Mark S. Rutherford

Mechanisms generating functionally heterogeneous macrophages: chaos revisited

Macrophage populations exhibit a wide range of antigenic and functional phenotypes, including cytokine production, response to immunomodulatory stimuli, and clearance of pathogens. The expanding clinical exploitation of recombinant growth factors and cytokines with the potential to regulate the production and function of peripheral macrophage populations necessitates an increased understanding of the mechanisms by which functionally distinct macrophage populations arise as well as the ramifications of macrophage heterogeneity. The present review summarizes recent data which supports multiple mechanisms by which heterogeneous macrophage populations arise: 1) differential signals experienced within diverse tissue microenvironments; 2) developmentally‐staged expression of specific functions; 3) clonal variation of myeloid progenitor cells; and 4) alternate hematopoietic stimulation. These data show that the above processes are not mutally exclusive and that each likely contributes to the observed heterogeneity of peripheral macrophage populations.

Swine in biomedical research: Creating the building blocks of animal models

The opportunities for utilizing swine biomedical models are immense, particularly in models that address lifestyle issues (nutrition, stress, alcohol, drugs of abuse, etc.). However, in order to fully capitalize upon the promise, there needs to be a more general recognition of these cofactors, such as nutrition, as key modulators of phenotype via genomic, epigenetic, and postgenomic mechanisms. Furthermore, increased interactions between nutrition scientists and clinical and fundamental researchers in other disciplines, including developmental biology, immunology, neuroscience, oncology, and cardiovascular and gastrointestinal physiology, are required. Closing discussions focused on the need for future conferences at more frequent intervals to support interactions between the various disciplines. This was especially critical because of the global distribution of investigators.

The Porcine Reproductive and Respiratory Syndrome Virus nsp2 Cysteine Protease Domain Possesses both trans- and cis-Cleavage Activities

ABSTRACT The N terminus of the replicase nonstructural protein 2 (nsp2) of porcine reproductive and respiratory syndrome virus (PRRSV) contains a putative cysteine protease domain (PL2). Previously, we demonstrated that deletion of either the PL2 core domain (amino acids [aa] 47 to 180) or the immediate downstream region (aa 181 to 323) is lethal to the virus. In this study, the PL2 domain was found to encode an active enzyme that mediates efficient processing of nsp2-3 in CHO cells. The PL2 protease possessed both trans- and cis-cleavage activities, which were distinguished by individual point mutations in the protease domain. The minimal size required to maintain these two enzymatic activities included nsp2 aa 47 to 240 (Tyr47 to Cys240) and aa 47 to 323 (Tyr47 to Leu323), respectively. Introduction of targeted amino acid mutations in the protease domain confirmed the importance of the putative Cys55- His124 catalytic motif for nsp2/3 proteolysis in vitro, as were three additional conserved cysteine residues (Cys111, Cys142, and Cys147). The conserved aspartic acids (e.g., Asp89) were essential for the PL2 protease trans-cleavage activity. Reverse genetics revealed that the PL2 trans-cleavage activity played an important role in the PRRSV replication cycle in that mutations that impaired the PL2 protease trans function, but not the cis activity, were detrimental to viral viability. Lastly, the potential nsp2/3 cleavage site was probed. Mutations with the largest impact on in vitro cleavage were at or near the G1196|G1197 dipeptide.

Bovine monocyte TLR2 receptors differentially regulate the intracellular fate of Mycobacterium avium subsp. paratuberculosis and Mycobacterium avium subsp. avium.

Pathogenic mycobacterial organisms have the capacity to inhibit macrophage activation and phagosome maturation. Although the mechanism is complex, several studies have incriminated signaling through TLR2 receptors with subsequent activation of the MAPK pathway p38 (MAPKp38) and overproduction of IL‐10 in the survival of pathogenic mycobacterial organisms. In the present study, we compared the response of bovine monocytes with infection by Mycobacterium avium subspecies paratuberculosis (MAP), the cause of paratuberculosis in ruminants, with the closely related organism M. avium subspecies avium (Maa), which usually does not cause disease in ruminants. Both MAP and Maa induced phosphorylation of MAPKp38 by bovine monocytes; however, addition of a blocking anti‐TLR2 antibody partially prevented MAPKp38 phosphorylation of MAP‐infected monocytes but not Maa‐infected monocytes. Addition of anti‐TLR2 antibody enhanced phagosome acidification and phagosome‐lysosome fusion in MAP‐containing phagosomes and enabled monocytes to kill MAP organisms. These changes were not observed in Maa‐infected monocytes. The effect on phagosome maturation appears to occur independently from the previously described inhibitory effects of IL‐10 on phagosome acidification and organism killing, as IL‐10 production was not affected by addition of anti‐TLR2 antibody to monocyte cultures. Therefore, signaling through the TLR2 receptor appears to play a role in phagosome trafficking and antimicrobial responses in MAP‐infected bovine mononuclear phagocytes.

