Impaired pulmonary host defense in mice lacking expression of the CXC chemokine lungkine

Lungkine (CXCL15) is a novel CXC chemokine that is highly expressed in the adult mouse lung. To determine the biologic function of Lungkine, we generated Lungkine null mice by targeted gene disruption. These mice did not differ from wild-type mice in their hematocrits or in the relative number of cells in leukocyte populations of peripheral blood or other tissues, including lung and bone marrow. However, Lungkine null mice were more susceptible to Klebsiella pneumonia infection, with a decreased survival and increased lung bacterial burden compared with infected wild-type mice. Histologic analysis of the lung and assessment of leukocytes in the bronchioalveolar lavage revealed that neutrophil numbers were normal in the lung parenchyma, but reduced in the airspace. The production of other neutrophil chemoattractants in the Lungkine null mice did not differ from that in wild-type mice, and neutrophil migration into other tissues was normal. Taken together, these findings demonstrate that Lungkine is an important mediator of neutrophil migration from the lung parenchyma into the airspace.     

Generation and characterization of mice lacking the zinc uptake transporter ZIP3

The mouse ZIP3 (SLC39A3) gene encodes an eight-transmembrane-domain protein that has been conserved in mammals and can function to transport zinc. To analyze the expression of ZIP3 in the early embryo and neonate and to determine its in vivo function, we generated ZIP3 null mice in which the ZIP3 open reading frame was replaced with that of the enhanced green fluorescent protein (EGFP) reporter. EGFP fluorescence revealed that ZIP3 was expressed in the inner cell mass of the blastocyst and later during embryonic development in many tissues. Elevated expression was apparent in the embryonic brain and neurotube and neonatal gonads. Homozygous knockout mice were viable and fertile and under normal growth conditions exhibited no obvious phenotypic abnormalities. Deletion of ZIP3 did not alter zinc homeostasis at the molecular level as assessed by essential metal levels and the expression of zinc-responsive genes. In knockout mice stressed with a zinc-deficient diet during pregnancy or at weaning, a subtle increase in the sensitivity to abnormal morphogenesis of the embryo and to depletion of thymic pre-T cells, respectively, was noted. These results suggest that this protein plays an ancillary role in zinc homeostasis in mice.     

The chemokine fractalkine inhibits Fas-mediated cell death of brain microglia

Fractalkine is a CX3C-family chemokine, highly and constitutively expressed on the neuronal cell surface, for which a clear CNS physiological function has yet to be determined. Its cognate receptor, CX3CR-1, is constitutively expressed on microglia, the brain-resident macrophages; however, these cells do not express fractalkine. We now show that treatment of microglia with fractalkine maintains cell survival and inhibits Fas ligand-induced cell death in vitro. Biochemical characterization indicates that this occurs via mechanisms that may include 1) activation of the phosphatidylinositol-3 kinase/protein kinase B pathway, resulting in phosphorylation and blockade of the proapoptotic functions of BAD; 2) up-regulation of the antiapoptotic protein Bcl-xL; and 3) inhibition of the cleavage of BH3-interacting domain death agonist (BID). The observation that fractalkine serves as a survival factor for primary microglia in part by modulating the protein levels and the phosphorylation status of Bcl-2 family proteins reveals a novel physiological role for chemokines. These results, therefore, suggest that the interaction between fractalkine and CX3CR-1 may play an important role in promoting and preserving microglial cell survival in the CNS.     

Unresolved questions from the analysis of mice lacking MCU expression

Entry of mitochondrial calcium is believed to play an essential role in regulating bioenergetics and initiating cell death pathways. We have recently described a mouse model lacking MCU expression. Surprisingly, these mice are viable and the cells and tissues from these animals do not exhibit any marked protection from cell death. Here, we discuss our findings as well as potential explanations for some of the more unexpected results.     

Molecular determinants of receptor binding and signaling by the CX3C chemokine fractalkine.

