Apolar mode of gastrulation leads to the formation of polarized larva in a marine hydroid,Dynamena pumila

BackgroundIn almost all metazoans examined to this respect, the axial patterning system based on canonical Wnt (cWnt) signaling operates throughout the course of development. In most metazoans, gastrulation is polar, and embryos develop morphological landmarks of axial polarity, such as blastopore under control/regulation from Wnt signaling. However, in many cnidarian species, gastrulation is morphologically apolar. The question remains whether сWnt signaling providing the establishment of a body axis controls morphogenetic processes involved in apolar gastrulation.ResultsIn this study, we focused on the embryonic development ofDynamena pumila, a cnidarian species with apolar gastrulation. We thoroughly described cell behavior, proliferation, and ultrastructure and examined axial patterning in the embryos of this species. We revealed that the first signs of morphological polarity appear only after the end of gastrulation, while molecular prepatterning of the embryo does exist during gastrulation. We have shown experimentally that inD. pumila,the morphological axis is highly robust against perturbations in cWnt activity.ConclusionOur results suggest that morphogenetic processes are uncoupled from molecular axial patterning during gastrulation inD. pumila. Investigation ofD. pumilamight significantly expand our understanding of the ways in which morphological polarization and axial molecular patterning are linked in Metazoa.

Chick cranial neural crest cells migrate by progressively refining the polarity of their protrusions

SummaryIn vivo quantitative imaging reveals that chick cranial neural crest cells throughout the migratory stream are morphologically polarized and migrate by progressively refining the polarity of their protrusions.AbstractTo move directionally, cells can bias the generation of protrusions or select among randomly generated protrusions. Here we use 3D two-photon imaging of chick branchial arch 2 directed neural crest cells to probe how these mechanisms contribute to directed movement, whether a subset or the majority of cells polarize during movement, and how the different classes of protrusions relate to one another. We find that cells throughout the stream are morphologically polarized along the direction of overall stream movement and that there is a progressive sharpening of the morphological polarity program. Neural crest cells have weak spatial biases in filopodia generation and lifetime. Local bursts of filopodial generation precede the generation of larger protrusions. These larger protrusions are more spatially biased than the filopodia, and the subset of protrusions that power motility are the most polarized of all. Orientation rather than position is the best correlate of the protrusions that are selected for cell movement. This progressive polarity refinement strategy may enable neural crest cells to efficiently explore their environment and migrate accurately in the face of noisy guidance cues.

Optogenetic toolkit reveals the role of Ca2+sparklets in coordinated cell migration

Cell migration is controlled by various Ca2+signals. Local Ca2+signals, in particular, have been identified as versatile modulators of cell migration because of their spatiotemporal diversity. However, little is known about how local Ca2+signals coordinate between the front and rear regions in directionally migrating cells. Here, we elucidate the spatial role of local Ca2+signals in directed cell migration through combinatorial application of an optogenetic toolkit. An optically guided cell migration approach revealed the existence of Ca2+sparklets mediated by L-type voltage-dependent Ca2+channels in the rear part of migrating cells. Notably, we found that this locally concentrated Ca2+influx acts as an essential transducer in establishing a global front-to-rear increasing Ca2+gradient. This asymmetrical Ca2+gradient is crucial for maintaining front–rear morphological polarity by restricting spontaneous lamellipodia formation in the rear part of migrating cells. Collectively, our findings demonstrate a clear link between local Ca2+sparklets and front–rear coordination during directed cell migration.

p21-Activated Kinases Regulate Directional Migration and Cytoskeletal Organization in Human Neutrophils

Abstract 834 Neutrophil chemotaxis is controlled by coordinated processes of directional sensing, polarization and motility. This study was designed to characterize the role of p21-activated kinases (PAKs) during the chemotaxis of human primary neutrophils. PAKs are known as effectors of the Rho GTPases Rac and Cdc42. It has been shown that PAK1 and PAK2 are strongly activated downstream of the f-Met-Leu-Phe (fMLP) receptor via Rac (Huang et al., MCB 1998). PAK1 is known to localize in lamellipodia at the leading edge of human neutrophils (Dharmawardhane et al., JLB 1999) and mediate persistent directional migration via Cdc42 in a neutrophil-like cell line (Li et al., Cell 2003). However, little is known about the specific role of PAK isoforms in spatial/temporal regulation of cytoskeletal dynamics in human neutrophils. Our data show that human neutrophils express PAK1, 2 and 4. Under an fMLP gradient, human neutrophils developed morphological polarity with a distinct leading edge and rear, and migrated up the fMLP gradient at the speed of 7.5 ± 0.56 μm/min. Inhibition of Rac or PI3K impaired directionality but did not significantly affect migration speed of chemotaxing neutrophils (6.3 ± 0.56 μm/min or 6.2 ± 0.85 μm/min, respectively). In contrast, neutrophils treated with the PAK inhibitor, PF3758309 (PF), displayed random migration, less polarization and reduced motility (3.1 ± 0.21 μm/min). These results suggest that PAK regulates neutrophil chemotaxis independently of the Rac-PI3K axis. The presence of PF did not abrogate intracellular Ca2+mobilization in fMLP-driven chemotactic condition. Instead, the decreased migratory ability by PAK inhibition was associated with multiple Ca2+ spikes. Immunofluorescence imaging shows that PAK2 but not PAK1, was phosphorylated and translocated from cytosol to actin-rich leading edge in the proximity to GTP-bound Rac within 3 min of fMLP stimulation. Notably, PF treatment resulted in partial neutrophil spreading and actin/myosin II translocation in the absence of extracellular stimuli, suggesting that basal level of PAK phosphorylation may be required for cytoskeletal integrity of resting neutrophils. Neutrophils pretreated with PF displayed less activation and translocation of PAK2 and Rac. In summary, our data demonstrate for the first time the distinct roles of PAK isoforms in human neutrophil morphological polarity and directional migration and suggest that PAK2 is activated downstream of fMLP receptor through Rho-family small GTPases. Disclosures: No relevant conflicts of interest to declare.