Differential immunocompetence of macrophages derived using macrophage or granulocyte-macrophage colony-stimulating factor.

Macrophages derived in vitro from bone marrow progenitors (bone marrow–derived macrophages, BMDMs) using either macrophage colony‐stimulating factor (CSF‐1) or granulocyte‐macrophage colony‐stimulating factor (GM‐CSF) as the myelopoietic stimulus display differential functional, morphological, and mRNA phenotypes. The data presented here demonstrate further that CSF‐1– and GM‐CSF–derived BMDMs differ in immunologic capacity. GM‐CSF–derived BMDMs, when compared to CSF‐1–derived BMDMs, showed greater cytolytic activity against tumor necrosis factor α (TNF‐α)–resistant, but not TNF‐α–sensitive, tumor targets. In contrast, CSF‐1–derived BMDMs produced nitrite in response to lipopolysaccharide (LPS) alone, whereas GM‐CSF–derived BMDMs required interferon γ plus LPS treatment. The two BMDM populations also showed differential sensitivities to LPS for secretion of TNF‐α and nitrite, but the maximal inducible amounts of these factors and prostaglandin E2 were similar between the BMDM populations. Lastly, GM‐CSF–derived but not CSF‐1–derived BMDMs showed an L‐arginine–dependent listeriacidal activity. These results show that the functional heterogeneity of CSF‐1– and GM‐CSF–derived macrophages is limited and appears to result largely from differences in the activational signals required by each BMDM population to elicit a given function.

Biphasic Modulation of Apoptotic Pathways in Cryptosporidium parvum-Infected Human Intestinal Epithelial Cells

ABSTRACT The impact of Cryptosporidium parvum infection on host cell gene expression was investigated by microarray analysis with an in vitro model using human ileocecal HCT-8 adenocarcinoma cells. We found changes in 333 (2.6%) transcripts at at least two of the five (6, 12, 24, 48, and 72 h) postinfection time points. Fifty-one of the regulated genes were associated with apoptosis and were grouped into five clusters based on their expression patterns. Early in infection (6 and 12 h), genes with antiapoptotic roles were upregulated and genes with apoptotic roles were downregulated. Later in infection (24, 48, and 72 h), proapoptotic genes were induced and antiapoptotic genes were downregulated, suggesting a biphasic regulation of apoptosis: antiapoptotic state early and moderately proapoptotic state late in infection. This transcriptional profile matched the actual occurrence of apoptosis in the infected cultures. Apoptosis was first detected at 12 h postinfection and increased to a plateau at 24 h, when 20% of infected cells showed nuclear condensation. In contrast, experimental silencing of Bcl-2 induced apoptosis in 50% of infected cells at 12 h postinfection. This resulted in a decrease in the infection rate and a reduction in the accumulation of meront-containing cells. To test the significance of the moderately proapoptotic state late in the infection, we inhibited apoptosis using pancaspase inhibitor Z-VAD-FMK. This treatment also affected the progression of C. parvum infection, as reinfection, normally seen late (24 h to 48 h), did not occur and accumulation of mature meronts was impaired. Control of host apoptosis is complex and crucial to the life of C. parvum. Apoptosis control has at least two components, early inhibition and late moderate promotion. For a successful infection, both aspects appear to be required.

The cryptosporidium parvum transcriptome during in vitro development

Cryptosporidiosis is caused by an obligate intracellular parasite that has eluded global transcriptional or proteomic analysis of the intracellular developmental stages. The transcript abundance for 3,302 genes (87%) of the Cryptosporidium parvum protein coding genome was elucidated over a 72 hr infection within HCT8 cells using Real Time-PCR. The parasite had detectable transcription of all genes in vitro within at least one time point tested, and adjacent genes were not co-regulated. Five genes were not detected within the first 24 hr of infection, one containing two AP2 domains. The fewest genes detected were at 2 hr post infection, while 30% (985) of the genes have their highest expression at 48 and/or 72 hr. Nine expression clusters were formed over the entire 72 hr time course and indicate patterns of transcriptional increases at each of the 7 time points collected except 36 hr, including genes paralleling parasite 18S rRNA transcript levels. Clustering within only the first 24 hr of infection indicates spikes in expression at each of the 4 time points, a group paralleling 18S rRNA transcript levels, and a cluster with peaks at both 6 and 24 hr. All genes were classified into 18 functional categories, which were unequally distributed across clusters. Expression of metabolic, ribosomal and proteasome proteins did not parallel 18S rRNA levels indicating distinct biochemical profiles during developmental stage progression. Proteins involved in translation are over-represented at 6 hr, while structural proteins are over-represented at 12 hr. Standardization methods identified 107 genes with <80% at a single of its total expression at a single time point over 72 hr. This comprehensive transcriptome of the intracellular stages of C. parvum provides insight for understanding its complex development following parasitization of intestinal epithelial cells.