Fractalkine/CX3CL1 is a membrane-tethered chemokine that functions as a chemoattractant and adhesion protein by interacting with the receptor CX3CR1. To understand the molecular basis for the interaction, an extensive mutagenesis study of fractalkine's chemokine domain was undertaken. The results reveal a cluster of basic residues (Lys-8, Lys-15, Lys-37, Arg-45, and Arg-48) and one aromatic (Phe-50) that are critical for binding and/or signaling. The mutant R48A could bind but not induce chemotaxis, demonstrating that Arg-48 is a signaling trigger. This result also shows that signaling residues are not confined to chemokine N termini, as generally thought. F50A showed no detectable binding, underscoring its importance to the stability of the complex. K15A displayed unique signaling characteristics, eliciting a wild-type calcium flux but minimal chemotaxis, suggesting that this mutant can activate some, but not all, pathways required for migration. Fractalkine also binds the human cytomegalovirus receptor US28, and analysis of the mutants indicates that US28 recognizes many of the same epitopes of fractalkine as CX3CR1. Comparison of the binding surfaces of fractalkine and the CC chemokine MCP-1 reveals structural details that may account for their dual recognition by US28 and their selective recognition by host receptors.     

The crystal structure of the chemokine domain of fractalkine shows a novel quaternary arrangement

Fractalkine, or neurotactin, is a chemokine that is present in endothelial cells from several tissues, including brain, liver, and kidney. It is the only member of the CX(3)C class of chemokines. Fractalkine contains a chemokine domain (CDF) attached to a membrane-spanning domain via a mucin-like stalk. However, fractalkine can also be proteolytically cleaved from its membrane-spanning domain to release a freely diffusible form. Fractalkine attracts and immobilizes leukocytes by binding to its receptor, CX(3)CR1. The x-ray crystal structure of CDF has been solved and refined to 2.0 A resolution. The CDF monomers form a dimer through an intermolecular beta-sheet. This interaction is somewhat similar to that seen in other dimeric CC chemokine crystal structures. However, the displacement of the first disulfide in CDF causes the dimer to assume a more compact quaternary structure relative to CC chemokines, which is unique to CX(3)C chemokines. Although fractalkine can bind to heparin in vitro, as shown by comparison of electrostatic surface plots with other chemokines and by heparin chromatography, the role of this property in vivo is not well understood.     

Peptide fragments of the fractalkine chemokine domain: Influence on migration of human monocytes

The CX3CL1 Fractalkine is the sole cytokine of the CX3C family. Its molecule consists of an extracellular N-terminal chemokine domain, a mucin-like rod, a transmembrane domain, and an intracellular domain. Fractalkine exhibits the properties of an adhesion molecule in the membrane-bound state. The fractalkine chemokine domain (FCD) is proteolytically released from a cellular membrane in a soluble form. It acts as a chemoattractant for leukocytes which express the CX3CR1 fractalkine receptor. Fractalkine participates in the development of a number of pathological inflammation-mediated processes. Therefore, a search for its inhibitors is an urgent problem. We determined the FCD antigenic determinants and synthesized the corresponding peptides: P41-52 H-Leu-Glu-Thr-Arg-Gln-His-Arg-Leu-Phe-Cys-Ala-Asp-NH₂, P53-60 H-Pro-Lys-Glu-Gln-Trp-Val-Lys-Asp-NH₂, and P60-71 H-Asp-Ala-Met-Gln-His-Leu-Asp-Arg-Gln-Ala-Ala-Ala-NH₂. The biological activity of these peptides was evaluated according to their action on the adhesion and migration of human peripheral blood monocytes which expressed the fractalkine receptor. FCD and the P41-52 peptide significantly increased monocyte adhesion and migration in comparison with the corresponding spontaneous adhesion and migration of the cells. The P53-60 and P60-71 peptides inhibited the FCD-stimulated monocyte adhesion and migration. We analyzed the influence of the prepared peptides on the interaction of FCD with heparin by EIA, because binding of chemokines to glycosaminoglycans of cellular surface and extracellular matrix was one of the conditions of the chemokine migration activity. The P41?C52 peptide competed with FCD for the heparin binding, whereas the P53?C60 and P60?C71 peptides had no significant effect.     

