A promoter ISRE and dual 5' YY1 motifs control IFN-gamma induction of the IRG-47 G-protein gene

Identification of a novel IRGM promoter single nucleotide polymorphism associated with tuberculosis

BACKGROUND

Human immunity-related GTPase M (IRGM) is found to play an important role in defense against intracellular pathogen Mycobacterium tuberculosis in vitro by regulating autophagy. To verify whether single nucleotide polymorphisms (SNPs) in the promoter region of IRGM gene are associated with tuberculosis (TB) 1.7 kb IRGM promoter region was sequenced and SNP analysis was conducted in TB patients and healthy controls.

METHODS

A simple and rapid procedure for extracting DNA from clotted-blood was developed in this study. A 1.7 kb IRGM promoter region was amplified and sequenced for nucleotide polymorphism search. Then, 3 SNPs were selected and analyzed in 216TB patients and 275 healthy subjects by ligase detection reaction technique.

RESULTS

DNA extracted by our method was of high quality and suitable for PCR, sequencing, and genotyping. We identified 29 polymorphisms in the 1.7 kb IRGM promoter region, including 11 novel polymorphisms not yet reported. Large population analysis showed that frequencies of -1208A allele (P=0.031), -1208AA genotype (P=0.042), and -1208A/-1161C/-947C (P=0.035) and -1208G/-1161C/-947C (P=0.030) haplotypes in cases were significantly different from those in controls.

CONCLUSIONS

In 1.7 kb IRGM promoter region, only -1208A/G polymorphism is associated with susceptibility to TB.

Importance of the interferon-alpha system in murine large intestine indicated by microarray analysis of commensal bacteria-induced immunological changes

Background

Although microbiota play a critical role in the normal development and function of host immune systems, the underlying mechanisms, especially those involved in the large intestine (LI), remain unknown. In the present study, we performed transcriptome analysis of the LI of germ-free (GF) and specific pathogen-free (SPF) mice of the IQI strain, an inbred strain established from ICR mice.

Results

GeneChip analysis, quantitative real-time RT-PCR, and reconfirmation using bacteria-inoculated GF mice revealed differences in the expression levels of several immune-related genes, such as cryptdin-related sequences (CRS), certain subsets of type 1 interferon (IFN)-related genes, class Ib MHC molecules, and certain complements. LI expressed no authentic cryptdins but predominantly expressed CRS2, 4, and 7. The mRNA levels of IFN-related genes, including Irf7, Isgf3g, Ifit1 and Stat1, were lower in SPF- and flora-reconstituted mice. When an oral IFN-α inducer tilorone analog, R11567DA, was administered to SPF mice, IFN-α was induced rapidly in the LI at 4 h, whereas no IFN-α protein was detected in the small intestine (SI) or blood. In situ hybridization and immunohistochemistry suggested that the IFN-α production originated from Paneth cells in the SI, and portions of lamina proprial CD11b- or mPDCA1-positive cells in the LI.

Conclusion

The present study suggests that microbial colonization, while inducing the expression of anti-microbial peptides, results in the down-regulation of certain genes responsible for immune responses, especially for type I IFN synthesis. This may reflect the adaptation process of the immune system in the LI to prevent excessive inflammation with respect to continuous microbial exposure. Further, the repertoire of anti-microbial peptides and the extraordinary role of interferon producing cells in the LI have been found to be distinct from those in the SI.

Emerging themes in IFN-gamma-induced macrophage immunity by the p47 and p65 GTPase families

Vertebrates have evolved complex immune specificity repertoires beyond the primordial components found in lower multi-cellular organisms to combat microbial infections. The type II interferon (IFN-gamma) pathway represents one such system, bridging innate and acquired immunity and providing host protection in a cell-autonomous manner. Recent large-scale transcriptome analyses of IFN-gamma-dependent gene expression in effector cells such as macrophages have highlighted the prominence of two families of GTPases -- p47 IRGs and p65 GBPs -- that are now beginning to emerge as major determinants of antimicrobial resistance. Here we discuss the recent clarification of known family members, their cellular biochemistry and host defense functions as a means to understanding the complex innate immune response engendered in higher vertebrates such as humans and mice.

