Insight into the mechanisms regulating immune homeostasis in health and disease.

Innate and adaptive immune systems consist of cells and molecules that work together in concert to fight against microbial infection and maintain homeostasis. Hosts encounter microbes / exogenous pathogen-associated molecular patterns (PAMPs) and endogenous damage-associated molecular patterns (DAMPs) all the time and they must have proper mechanisms to counteract the danger such that appropriate responses (e.g., degree of inflammation and types of mediators induced) can be mounted in different scenarios. Increasing numbers of endogenous danger signals of host origin are being identified including, for example, uric acid and cholesterol crystals, high mobility group box1 (HMGB1) protein, oxidized LDL, vesicans, heat shock proteins (HSPs) and self DNA. Many of these endogenous ligands have been shown to be associated with inflammation-related diseases like atherosclerosis, gout and type 2 diabetes. Several DAMPs appear to have the ability to interact with more than one receptor. We are now beginning to understand how the immune system can distinguish infection from endogenous ligands elaborated following cellular insults and tissue damage. Appropriate responses to maintain the homeostatic state in health and disease depend largely on the recognition and response to these stimuli by germline encoded pattern-recognition receptors (PRRs) present on both immune and non-immune cells. These receptors are, for example, Toll-like receptors (TLRs), C-type lectin receptors (CLRs) and cytosolic receptors (e.g., RLRs, NLRs and some intracellular DNA sensors). Atypical PRR “danger” receptors, like the receptor for advanced glycation end products (RAGE) and their ligands have been identified. A proper response to maintain homeostasis relies on specific negative regulators and regulatory pathways to dampen its response to tissue injury while maintaining the capacity to eliminate infection and induce proper tissue repair. Moreover, some PRRs (e.g., TLR2,TLR4 and NLRP3) and atypical PRRs can recognize both PAMPs and DAMPs, either as single entities or after forming complexes (e.g., immune complexes, or DNA- HMGB1 and DNA-LL37 complexes), so there must be a mechanism to selectively depress or alleviate the inflammatory response to DAMPs, while leaving that of PAMPs intact. Excessive inflammatory responses can induce considerable tissue damage and can be highly detrimental to the host. For example, CD24 reacting with HMGB1 and HSPs has been implicated to function as negative regulator for RAGE. In this review, I will briefly overview the information on various host and microbial components and bring together the information to synthesize a model to explain how homeostasis can be maintained in states of health and disease. Understanding the molecular mechanisms by which the immune system functions under different scenarios will provide us with ways and means to design appropriate approaches, for example, to prevent or treat autoimmune and inflammatory diseases or the ability to design new drugs or formulate safe chemicals for vaccine adjuvants.

Differential gene expression profiles of lung epithelial cells exposed to burkholderia pseudomallei and burkholderia thailandensis during the initial phase of infection.

Burkholderia pseudomallei is the causative agent of melioidosis, and its infection usually affects pa-tients’ lungs. The organism is a facultative intracellular Gram-negative bacillus commonly found in soil and water in endemic tropical regions. Another closely related Burkholderia species found in soil and water is B. thailandensis. This bacterium is a non-pathogenic environmental saprophyte. B. pseudomallei is considerably more efficient than B. thailandensis in host cell invasion and adherence. A previous study by our group demonstrated that after suc-cessfully invading cells, there was no difference in the ability to survive and to replicate between both Burkholderia species in cultured A549 human lung epithelial cells. In this study, Human Affymetrix GeneChips were used to identify the difference in gene expression profiles of A549 cells after a 2-h exposure to B. pseudomallei and B. thai-landensis. A total of 280 of 22,283 genes were expressed at higher levels in the B. pseudomallei-infected cells than in the B. thailandensis-infected cells, while 280 genes were expressed at lower levels in the B. pseudomallei-infected cells. Approximately 9% of these genes were involved in immune response and apoptosis. Those genes were further selected for gene expression analysis using reverse transcription PCR and/or real-time RT-PCR. The results of RT-PCR and real-time RT-PCR are in accordance with data from the microarray data in that bcl2 gene expression in the B. pseudomallei-infected cells was 2-fold higher than the level in the B. thailandensis-infected cells even though no apoptosis was seen in the infected cells. The levels of E-selectin, ICAM-1, IL-11, IRF-1, IL-6, IL-1 and LIF genes expression in the B. pseudomallei-infected cells were 1.5-5 times lower than in the B. thailan-densis-infected cells. However, both species stimulated the same level of IL-8 production from the tested epithelial cell line, and no difference in the ratio of adherent polymorphonuclear cells (PMNs) to infected A549 cells of both species was observed. Taken together, our results suggest that B. pseudomallei manipulates host response in fa-vor of its survival in the host cell, which may explain the more virulent characteristics of B. pseudomallei when compared with B. thailandensis.