Urinary protein analysis in mice lacking major urinary proteins

Mouse urine contains major urinary proteins (MUPs) that are not found in human urine. Therefore, even healthy mice exhibit proteinuria, unlike healthy humans, making it challenging to use mice as models for human diseases. It was also unknown whether dipsticks for urinalysis could measure protein concentrations precisely in urine containing MUPs. To resolve these problems, we produced MUP-knockout (Mup-KO) mice by removing the Mup gene cluster using Cas9 proteins and two guide RNAs and characterized the urinary proteins in these mice. We measured the urinary protein concentrations in Mup-KO and wild-type mice using a protein quantitation kit and dipsticks. We also examined the urinary protein composition using SDS-PAGE and two-dimensional electrophoresis (2DE). The urinary protein concentration was significantly lower (P<0.001) in Mup-KO mice (17.9 ± 1.8 mg/dl, mean ± SD, n=3) than in wild-type mice (73.7 ± 8.2 mg/dl, n=3). This difference was not reflected in the dipstick values, perhaps due to the low sensitivity to MUPs. This suggests that dipsticks have limited ability to measure changes in MUPs with precision. SDS-PAGE and 2DE confirmed that Mup-KO mice, like humans, had no MUPs in their urine, whereas wild-type mice had abundant MUPs in their urine. The absence of the masking effect of MUPs in 2DE would enable clear comparisons of urinary proteins, especially low-molecular-weight proteins. Thus, Mup-KO mice may provide a useful model for human urinalysis.     

Ultrastructure and function of the fractalkine mucin domain in CX(3)C chemokine domain presentation

Fractalkine (FKN), a CX(3)C chemokine/mucin hybrid molecule on endothelium, functions as an adhesion molecule to capture and induce firm adhesion of a subset of leukocytes in a selectin- and integrin-independent manner. We hypothesized that the FKN mucin domain may be important for its function in adhesion, and tested the ability of secreted alkaline phosphatase (SEAP) fusion proteins containing the entire extracellular region (FKN-SEAP), the chemokine domain (CX3C-SEAP), or the mucin domain (mucin-SEAP) to support firm adhesion under flow. CX3C-SEAP induced suboptimal firm adhesion of resting peripheral blood mononuclear cells, compared with FKN-SEAP, and mucin-SEAP induced no firm adhesion. CX3C-SEAP and FKN-SEAP bound to CX(3)CR1 with similar affinities. By electron microscopy, fractalkine was 29 nm in length with a long stalk (mucin domain), and a globular head (CX(3)C). To test the function of the mucin domain, a chimeric protein replacing the mucin domain with a rod-like segment of E-selectin was constructed. This chimeric protein gave the same adhesion of peripheral blood mononuclear cells as intact FKN, both when immobilized on glass and when expressed on the cell surface. This implies that the function of the mucin domain is to provide a stalk, extending the chemokine domain away from the endothelial cell surface to present it to flowing leukocytes.     

Generation and analysis of Siah2 mutant mice

Siah proteins function as E3 ubiquitin ligase enzymes to target the degradation of diverse protein substrates. To characterize the physiological roles of Siah2, we have generated and analyzed Siah2 mutant mice. In contrast to Siah1a knockout mice, which are growth retarded and exhibit defects in spermatogenesis, Siah2 mutant mice are fertile and largely phenotypically normal. While previous studies implicate Siah2 in the regulation of TRAF2, Vav1, OBF-1, and DCC, we find that a variety of responses mediated by these proteins are unaffected by loss of Siah2. However, we have identified an expansion of myeloid progenitor cells in the bone marrow of Siah2 mutant mice. Consistent with this, we show that Siah2 mutant bone marrow produces more osteoclasts in vitro than wild-type bone marrow. The observation that combined Siah2 and Siah1a mutation causes embryonic and neonatal lethality demonstrates that the highly homologous Siah proteins have partially overlapping functions in vivo.     

Altered fractalkine cleavage results in an organ-specific 17 kDa fractalkine fragment in salivary glands of NOD mice

