Macrophage Reviews

Schett G. Cells of the synovium in rheumatoid arthritis. Osteoclasts.

Arthritis Research & Therapy. 2007 Feb 15;9(1):203.

Abstract

Osteoclasts are multinucleated cells of hematopoietic origin and are the primary bone resorbing cells. Numerous osteoclasts are found within the synovial tissue at sites adjacent to bone, creating resorption pits and local bone destruction. They are equipped with specific enzymes and a proton pump that enable them to degrade bone matrix and solubilize calcium, respectively. The synovial tissue of inflamed joints has a particularly high potential to accumulate osteoclasts because it harbors monocytes/macrophages, which function as osteoclast precursors, as well as cells that provide the specific molecular signals that drive osteoclast formation. Osteoclasts thus represent a link between joint inflammation and structural damage since they resorb mineralized tissue adjacent to the joint and destroy the joint architecture.

Lutzky V, Hannawi S, Thomas R. Cells of the synovium in rheumatoid arthritis. Dendritic cells.

Arthritis Research & Therapy. 2007 Sep 7;9(4):219.

Abstract

Dendritic cells are the major antigen-presenting and antigen-priming cells of the immune system. We review the antigen-presenting and proinflammatory roles played by dendritic cells in the initiation of rheumatoid arthritis (RA) and atherosclerosis, which complicates RA. Various signals that promote the activation of NF-κB and the secretion of TNF and IL-1 drive the maturation of dendritic cells to prime self-specific responses, and drive the perpetuation of synovial inflammation. These signals may include genetic factors, infection, cigarette smoking, immunostimulatory DNA and oxidized low-density lipoprotein, with major involvement of autoantibodies. We propose that the pathogenesis of RA and atherosclerosis is intimately linked, with the vascular disease of RA driven by similar and simultaneous triggers to NF-κB.

Yang Q, Shi Y, He J, Chen Z.
The evolving story of macrophages in acute liver failure.

Immunology Letters [Internet]. 2012 Jul [cited 2012 Jul 27];(0).

Acute liver failure (ALF) remains a worldwide problem. The innate immune system acts as an important regulator of ALF. Kupffer cells (KCs), the resident macrophages in liver, play a key role in liver innate immune response. Recent researches have shown that macrophages display a remarkable plasticity and can differentiate into functionally diverse subsets. However, the dynamic polarized phenotypes and functional status of macrophages in different stage of ALF are not clear. In this paper, we present a review of evidence that KCs play a significant role in the pathogenesis of ALF, including the phenotype and functions of macrophages, signaling pathways involved in macrophage functional status and cell-crosstalks of KCs with other immune cells. More information on macrophages will promote a better understanding of the cellular molecular mechanisms of ALF and provide new insights for the development of therapeutic targets for ALF.

van den Berg WB, van Lent PLEM.
CHAPTER 16 – The Role of Macrophages in Chronic Arthritis.

Immunobiology. 1996 Oct;195(4–5):614–23.

Rheumatoid arthritis is characterized by a mononuclear infiltrate in the synovial tissue of the affected joints, considerable thickening of the synovial lining layer and concomitant destruction of cartilage and bone. Macrophages probably play a central role and the contribution of the synovial lining macrophages is addressed in studies in experimental murine arthritis models. Emphasis is given to the involvement in arthritis expression and cartilage destruction. The role of TNF-α and IL-1, and the modulatory cytokines IL-4/ IL-10 is briefly discussed.

Tabas I.
Macrophage death and defective inflammation resolution in atherosclerosis.

Nature Reviews Immunology. 2009 Dec 4;10(1):36–46.

A key event in atherosclerosis is a maladaptive inflammatory response to subendothelial lipoproteins. A crucial aspect of this response is a failure to resolve inflammation, which normally involves the suppression of inflammatory cell influx, effective clearance of apoptotic cells and promotion of inflammatory cell egress. Defects in these processes promote the progression of atherosclerotic lesions into dangerous plaques, which can trigger atherothrombotic vascular disease, the leading cause of death in industrialized societies. In this Review I provide an overview of these concepts, with a focus on macrophage death and defective apoptotic cell clearance, and discuss new therapeutic strategies designed to boost inflammation resolution in atherosclerosis.

