Acylation of lysophospholipids by rabbit alveolar macrophages. Specificities of CoA-dependent and CoA-independent reactions

Intact alveolar macrophages were found to acylate alkyl- and acyllysophospholipids with a high selectivity for arachidonate. A specific mechanism appears responsible for the incorporation of arachidonate into lysophospholipids in intact cells since the kinetic pattern for the formation of the 20:4 species was different from all other species. This specificity was investigated in more detail by examining the enzymatic acylation of 1-alkyl-2-lyso-sn-glycero-3-phosphocholine by macrophage membranes; in the absence of CoA, ATP, and Mg2+, this lysophospholipid was acylated with a high preference for arachidonate that was independent of added free fatty acids. The addition of CoA alone increased the rate of acylation of 1-alkyl-2-lyso-sn-glycero-3-phosphocholine, mainly due to an increase in the formation of species other than those containing arachidonate. When CoA, ATP, and Mg2+ were present, the macrophage membranes catalyzed the acylation of 1-alkyl-2-lyso-sn-glycero-3-phosphocholine without preference for arachidonate. A different apparent Km and Vmax was observed for reactions involving each cofactor condition. We conclude that the acylation of alkyl- and acyllysophospholipids by rabbit alveolar macrophages occurs by three separate mechanisms: a CoA-independent transacylation, a CoA-dependent transacylation (reverse reaction catalyzed by acyl-CoA acyltransferase), and an acyl-CoA-dependent acylation. The CoA-independent transacylation reaction is unique in that it is specific for arachidonate and accounts for the selective acylation of alkyl- and acyllysophospholipids by arachidonate in membrane preparations of alveolar macrophages. This reaction appears to be extremely important in the remodeling of phospholipid molecular species and the mobilization of arachidonate into ether-linked lipids. The transfer of arachidonate to 1-alkyl-2-lyso-sn-glycero-3-phosphocholine also is of importance in the final inactivation step for platelet activating factor (1-alkyl-2-acetyl-sn-glycero-3-phosphocholine), whereby 1-alkyl-2-arachidonoyl-sn-glycerol-3-phosphocholine (a stored precursor of both platelet activating factor and arachidonic acid metabolites) is formed.     

Laminar restriction of retinal macrophagic response to optic nerve axotomy in the rat.

Following optic nerve transection, most of the retinal ganglion cells die. Their debris is promptly cleared by phagocytic cells. It is currently not known to what extent peripherally derived macrophages contribute to this activity. Using antibodies OX42 and ED-1, phagocytic cells were labeled in the retinas of optic nerve lesioned adult rats. To distinguish whether the cells were reactive microglial or macrophagic in origin, blood-borne monocytes were labeled with fluorescent microspheres while in the systemic circulation. Macrophages invaded the retina, but only in the nerve fiber layer, sparing the ganglion cell and other layers. These macrophages engulfed only the axonal debris from dying ganglion cells, not their degenerating cell bodies. These results indicate that although peripherally derived monocytic cells are recruited into the retrogradely degenerating retina, their role in clearing debris is limited to the optic fiber layer.     

Proper macrophagic differentiation requires both autophagy and caspase activation

Autophagy allows the elimination of superfluous or damaged macromolecules or organelles. Genetic evidence indicates that autophagy plays essential functions during differentiation. The differentiation of human blood monocytes into macrophages is a caspase-dependent process triggered by colony stimulating factor1 (CSF1/CSF-1). We have established, using pharmacological inhibitors, siRNA approaches and Atg7^?/? mice, that autophagy is required for proper CSF1/CSF-1-driven differentiation of human and murine monocytes and acquisition of phagocytic functions. Collectively, these findings highlight an essential role of autophagy during monocyte differentiation and acquisition of macrophage functions. Deciphering the complex interplay between caspase and autophagy that occurs during this process will undoubtedly bring new insights in our understanding of monocyte differentiation.     

