The role of group 1 and group 2 CD1-restricted T cells in microbial immunity

Group 1 and group 2 CD1 present both self and microbial lipid antigens to T cells. While group 1 CD1-restricted T cells are known for their ability to recognize mycobacterial glycolipid antigens, group 2 CD1-restricted T cells are recognized as regulatory T cells that can influence the outcome of innate and adaptive immune responses. The evidence that these T cells contribute to host defense against infectious diseases is reviewed.     

Monoclonal antibody against non-histone chromosomal protein high mobility group 1 Co-migrates with high mobility group 1 into the nucleus

Non-histone chromosomal protein high mobility group 1 (HMG-1) rapidly migrates into the nucleus when injected into the cytoplasm of bovine fibroblasts and HeLa cells by red cell-mediated microinjection (Rechsteiner, M., and Kuehl, L. (1979) Cell 16, 901-908). We isolated hybridomas secreting monoclonal antibodies against HMG-1. One of these monoclonal antibodies, FR-1, inhibited in vitro binding of 125I-HMG-1 to chromatin isolated from FL cells. When 125I-HMG-1 was co-introduced with antibody FR-1 by red cell-mediated microinjection, antibody FR-1 did not prevent the accumulation of 125I-HMG-1 in the nucleus. When 125I-antibody FR-1 or fluorescein isothiocyanate antibody FR-1 was introduced into the cytoplasm of FL cells, most of the antibody did not accumulate in the nucleus. But when 125I- or fluorescein isothiocyanate antibody FR-1 was co-introduced with HMG-1 into the cytoplasm of FL cells, it did migrate into the nucleus.     

Domain-domain interactions in high mobility group 1 protein (HMG1).

The high mobility group protein HMG1 is a conserved chromosomal protein with two homologous DNA-binding domains, A and B, and an acidic carboxy-terminal tail, C. The structure of isolated domains A and B has been previously determined by NMR, but the interactions of the different domains within the complete protein were unknown. By means of differential scanning calorimetry and circular dichroism we have investigated the thermal stability of HMG1, of the truncated protein A-B (HMG1 without the acidic tail C) and of the isolated domains A and B. In 3 mm sodium acetate buffer, pH 5, the thermal melting of domains A and B are identical (transition temperature tm = 43 degrees C and 41 degrees C, denaturation enthalpies DeltaH = 46 kcal.mol-1). The thermal melting of protein A-B presents two nearly identical transitions (tm = 40 degrees C and 41 degrees C, DeltaH = 44 kcal.mol-1 and 46 kcal.mol-1, respectively). We conclude that the two domains A and B within protein A-B behave as independent domains. The thermal melting of HMG1 is biphasic. The two transitions have a different value of tm (38 degrees C and 55 degrees C) and corresponding values of DeltaH around 40 kcal.mol-1. We conclude that within HMG1, the acidic tail C is interacting with one of the two domains A and B, however, the two domains A and B do not interact with each other. At 37 degrees C, one of the two domains A and B, within HMG1, is partly unfolded, whereas the other which interacts with the acidic tail C, is fully native. The interaction free energy of the acidic tail C is estimated to be in the range of 2.5 kcal.mol-1 based on simulations of the thermograms of HMG1 as a function of the interaction free energy.     

The replicative fitness of primary human immunodeficiency virus type 1 (HIV-1) group M, HIV-1 group O, and HIV-2 isolates

The main (M) group of human immunodeficiency virus type 1 (HIV-1) is responsible for the global AIDS epidemic while HIV-1 group O (outlier) and HIV type 2 are endemic only in west and central Africa. The failure of HIV-2 and especially HIV-1 group O to spread following the initial zoonotic jumps is not well understood. This study was designed to examine the relative replicative capacities between these human lentiviruses. A pairwise competition experiment was performed with peripheral blood mononuclear cells with eight HIV-2 isolates, 6 group O viruses, and 15 group M viruses of subtype A (2 viruses), B (5 viruses), C (4 viruses), D (2 viruses) and CRF01_AE (2 viruses). HIV-1 group M isolates of any subtype were typically 100-fold-more fit than group O or HIV-2 strains when competed in peripheral blood mononuclear cells from various humans. This order in replicative fitness was also observed when virus pairs were added to human dendritic cells and then cocultured with primary, quiescent T cells, which is the model for HIV-1 transmission. These results suggest that reduced replicative and transmission fitness may be contributing to the low prevalence and limited geographical spread of HIV-2 and group O HIV-1 in the human population.     

The human Duffy blood group in rhesus monkeys1

There is good evidence that susceptibility to Plasmodium vivax infection and to P. knowlesi erythrocyte invasion is influenced by certain human Duffy (Fy) blood group antigens. Since P. knowlesi readily infects rhesus monkeys (Macaca mulatto), it was not surprising to find an Fy-like antigen on rhesus erythrocytes. Using human Fy antisera in elution and absorption experiments, we found that all 40 rhesus monkeys tested displayed the Fy(a-b +) phenotype. Furthermore, the rhesus Fy^bantigen was inactivated by chymotrypsin but not by trypsin, suggesting that it is homologous to the human Fy^bantigen. Preliminary serological analyses and enzyme hydrolysis experiments suggest that none of the 13 blood group systems that we have described in rhesus are analogous to the human Fy system. Thus, it appears that there is no Duffy-like polymorphism in rhesus monkeys.     