Analysis of interaction partners for perilipin and ADRP on lipid droplets

Despite the critical roles of intracellular lipid droplets (LDs) in lipid storage and metabolism, little is known about the molecular mechanisms of their functions. Several protein components associated with the surface of LDs have been identified. A major one is perilipin in adipocytes and steroidogenic cells, whereas ADRP in most other cell types. They are loosely grouped as a small protein family sharing a common N-terminal motif, called the PAT domain. Perilipin regulates the breakdown of triacylglycerol in LDs via its phosphorylation. ADRP is characterized as a fatty acid binding protein and involved in lipid uptake and LD formation. For examining the functions of perilipin and ADRP at the molecular level, we performed yeast two-hybrid screening in this study, to find their functional partners. We identified CGI-58, a product of the causal gene of Chanarin-Dorfman syndrome (CDS), as an interactor for both perilipin and ADRP. Specific interaction between CGI-58 and perilipin was confirmed in a GST-pulldown assay and supported by fluorescence microscopic analyses. We further demonstrated that CGI-58 is principally located at the surface of LDs in 3T3-L1 cells, together with perilipin, and its expression is upregulated upon stimulation for adipocyte differentiation. Other than CGI-58, we also identified in yeast two-hybrid screening HSP86 and D52 tumor proteins as binding partners of perilipin, and IRG-47 of ADRP. These factors might be cooperated with perilipin and ADRP, and hence involved in membrane dynamics of LDs as well as the regulation of lipolysis on the surface of LDs.

The interferon-inducible p47 (IRG) GTPases in vertebrates: loss of the cell autonomous resistance mechanism in the human lineage

A survey of p47 GTPases in several vertebrate organisms shows that humans lack a p47 GTPase-based resistance system, suggesting that mice and humans deploy their immune resources against vacuolar pathogens in radically different ways.

Background

Members of the p47 (immunity-related GTPases (IRG) family) GTPases are essential, interferon-inducible resistance factors in mice that are active against a broad spectrum of important intracellular pathogens. Surprisingly, there are no reports of p47 function in humans.

Results

Here we show that the p47 GTPases are represented by 23 genes in the mouse, whereas humans have only a single full-length p47 GTPase and an expressed, truncated presumed pseudo-gene. The human full-length gene is orthologous to an isolated mouse p47 GTPase that carries no interferon-inducible elements in the promoter of either species and is expressed constitutively in the mature testis of both species. Thus, there is no evidence for a p47 GTPase-based resistance system in humans. Dogs have several interferon-inducible p47s, and so the primate lineage that led to humans appears to have lost an ancient function. Multiple p47 GTPases are also present in the zebrafish, but there is only a tandem p47 gene pair in pufferfish.

Conclusion

Mice and humans must deploy their immune resources against vacuolar pathogens in radically different ways. This carries significant implications for the use of the mouse as a model of human infectious disease. The absence of the p47 resistance system in humans suggests that possession of this resistance system carries significant costs that, in the primate lineage that led to humans, are not outweighed by the benefits. The origin of the vertebrate p47 system is obscure.

Immune control of phagosomal bacteria by p47 GTPases

Sequestered from the action of complement, antibody and lytic peptides, phagosomal pathogens pose a unique problem for the innate immune system both in terms of detection and disposal. An immunologically induced 47-kDa (p47) GTPase family recruited to nascent phagosomes (PGs) has provided new insights into how vertebrates deal with facultative bacteria occupying a vacuolar niche. Research over the past 2 years in particular has identified several molecular determinants that underlie the membrane trafficking functions of LRG-47 and other p47 GTPases as part of a PG remodeling program. When coupled to signals issuing from pathogen-specific Toll-like receptors, the p47 proteins may constitute a novel sensory system enlisted by mammals, birds and fish to decode the language of immune recognition against this particular class of infectious agents.

IFN-inducible GTPases and immunity to intracellular pathogens

By eliciting host antimicrobial programs in nearly all nucleated cells interferons (IFNs) help orchestrate the innate immune response of mammals to a diverse array of microbial pathogens. Recent work has highlighted the complexity of this transcriptional repertoire and the emergence of several families of IFN-inducible guanosine 5' triphosphatases (GTPases)--p47, guanylate-binding protein (GBP), Mx and very large inducible GTPases (VLIG)--that subsume pathogen-specific roles. Such specificity arises from a combination of both the type and timing of inductive stimuli, target-cell population, subcellular binding partners and the infectious agent encountered. Evolution of different GTPase families to combat compartmentalized versus cytosolic pathogens reveals a hitherto unexpected level of intracellular discrimination during vertebrate host defense.

