Lynda M. Pierini

Targeted recycling of PECAM from endothelial surface-connected compartments during diapedesis

Leukocytes enter sites of inflammation by squeezing through the borders between endothelial cells that line postcapillary venules at that site. This rapid process, called transendothelial migration (TEM) or diapedesis, is completed within 90 s after a leukocyte arrests on the endothelial surface. In this time, the leukocyte moves in ameboid fashion across the endothelial borders, which remain tightly apposed to it during transit. It is not known how the endothelial cell changes its borders rapidly and reversibly to accommodate the migrating leukocyte. Here we show that there is a membrane network just below the plasmalemma at the cell borders that is connected at intervals to the junctional surface. PECAM-1, an integral membrane protein with an essential role in TEM, is found in this compartment and constitutively recycles evenly along endothelial cell borders. During TEM, however, recycling PECAM is targeted to segments of the junction across which monocytes are in the act of migration. In addition, blockade of TEM with antibodies against PECAM specifically blocks the recruitment of this membrane to the zones of leukocyte migration, without affecting the constitutive membrane trafficking.

A membrane protein preserves intrabacterial pH in intraphagosomal Mycobacterium tuberculosis

Acidification of the phagosome is considered to be a major mechanism used by macrophages against bacteria, including Mycobacterium tuberculosis (Mtb). Mtb blocks phagosome acidification, but interferon-γ (IFN-γ) restores acidification and confers antimycobacterial activity. Nonetheless, it remains unclear whether acid kills Mtb, whether the intrabacterial pH of any pathogen falls when it is in the phagosome and whether acid resistance is required for mycobacterial virulence. In vitro at pH 4.5, Mtb survived in a simple buffer and maintained intrabacterial pH. Therefore, Mtb resists phagolysosomal concentrations of acid. Mtb also maintained its intrabacterial pH and survived when phagocytosed by IFN-γ–activated macrophages. We used transposon mutagenesis to identify genes responsible for Mtbs acid resistance. A strain disrupted in Rv3671c, a previously uncharacterized gene encoding a membrane-associated protein, was sensitive to acid and failed to maintain intrabacterial pH in acid in vitro and in activated macrophages. Growth of the mutant was also severely attenuated in mice. Thus, Mtb is able to resist acid, owing in large part to Rv3671c, and this resistance is essential for virulence. Disruption of Mtbs acid resistance and intrabacterial pH maintenance systems is an attractive target for chemotherapy.

Spatial and temporal sequence of capsule construction in Cryptococcus neoformans

The pathogenic yeast Cryptococcus neoformans is distinguished by an extensive polysaccharide capsule, which impedes host defences and is absolutely required for fungal virulence. Despite the biological importance of the capsule, nothing is known about how it is assembled. Substantial capsule growth occurs in two distinct situations relevant to cryptococcal pathogenesis: formation of new buds and induction of capsule on mature cells. We developed pulse–chase protocols to examine these events in a dynamic way using a variety of microscopy techniques. We show that the capsule overlying buds is newly synthesized and differs physically from the corresponding parental material. New capsule formed by mature cells upon induction of synthesis is added at the inner aspect of the existing structure, displacing pre‐existing material outwards. Surprisingly, new polysaccharide material is also deposited throughout the capsule, yielding a progressively denser structure. These results yield the first model of capsule synthesis and open new lines of investigation into the underlying mechanisms.

Elevated Plasma Membrane Cholesterol Content Alters Macrophage Signaling and Function

Objective—During atherogenesis, macrophages migrate into the subendothelial space where they ingest deposited lipoproteins, accumulate lipids, and transform into foam cells. It is unclear why these macrophages do not remove their lipid loads from the region. This study was aimed at testing the hypothesis that macrophage behavior is altered when membrane cholesterol levels are elevated, as might be the case for cells in contact with lipoproteins within atherosclerotic lesions. Methods and Results—We examined the effects of elevating membrane cholesterol on macrophage behavior. J774 macrophages were treated with either acetylated low-density lipoprotein (ac-LDL) and ACAT inhibitor or cholesterol-chelated methyl-β-cyclodextrin (chol-MβCD) to increase membrane cholesterol levels. Our results show that elevating the membrane cholesterol of J774 macrophages induced dramatic ruffling, stimulated cell spreading, and affected F-actin organization. Cellular adhesion was required for these effects, and Rac-mediated signaling pathways were involved. Additionally, 3-dimensional transwell chemotaxis assays showed that migration of J774 macrophages was significantly inhibited when membrane cholesterol levels were raised. Conclusions—These findings indicate that increased membrane cholesterol causes dramatic effects on macrophage cellular functions related to the actin cytoskeleton. They should provide new insights into the early steps of atherogenesis.