Sjögren''s syndrome is a rheumatic disease in which the salivary and lacrimal glands are the principal targets of a pathological autoimmune reaction. Previous studies in mice indicated that delayed organogenesis and aberrant cell physiology followed by an increase in acinar cell apoptosis precede chronic focal inflammation in the salivary glands and the manifestation of impaired exocrine gland secretion. In a recent study by Wildenberg and colleagues, the authors report aberrant proteolytic activity in the salivary glands of non-obese diabetic mice and the generation of a unique organ-specific 17 kDa fragment of the chemokine and adhesion molecule fractalkine.In the previous issue of Arthritis Research & Therapy, aberrant proteolytic activity in the salivary glands of non-obese diabetic (NOD) mice with spontaneous experimental Sjögren''s syndrome (SS) was reported [1]. SS is a rather common systemic autoimmune disease characterized by exocrine gland inflammation and impaired glandular function [2]. The NOD strain has become a commonly used spontaneous model for SS in which several SS-related hypotheses have been developed or tested. Although the initiating event leading to the accumulation of mononuclear cells in the exocrine glands is unknown, studies in NOD mice and related congenic strains carrying the Aec1 and Aec2 loci showed aberrant proteolytic activity [3], elevated apoptosis and activated interferon-γ, Toll-like receptor (TLR)3 and TLR7 associated pathways in the salivary glands prior to manifestation of the disease [4].Wildenberg and colleagues [1] now provide evidence that fractalkine is cleaved to a unique organ-specific 17 kDa fragment in the salivary glands of NOD mice. This phenomenon was observed from as early as 10 weeks of age. At this time-point the mice probably displayed a pre-disease or sub-clinical stage of SS [5]. Altered cleavage was subsequently observed until 20 weeks of age when SS in NOD mice is thought to have advanced to an overt disease stage [5]. Unfortunately, the protease involved in the cleavage of this apparently unique and organ-specific17 kDa fragment has not yet been identified. The cleavage, however, did not seem to depend on Caspase-3, ADAM-10, ADAM-17, MMP-2 and/or MMP-9 activity [1]. Throughout the same period of time, NOD mice presented autoantibodies recognizing 31 kDa fractalkine.The authors mainly discuss their finding from the perspective of fractalkine as a potentially new autoantigen in SS [1]. Although such hypotheses are highly speculative considering the present core of knowledge, we believe that chemokines in general, and fractalkine in particular, deserve more attention in SS research. We recently found specific chemokines to be associated with different aspects of experimental SS [6], and prevention of hyposalivation in NOD mice through administration of heat-shock protein 60 kDa coincided with normalization of multiple chemokine levels in saliva [7].In contrast to other chemokines, fractalkine can be found in two specific forms, which allows fractalkine to participate in very distinct biological processes. Soluble fractalkine acts as a potent chemotactic factor for monocytes, natural killer (NK)-cells, and T-cells expressing CX3C receptor (CX3R)1. In addition, a membrane-anchored form, which is unusual for chemokines, is expressed on endothelial cells and also several cell types associated with exocrine glands [8]. To what extent fractalkine expression patterns might be altered in salivary glands obtained from patients with SS in comparison with viral infections or homeostatic conditions, however, remains to be investigated [8].By acting as an adhesion molecule, membrane-bound frac-talkine may facilitate extravasation of CX3CR1-expressing leukocytes [9,10]. In addition, CX3CR1 appears to be a selective surface marker for leukocyte subsets, which exert cytotoxic effector functions. Fractalkine may also lead to increased interferon-γ, tumor necrosis factor-γ and granulocyte monocyte colony stimulating factor production by NK-cells and other cell subsets that have been suggested to play a role in the initiation phase and pathogenesis of inflammatory conditions, such as atherosclerosis [10], glomerulonephritis [9] and rheumatoid arthritis (RA) [9]. Although these disorders are multifactorial in nature, exposure to microbial agents is thought to play a role in their initiation [2,9,10]. Several viral proteins were reported to bind a broad spectrum of mediators of the immune system, including fractalkine [8]. Specific gene polymorphisms have been reported to be risk factors for coronary heart disease [10] and deletion of CX3CR1 in apolipoprotein E deficient mice reduced atherosclerotic lesion formation [10]. Fractalkine has also been associated with the pathogenesis of RA after fractalkine and CX3CR1 expression were reported to be upregulated in the synovium of patients with RA [9]. Supporting the notion of the disease-modulating activity of fractalkine in RA, administration of anti-fractalkine antibodies ameliorated experimental RA [9]. With regard to diseases involving the kidneys, a viral fractalkine antagonist reduced kidney inflammation and proteinurea in the Wistar-Kyoto crescentic glomerulonephritis model [9]. In concordance, anti-CX3CR1 blocked lymphocytic infiltration and the development of subsequent stages of glomerulonephritis in these rats [9]. In MRL^lpr mice a truncated fractalkine analogue with the capability of antagonizing the actions of fractalkine also significantly ameliorated several aspects of lupus nephritis and vasculitis [9].The findings reported by Wildenberg and colleagues add the aspect of organ-specific cleavage of fractalkine to its potential role in a specific autoimmune condition. Unfortunately, the report does not address the effect of altered cleavage on fractalkine''s biological activities, for example, chemotaxis. Based on the results presented it is therefore difficult to speculate if fractalkine, through altered cleavage, might be rendered either more potent or less efficient with regard to certain of its actions. The study by Wildenberg and colleagues provides, however, a rationale for conducting such functional studies in the future. In parallel, it would be interesting to address if the described autoantibodies might have the potential to modulate fractalkine related inflammatory processes.     

