A computer-assisted system for reconstructing and interpreting the dynamic three-dimensional relationships of the outer surface, nucleus and pseudopods of crawling cells.

Newly developed software additions to the three-dimensional dynamic image analysis system, 3D-DIAS, are described for simultaneously reconstructing and motion analyzing in three dimensions the outer surface, nucleus and pseudopods of living, crawling cells. This new system is then used to describe for the first time a nuclear behavior cycle in translocating Dictyostelium discoideum amoebae and to investigate the role of pseudopod extension in this process. The nuclear behavior cycle is tuned to the two phases of the general cell behavior cycle [Wessels et al., 1994], and includes nuclear migration both in the z- and in the x,y-axes from the proximal border of the prior anterior pseudopod to the proximal border of a newly expanding anterior pseudopod. Nuclear migration is cued by pseudopod-substratum contact, achieves velocities in excess of 50 microm/min, and is accompanied by characteristic changes in nuclear shape. The rules and characteristics of nuclear behavior are demonstrated to be intact in two mutants affecting pseudopod formation, a myosin IB null mutant (myoB-) and a myosin II heavy chain phosphorylation mutant (3XALA). The rules and characteristics of nuclear migration, however, are disrupted upon dissolution of microtubules by colcemid. Together the above results demonstrate that the newly developed 3D-DIAS system can be used to gain new insights into the dynamic changes in the intracellular 3D architecture associated with cellular translocation.

Phosphorylation of the Dictyostelium myosin II heavy chain is necessary for maintaining cellular polarity and suppressing turning during chemotaxis.

Conversion of the three mapped threonine phosphorylation sites in the myosin II heavy chain tail to alanines results in a mutant (3XALA) in Dictyostelium discoideum, which displays constitutive myosin overassembly in the cytoskeleton and increased cortical tension. To assess the importance of myosin phosphorylation in cellular translocation and chemotaxis, 3XALA mutant cells have been analyzed by 2D and 3D computer-assisted methods in buffer, in a spatial gradient of cAMP, and after the rapid addition of cAMP. 3XALA cells crawling in buffer exhibit distinct abnormalities in cellular shape, the maintenance of polarity and the complexity of the pseudopod perimeter. 3XALA cells crawling in buffer also exhibit a decrease in directionality. In a spatial gradient of cAMP, the behavioral defects are accentuated. In a spatial gradient, 3XALA cells exhibit a repeating 1- to 2-min behavior cycle in which the shape of each cell changes abnormally from elongate to extremely wide with lateral, opposing pseudopods. At the end of each cycle, 3XALA cells turn 90 degrees into the left or right lateral pseudopod, resulting in a dramatic depression in chemotactic efficiency, even though 3XALA cells are chemotactically responsive to cAMP. These results demonstrate that the phosphorylation of myosin II heavy chain plays a critical role in the maintenance of cell shape and in persistent translocation in a spatial gradient of chemoattractant.

T cells and HIV-induced T cell syncytia exhibit the same motility cycle.

Ameboid cells ranging in complexity from Dictyostelium amebas to human polymorphonuclear leukocytes (PMNs) translocate in a cyclical fashion. Using computer-assisted motion analysis, we have analyzed the motility of human lymphocytes of the immortal SupT1 cell line and of a peripheral blood mononuclear cell population highly enriched for CD4-positive cells (CD4-enriched PBMCs) on four substrates--plastic, dehydrated rat tail collagen, hydrated rat tail collagen, and bovine aortic endothelium. In addition, we have analyzed the motility on these substrates of syncytia induced by human immunodeficiency virus (HIV) in cultures of both cell types. It is demonstrated that both SupT1 cells and CD4-enriched PBMCs exhibit a motility cycle with a period of 1.6 min that is independent of substrate, independent of average cell velocity, and similar to the periods of translocating Dictyostelium amebas and PMNs. More surprisingly, it is demonstrated that HIV-induced SupT1 and PBMC syncytia with volumes 10 to 100 times those of single cells exhibit the same motility cycle as their single-cell progenitors. These observations support the generality of the motility cycle in animal cells and, for the first time, demonstrate that the cycle is independent of cell size.

Use of stem proteins and isozymes for the identification of celery varieties.

Separation of stem proteins by sodium dodecyl sulfate polyacrylamide gel electrophoresis permitted classification of 17 celery varieties (Apium graveolens L.) into 7 groups. Several of these groups could be further subdivided into 11 subgroups with gel electrophoresis patterns of 4 isozyme systems. Classification from gel banding patterns was consistent with that based on pedigree histories.