Immune responses of selected phagotopes from monoclonal antibodies of Burkholderia pseudomallei.

Random peptide libraries displayed by bacteriophage T7 and M13 were employed to identify mimotopes from 4 monoclonal antibodies (MAbs) specific to Burkholderia pseudomallei. Insert DNA sequences of bound phages selected from four rounds of panning with each MAb revealed peptide sequences corresponding to B. pseudomallei K96243 hypothetical protein BPSL2046, hypothetical protein BpseP_02000035, B. pseudomallei K96243 hypothetical protein BPSS0784, B. pseudomallei 1710b hypothetical protein BURPS1710b_1104, and B. cenocepacia H12424 TonB-dependent siderophore receptor, all located at the outer membrane. The immune responses from all selected phagotopes were significantly higher than that of lipopolysaccharide. The study demonstrates the feasibility of identifying mimotopes through screening of phage-displayed random peptide libraries with B. pseudomallei MAbs.

Reduced interleukin-17 expression of Burkholderia pseudomallei-infected peripheral blood mononuclear cells of diabetic patients.

Burkholderia pseudomallei is the causative agent of melioidosis. One of the main risk factors for B. pseudomallei infection in endemic areas is diabetes mellitus. The present study investigated IL-17 mRNA and protein expression by peripheral blood mononuclear cells in response to B. pseudomallei infection in 10 diabetic patients in comparison to 10 healthy blood donors. The IL-17 expression in diabetic patients was significantly lower (p < 0.05) than in the controls. However, IL-23 mRNA expression of the 2 groups was comparable. The present findings suggest that melioidosis affects T cell IL-17 production and that patients with diabetes mellitus have a defective IL-17 production in response to this type of infection.

Synergistic cytotoxicity and apoptosis induced in human cholangiocarcinoma cell lines by a combined treatment with tumor necrosis factor-alpha (TNF-alpha) and triptolide.

Cholangiocarcinoma is known to be relatively resistant to chemotherapy. One alternative approach is to use a combination of an immunomodulating agent with an anticancer drug. Here we studied the synergistic actions of TNF-alpha and triptolide (a diterpene epoxide prepared from Tripterygium wilfordii), previously shown to have antitumor activity against hamster cholangiocarcinoma (CCA) cells. Three human CCA cell lines (HuCCA-1, HubCCA-1, KKU-100 cell lines) were subjected to a combined treatment of TNF-alpha (0.1-10 ng/ml) and triptolide (5-50 ng/ml) for 24 hours in microculture plates. The combination of TNF-alpha and triptolide had a significantly increased cytotoxic activity over that of triptolide alone (p < 0.05). Under the same conditions, TNF-alpha by itself was not cytotoxic to these cell lines. Similarly, the combined treatment could also accelerate apoptotic cell death in all three human cholangiocarcinoma cell lines. The combined treatment of TNF-alpha at 10 ng/ml and triptolide at 50 ng/ml for 6-10 hours achieved a percentage of apoptotic cells shown by DAPI staining of 18-65%, compared to only 6-20% apoptotic cells for triptolide alone. Analyzing the possible mechanisms of the combined treatment, we found by Western blot that at 6 hours, there was a poly (ADP-ribose) polymerase (PARP) cleavage which was not detectable by the treatment of either TNF-alpha or triptolide alone. The cleavage of PARP was inhibited when the cells were pretreated with the enzyme inhibitor AC-DEVD-CMK, suggesting that apoptosis induced by the combination of TNF-alpha and triptolide involved activation of caspase 3. These results indicate that apoptosis of human cholangiocarcinoma cell lines as induced by a combination of TNF-alpha and triptolide is mediated through caspase 3 activation.