Fancm基因敲除小鼠构建及其表型分析

目的构建范可尼贫血通路Fancm基因敲除小鼠,研究Fancm基因缺失对小鼠生理功能,特别是雄性生殖器官的影响。方法采用CRISPR/Cas9技术,获得Fancm基因敲除小鼠。分析FANCM蛋白在野生型和Fancm^-/-小鼠睾丸组织中的表达。统计Fancm^-/-小鼠的出生率、体重、性别比例及子代生育情况,分析血液常规指标。组织形态学研究雄性Fancm^-/-小鼠睾丸生理病理表型。结果敲除Fancm基因ATG区域,获得稳定遗传的C57BL/6背景Fancm^-/-小鼠。Fancm^-/-小鼠睾丸中FANCM蛋白表达完全丢失。Fancm^-/-小鼠无明显的胚胎致死现象,但雌性Fancm-/-小鼠数目显著少于雄性Fancm^-/-小鼠。同窝Fancm^-/-小鼠比较野生型体重无明显区别,部分血常规指标有显著性差异。Fancm^-/-小鼠有明显的生殖能力缺陷。雄性Fancm^-/-小鼠睾丸有显著的发育缺陷,其生精细胞凋亡增加、细胞周期阻滞,影响睾丸发育与精子的生成。结论成功获得稳定遗传C57BL/6背景Fancm^-/-小鼠,Fancm基因参与小鼠的生长发育,特别是雄性生殖器官功能的维持及调控。     

Phenotypic analysis of seizure-prone mice lacking L-isoaspartate (D-aspartate) O-methyltransferase.

Within proteins and peptides, both L-asparaginyl and L-aspartyl residues spontaneously degrade, generating isomerized and racemized aspartyl residues. The enzyme protein L-isoaspartate (D-aspartate) O-methyltransferase (E.C. 2.1.1.77) initiates the conversion of L-isoaspartyl and D-aspartyl residues to normal L-aspartyl residues. This "repair" reaction helps to maintain proper protein conformation by preventing the accumulation of damaged proteins containing abnormal amino acid residues. Pcmt1-/- mice manifest two key phenotypes: a fatal seizure disorder and retarded growth. In this study, we characterized both phenotypes and demonstrated that they are linked. Continuous electroencephalogram monitoring of Pcmt1-/- mice revealed that abnormal cortical activity for approximately 50% of each 24-h period, even in mice that had no visible evidence of convulsions. The fatal seizure disorder in Pcmt1-/- mice can be mitigated but not eliminated by antiepileptic drugs. Interestingly, antiepileptic therapy normalized the growth of Pcmt1-/- mice, suggesting that the growth retardation is due to seizures rather than a global disturbance in growth at the cellular level. Consistent with this concept, the growth rate of Pcmt1-/- fibroblasts was indistinguishable from that of wild-type fibroblasts.     

Mutational analysis of the fractalkine chemokine domain. Basic amino acid residues differentially contribute to CX3CR1 binding, signaling, and cell adhesion

Fractalkine (FKN/CX3CL1) is a unique member of the chemokine gene family and contains a chemokine domain (CD), a mucin-like stalk, a single transmembrane region, and a short intracellular C terminus. This structural distinction affords FKN the property of mediating capture and firm adhesion of FKN receptor (CX3CR1)-expressing cells under physiological flow conditions. Shed forms of FKN also exist, and these promote chemotaxis of CX3CR1-expressing leukocytes. The goal of the present study was to identify specific residues within the FKN-CD critical for FKN-CX3CR1 interactions. Two residues were identified in the FKN-CD, namely Lys-7 and Arg-47, that are important determinants in mediating an FKN-CX3CR1 interaction. FKN-K7A and FKN-R47A mutants exhibited 30-60-fold decreases in affinity for CX3CR1 and failed to arrest efficiently CX3CR1-expressing cells under physiological flow conditions. However, these mutants had differential effects on chemotaxis of CX3CR1-expressing cells. The FKN-K7A mutant acted as an equipotent partial agonist, whereas the FKN-R47A mutant had marked decreased potency and efficacy in measures of chemotactic activity. These data identify specific structural features of the FKN-CD that are important in interactions with CX3CR1 including steady state binding, signaling, and firm adhesion of CX3CR1-expressing cells.     

