即早基因c-fos在THP-1单核巨噬细胞亚型极化中的差异表达*

目的:探讨即早基因c-fos在THP-1巨噬细胞亚型极化过程中的表达变化。方法:运用PMA刺激诱导THP-1单核细胞极化为巨噬细胞,观察c-fos在单核细胞极化过程中的表达变化;在PMA刺激的基础上,分别运用LPS和IL-4诱导THP-1巨噬细胞向M1及M2亚型极化,实时定量PCR及Western blot技术分析刺激24 h时,细胞亚型标记物CD274、CD86和CD163的表达变化,并动态观察诱导极化过程中,c-fos的表达情况。结果:c-fos在PMA刺激THP-1单核细胞分化为巨噬细胞过程中蛋白和mRNA水平显示上调;LPS诱导THP-1巨噬细胞极化为M1型过程中,c-fos蛋白和mRNA水平表达降低,其特异性标记物在24 h呈现出M1型极化的特点(CD86蛋白表达升高,CD274、CD163蛋白表达降低);IL-4诱导THP-1巨噬细胞极化为M2型过程中,c-fos蛋白和mRNA水平表达升高,其特异性标记物在24 h表现出M2型极化的特点(CD86蛋白表达降低,CD274、CD163蛋白表达升高)。结论:c-fos参与了THP-1单核细胞向巨噬细胞极化的过程,并且可能通过抑制巨噬细胞M1亚型形成,促进巨噬细胞向M2亚型极化的作用参与巨噬细胞的亚型极化及其功能调节中。     

巨噬细胞极化在单纯疱疹病毒1型感染中的作用研究进展

巨噬细胞具有功能可塑性，使其能够根据微环境线索不同极化为不同表型，主要分为两种类型，即促炎M1型巨噬细胞和抗炎M2型巨噬细胞，它们在单纯疱疹病毒1型（Herpes simplex virus-1, HSV-1）感染的疾病发展中行使不同的功能。当巨噬细胞出现极化失衡时，可以通过多种因素对其失衡状态进行调节，靶向调节巨噬细胞的极化状态对于治疗HSV-1感染具有重要意义。本文对巨噬细胞极化及其在HSV-1感染中的作用研究进展进行总结，以期为HSV-1感染的进一步研究及治疗提供参考依据。     

巨噬细胞的分类及其调节性功能的差异

巨噬细胞在固有免疫和适应性免疫反应中具有重要的作用,它可将加工后的抗原提呈给相应的T细胞,活化后的T细胞通过细胞膜上的分子或分泌的细胞介素进一步活化巨噬细胞。此时的巨噬细胞吞噬杀伤能力大大加强,并释放各种活性物质,因此巨噬细胞是主要的炎性反应调节细胞。巨噬细胞可分为经典活化和选择性活化的巨噬细胞,其在炎性反应过程中分泌不同的细胞因子、趋化因子等,然后间接或直接地参与各种炎症性疾病的反应过程。该文介绍了不同型巨噬细胞在胰岛素抵抗、HIV感染和肿瘤等疾病中的调节功能。     

免疫系统防御强,遇到缺氧HIF帮（英文）

缺氧诱导因子(hypoxia-inducible factor,HIF)是一类受氧调控的转录因子。其α亚基是氧敏感性亚基,包括HIF-1α、HIF-2α和HIF-3α,与β亚基形成异源二聚体,活化目标基因的表达以调节细胞对低氧的反应。HIF本身受到精细调节,包括转录组水平的调节,以及通过蛋白质翻译后修饰所进行的蛋白质水平的调节,以确保细胞对低氧压力产生适当反应。免疫应答常伴随局部组织的低氧状况,HIF是低氧环境中先天免疫和适应性免疫应答的重要调节因子。在天然免疫系统,HIF激活一系列与代谢相关的基因表达,调节中性粒细胞、巨噬细胞和树突状细胞的发育、极化和功能。对于适应性免疫,近年来的研究确立了HIF在CD4+T细胞分化和功能中的重要作用。本综述将重点讨论近年来有关HIF调节机制,及其在免疫细胞功能研究的进展。     