The molecular population genetics of HIV-1 group O

HIV-1 group O originated through cross-species transmission of SIV from chimpanzees to humans and has established a relatively low prevalence in Central Africa. Here, we infer the population genetics and epidemic history of HIV-1 group O from viral gene sequence data and evaluate the effect of variable evolutionary rates and recombination on our estimates. First, model selection tools were used to specify suitable evolutionary and coalescent models for HIV group O. Second, divergence times and population genetic parameters were estimated in a Bayesian framework using Markov chain Monte Carlo sampling, under both strict and relaxed molecular clock methods. Our results date the origin of the group O radiation to around 1920 (1890-1940), a time frame similar to that estimated for HIV-1 group M. However, group O infections, which remain almost wholly restricted to Cameroon, show a slower rate of exponential growth during the twentieth century, explaining their lower current prevalence. To explore the effect of recombination, the Bayesian framework is extended to incorporate multiple unlinked loci. Although recombination can bias estimates of the time to the most recent common ancestor, this effect does not appear to be important for HIV-1 group O. In addition, we show that evolutionary rate estimates for different HIV genes accurately reflect differential selective constraints along the HIV genome.     

Confirmation of putative HIV-1 group P in Cameroon

We report the second human immunodeficiency virus (HIV) belonging to the new HIV type 1 (HIV-1) group P lineage that is closely related to the simian immunodeficiency virus found in gorillas. This virus was identified in an HIV-seropositive male hospital patient in Cameroon, confirming that the group P virus is circulating in humans. Results from screening 1,736 HIV-seropositive specimens collected in Cameroon indicate that HIV-1 group P infections are rare, accounting for only 0.06% of HIV infections. Despite its rarity, group P shows evidence of adaptation to humans.     

The D blood group system of the horse1

Three new horse blood group factors designated E₂, E' and Y were described. Evidence was presented that these three factors as well as the factors D, J and E₁ known before, belong to the D system established by Stormont & Suzuki (1964). That system was thus extended from being a two factor, three allele system, to the most complex system known in the horse so far. It was demonstrated that the D system is closed through the factors E₂ and E'. However a few exceptions to that rule were encountered. A minimum of 10 alleles, two of which were extremely rare seemed to control the system. Frequencies of the factors and the genes of the system were given for the Swedish Trotter breed and the North-Swedish Horse breed.     

高速泳动族蛋白1的致炎症作用机制

高速泳动族蛋白1(high-mobility group box 1,HMGB1)是一种高度保守的DNA结合蛋白,具有维持核小体结构和调节基因转录的功能,近来发现它是炎性反应强有力的促炎因子。在大多炎性疾病,特别是脓毒症病例中,HMGB1的血清和组织水平均显著升高,而且它与其受体如糖基化终末产物受体(receptor for advanced glycation end products,RAGE)、Toll样受体4(toll-like receptor,TLR4)、Toll样受体2(TLR2)等相互作用促进炎性疾病的发展。为了进一步了解HMGB1,本文就HMGB1的结构、生物学活性、与免疫细胞相互作用、细胞表面受体、以及拮抗HMGB1的药物等进行综述。     

Reduced methyl group acceptance of 1-beta-D-arabinofuranosylcytosine-containing DNA polymers

Previous studies have shown that 1-beta-D-arabinofuranosylcytosine (ara-C) can induce differentiation of various malignant cells and that DNA methylation patterns become altered under ara-C treatment of those cells. The aim of this study was to investigate whether this influence on DNA methylation is caused by a direct effect of DNA-incorporated ara-C molecules on nuclear DNA methylase. For this reason, we constructed various ara-C-substituted DNA polymers and used them as substrates for highly purified eukaryotic DNA methylase isolated from murine P815 mastocytoma cells. The ara-C incorporation into DNA polymers was measured by either an ara-C-specific radioimmunoassay or by use of radioactive-labelled ara-C during the synthesis of those polymers. We found an inverse correlation between the level of ara-C substitution of the DNA polymers and their methyl group acceptance. Kinetic experiments performed with ara-C-modified DNA polymers pointed out that the mode of action of DNA methylase remains unaltered. DNA methylase is neither detached nor fixed at an ara-C site, but is somehow hindered in its enzymatic activity, probably by slowing down the walking mechanism. Hence, the previously observed hypermethylation of DNA of some eukaryotic cells, propagated in the presence of ara-C, is apparently not due to a direct effect of DNA-incorporated ara-C molecules on endogenous DNA methylase.     