A pharmacological cocktail for arresting actin dynamics in living cells

The actin cytoskeleton is regulated by factors that influence polymer assembly, disassembly, and network rearrangement. Drugs that inhibit these events have been used to test the role of actin dynamics in a wide range of cellular processes. Previous methods of arresting actin rearrangements take minutes to act and work well in some contexts, but can lead to significant actin reorganization in cells with rapid actin dynamics, such as neutrophils. In this paper, we report a pharmacological cocktail that not only arrests actin dynamics but also preserves the structure of the existing actin network in neutrophil-like HL-60 cells, human fibrosarcoma HT1080 cells, and mouse NIH 3T3 fibroblast cells. Our cocktail induces an arrest of actin dynamics that initiates within seconds and persists for longer than 10 min, during which time cells maintain their responsivity to external stimuli. With this cocktail, we demonstrate that actin dynamics, and not simply morphological polarity or actin accumulation at the leading edge, are required for the spatial persistence of Rac activation in HL-60 cells. Our drug combination preserves the structure of the existing cytoskeleton while blocking actin assembly, disassembly, and rearrangement, and should prove useful for investigating the role of actin dynamics in a wide range of cellular signaling contexts.

Global Gene Expression Analysis Identifies PDEF Transcriptional Networks Regulating Cell Migration during Cancer Progression

Prostate derived ETS factor (PDEF) is an ETS (epithelial-specific E26 transforming sequence) family member that has been identified as a potential tumor suppressor. In multiple invasive breast cancer cells, PDEF expression inhibits cell migration by preventing the acquisition of directional morphological polarity conferred by changes in cytoskeleton organization. In this study, microarray analysis was used to identify >200 human genes that displayed a common differential expression pattern in three invasive breast cancer cell lines after expression of exogenous PDEF protein. Gene ontology associations and data mining analysis identified focal adhesion, adherens junctions, cell adhesion, and actin cytoskeleton regulation as cell migration-associated interaction pathways significantly impacted by PDEF expression. Validation experiments confirmed the differential expression of four cytoskeleton-associated genes with known functional associations with these pathways: uPA, uPAR, LASP1, and VASP. Significantly, chromatin immunoprecipitation studies identified PDEF as a direct negative regulator of the metastasis-associated gene uPA and phenotypic rescue experiments demonstrate that exogenous urokinase plasminogen activator (uPA) expression can restore the migratory ability of invasive breast cancer cells expressing PDEF. Furthermore, immunofluorescence studies identify the subcellular relocalization of urokinase plasminogen activator receptor (uPAR), LIM and SH3 protein (LASP1), and vasodilator-stimulated protein (VASP) as a possible mechanism accounting for the loss of morphological polarity observed upon PDEF expression.

A developmentally regulated Na-H exchanger in Dictyostelium discoideum is necessary for cell polarity during chemotaxis

Increased intracellular H+ efflux is speculated to be an evolutionarily conserved mechanism necessary for rapid assembly of cytoskeletal filaments and for morphological polarity during cell motility. In Dictyostelium discoideum, increased intracellular pH through undefined transport mechanisms plays a key role in directed cell movement. We report that a developmentally regulated Na-H exchanger in Dictyostelium discoideum (DdNHE1) localizes to the leading edge of polarized cells and is necessary for intracellular pH homeostasis and for efficient chemotaxis. Starved DdNHE1-null cells (Ddnhe1−) differentiate, and in response to the chemoattractant cAMP they retain directional sensing; however, they cannot attain a polarized morphology, but instead extend mislocalized pseudopodia around the cell and exhibit decreased velocity. Consistent with impaired polarity, in response to chemoattractant, Ddnhe1− cells lack a leading edge localization of F-actin and have significantly attenuated de novo F-actin polymerization but increased abundance of membrane-associated phosphatidylinositol 3,4,5-trisphosphate (PI(3,4,5)P3). These findings indicate that during chemotaxis DdNHE1 is necessary for establishing the kinetics of actin polymerization and PI(3,4,5)P3 production and for attaining a polarized phenotype.