Impaired motility of neonatal PMN leukocytes: relationship to abnormalities of cell orientation and assembly of microtubules in chemotactic gradients.

To allow a further understanding of the pathogenesis of impaired stimulated locomotion by polymorphonuclear leukocytes (PMNs) in human neonates, we studied cellular orientation by neonatal PMNs in response to well-defined chemotactic gradients (Zigmond orientation chambers) and characterized the cytoplasmic microtubule (MT) complex of neonatal PMNs during cell orientation and movement. PMN suspensions obtained from 52 neonates demonstrated a diminished capacity to undergo orientation at all time intervals after exposure to gradients of N-formyl-methionyl-leucyl phenylalanine (f-Met-Leu-Phe) or C5a. Among responding (orienting) neonatal PMNs observed, only 70% (f-Met-Leu-Phe) or 59% (C5a) oriented accurately (toward chemotactic gradients) as compared to values of 96% (f-Met-Leu-Phe) or 92% (C5a) for adult controls. Furthermore, neonatal PMNs failed to alter their direction of orientation/migration when chemotactic gradients were reversed. Similar abnormalities were observed when 10-fold gradients of f-Met-Leu-Phe were employed over a concentration range between 10(-7) and 10(-11) M. Employing tubulin immunofluorescence, the cytoplasmic MT complex of-neonatal PMNs was assessed prior to and after cell exposure to uniform concentrations or gradients of chemotactic factors (CFs). MT assembly by neonatal PMNs studied under these experimental conditions was significantly diminished. Neonatal cell suspensions demonstrated 26 +/- 5 (f-Met-Leu-Phe) or 27 +/- 6 (C5a) MT/cell as compared to respective values of 36 +/- 6 or 35 +/- 5 for adult suspensions (P less than .001). MT lengths of neonatal PMNs increased from 6.7 +/- 1 micron (PBS) to 7.5 +/- 1 micron (f-Met-Leu-Phe) or 7.3 +/- 1 micron (C5a) as compared to values of 6.5 +/- 1 micron (PBS), 11.1 +/- 1 micron (f-Met-Leu-Phe), and 10.9 +/- 1 micron (C5a) for adult PMNs exposed to gradients or uniform concentrations of CFs (P less than .01 for both f-Met-Leu-Phe and C5a). Thus, the polymerized tubulin mass product of chemotactically stimulated neonatal PMNs (202 micron) was significantly (P less than .001) diminished as compared to adult PMNs (360 micron). As shown by a [3H]colchicine binding assay, impaired MT assembly could not be attributed to diminished cytoplasmic tubulin content of neonatal PMNs, which was comparable to adult PMNs.

Cytoplasmic microtubules in polymorphonuclear leukocytes: effects of chemotactic stimulation and colchicine.

Indirect immunofluorescent (IIF) techniques employing antitutulin and anticentrosome antibodies were modified for studies of migrating polymorphonuclear (PMNs) leukocytes exposed to gradients or uniform concentrations of chemotactic factor (CF). No significant changes in microtubule (MT) number per cell occurred with chemotactic activation. Significant increases in average MT length per cell occurred upon exposure to gradients or uniform concentrations of CFs. Elongation of MT parallel to the direction of cell migration occurred coincident with shortening of other sets of MTs perpendicular to the direction of cell migration. MT extended radially from a single microtubule organizing center (MTOC) in greater than 99.9% of cells. Following chemotactic activation, the location of the MTOC was observed between nuclear lobes in 65% of fully polarized cells, "posterior" to the nucleus in congruent to 34% and "anterior" in less than 1%. Thus alterations of MT array occur coincident with cell orientation or migration in response to chemotactic stimuli.

Variations in cell form and cytoskeleton in human breast carcinoma cells in vitro.

Cell form and cytoskeletal organization were investigated in 13 human breast carcinoma cell lines in vitro. Using tubulin antibodies and indirect immunofluorescence to detect the arrangement of cytoplasmic microtubules, three distinct cell phenotypes were recognized: (a) cells with extensive arrays of microtubules (type 1); (b) cells which were diffusely stained with microtubules apparent only near the cell margins (type II intermediate); and (c) cells in which individual microtubules could not be detected and only diffuse fluorescence was apparent (type II diffuse). Type I cells were flattened epithelial-like cells, much like normal mammary epithelial cells, which when stained with actin antibody displayed many brightly fluorescent parallel cables or "stress fibers." Many microtubules and microfilament bundles were observed in type I cells when examined by transmission electron microscopy. Type II cells were more rounded, often grew in multilayered colonies, and displayed fewer microtubules and microfilament bundles when examined by either immunofluorescence or electron microscopy. Type II cells ranged from very small rounded cells with diffuse tubulin and actin immunofluorescence (type II diffuse) to more flattened cells in which microtubules and actin cables were observed near the flattened cell margins (type II intermediate). Since all of the cells were derived initially from malignant metastatic lesions and some were tumorigenic when injected into athymic nude mice, we assume that they remained malignant in vitro. Thus, in human breast carcinoma cells in vitro, it is not possible to associate any specific cell morphology or cytoskeletal phenotype with cancer or metastasis in vivo. Whether or not these same conclusions hold for breast tumor cells in situ remains to be determined.