免疫系统防御强，遇到缺氧HIF帮

缺氧诱导因子（hypoxia-inducible factor,HIF）是一类受氧调控的转录因子。其α亚基是氧敏感性亚基,包括HIF-1α、HIF-2α和HIF-3α,与β亚基形成异源二聚体,活化目标基因的表达以调节细胞对低氧的反应。HIF本身受到精细调节,包括转录组水平的调节,以及通过蛋白质翻译后修饰所进行的蛋白质水平的调节,以确保细胞对低氧压力产生适当反应。免疫应答常伴随局部组织的低氧状况,HIF是低氧环境中先天免疫和适应性免疫应答的重要调节因子。在天然免疫系统,HIF激活一系列与代谢相关的基因表达,调节中性粒细胞、巨噬细胞和树突状细胞的发育、极化和功能。对于适应性免疫,近年来的研究确立了HIF在CD4⁺T细胞分化和功能中的重要作用。本综述将重点讨论近年来有关HIF调节机制,及其在免疫细胞功能研究的进展。     

巨噬细胞在中枢神经系统髓鞘再生中的作用

中枢神经系统脱髓鞘疾病,因其高发病率、高致残率等特点而备受关注。现有研究以适应性免疫反应导致神经系统损伤为主,而先天免疫系统在髓鞘再生中的作用直到最近才成为研究热点。以巨噬细胞为对象,从中枢神经系统中巨噬细胞的种类及来源、巨噬细胞的极化类型、小胶质细胞和单核细胞来源巨噬细胞的异同、衰老对巨噬细胞功能和髓鞘再生的影响等方面,综述了巨噬细胞在中枢神经系统尤其是髓鞘再生中的作用,以期为临床治疗提供一定理论依据。     

姜黄素激活PPAR-γ通路改变巨噬细胞的极化状态

过氧化物酶体增殖物激活受体γ(peroxisome proliferator-activated receptorγ,PPAR-γ)通路是调节替换活化的(alternatively activated)M2型巨噬细胞极化的中心环节.姜黄素是PPAR-γ的天然激动剂,有着良好的抗炎作用.本研究通过建立巨噬细胞株的体外炎症模型,用姜黄素及PPAR-γ的特异性抑制剂GW9662对其进行干预,观察巨噬细胞株极化状态的改变.结果显示,姜黄素可以促使巨噬细胞向M2型极化,当特异性抑制PPAR-γ通路后,姜黄素促进巨噬细胞向M2型极化的作用受到抑制.结果表明,姜黄素可能是通过激动PPAR-γ通路促使巨噬细胞向M2型极化,为进一步研究姜黄素的抗炎机制及治疗慢性低度炎症相关的代谢性疾病提供了一个新的思路.     

微RNA介导巨噬细胞极化的转录后调控

巨噬细胞极化是根据周围刺激环境做出表型调节的一个过程.一般极化为2个表型,分别为经典激活的M1巨噬细胞和替代激活的M2巨噬细胞.简而言之,M1巨噬细胞的特征是促炎和抗肿瘤;M2巨噬细胞是抗炎和促肿瘤.巨噬细胞极化被认为是人体生理和病理的关键调节器,其发挥作用的有效性依赖于关键因子的协调表达,而这些关键因子的表达在转录后...     

肿瘤相关巨噬细胞极化的研究进展

肿瘤相关巨噬细胞是肿瘤组织局部浸润的巨噬细胞,在肿瘤组织微环境中,这些巨噬细胞发生M2型极化,从而发挥免疫抑制效应,促进肿瘤增殖。而M2型极化的肿瘤相关巨噬细胞也能够被再次诱导逆向极化形成具有抗肿瘤效应的M1型肿瘤相关巨噬细胞,激发机体产生特异性抗肿瘤免疫应答。促进肿瘤相关巨噬细胞M1型极化由此成为当前抗肿瘤免疫防治研究的热点。将对有关肿瘤相关巨噬细胞极化的新进展进行综述,为抗肿瘤免疫研究提供新的思路。     

烫伤对小鼠腹腔巨噬细胞LPS/Toll信号通路的影响—— c-fos基因表达、AP-1和NF-κB的DNA结合活性及IL-12 p40基因表达的抑制

烫伤能够引起机体免疫系统功能的抑制, 其机制目前还不很清楚. 巨噬细胞在机体防御系统的调节中居重要地位, 因此研究烫伤对巨噬细胞的效应就显得非常必要. 转录因子AP-1和NF-κB是Toll样受体介导的信号通路中的重要成员, 对于多种参与免疫反应的基因尤其是细胞因子基因的诱导表达必不可少[1]. 应用小鼠烫伤模型, 研究了烫伤对于上述两个重要转录因子的效应. 发现烫伤后, 小鼠腹腔巨噬细胞中LPS介导的c-fos基因表达, AP-1和NF-κB的DNA结合活性及IL-12 p40基因表达均被显著地抑制. 这一结果提示, 巨噬细胞Toll信号通路的变化与烫伤引起的机体免疫功能紊乱密切相关.     

