An important characteristic of the functional differentiation of the blood monocyte is the development of its capacity to recognize and respond to stimuli. This ability is mediated to a large extent by specific receptor glycoproteins located on the cell surface. Stimulation of mononuclear phagocytes via these receptors results in a rapid rise in intracellular Ca++ concentration, accompanied or followed by a change in membrane potential, generation of oxidative products, degranulation, and effector functions such as phagocytosis, aggregation, or locomotion. While the development of these characteristics is difficult to characterize in vivo, several investigators have demonstrated in vitro changes in these cells that correlate with the development of effector function. To examine the mechanisms of specific membrane-stimulus interactions of monocytes as they differentiate into macrophage-like cells, we studied the responses of human monocytes and of monocytes incubated in serum-containing medium for up to 96 hr to the chemotactic peptide formyl-methionyl-leucyl-phenylalanine (fMLP). Freshly isolated monocytes exhibited little change in transmembrane potential following stimulation with an optimal concentration of peptide and underwent a significant increase only after 48 hr in culture. While constant resting intracellular Ca++ concentrations were maintained during the culture period, intracellular Ca++ levels following fMLP stimulation increased with with incubation in serum, for up to 96 hr. In contrast, fMLP-induced respiratory burst activity increased from 0 to 24 hr in culture; it remained elevated at 48 hr but declined again by 96 hr. Incubation of the cells for 24 hr increased their random (unstimulated) motility in modified Boyden chambers but did not alter the cells' directed (chemotactic) response to fMLP in comparison to the response of freshly isolated monocytes. Peptide binding to the cells did not increase during the incubation period, indicating that an increase in receptor number or in affinity for fMLP was not responsible for the enhanced responsiveness to fMLP as incubation time increased. These studies indicate that incubation of monocytes in serum-containing medium leads to a complex, altered series of responses to fMLP that correlate with the differentiation of the original monocytes in vitro and may relate to the in vivo differentiation of monocytes to macrophages.
Treatment of human leukemic HL-60 cells with N,N-dimethylformamide (DMF) induces them to mature until they reach granulocytoid morphology 3-6 d later. We have reported a maturation-dependent ability of these cells to respond to phorbol myristate acetate (PMA), as evaluated by membrane depolarization and by oxidative burst product formation (Newburger et al.: J. Biol. Chem. 259,3771, 1984). More recently we have attempted to develop techniques for simultaneous evaluation of these parameters during HL-60 cell maturation. Here, we compare the cytoplasmic [Ca++] and membrane potential changes elicited by the chemotactic peptide fMLP via simultaneous measurement of individual cells in a fluorescence-activated cell sorter (FACS), as done previously for mature granulocytes (Lazzari et al.: J. Biol. Chem. 261,9710, 1986). The stimulus-induced [Ca++]in changes are detected with the fluorescent probe Indo-1 and reproducibly increase in magnitude for a subpopulation of cells as the cells mature into granulocytes. Ca++ responsiveness to formyl peptide is restricted to a subpopulation of HL-60 granulocytes which expresses receptors for chemotactic peptide and consistently increases in magnitude (in response to the same concentration of agonist) with maturation. In contrast, there is less consistency in the direction or magnitude of membrane potential changes elicited under the same circumstances from the same maturing HL-60 cells.