Proper macrophagic differentiation requires both autophagy and caspase activation

Autophagy allows the elimination of superfluous or damaged macromolecules or organelles. Genetic evidence indicates that autophagy plays essential functions during differentiation. The differentiation of human blood monocytes into macrophages is a caspase-dependent process triggered by colony stimulating factor1 (CSF1/CSF-1). We have established, using pharmacological inhibitors, siRNA approaches and Atg7^−/− mice, that autophagy is required for proper CSF1/CSF-1-driven differentiation of human and murine monocytes and acquisition of phagocytic functions. Collectively, these findings highlight an essential role of autophagy during monocyte differentiation and acquisition of macrophage functions. Deciphering the complex interplay between caspase and autophagy that occurs during this process will undoubtedly bring new insights in our understanding of monocyte differentiation.     

Human IRF1 governs macrophagic IFN-γ immunity to mycobacteria

1. Download : Download high-res image (169KB)
2. Download : Download full-size image

     

Morphologic aspects of alveolar microcirculation.

Direct observations of the flow direction and connections between arteries and veins in the mammal lung are difficult. When we divide the lung into smaller units like acini or segments we can observe a central supply of the unit with arterial blood that has venous drainage at different points of the periphery. Consideration of the situation prevailing at birth strongly suggests a preferential flow direction through paths located in primary septa at the bottom of alveoli. Capillaries of the secondary septa placed between alveoli open to the same duct represent collaterals of the mainstream flow filled only if pressure conditions permit. Another significant feature is the presence of pleated alveolar septa. While capillaries inside the interalveolar wall mostly appear flat or collapsed, the capillaries of the pleated alveolar corners are always wide open. Often they show openings into a small venule placed inside the pleated area, which strongly suggests that the pleated areas contain the venous side of the capillaries.     

Protective reactions of gastropod molluscs. 1. Cell reactions

Protective reactions of molluscs are traditionally considered in cell and humoral aspects. The paper analyses original data and recent reference data oncell (phagocytic) reactions of gastropod molluscs. The main attention is paid to peculiarities of hemopoiesis, cell elements of hemolymph, and dynamics and mechanics of encapsulating the parasites.     

Ultrastructural study of the neuroglial and macrophagic reaction in Wallerian degeneration of the adult rat optic nerve.

The Wallerian degeneration of the optic nerve of adult rat has been studied after destroying the retina. Animals were sacrificed between 4 days and 1 year after the lesion. Different cell types of the optic nerve have been studied ultrastructurally. Our results demonstrate the existence of a population of macrophages, probably of microglial origin, responsible for scavenging degenerated myelin. Astrocytes suffer a process of proliferation and hypertrophy, and are massively stuffed by gliofilaments, leading to a glial scar. These cells apparently do not participate in phagocytic phenomena, while some cytoplasmic inclusions (e.g. lipid droplets) suggest some implication in the local metabolization of some tissue degradation products. Oligodendrocytes do not undergo ultrastructural changes, showing a rather quiescent appearance.     

Defensive reactions of gastropod molluscs. Humoral reactions

Humoral protective reactions and their mechanisms in gastropod mollusks are considered based on the results of various investigations. It is important to note that lectines in molluscs, as well as in other invertebrates, are functional analogues of immunoglobulins in vertebrates.     

Collagenase from rabbit pulmonary alveolar macrophages.

Rabbit pulmonary alveolar macrophages produce a collagenase which lyses labeled collagen gels, specifically cleaves collagen types I, II and III, is inhibited by ethylenediaminetetraacetate, cysteine, dithiothreitol and serum but is not inhibited by a serine protease inhibitor. Alveolar macrophage collagenase activity can be enhanced by $\text{in vivo}$ BCG activation, $\text{in vitro}$ latex, silica or mycobacterium activation and by $\text{in vitro}$ uncovering of latent enzymatic activity with trypsin treatment. The production of collagenase by unactivated alveolar macrophages and the presence of “latent” collagenase in culture media of alveolar macrophages are examples of significant differences between alveolar and peritoneal macrophages.     

