting at 2 mo of
age, bindarit administration significantly reduced expression of MCP-1,
proteinuria, renal impairment, and prolonged animal survival
(Table 6)
(164).
The MRL-Faslpr mouse serves as an additional model of systemic lupus. These animals show an upregulation of RANTES and develop a nephritis with glomerular, perivascular, and interstitial inflammation (165). Tubular epithelial cells, genetically manipulated to express RANTES protein, were injected into kidneys of MRL-Faslpr mice. This led to an interstitial infiltrate composed mainly of CD4+ T cells and to a lesser extent CD8+ T cells and macrophages. By contrast, when colony-stimulating factor-1 (CSF-1) was overexpressed in kidneys using the same approach, an equal number of CD4+ and CD8+ T infiltrating cells were seen. The authors postulated complementary roles for RANTES and CSF-1 during autoimmune nephritis in MRL-Faslpr mice.
Immune Complex Glomerulonephritis
A model of immune complex glomerulonephritis in the rabbit is induced by
the administration of BSA in combination with LPS
(166). An influx of
neutrophils into glomeruli, fusion of foot processes, and proteinuria by day 8
characterize this model
(166). IL-8 expression by
affected glomeruli was associated with an increased urinary IL-8 excretion
(166). Injection of an
anti-IL-8 antibody reduced glomerular neutrophil infiltration, prevented
fusion of foot processes, and normalized proteinuria
(166).
In Wistar rats, an immune complex nephritis was induced by the injection of ovalbumin over a period of several weeks. This resulted in an increase of MCP-1 mRNA expression in the renal cortex (167). Immunohistochemistry showed intense MCP-1 staining in glomerular capillaries, mesangial areas, proximal tubular epithelium, and interstitial mononuclear infiltrates (167). Treatment with an angiotensin-converting enzyme inhibitor reduced MCP-1 expression (167). These data suggest a possible link between renal immune injury, the angiotensin system, and specific chemokines (Table 6) (122,123,125,167).
A recent abstract described increased MCP-1, RANTES, CCR1, CCR2, and CCR5 mRNA during the early phase of apoferritin-induced immune complex nephritis in Balb/c mice (168). This upregulation of chemokines preceded the glomerular infiltration of leukocytes. Chemokine expression and the leukocyte infiltration disappeared after discontinuation of antigen exposure and the initiation of healing (168).
Puromycin Aminonucleoside Nephrosis
In rats the injection of puromycin aminonucleoside leads to proteinuria. A
marked mononuclear interstitial infiltrate (predominantly macrophages) occurs
together with an increase of IP-10, MCP-1, MCP-3, and TCA3 mRNA expression
(169,170,171).
Expression of CINC, MIP-2, and MIP-1 was not detected, and RANTES
expression was low and did not change
(171). A neutralizing MCP-1
antibody reduced interstitial infiltration by macrophages
(169).
The hepatic hydroxymethylglutaryl CoA reductase inhibitor lovastatin suppressed MCP-1 expression by mesangial cells (172) and significantly reduced the interstitial influx of macrophages in the puromycin model (170). These findings are of particular interest, because interstitial infiltrates are a prognostic factor for the progression of human disease (85).
Tubulointerstitial Nephritis
Immunization of Brown Norway rats with bovine tubular basement membrane
induces a severe tubular interstitial nephritis
(173). In this model, MCP-1
mRNA expression precedes an influx of mononuclear cells on day 8 but is no
longer detectable by day 10
(173). The early increase in
CINC and MIP-2 mRNA expression was associated with neutrophil infiltration. A
later expression of MCP-1, MIP-1, and MIP-1ß mRNA correlated with
a monocyte influx (174).
Treatment with a neutralizing MCP-1 antibody or an MCP-1 receptor antagonist
reduced macrophage influx (20 and 60%, respectively)
(Table 6) (174).
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Other Renal Disease Models |
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Injection of diethylaminoethyl dextran leads to proteinuria in Lewis rats but without significant cellular infiltration and without immune complex deposition (176). In this model, strong glomerular localization of RANTES was seen, but apparently was insufficient to cause a cell infiltrate (176).
