Intraphagosomal Free Ca Changes during Phagocytosis.

Phagocytosis (and endocytosis) is an unusual cellular process that results in the formation of a novel subcellular organelle, the phagosome. This phagosome contains not only the internalised target of phagocytosis but also the external medium, creating a new border between extracellular and intracellular environments. The boundary at the plasma membrane is, of course, tightly controlled and exploited in ionic cell signalling events.

Microinjection and Micropipette-Controlled Phagocytosis Methods for Neutrophils.

The ability to microinject substances into the cytosol of living neutrophils opens the possibility of manipulating the chemistry within the cell and also of monitoring changes using indicators which otherwise cannot be introduced into the cell. However, neutrophils cannot be microinjected by the conventional glass pipette insertion method. Here we outline two techniques which work well with neutrophils, namely, SLAM (Simple Lipid-Assisted Microinjection) and electromicroinjection.

Minimal impact electro-injection of cells undergoing dynamic shape change reveals calpain activation.

The ability of neutrophils to rapidly change shape underlies their physiological functions of phagocytosis and spreading. A major problem in establishing the mechanism is that conventional microinjection of substances and indicators interferes with this dynamic cell behaviour. Here we show that electroinjection, a "no-touch" point-and-shoot means of introducing material into the cell, is sufficiently gentle to allow neutrophils to be injected whilst undergoing chemokinesis and spreading without disturbing cell shape change behaviour.

Microinjection methods for neutrophils.

The ability to microinject substances into the cytosol of living neutrophils opens the possibility of manipulating the chemistry within the cell and also of monitoring changes using indicators which otherwise cannot be introduced into the cell. However, neutrophils cannot be microinjected by the conventional glass pipette insertion method. Here, we outline two techniques which work well with neutrophils, namely, SLAM (simple lipid-assisted microinjection) and electroinjection.

Fibroblast dysfunction is a key factor in the non-healing of chronic venous leg ulcers.

Chronic age-related degenerative disorders, including the formation of chronic leg wounds, may occur due to aging of the stromal tissues and ensuing dysfunctional cellular responses. This study investigated the impact of environmental-driven cellular aging on wound healing by conducting a comprehensive analysis of chronic wound fibroblast (CWF) behavior in comparison with patient-matched healthy skin normal fibroblasts (NF). The dysfunctional wound healing abilities of CWF correlated with a significantly reduced proliferative life span and early onset of senescence compared with NF.

Lipid-protein cargo transfer: a mode of direct cell-to-cell communication for lipids and their associated proteins.

Cells in tissues or in experimental cell colonies respond to stimuli in a co-ordinated manner when they are electrically and chemically coupled by gap junctions. These junctions permit the cell-to-cell passage of small molecules, such as inositol tris phosphate (IP(3)) within the colony and are important in co-ordinating tissue activity. This is the only recognised mechanism of direct chemical signalling that does not involve the release of an extracellular messenger between cells.

Ca influx shutdown in neutrophils induced by Fas (CD95) cross-linking.

In neutrophils, as in most other cell types, Ca(2+) signalling is important for a number of cellular activities. Although inositol(1,4,5)trisphosphate-mediated release of Ca(2+) from intracellular stores is a necessary prelude, it is the Ca(2+) influx that is responsible for many of the neutrophil responses. We report here that although elevations of cytosolic Ca(2+) do not accompany Fas-mediated apoptosis in neutrophils, the Ca(2+) influx component of the response to N-formyl-methionyl-leucyl-phenylalanine (FMLP) becomes selectively inactived as the neutrophils progress towards accelerated apoptosis induced by Fas (CD95) cross-linking.

Ca(2+), calpain and 3-phosphorylated phosphatidyl inositides; decision-making signals in neutrophils as potential targets for therapeutics.

The chemical signals within neutrophils that control their behaviour are complex and these signals control the complex activity of neutrophils with precision. Failure of neutrophils to reform their antibacterial activity would lead to infection, while over-activity of neutrophils may lead to tissue damage and inflammatory disease. The identity of some of the intracellular signals is becoming clear and insights into the potential for interplay between them are being sought.

Exclusion of exogenous phosphatidylinositol-3,4,5-trisphosphate from neutrophil-polarizing pseudopodia: stabilization of the uropod and cell polarity.

Although there is accumulating evidence that the generation and localization of phosphatidylinositol-3,4,5-trisphosphate (PtdIns(3,4,5)P(3)) have important functions in neutrophil polarization and chemotaxis, the mechanism of this linkage has yet to be established. Here, using exogenous fluorescent PtdIns(3,4,5)P(3) introduced into the inner leaflet of the neutrophil plasma membrane by a cationic carrier, we show that: first, PtdIns(3,4,5)P(3) uniformly delivered to the neutrophil plasma membrane is excluded from newly forming pseudopodia; second, PtdIns(3,4,5)P(3) translocates to and is immobilized at the pole opposite a stable polarizing pseudopod; third, asymmetric delivery of PtdIns(3,4,5)P(3) to the neutrophil triggers the generation of polarizing pseudopodia at the opposite pole; and finally, PtdIns(3,4,5)P(3) triggers repetitive Ca(2+) signals, the onset of which precedes morphological polarization. These data suggest that translocation and immobilization of PtdIns(3,4,5)P(3) or a 3,x-phosphorylated metabolite in the uropod functions as an important polarization cue that defines neutrophil polarity and stabilizes the generation of pseudopodia at the opposite pole.

Phagosomal oxidative activity during beta2 integrin (CR3)-mediated phagocytosis by neutrophils is triggered by a non-restricted Ca2+ signal: Ca2+ controls time not space.

The temporal and spatial relationship between particle binding to the neutrophil by beta2 integrin (CR3), the Ca2+ elevation and subsequent oxidase activation has been unclear. This is because of the difficulty in studying the time course of individual phagocytic events in individual neutrophils. Here, we have used a micromanipulation technique to present C3bi-opsonised zymosan particles to the neutrophil under observation.

Intranuclear Ca2+ signals within individual nuclear lobes of neutrophils.

Cytosolic free Ca(2+)and intranuclear Ca(2+)behave similarly in human neutrophils. However, conventional laser scanning at 350 ms/frame resolution at lower than physiological temperatures demonstrates that (i) the nuclear fluo3-Ca(2+)signal persists longer than the cytosolic signal in some (but not all) nuclear lobes, (ii) the neutrophil nuclear membrane and fine inter-lobe filaments present barriers to diffusion of fluo3-Ca(2+)and lucifer yellow, and (iii) the diffusion barrier correlates with condensed chromosomal material on the nuclear envelope and blockage of the movement of fluo3-Ca(2+)into individual nuclear lobes.