SPION primes THP1 derived M2 macrophages towards M1-like macrophages

Potentially, cellular iron regulates functional plasticity in macrophages yet; interaction of functionally polarized macrophages with iron-oxide nanoparticles has never been studied. We found that monocyte differentiation alters cellular ferritin and cathepsin L levels and induces functional polarization in macrophages. Iron in super paramagnetic iron-oxide nanoparticle (SPION) induces a phenotypic shift in THP1 derived M2 macrophages towards a high CD86+ and high TNF α+ macrophage subtype. This phenotypic shift was accompanied by up-regulated intracellular levels of ferritin and cathepsin L in M2 macrophages, which is a characteristic hallmark of M1 macrophages. Atherogenic oxysterols reduce phagocytic activity in macrophage subtypes, and thus these cells may escape detection by iron-oxide nanoparticles (INPs) in-vivo.     

Doxycycline Inhibits Polarization of Macrophages to the Proangiogenic M2-type and Subsequent Neovascularization

Macrophages occur along a continuum of functional states between M1-type polarized macrophages with antiangiogenic and antitumor activity and M2-type polarized macrophages, which have been implicated to promote angiogenesis and tumor growth. Proangiogenic M2-type macrophages promote various pathologic conditions, including choroidal neovascularization in models of neovascular age-related macular degeneration, or certain cancers, such as glioblastoma multiforme. Thus, a potential novel therapeutic approach to target pathological angiogenesis in these conditions would be to inhibit the polarization of macrophages toward the proangiogenic M2-type. However, no pharmacological inhibitors of M2-type macrophage polarization have been identified yet. Here we performed an unbiased pharmacological and small chemical screen to identify drugs that inhibit proangiogenic M2-type macrophage polarization and block pathologic macrophage-driven neovascularization. We identified the well tolerated and commonly used antibiotic doxycycline as a potent inhibitor of M2-type polarization of macrophages. Doxycycline inhibited, in a dose-dependent manner, M2-type polarization of human and bone marrow-derived mouse macrophages without affecting cell viability. Furthermore, doxycycline inhibited M2-type macrophage polarization and subsequent neovascularization in vivo in a laser injury model of choroidal neovascularization. Thus, doxycycline could be used to enhance current antiangiogenic treatment approaches in various conditions that are promoted by proangiogenic M2-type macrophages, including neovascular age-related macular degeneration and certain cancers.     

Reference gene selection and validation for mRNA expression analysis by RT-qPCR in murine M1- and M2-polarized macrophage

Molecular Biology Reports - Murine bone marrow-derived macrophages (M0) and M1- and M2-polarized macrophages are being widely used as a laboratory model for polarized macrophages related molecular...     

Dynamics of macrophage polarization reveal new mechanism to inhibit IL-1β release through pyrophosphates

In acute inflammation, extracellular ATP activates P2X₇ ion channel receptors (P2X₇R) on M1 polarized macrophages to release pro-inflammatory IL-1β through activation of the caspase-1/nucleotide-binding domain and leucine-rich repeat receptor containing pyrin domain 3 (NLRP3) inflammasome. In contrast, M2 polarized macrophages are critical to the resolution of inflammation but neither actions of P2X₇R on these macrophages nor mechanisms by which macrophages switch from pro-inflammatory to anti-inflammatory phenotypes are known. Here, we investigated extracellular ATP signalling over a dynamic macrophage polarity gradient from M1 through M2 phenotypes. In macrophages polarized towards, but not at, M2 phenotype, in which intracellular IL-1β remains high and the inflammasome is intact, P2X₇R activation selectively uncouples to the NLRP3-inflammasome activation but not to upstream ion channel activation. In these intermediate M1/M2 polarized macrophages, extracellular ATP now acts through its pyrophosphate chains, independently of other purine receptors, to inhibit IL-1β release by other stimuli through two independent mechanisms: inhibition of ROS production and trapping of the inflammasome complex through intracellular clustering of actin filaments.     

Local Delivery of Polarized Macrophages Improves Reperfusion Recovery in a Mouse Hind Limb Ischemia Model

Aims

Enhancement of collateral development in coronary or peripheral artery disease is a therapeutic target, but it has proven difficult to achieve. Macrophages are key players in collateral remodeling, yet the effect of different macrophage subsets on arteriogenesis has not been investigated.