A model of endotoxemia by LPS injection in Wistar rats leads to glomerular RANTES expression and an influx of macrophages (177). Supplementation with L-arginine, a precursor for nitric oxide (NO) synthesis, reduced the RANTES expression. A nonspecific NO synthase inhibitor resulted in increased RANTES expression and a glomerular infiltrate (177). These studies suggest that the NO pathway may be a counter regulator for LPS-induced RANTES expression and macrophage infiltration.
Chemokine Expression in Unilateral Ureteral Obstruction
Interstitial macrophage infiltration is a prominent feature of unilateral
ureteral obstruction (178).
MCP-1 mRNA is induced by tubular cells in the obstructed kidney
(178,179).
Angiotensin-converting enzyme inhibition and an AT1 antagonist
decreased MCP-1 expression and reduced the macrophage infiltrate and fibrosis
(178).
Chemokine Expression in Renal Ischemia
As early as 1991, Safirstein et al. described the expression of
mRNA of the "early response genes" JE (MCP-1) and KC (GRO-)
during renal ischemia (180).
The induction of MCP-1/JE can be prevented by treatment with
methylprednisolone (128).
Furthermore, renal ischemia causes an upregulation of IL-8 that can be
inhibited by treatment with -melanocyte-stimulating hormone, raising
the possibility that -melanocyte-stimulating hormone may act as a
counter-regulatory hormone for chemokine induction
(181).
Temporary renal pedicle occlusion with simultaneous right nephrectomy resulted in expression of RANTES and MCP-1 after 2 d (182,183). Treatment with bioflavonoids, agents with potential immunosuppressive and renoprotective properties, preserved histologic integrity and renal function, and prevented MCP-1 and RANTES upregulation (183). Blocking the T cell costimulatory molecule B7 by a soluble CTLA4Ig protein resulted in nearly complete suppression of RANTES and MCP-1 (182). Thus, non-immune-mediated injuries can be potent inductors of chemokines, which appear to play an integral role in tissue injury and repair and the associated leukocyte influx, regardless of the initiating insult.
Renal Transplantation
Rat models of transplantation have allowed a functional analysis of the
role of chemokines in acute and chronic renal rejection
(81,184,185).
In acute renal transplant rejection in the rat, Nagano et al. found
that RANTES mRNA was upregulated by 6 h during the initial transplant
rejection phase and again after 3 to 6 d
(185). The authors speculated
that expression of E-selectin and RANTES within the first few hours after
engraftment may occur secondary to ischemic injury and could help trigger
subsequent immunologic events
(185). In addition, they
concluded that macrophages and their products may play a larger role in the
process than previously appreciated
(185).
The functional role of RANTES and its receptors was recently evaluated in rat models of acute renal allograft rejection using the RANTES receptor antagonist Met-RANTES (81). Treatment with Met-RANTES significantly reduced the vascular and tubular damage associated with acute rejection and suppressed mononuclear infiltration (81). Treatment with Met-RANTES and low-dose cyclosporin A markedly attenuated the damage to vessels, tubules, and the interstitial rejection (81). The potential clinical advantage of chemokine antagonists such as Met-RANTES may lie in their early effects on the suppression of cellular infiltration and subsequent graft damage, which may help lower the inclination toward the development of chronic transplant dysfunction.
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Chemokines in Human Kidney Diseases |
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Chemokines and Chemokine Receptors in Glomerular Diseases
The expression of IL-8 and MCP-1
(108,186,188,193)
has been reported In IgA nephropathy. IL-8 mRNA was localized to glomeruli
(188), and MCP-1 protein was
detected in vascular endothelial cells
(188), tubular epithelial
cells
(108,186,188,193),
infiltrating mononuclear cells
(186,188),
and parietal cells of Bowman's capsule
(186). MCP-1 was not seen in
glomeruli that did not show proliferative nephropathy
(144,194).