Postnatal alveolar development of the rabbit.

Previous studies of alveolarization have used rats or lambs; however, neither closely reflects human alveolar development. We characterized alveolar development in rabbits (n = 3-7 /group) at 28 days gestation (dg) to 9 mo to determine whether they followed the human pattern more closely. The right lung was made up of 30% alveolar and 50% duct space at 28 dg to 3 days and of 50 and 30%, respectively, at 14 days to 9 mo. Tissue fraction and alveolar wall thickness decreased by 40% 28 dg to birth. At birth, approximately 4.5% of the number of alveoli seen at 9 mo were present, with alveolar number increasing progressively well into adulthood. The rate of alveolar formation was high around birth, decreasing progressively with age. Alveolar volume increased more than twofold (28 dg to birth) and continued to increase postnatally to 16 wk. Surface fraction decreased by 17% (28 dg to 3 days), after which it remained uniform. Our findings suggest that the timing of onset of alveolarization in humans and rabbits is similar and that rabbits may be used to model postnatal influences on alveolar development.     

Laminar restriction of retinal macrophagic response to optic nerve axotomy in the rat

Following optic nerve transection, most of the retinal ganglion cells die. Their debris is promptly cleared by phagocytic cells. It is currently not known to what extent peripherally derived macrophages contribute to this activity. Using antibodies OX42 and ED‐1, phagocytic cells were labeled in the retinas of optic nerve lesioned adult rats. To distinguish whether the cells were reactive microglial or macrophagic in origin, blood‐borne monocytes were labeled with fluorescent microspheres while in the systemic circulation. Macrophages invaded the retina, but only in the nerve fiber layer, sparing the ganglion cell and other layers. These macrophages engulfed only the axonal debris from dying ganglion cells, not their degenerating cell bodies. These results indicate that although peripherally derived monocytic cells are recruited into the retrogradely degenerating retina, their role in clearing debris is limited to the optic fiber layer. © 1999 John Wiley & Sons, Inc. J Neurobiol 40: 55–66, 1999     

Ultrastructure of bacilli and the bacillary origin of the macrophagic inclusions in Whipple's disease

An electron microscopic and cytochemical study of the Whipple bacillus in jejunal biopsies from three untreated patients was made using fixation procedures developed for the satisfactory preservation of bacterial ultrastructure. The envelopes of the normal-looking bacilli present free in the lamina propria consisted of the following layers. (i) A cytoplasmic membrane with a triple-layered profile and a mean thickness (peak-to-peak distance) of 6.08 nm. (ii) A thick (20 nm) cell wall containing peptidoglycan; the wall had a hitherto undescribed inner layer that contained polysaccharides, possibly teichoic acids. (iii) Surrounding the cell wall, a surface membrane with a symmetric profile and a mean peak-to-peak distance of 4.74 nm. The ultrastructural pattern of the Whipple bacillus wall corresponds to that of Gram-positive bacteria, but with an additional surface membrane. This membrane is different from the outer membrane of Gram-negative bacteria because it has a symmetric profile, is thinner and has no periodic acid-Schiff (PAS)-positive components. Normal-looking bacilli were seen very rarely inside jejunal macrophages, but degenerating bacteria were abundant in these phagocytes. Electron microscopy and ultrastructural cytochemistry of Whipple bacilli inside jejunal macrophages of the three untreated patients showed that the degenerative process is a sequence that leads to the loss of bacillary forms and to the accumulation of bacterial remnants resistant to degradation by the macrophage. These remnants correspond to the innermost, polysaccharide-containing portion of the bacillus wall. The progressive accumulation of these PAS-positive wall remnants is the origin of the intramacrophagic inclusions that are important in the histological diagnosis of Whipple's disease. The reported results indicate that in the three patients studied, the Whipple bacillus multiplies extracellularly, the bacteria that are phagocytosed by macrophages being degraded.