Kinne RW, Stuhlmüller B, Burmester G-R.
Cells of the synovium in rheumatoid arthritis. Macrophages.

Arthritis Research & Therapy. 2007 Dec 21;9(6):224.

The multitude and abundance of macrophage-derived mediators in rheumatoid arthritis and their paracrine/autocrine effects identify macrophages as local and systemic amplifiers of disease. Although uncovering the etiology of rheumatoid arthritis remains the ultimate means to silence the pathogenetic process, efforts in understanding how activated macrophages influence disease have led to optimization strategies to selectively target macrophages by agents tailored to specific features of macrophage activation. This approach has two advantages: (a) striking the cell population that mediates/amplifies most of the irreversible tissue destruction and (b) sparing other cells that have no (or only marginal) effects on joint damage.

Lee J, Hartman M, Kornfeld H.
Macrophage Apoptosis in Tuberculosis.

Yonsei Med J. 2009 Feb 28;50(1):1–11.

Mycobacterium tuberculosis (Mtb) is an intracellular pathogen that infects alveolar macrophages following aerosol transmission. Lung macrophages provide a critical intracellular niche that is required for Mtb to establish infection in the human host. This parasitic relationship is made possible by the capacity of Mtb to block phagosome maturation following entry into the host macrophage, creating an environment that supports bacillary replication. Apoptosis is increasingly understood to play a role in host defense against intracellular pathogens including viruses, fungi, protozoa and bacteria. In the last 15 years an understanding of the role that macrophage apoptosis plays in TB has begun to emerge. Here we review the history and current state of the art of this topic and we offer a model of the macrophage-pathogen interaction that takes into the account the complexities of programmed cell death and the relationship between various death signaling pathways and host defense in TB.

Liu J, Sun Y, Drubin DG, Oster GF.
The Mechanochemistry of Endocytosis.

PLoS Biol. 2009;7(9):e1000204.

An integrated theoretical model reveals how the chemical and the mechanical aspects of endocytosis are coordinated coherently in yeast cells, driving progression through the endocytic pathway and ensuring efficient vesicle scission in vivo.

Mosser DM, Edwards JP.
Exploring the full spectrum of macrophage activation.

Nature Reviews Immunology. 2008 Dec 1;8(12):958–69.

Macrophages display remarkable plasticity and can change their physiology in response to environmental cues. These changes can give rise to different populations of cells with distinct functions. In this Review we suggest a new grouping of macrophage populations based on three different homeostatic activities — host defence, wound healing and immune regulation. We propose that similarly to primary colours, these three basic macrophage populations can blend into various other ‘shades’ of activation. We characterize each population and provide examples of macrophages from specific disease states that have the characteristics of one or more of these populations.

Plüddemann A, Mukhopadhyay S, Gordon S.
The Interaction of Macrophage Receptors with Bacterial Ligands.

Expert Reviews in Molecular Medicine. 2006;8(28):1–25.

Innate immune receptors play a key role in the early recognition of invading bacterial pathogens and initiate the crucial innate immune response. The diverse macrophage receptors recognise Gram-positive and Gram-negative bacteria via conserved structures on the bacterial surface and facilitate phagocytosis and/or signalling, providing the trigger for the adaptive immune response. These receptors include scavenger receptors, C-type lectins, integrins, Toll-like receptors and siglecs. The bacterial ligands generally recognised by these receptors range from lipopolysaccharides on Gram-negative bacteria to peptidoglycan and lipoteichoic acid on Gram-positive bacteria. However, emerging evidence indicates that bacterial proteins are also important ligands; for example, surface proteins from Neisseria meningitidis have been shown to be ligands for class A scavenger receptors. In addition, a group of cytosolic receptors, the NBS-LRR proteins, have been implicated in recognition of bacterial breakdown products. It is becoming increasingly apparent that macrophage receptors can act in conjunction with one another to deliver an appropriate response.