Genes expressed during the IFN gamma-induced maturation of pre-B cells

Interferon-gamma (IFN gamma) exerts diverse responses in B cell development ranging from growth arrest and apoptosis to proliferation and differentiation. IFN gamma stimulates murine 70Z/3 pre-B cells to express surface immunoglobulin (Ig) and this system serves as a useful model for the pre-B to immature B cell transition in B cell development. To analyze this developmental transition, we used a PCR-based subtractive hybridization in combination with miniarray screening to identify differentially-expressed genes in IFN gamma-stimulated compared with unstimulated 70Z/3 pre-B cells. The majority (44%) of the differentially-expressed genes obtained were known IFN gamma-inducible. These included multiple isolates from each of three multi-gene families, including two guanylate-binding protein (47 and 67kDa GBP) families of GTPases and the hematopoietic IFN gamma-inducible nuclear protein family (HIN-200). These multiple isolates of genes comprised the majority of the total isolated and sequenced clones. Other known IFN gamma-induced genes in this group included Ig kappa light chain and Ly-6, as well as genes with functions in antigen processing, cellular regulation, and cytoskeletal organization. Another 36% of the genes identified were previously known, but not known to be IFN gamma-inducible (e.g. pre-B cell enhancing factor, PBEF). The remaining 20% of the IFN gamma-induced isolates did not match entries in Genbank, and thus, may represent novel genes involved in IFN gamma responses and/or in the pre-B to immature B cell transition. Overall, the majority of the individual genes isolated were either not known to be IFN gamma responsive or were not previously known.

YY1 binds five cis-elements and trans-activates the myeloid cell-restricted gp91(phox) promoter

Four transcriptional activating cis-elements within the gp91(phox) promoter bind a protein complex of similar mobility and binding specificity, denoted BID (binding increased during differentiation). The intensity of BID complexes increases upon myeloid cell differentiation, coincident with induction of gp91(phox) expression, and BID competes with the transcriptional repressor CDP for binding to each of these promoter elements. To determine the identity of BID, an expression library was ligand screened with the BID-binding site that surrounds the -145-base pair (bp) region of the gp91(phox) promoter. One recovered factor that exhibits the expected binding specificity is YY1, a ubiquitous multifunctional transcription factor. BID complexes that form with the four binding sites within the gp91(phox) promoter are disrupted by YY1 antiserum, and a fifth YY1-binding site was detected in the -412-bp promoter region. Overexpression of YY1 in transient co-transfection assays trans-activates a minimal promoter containing two copies of the -145-bp binding site from the gp91(phox) promoter. Neither the level of YY1 protein nor DNA binding activity increases during myeloid cell differentiation. These studies identify a target gene of YY1 function in mature myeloid cells, and demonstrate that YY1 function can be controlled during myeloid development by the modulation of a competing DNA-binding factor.

Two Families of GTPases Dominate the Complex Cellular Response to IFN-γ

IFN-γ induces a number of cellular programs functional in innate and adaptive resistance to infectious pathogens. It has recently become clear that the complete cellular response to IFN-γ is extraordinarily complex, with >500 genes (i.e., ∼0.5% of the genome) activated. We made suppression-subtractive hybridization differential libraries from IFN-γ-stimulated primary mouse embryonic fibroblasts and from a mouse macrophage cell line, ANA-1, in each case with reference to unstimulated cells. Of ∼250 clones sequenced at random from the two libraries, >35% were representatives of one or the other of two small unrelated families of GTPases, the 65-kDa and 47-kDa families. These families dominate the IFN-γ-induced response in both cell types. We report here the full-length sequences of one new 65-kDa and two new 47-kDa family members. The 65-kDa family members are under transcriptional control of IRF-1, whereas the 47-kDa family members are inducible in embryonic fibroblasts from IRF-1−/− mice. Members of both GTPase families are strongly up-regulated in livers of wild-type mice infected with the pathogenic bacterium, Listeria monocytogenes, but not in IFN-γR0/0 mice. These GTPases appear to be dedicated to the IFN-γ response, since resting levels are negligible and since neither family shows any significant relationship to any other described family of GTPases. Understanding the role of these GTPases in IFN-γ-mediated resistance against pathogens is the task for the future.