Direct suppression of phagocytosis by amphipathic polymeric surfactants.

Recent studies have demonstrated that phagocytosis of colloidal particles by the mononuclear phagocytes of the liver and spleen can be controlled by either coating or stabilizing particulate carriers with the amphipathic polymeric surfactants, F108 and T908. These surfactants consist of copolymers of polypropylene oxide (PPO) and polyethylene oxide (PEO) and, when adsorbed to particulate surfaces, significantly decrease sequestration of particulates by the mononuclear phagocytes (MPS) of the liver. To evaluate these observations further, murine peritoneal macrophages were incubated for varying periods with surfactant-coated and noncoated polystyrene particles (PSPs). Phagocytosis was monitored using gamma counting and quantitative fluorescence microscopy. The data show that phagocytosis is decreased when PSPs are coated with F108 and T908. In addition, suppression of phagocytic activity was observed when cells were pretreated with the surfactant and then challenged with noncoated particles. The data confirm previous observations that polymeric surfactants consisting of PEO and PPO protect particulate carriers from rapid uptake by the MPS of the liver. Further, F108 and T908 suppress phagocytosis directly without affecting the integrity, viability, or functional state of the cell.

Extracellular matrix allows PC12 neurite elongation in the absence of microtubules.

Several groups have shown that PC12 will extend microtubule-containing neurites on extracellular matrix (ECM) with no lag period in the absence of nerve growth factor. This is in contrast to nerve growth factor (NGF)-induced neurite outgrowth that occurs with a lag period of several days. During this lag period, increased synthesis or activation of assembly-promoting microtubule-associated proteins (MAPs) occurs and is apparently required for neurite extension. We investigated the growth and microtubule (MT) content of PC12 neurites grown on ECM in the presence or absence of inhibitors of neurite outgrowth. On ECM, neurites of cells with or without prior exposure to NGF contain a normal density of MTs, but frequently contain unusual loops of MTs in their termini that may indicate increased MT assembly. On ECM, neurites extend from PC12 cells in the presence of 10 microM LiCl at significantly higher frequency than on polylysine. On other substrates, LiCl inhibits neurite outgrowth, apparently by inhibiting phosphorylation of particular MAPs (Burstein, D. E., P. J. Seeley, and L. A. Greene. 1985. J. Cell Biol. 101:862-870). Although 35-45% of 60 Li(+)-neurites examined were found to contain a normal array of MTs, 25-30% were found to have a MT density approximately 15% of normal. The remaining 30% of these neurites were found to be nearly devoid of MTs, containing only occasional, ambiguous, short tubular elements. We also found that neurites would extend on ECM in the presence of the microtubule depolymerizing drug, nocodazole. At 0.1 micrograms/ml nocodazole, cells on ECM produce neurites that contain a normal density of MTs. This is in contrast to the lack of neurite outgrowth and retraction of extant neurites that this dose produces in cells grown on polylysine. At 0.2 microgram/ml nocodazole, neurites again grew out in substantial number and four of five neurites examined ultrastructurally were found to be completely devoid of microtubules. We interpret these results by postulating that growth on ECM relieves the need for MTs to serve as compressive supports for neurite tension (Dennerll, T. J., H. C. Joshi, U. L. Steel, R. E. Buxbaum, and S. R. Heidemann. 1988. J. Cell Biol. 107:665). Because compression destabilizes MTs and favors disassembly, this would tend to increase MT assembly relative to other conditions, as we found. Additionally, if MTs are not needed as compressive supports, neurites could grow out in their absence, as we also observed.

Tension and compression in the cytoskeleton of PC-12 neurites. II: Quantitative measurements.

We assessed the mechanical properties of PC-12 neurites by applying a force with calibrated glass needles and measured resulting changes in neurite length and deflection of the needle. We observed a linear relationship between force and length change that was not affected by multiple distensions and were thus able to determine neurite spring constants and initial, nondistended, rest tensions. 81 out of 82 neurites showed positive rest tensions ranging over three orders of magnitude with most values clustering around 30-40 mu dynes. Treatment with cytochalasin D significantly reduced neurite rest tensions to an average compression equal to 14% of the former tension and spring constants to an average of 17% of resting values. Treatment with nocodazole increased neurite rest tensions to an average of 282% of resting values but produced no change in spring constant. These observations suggest a particular type of complementary force interaction underlying axonal shape; the neurite actin network under tension and neurite microtubules under compression. Thermodynamics suggests that microtubule (MT) assembly may be regulated by changes in compressive load. We tested this effect by releasing neurite attachment to a polylysine-coated surface with polyaspartate, thus shifting external compressive support onto internal elements, and measuring the relative change in MT polymerization using quantitative Western blotting. Neurons grown on polylysine or collagen without further treatment had a 1:2 ratio of soluble to polymerized tubulin. When neurites grown on polylysine were treated with 1% polyaspartate for 15-30 min, 80% of neurites retracted, shifting the soluble: polymerized tubulin ratio to 1:1. Polyaspartate treatment of cells grown on collagen, or grown on polylysine but treated with cytochalasin to reduce tension, caused neither retraction nor a change in the soluble:polymerized tubulin ratio. We suggest that the release of adhesion to the dish shifted the compressive load formerly borne by the dish onto Mts causing their partial depolymerization. Our observations are consistent with the possibility that alterations in MT compression during growth cone advance integrates MT assembly with the advance.