Medical Engineering and Medical PhysicsI. ABSTRACT Methods of obtaining nuclear magnetic resonance (NMR) images containing chemical shift information are presented. Using a three-dimensional Fourier Transform approach (two spatial axes and one resonance frequency axis), proton chemical shift images were acquired in phantoms and in-vivo using both spin echo and free induction decay (FID) pulse sequences. A proton resonance frequency of 61.5 MHz, corresponding to a magnetic field strength of 1.44 tesla, was used. In simple phantoms, chemical shift images indicate that spectral resolution of 0.7 parts per million (ppm) is readily achieved at all locations within the image matrix, even when using a magnet not specifically designed for chemical shift spectroscopy. In-vivo images of normal human forearms and cat heads yield separable signals from water and lipid protons. In the cat brain, no appreciable NMR signal originates from membrane lipids (e.g., myelin); images acquired using FID pulse sequences imply T 2 relaxation times less than 2 msec for these protons. The measurement of magnetic susceptibility using this technique is also demonstrated. The effect of susceptibility variations in-vivo appears in general to be less than 1 ppm.Proton chemical shift imaging was used to study fatty liver change in the rat. The correlation between lipid group signal intensity from chemical shift images i'n-viv and liver triglyceride levels measured in-vitro was good (r = .97). In-vivo T 1 relaxation time measurements were made on lipid and water protons separately. Values calculated were corrected for the influence of gaussian plane selection and spin echo data acquisition, and demonstrate different T 1 times reflecting two distinct populations of non-exchanging protons. Proton chemical shift imaging offers enhanced sensitivity over conventional NMR imaging techniques in characterizing fatty liver disease.Selective saturation (solvent suppression) techniques were used in an imaging context in both phantoms and in-vivo. Using a three-dimensional chemical shift imaging approach, data presented demonstrate the feasibility of imaging proton metabolites at low concentration. Phantom studies without solvent suppression failed to detect lactate at 80 mM; however with solvent suppression, lactate at 40 mM was imaged in a reasonable time (approximately 50 minutes). Using a conventional two-dimensional NMR imaging technique preceded by a selective (saturating) pulse, signal from water or lipid protons were eliminated (>95% reduction in signal intensity), resulting in images of -CH 2 -or H 2 0 proton distribution with resolution and imaging times equivalent to conventional proton images. With improvements in imaging systems, these techniques may play an important role in the non-invasive evaluation of tissue ischemia using proton NMR. where Y is the gyromagnetic ratio (defined as the ratio of the nuclear magnetic moment to the spin angular momentum) and B is the magnetic field seen by the nucleus (5). This B field is traditionally rewritte...
Stimulation of phagocytic leukocytes with chemotactic factors results in transient acidification, followed by alkalinization of the cytosol. Human monocytes are known to alter their functional responses to the chemotactic peptide N-formylmethionyl-leucyl-phenylalanine (fMLP) in a complex fashion as they mature in vitro to macrophages. To examine the evolution of the cytoplasmic pH (pHi) response of monocytes to fMLP as they mature into macrophages, we incubated cells for 0, 24, 48, and 96 h (Medium-199 + 10% fetal bovine serum; 37 degrees C) and examined pHi using the fluorescent probe 2',7'-bis(carboxyethyl)-5(6)-carboxyfluorescein (BCECF; 1 microM) and a Perkin-Elmer 650/10 spectrofluorimeter (lambda em = 530 nm, lambda ex = 500, 450 nm) as previously described. The resting pHi of fresh (0 h) monocytes was 7.07 +/- 0.16 (SD) and was unchanged after incubation for 24, 48, or 96 h (7.09, 7.11, 7.05, respectively). Cells exhibited an fMLP dose-dependent cytoplasmic acidification, with maximal delta pHi occurring 30-60 s after exposure to 10(-7) M fMLP. The response to fMLP did not change with the duration of incubation and, as with neutrophils, cytoplasmic realkalinization was blocked by dimethylamiloride (20 microM). Incubation with 2-deoxyglucose (10 min, 5 mM), sufficient to inhibit by more than 90% the formyl peptide-stimulated superoxide generation by monocytes, slowed fMLP-induced acidification and abrogated the alkalinization. In addition, monocytes isolated from the blood of a patient with X-linked chronic granulomatous disease (CGD) underwent fMLP-induced acidification that was unmasked further by coincubation with dimethylamiloride, in a manner quantitatively similar to that of normal monocytes, despite the inability of the CGD cells to produce superoxide. The chemotactic factor-induced cytoplasmic pH responses of monocytes/macrophages remained constant as the cells matured in vitro and exhibited a dimethylamiloride-independent acidification and dependent alkalinization, as did the response in neutrophils. The cytoplasmic acidification of these cells thus did not correlate with the cells' production of superoxide and with the concomitant hexose monophosphate shunt activation, as has been suggested for other leukocyte types.
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