In mild disease courses, MCP-1 was rarely expressed, whereas severe cases with
interstitial infiltrates showed strong expression of MCP-1, which correlated
well with monocyte infiltration and interstitial damage
(186). Renal function was
found to be significantly worse in patients with detectable MCP-1 expression
(194). In IgA nephropathy,
CCR1, CCR2a, and CCR2b were detected in biopsy tissue by reverse
transcription-PCR (194). A
strong glomerular expression of CXCR3, primarily by mesangial cells, was found
by immunohistochemistry (35).
CXCR3 was also found on infiltrating leukocytes, and endothelial and vascular
smooth muscle cells (35). On
the other hand, CCR5-positive cells are not present in glomeruli, but were a
prominent part of the interstitial infiltrate
(195). In summary, in IgA
nephropathy MCP-1 is expressed by tubulointerstitial cells, and the chemokine
receptors CCR2 and CCR5 are found on inflammatory cells. CXCR3 is expressed on
intrinsic glomerular cells and may act as a mechanism for glomerular mesangial
proliferation (35).
MCP-1 expression has not been found in glomeruli from nonproliferating diseases, such as membranous nephropathy, minimal change disease, thin basement membrane disease, and diabetic nephropathy (144). In contrast to the absence of glomerular chemokine expression in membranous nephropathy, MCP-1 and RANTES were expressed by tubular epithelial cells during proteinuria, and their expression was associated with interstitial cell infiltration and fibrosis (193,196). No CCR5-positive cells were detected within glomeruli during membranous nephropathy, but CCR5-positive mononuclear cells—predominantly CD3-positive T cells—were seen in the interstitium (195). This CCR5-positive T cell infiltrate may be related to the tubulointerstitial damage noted in these biopsies (195).
Chemokines and Chemokine Receptors in Proliferative and Crescentic
Glomerulonephritis
Rovin et al. described the distribution of MCP-1 by
immunohistochemistry in patients with idiopathic crescentic
glomerulonephritis, Wegener's granulomatosis, and lupus nephritis
(144). A focal, granular
staining for MCP-1 with a mesangial distribution (and in some crescents) was
detected (144). Cock-well
et al. studied 20 patients with glomerulonephritis due to different
forms of vasculitis by in situ hybridization
(197). MCP-1, MIP-1,
and MIP-1ß were expressed in some glomeruli at similar levels and in
crescents (197). RANTES
expression was described in 11% of the glomeruli
(197). MCP-1 was not detected
in the glomeruli of patients with lupus nephritis
(189). By in situ
hybridization, patients with lupus nephritis showed MCP-1 expression on
endothelial cells, cortical tubules, and infiltrating mononuclear cells in the
interstitium
(189,197).
In patients with cryoglobulinemic glomerulonephritis, a significant
upregulation of MCP-1 expression was seen in glomeruli and in areas of
tubulointerstitial damage
(191). The MCP-1 was
localized to tubular cells, parietal cells, and cells of the glomerular tuft,
and correlated with glomerular and interstitial macrophage infiltration
(191). The expression of
MIP-1ß and MIP-1 fits with the preliminary observation that
crescents contain CCR5-positive cells
(198). In crescentic
glomerulonephritis, the expression of MIP-1 and MCP-1 was found in
tubules, peritubular capillaries, and infiltrating leukocytes. MIP-1
was also present in crescents
(199). Cockwell et
al. described the distribution of IL-8 mRNA and protein in patients with
antineutrophil cytoplasmic antibody-associated glomerulonephritis
(200). About 30% of the
glomeruli showed IL-8 expression at sites of inflammation. Outside the
glomeruli, IL-8 mRNA was detected in interstitial infiltrates and proximal
tubular epithelial cells. IL-8 protein was present in 50% of the glomeruli and
was prominent in crescents and parietal cells. Intraglomerular leukocyte
accumulation correlated with the IL-8 expression
(200).
Chemokines and Chemokine Receptors in Tubulointerstitial
Diseases
Biopsy samples from patients with acute interstitial nephritis were studied
by In situ hybridization and immunohistochemistry for MCP-1
expression (186). MCP-1 was
expressed by tubular as well as infiltrating cells and was detected in
parietal cells of Bowman's capsule but not within the glomerular tuft. Eitner
et al. described expression of CCR5 mRNA in interstitial infiltrates
(201) that was confirmed by
immunohistochemistry, where CCR5-positive cells correlated with the presence
of an interstitial T cell infiltrate
(195).