Methods and Results

Murine macrophages were cultured from bone marrow and polarized into M1 (IFNγ), M2a (IL-4) or M2c (IL-10) subsets. C57BL/6 mice underwent femoral artery ligation followed by intramuscular injection of macrophage subsets. Using eGFP expressing macrophages, cells could be detected at least 6 days after ligation and were located in the perivascular space of collateral vessels. After 14 days, perfusion ratio was increased in animals treated with M1 as well as M2a and M2c macrophages compared to control. Depletion of circulating monocytes by clodronate liposome injections did not hamper reperfusion recovery, however, treatment with exogenous polarized macrophages improved perfusion ratio after 14 days again. We used IL10R^fl/fl/LysMCre⁺ mice to study the effect of inhibition of endogenous polarization towards specifically M2c macrophages on arteriogenesis. Deletion of the IL10-receptor (IL10R) in the myeloid lineage did not affect reperfusion recovery, yet the pro-arteriogenic effect of exogenously injected M2c macrophages was still present.

Conclusions

Local injection of polarized macrophages promotes reperfusion recovery after femoral artery ligation and is not influenced by depletion of circulatory monocytes. Preventing endogenous M2c polarization did not affect reperfusion recovery suggesting that M2c’s are not required for collateralization, but are sufficient to induce collateral formation upon exogenous administration. This is the first study using local injection of macrophage subsets showing the pro-arteriogenic effect of polarized macrophages.     

Macrophages modulate the viability and growth of human mesenchymal stem cells

Following myocardial infarction, tissue repair is mediated by the recruitment of monocytes and their subsequent differentiation into macrophages. Recent findings have revealed the dynamic changes in the presence of polarized macrophages with pro‐inflammatory (M1) and anti‐inflammatory (M2) properties during the early (acute) and late (chronic) stages of cardiac ischemia. Mesenchymal stem cells (MSCs) delivered into the injured myocardium as reparative cells are subjected to the effects of polarized macrophages and the inflammatory milieu. The present study investigated how cytokines and polarized macrophages associated with pro‐inflammatory (M1) and anti‐inflammatory (M2) responses affect the survival of MSCs. Human MSCs were studied using an in vitro platform with individual and combined M1 and M2 cytokines: IL‐1β, IL‐6, TNF‐α, and IFN‐γ (for M1), and IL‐10, TGF‐β1, TGF‐β3, and VEGF (for M2). In addition, polarization molecules (M1: LPS and IFN‐γ; M2: IL‐4 and IL‐13) and common chemokines (SDF‐1 and MCP‐1) found during inflammation were also studied. Indirect and direct co‐cultures were conducted using M1 and M2 polarized human THP‐1 monocytes. M2 macrophages and their associated cytokines supported the growth of hMSCs, while M1 macrophages and their associated cytokines inhibited the growth of hMSCs in vitro under certain conditions. These data imply that an anti‐inflammatory (M2) environment is more accommodating to the therapeutic hMSCs than a pro‐inflammatory (M1) environment at specific concentrations. J. Cell. Biochem. 114: 220–229, 2012. © 2012 Wiley Periodicals, Inc.     

Modulation of Chitotriosidase During Macrophage Differentiation

Macrophages as a principal component of immune system play an important role in the initiation, modulation, and final activation of the immune response against pathogens. Upon stimulation with different cytokines, macrophages can undergo classical or alternative activation to become M1 or M2 macrophages, which have different functions during infections. Although chitotriosidase is widely accepted as a marker of activated macrophages and is thought to participate in innate immunity, particularly in defense mechanisms against chitin containing pathogens, little is known about its expression during macrophages full maturation and polarization. In this study we analyzed CHIT-1 modulation during monocyte-to-macrophage maturation and during their polarization. The levels of CHIT-1 expression was investigated in human monocytes obtained from buffy coat of healthy volunteers, polarized to classically activated macrophages (or M1), whose prototypical activating stimuli are interferon-γ and lipopolysaccharide, and alternatively activated macrophages (or M2) obtained by interleukin-4 exposure by real-time PCR and by Western blot analysis. During monocyte–macrophage differentiation both protein synthesis and mRNA analysis showed that CHIT-1 rises significantly and is modulated in M1 and M2 macrophages.Our results demonstrated that variations of CHIT-1 production are strikingly associated with macrophages polarization, indicating a different rule of this enzyme in the specialized macrophages.