Macrophage endocytosis of high-mobility group box 1 triggers pyroptosis

Macrophages can be activated and regulated by high-mobility group box 1 (HMGB1), a highly conserved nuclear protein. Inflammatory functions of HMGB1 are mediated by binding to cell surface receptors, including the receptor for advanced glycation end products (RAGE), Toll-like receptor (TLR)2, TLR4, and TLR9. Pyroptosis is a caspase-1-dependent programmed cell death, which features rapid plasma membrane rupture, DNA fragmentation, and release of proinflammatory intracellular contents. Pyroptosis can be triggered by various stimuli, however, the mechanism underlying pyroptosis remains unclear. In this study, we identify a novel pathway of HMGB1-induced macrophage pyroptosis. We demonstrate that HMGB1, acting through RAGE and dynamin-dependent signaling, initiates HMGB1endocytosis, which in turn induces cell pyroptosis. The endocytosis of HMGB1 triggers a cascade of molecular events, including cathepsin B release from ruptured lysosomes followed by pyroptosome formation and caspase-1 activation. We further confirm that HMGB1-induced macrophage pyroptosis also occurs in vivo during endotoxemia, suggesting a pathophysiological significance for this form of pyroptosis in the development of inflammation. These findings shed light on the regulatory role of ligand-receptor internalization in directing cell fate, which may have an important role in the progress of inflammation following infection and injury.Infection and injury, the most challenging factors to the survival of species throughout evolution, are still major causes of human death worldwide. Infection and severe trauma share many overlapping features in the mechanism of activation of the innate immune system through pathogen-associated molecular pattern molecules derived from microbes and damage-associated molecular pattern (DAMP) molecules released by damaged tissues.^{1, 2} High-mobility group box 1 (HMGB1), a highly conserved ubiquitous protein present in the nucleus and cytoplasm of nearly all cell types, is the prototypic DAMP molecule.³ During infection and sterile tissue injury, HMGB1 is released from cells and serves as a necessary and sufficient mediator of inflammation to induce a variety of cellular responses including cell chemotaxis and release of pro-inflammatory cytokines.^{4, 5} Inflammatory functions of HMGB1 are mediated by binding to the cell surface receptors, including the receptor for advanced glycation end products (RAGEs), Toll-like receptor (TLR)2, TLR4, and TLR9.^{6, 7}RAGE is a type I transmembrane protein and a member of the immunoglobulin superfamily expressed in many cell populations, including endothelial cells, vascular smooth muscle cells, neurons, neutrophils, and macrophages/monocytes.⁸ RAGE has been implicated as a receptor mediating the chemotaxis and cytokine activity of HMGB1 in macrophages and tumor cells.^{7, 9, 10} RAGE engagement by multiple ligands is linked to a range of signaling pathways including activation of NF-κB,^{11, 12} PI3K/Akt,¹³ MAPKs,^{14, 15} Jak/STAT,¹⁶ and Rho GTPases,¹⁷ although how RAGE transduces the signaling is not fully addressed.Pyroptosis is a caspase-1-dependent programmed cell death, which is morphologically and mechanistically distinct from other forms of cell death such as apoptosis and necrosis.¹⁸ Previous observations suggested that pyroptosis features rapid plasma membrane rupture and release of proinflammatory intracellular contents, contrasting with the characteristic of apoptosis, which packs cellular contents and induces non-inflammatory phagocytic uptake of the apoptotic bodies by macrophages.¹⁹ Pyroptosis can be triggered by various pathological stimuli, such as microbial infection, stroke, heart attack, or cancer;¹⁸ however, the mechanism that underlies pyroptosis formation in response to inflammatory mediators remains unclear. In this study, we identify a novel pathway of HMGB1-induced pyroptosis. We demonstrate that HMGB1 acting through RAGE on macrophages triggers dynamin-dependent endocytosis of HMGB1, which in turn induces cell pyroptosis. The endocytosis of HMGB1 initiates a cascade of molecular events, including cathepsin B (CatB) activation and release from ruptured lysosomes, followed by pyroptosome formation and caspase-1 activation. We further confirm that this in vitro observation of HMGB1-induced macrophage pyroptosis also occurs in vivo during endotoxemia, suggesting a pathophysiological significance for pyroptosis in the development of inflammation.     

晚期炎症介质-高迁移率族蛋白B-1

高迁移率族蛋白-1(HMGB-1)是一类广泛存在于真核细胞内的非组核蛋白,是由肿瘤坏死因子(TNF-a)刺激巨噬细胞分泌。HMGB-1全身性炎症反应失控性发展是致使组织损伤和器官衰竭的根本原因,在脓毒症HMGB-1升高程度与感染严重性呈正相关。HMGB-1是炎症晚期重要介质,抑制HMGB-1能够预防内毒素和细菌攻击所致MODS,改善严重脓毒症的预后。尽管对HMGB-1防治作用的确切机制与应用效果尚待深入探讨,但HMGB-1为临床干预脓毒症提供了较宽的时间窗。