Characterization of mice lacking the gene for cholecystokinin

CCK acts peripherally as a satiating peptide released during meals in response to lipid feeding and centrally functions in the modulation of feeding, exploratory, and memory activities. The present study determined metabolic parameters, food intake, anxiety-like behaviors, and cognitive function in mice lacking the CCK gene. We studied intestinal fat absorption, body composition, and food intake of CCK knockout (CCK-KO) mice by using the noninvasive measurement of intestinal fat absorption along with quantitative magnetic resonance (QMR) imaging and the DietMax system, respectively. Additionally, exploratory and memory capacities were assessed by monitoring running wheel activity and conducting elevated plus-maze and Morris water-maze tests with these mice. Compared with wild-type (WT) littermate controls, CCK-KO mice had normal food intake, fat absorption, body weight, and body mass. CCK-KO mice ate more food than control animals during the light period and less food during the dark period. Energy expenditure was unchanged between the genotypes; however, CCK-KO mice displayed greater fatty acid oxidation. CCK-KO mice were as active as WT animals in the running wheel test. CCK-KO mice spent more time in the closed arms of an elevated plus-maze, indicative of increased anxiety. Additionally, CCK-KO mice exhibited attenuated performance in a passive avoidance task and impaired spatial memory in the Morris water maze test. We conclude that CCK is involved in metabolic rate and is important for memory and exploration. CCK is intimately involved in multiple processes related to cognitive function and food intake regulation.     

Unique role of the chemokine domain of fractalkine in cell capture. Kinetics of receptor dissociation correlate with cell adhesion

The chemokine fractalkine (FK) has two structural features that make it unique in the chemokine family: a CX(3)C motif and an extended carboxyl terminus that anchors it to the cell surface. This mucin-like stalk or an equivalent spacer is required for FK to mediate the adhesion of cells expressing its receptor, CX(3)CR1. To determine whether the ability of FK to act as a cell adhesion molecule is due to the unique presentation of a chemokine domain on a stalk or to properties of the chemokine domain itself, we created a series of chimeras in which other soluble chemokines (RANTES (regulated on activation normal T cell expressed), monocyte chemoattractant protein 1, macrophage inflammatory protein 1 beta, secondary lymphoid tissue chemokine, and interleukin 8) were fused to the mucin stalk. When tested in a static-cell adhesion assay, many of these chemokine chimeras demonstrated activity equivalent to that of FK. In flow assays, however, none of the chimeras captured cells as efficiently as FK. Interestingly, FK captured cells expressing either CX(3)CR1 or the viral receptor US28. Cells bound to FK without rolling or detaching, whereas the interleukin 8 and monocyte chemoattractant protein 1 chimeras induced primarily cell rolling and detaching, respectively. In binding studies, FK has a significantly slower off-rate from its receptors than any of the other chemokine chimeras had for their cognate receptors. We conclude that presentation of a chemokine atop a mucin-like stalk is not, in and of itself, sufficient to capture cells. The unique ability of FK to mediate adhesion under flow may be a function of its slow receptor off-rate.     

Characterization of chemokine and chemokine receptor expression during Pneumocystis infection in healthy and immunodeficient mice

We examined gene expression levels of multiple chemokines and chemokine receptors during Pneumocystis murina infection in wild-type and immunosuppressed mice, using microarrays and qPCR. In wild-type mice, expression of chemokines that are ligands for Ccr2, Cxcr3, Cxcr6, and Cxcr2 increased at days 32–41 post-infection, with a return to baseline by day 75–150. Concomitant increases were seen in Ccr2, Cxcr3, and Cxcr6, but not in Cxcr2 expression. Induction of these same factors also occurred in CD40-ligand and CD40 knockout mice but only at a much later time-point, during uncontrolled Pneumocystis pneumonia (PCP). Expression of CD4 Th1 markers was increased in wild-type mice during clearance of infection. Ccr2 and Cx3cr1 knockout mice cleared Pneumocystis infection with kinetics similar to wild-type mice, and all animals developed anti-Pneumocystis antibodies. Upregulation of Ccr2, Cxcr3, and Cxcr6 and their ligands supports an important role for T helper cells and mononuclear phagocytes in the clearance of Pneumocystis infection. However, based on the current and prior studies, no single chemokine receptor appears to be critical to the clearance of Pneumocystis.