Chemokines and Chemokine Receptors during Renal Transplant
Rejection
Acute allograft rejection is characterized by a mononuclear cell infiltrate
consisting primarily of T cells, macrophages, and occasional eosinophils
(202,203).
The chemokines IL-8, ENA-78, MCP-1, MIP-1, MIP-1ß, and RANTES have
all been implicated in the pathogenesis of acute rejection
(204,205,206,207,208,209).
One of the most studied chemokines in this regard is the CC chemokine RANTES
(205,210).
During cell-mediated rejection, in situ hybridization localized
RANTES mRNA to infiltrating cells and tubular epithelium
(210). RANTES protein was
found on mononuclear cells, tubular epithelium, and the vascular endothelium
(205). This expression
mirrors the distribution of CCR5-positive leukocytes found in areas of
endothelialitis, tubulitis, and interstitial infiltrates during cellular
rejection (195). Strehlau and
coworkers used reverse transcription-PCR to evaluate gene expression in human
renal allograft biopsies and concluded that RANTES and IL-8 expression are
sensitive but not specific markers of allograft rejection
(211). Grandaliano et
al. found an increased amount of MCP-1 in uring during rejection
corresponding to elevated renal MCP-1 expression
(204). An increased amount of
urinary IL-8 was described during acute rejection, which returned to normal
levels after successful treatment
(206).
DARC Expression in Kidney Disease
A study of children with HIV-associated nephropathy, HIV-associated
hemolytic uremic syndrome (HUS), and classic HUS
(212) reported DARC mRNA and
protein localized to endothelial cells of postcapillary renal venules in
normal kidney. The biopsies of the patients showed increased DARC expression
on glomerular capillaries, collecting duct epithelial cells, and interstitial
inflammatory cells (212).
DARC upregulation on peritubular endothelium was described during transplant
rejection especially at sites of inflammation in a recent abstract
(213). The role of this
upregulation of DARC during renal diseases is unknown.
Quantification of Urinary Chemokines as a Measure of Renal
Production
Elevated urinary MCP-1 levels occur in proliferative lupus nephritis, IgA
nephropathy, proliferative glomerulonephritis associated with endocarditis,
membranoproliferative glomerulonephritis, crescentic glomerulonephritis, and
in transplant rejection
(187,188,189,190,191,199).
Only moderately increased amounts of MCP-1 have been measured in membranous
nephropathy, focal segmental glomerulosclerosis, and diabetic nephropathy,
consistent with moderate glomerular cell infiltration in these diseases
(190). Urinary MCP-1 levels
correlated with urinary protein excretion and macrophage infiltration of the
glomeruli (190). No
correlation between serum and urine MCP-1 was seen
(187).
High urinary MCP-1 excretion was found in patients with active lupus
nephritis compared with healthy control subjects
(189,190,192).
Urinary MCP-1 levels were reduced by highdose glucocorticoid therapy and
remained low during remission
(187,189,192).
Elevated urinary excretion of MCP-1 and MIP-1 was also reported in
patients with crescentic glomerulonephritis, and treatment reduced excretion
of both chemokines (199).
Similar results were reported for IL-8, with high levels seen during severe
lupus nephritis, and a significant reduction in IL-8 levels was seen after
glucocorticoid therapy
(187,189).
A correlation between urinary MCP-1 levels, mesangial proliferation, and interstitial infiltrate has been described in IgA nephropathy (186,188). Patients with severe IgA nephropathy showed higher MCP-1 levels compared with patients with mild disease (186). IL-8 levels were only elevated during the acute phase and correlated with glomerular endocapillary proliferation and the degree of hematuria (188).