Proteolytic Products of the Porcine Reproductive and Respiratory Syndrome Virus nsp2 Replicase Protein

ABSTRACT The nsp2 replicase protein of porcine reproductive and respiratory syndrome virus (PRRSV) was recently demonstrated to be processed from its precursor by the PL2 protease at or near the G1196|G1197 dipeptide in transfected CHO cells. Here the proteolytic cleavage of PRRSV nsp2 was further investigated in virally infected MARC-145 cells by using two recombinant PRRSVs expressing epitope-tagged nsp2. The data revealed that PRRSV nsp2 exists as different isoforms, termed nsp2a, nsp2b, nsp2c, nsp2d, nsp2e, and nsp2f, during PRRSV infection. Moreover, on the basis of deletion mutagenesis and antibody probing, these nsp2 species appeared to share the same N terminus but to differ in their C termini. The largest protein, nsp2a, corresponded to the nsp2 product identified in transfected CHO cells. nsp2b and nsp2c were processed within or near the transmembrane (TM) region, presumably at or near the conserved sites G981|G982 and G828|G829|G830, respectively. The C termini for nsp2d, -e, and -f were mapped within the nsp2 middle hypervariable region, but no conserved cleavage sites could be definitively predicted. The larger nsp2 species emerged almost simultaneously in the early stage of PRRSV infection. Pulse-chase analysis revealed that all six nsp2 species were relatively stable and had low turnover rates. Deletion mutagenesis revealed that the smaller nsp2 species (e.g., nsp2d, nsp2e, and nsp2f) were not essential for viral replication in cell culture. Lastly, we identified a cellular chaperone, named heat shock 70-kDa protein 5 (HSPA5), that was strongly associated with nsp2, which may have important implications for PRRSV replication. Overall, these findings indicate that PRRSV nsp2 is increasingly emerging as a multifunctional protein and may have a profound impact on PRRSV replication and viral pathogenesis.

Expression of endogenous antimicrobial peptides in normal canine skin.

The cutaneous barrier contains small, cationic antimicrobial peptides that participate in the innate immunity against a wide variety of pathogens. Despite their immune importance, knowledge of canine defensins and their expression is limited primarily to testicular tissue and their relation to coat colour. Studies have shown that the absence of these antimicrobial peptides contribute to increased secondary infections in humans. The goals of this study were to identify defensin and protease inhibitor peptide genes by performing a computer-based iterative screen of the canine genome and to determine whether antimicrobial peptides are expressed in normal canine skin. Reverse transcription-polymerase chain reaction (RT-PCR) was used to test for the expression of several antimicrobial peptides in the skin of five normal dogs. RNA from testis was used for comparison. The iterative screen identified 65 putative antimicrobial peptide genes on nine chromosomes, the majority clustered on chromosomes 16 and 24. Amplification of normal canine skin cDNAs demonstrated expression of antimicrobial peptide genes in five different body sites. These findings will provide a tool for future studies examining the association between antimicrobial gene expression and cutaneous immunity in dogs.

Genetic risk factors for insidious equine recurrent uveitis in Appaloosa horses

Appaloosa horses are predisposed to equine recurrent uveitis (ERU), an immune-mediated disease characterized by recurring inflammation of the uveal tract in the eye, which is the leading cause of blindness in horses. Nine genetic markers from the ECA1 region responsible for the spotted coat color of Appaloosa horses, and 13 microsatellites spanning the equine major histocompatibility complex (ELA) on ECA20, were evaluated for association with ERU in a group of 53 Appaloosa ERU cases and 43 healthy Appaloosa controls. Three markers were significantly associated (corrected P-value <0.05): a SNP within intron 11 of the TRPM1 gene on ECA1, an ELA class I microsatellite located near the boundary of the ELA class III and class II regions and an ELA class II microsatellite located in intron 1 of the DRA gene. Association between these three genetic markers and the ERU phenotype was confirmed in a second population of 24 insidious ERU Appaloosa cases and 16 Appaloosa controls. The relative odds of being an ERU case for each allele of these three markers were estimated by fitting a logistic mixed model with each of the associated markers independently and with all three markers simultaneously. The risk model using these markers classified ~80% of ERU cases and 75% of controls in the second population as moderate or high risk, and low risk respectively. Future studies to refine the associations at ECA1 and ELA loci and identify functional variants could uncover alleles conferring susceptibility to ERU in Appaloosa horses.