Flotillas of lipid rafts fore and aft

To effectively combat invading pathogens, immune cells must rapidly switch from roughly spherical resting cells to polarized migratory ones, which then move in a directed fashion to the site of infection. The dramatic metamorphosis of leukocytes into polarized cells and their subsequent migration are two of the most fascinating phenomena in cell biology. Polarization and migration require the spatial and temporal control of signal transduction molecules so that substrate attachment and membrane extension occur at the cell front, while detachment and membrane retraction happen at the rear. How do cells coordinate signaling molecules to perform contrasting functions at opposite poles? It has long been appreciated that there is polarization in the protein machinery involved in cell migration. However, it is becoming evident that lipids are also distributed nonuniformly, and the distribution of lipids is an important factor for directional migration. In a paper in this issue of PNAS, Gomez-Mouton et al. (1) provide further evidence for the importance of specialized lipid domains in establishing and maintaining the polarity of motile cells. In particular, they show that both the leading edge and the uropod of polarized T lymphocytes are enriched in lipid components that partition into raft-like lipid domains. An interesting finding is that the distribution of certain lipid raft components differs at the two poles. Thus, ganglioside GM3 is enriched at the leading edge, whereas GM1 is concentrated at the uropod. Treatments such as cholesterol depletion, which disrupts plasma membrane organization, prevent the development of a polarized morphology and cell migration.

RP105 Facilitates Macrophage Activation by Mycobacterium tuberculosis Lipoproteins

RP105, phylogenetically related to Toll-like receptor (TLR)-4, is reported to facilitate B cell activation by the TLR4-agonist lipopolysaccharide (LPS)--but to limit LPS-induced cytokine production by antigen-presenting cells. Here, we show that the role of RP105 extends beyond LPS recognition and that RP105 positively regulates macrophage responses to Mycobacterium tuberculosis (Mtb) lipoproteins. Mtb-infected RP105(-/-) mice exhibited impaired proinflammatory cytokine responses associated with enhanced bacterial burden and increased lung pathology. The Mtb 19 kDa lipoprotein induced release of tumor necrosis factor in a manner dependent on both TLR2 and RP105, and macrophage activation by Mtb lacking mature lipoproteins was not RP105 dependent. Thus, mycobacterial lipoproteins are RP105 agonists. RP105 physically interacted with TLR2, and both RP105 and TLR2 were required for optimal macrophage activation by Mtb. Our data identify RP105 as an accessory molecule for TLR2, forming part of the receptor complex for innate immune recognition of mycobacterial lipoproteins.

Elevated Cholesterol Levels in the Plasma Membranes of Macrophages Inhibit Migration by Disrupting RhoA Regulation

Objective—Atherogenesis begins as small subendothelial accumulations of foam cells that develop through unregulated uptake of modified and aggregated low-density lipoprotein (LDL). The reason why foam cells remain in the atherosclerotic plaque rather than migrating out of the area is unclear. We tested the hypothesis that elevated membrane cholesterol levels, which may result from interactions with aggregated LDL, affect macrophage migration. Methods and Results—Cholesterol loading by incubation with cholesterol-chelated methyl-β-cyclodextrin decreased migration of J774A.1 macrophages toward complement 5a (C5a) in transwell migration assays, even though cholesterol-loaded macrophages responded to a bath application of C5a. In a micropipette polarization assay, cholesterol-loaded cells polarized toward a C5a gradient. In a transwell migration assay, cholesterol-loaded cells extended lamellae through the filter pores but were unable to translocate their cell bodies. Cholesterol loading decreased both the cellular levels of GTP-bound active RhoA and the phosphorylation of myosin light chain. Expression of constitutively active RhoA largely prevented the inhibition of cell migration by cholesterol loading. Conclusions—These results suggest that increases in plasma membrane cholesterol content alter RhoA activation, resulting in inhibition of cell migration. These findings provide one possible explanation for the retention of foam cells in atherosclerotic lesions.

Aggregated LDL in Contact With Macrophages Induces Local Increases in Free Cholesterol Levels That Regulate Local Actin Polymerization

Objective—Interaction of macrophages with aggregated matrix-anchored lipoprotein deposits is an important initial step in atherogenesis. Aggregated lipoproteins require different cellular uptake processes than those used for endocytosis of monomeric lipoproteins. In this study, we tested the hypothesis that engagement of aggregated LDL (agLDL) by macrophages could lead to local increases in free cholesterol levels and that these increases in free cholesterol regulate signals that control cellular actin. Methods and Results—AgLDL resides for prolonged periods in surface-connected compartments. Although agLDL is still extracellular, we demonstrate that an increase in free cholesterol occurs at sites of contact between agLDL and cells because of hydrolysis of agLDL-derived cholesteryl ester. This increase in free cholesterol causes enhanced actin polymerization around the agLDL. Inhibition of cholesteryl ester hydrolysis results in decreased actin polymerization. Conclusions—We describe a novel process that occurs during agLDL–macrophage interactions in which local release of free cholesterol causes local actin polymerization, promoting a pathological positive feedback loop for increased catabolism of agLDL and eventual foam cell formation.

Optical Microscopy–Based Migration Assay for Human Neutrophils

This unit describes an in vitro microscopy assay for examining the migration of human neutrophils in two dimensions to identify the underlying cause of a migration defect and to evaluate a variety of migration parameters that cannot be studied using migration through a porous filter. Freshly isolated human neutrophils a placed in the chamber, stimulated, and images are collected at various time points. The data can be used to determine the effects of a pharmacological treatment on the migration of individual cells.