Other renal diseases that present elevated levels of IL-8 include acute postinfectious glomerulonephritis, membranoproliferative glomerulonephritis, and cryoglobulinemia (187). The urinary IL-8 levels were higher in patients with glomerular leukocyte infiltration than in those without infiltration (187). Children with HUS showed a significant increase in both IL-8 and MCP-1 excretion (214). Thus, urinary excretion of chemokines may reflect the intrarenal inflammatory cell infiltrate and may be of prognostic value as a measure of continued intrarenal inflammation.
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A Model for Chemokines in Renal Diseases |
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, IFN-, plateletactivating factor, reactive
oxygen species, etc.), promotes the upregulation and activation of selectins
and integrins on leukocytes and endothelial cells leading to adhesion,
transendothelial migration, and infiltration of specific subsets of
leukocytes. T cells, monocytes, and polymorphonuclear leukocytes appear to
preferentially adhere to different microvascular compartments in the kidney.
For example, T cells are rare in glomeruli but are common in interstitial
infiltrates. The specialized endothelia found in the kidney, e.g.,
glomerular, peritubular, have different characteristics, but at present
information on the surface expression of selectin ligands is lacking
(215). The role of this
endothelial heterogeneity in the kidney for the leukocyte adhesion and
infiltration process remains to be elucidated.
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An additional consequence of local cell activation may include the induced expression of chemokine receptors such as CCR1 and CXCR3 by mesangial cells, and other renal cell types. The expression of CXCR3 by mesangial cells in concert with local production of the chemokine IP-10 could lead to mesangial cell proliferation (35).
During the "amplification phase," spillover of proinflammatory factors from affected glomeruli could reach the peritubular capillary circulation, as well as the tubular lumen via ultrafiltration, especially in the context of proteinuria with loss of the ultrafiltration barrier. In addition, protein and lipids escaping through damaged glomeruli could "stress" proximal tubular cells. In concert with inflammatory mediators, this could lead to an activation of tubular and interstitial cells and the production of additional chemokines, resulting in interstitial mononuclear cell infiltration. Similarly, the parietal cells of Bowman's capsule apparent bystander cells in this process could become activated and thus release chemokines into the surrounding interstitium. This sort of event could help explain the accentuated periglomerular infiltrate seen in some renal diseases. The periglomerular infiltrate may play a role in the eventual rupture of Bowman's capsule, which would open the door for T cells, macrophages, and fibroblasts to invade the urinary space and damage the parietal and visceral epithelial cells. This could be an example of the "point of no return," in which amplification of a glomerular injury results in irreversible sclerosis. Thus, a cycle initiated through glomerular damage could, in the absence of sufficient counter-regulatory signals, result in downstream tubular-interstitial injury, interstitial inflammation, and fibrosis (progression phase) (Figure 1D).
Of course, renal inflammation does not always end with chronic damage. The events initiated during inflammation normally end in resolution of the disease process. Recent results suggest that some chemokines and their receptors may also assist in downmodulating the inflammatory response, a hypothesis that deserves further investigation.
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Conclusions, Future Directions, and Therapeutic Outlook |
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B (217), and
blockade of NF-B function leads to suppression of chemokine release by
renal cells
(51,218).
Elevated urinary chemokines in human lupus nephritis are decreased by
glucocorticoid therapy
(187,189,190,192).
Glucocorticoid suppression of chemokine expression may be one component of the
general beneficial effects of glucocorticoid therapy seen in lupus
nephritis. In animal models, a connection between angiotensin II, chemokine production by renal cells (122), and beneficial effects of angiotensin blockade were described (122,125,178). Thus, a reduction in chemokine production may be one beneficial effect of angiotensin-blocking drugs in the treatment of renal disease.
The side effects of nonsteroidal anti-inflammatory drugs (NSAID) are well established and are mostly related to alterations in renal hemodynamics and transport (219). The rare NSAID-related nephrotic syndrome and interstitial nephritis are thought to result from immunologic effects of these drugs (219). In this context, it is of interest that PGE suppresses chemokine production in mesangial cells and chemokine receptor expression on monocytes-macrophages (53,220). Therefore, PGE and possibly PGI2 may also inhibit chemokine production. This is supported by studies in the Thy 1.1 model, in which PGE administrati
