Marcela Camacho

Leishmania amazonensis infection may affect the ability of the host macrophage to be activated by altering their outward potassium currents

Understanding the impact of intracellular pathogens on the behaviour of their host cells is key to designing new interventions. We are interested in how Leishmania alters the electrical functioning of the plasma membrane of the macrophage it infects. The specific question addressed here is whether Leishmania amazonensis infection alters the macrophages outward currents and what the consequences of such changes might be. Using the whole cell configuration of the patch clamp technique, we show that outward peak current density remains constant over the period studied but that time to peak and sensitivity to inhibitors vary during infection. Infected cells take 40% longer to activate and are more sensitive to the potassium channel inhibitor tetraethyl ammonium, compared to control cells, indicating increased potassium outward current activity. Activation of macrophages is associated with increases of nitric oxide production and membrane area, depolarization of the macrophage membrane, down regulation of inward potassium and up regulation of outward currents. After Leishmania infection, macrophage activation is characterised by a reduction of nitric oxide production and of outward current density. We therefore suggest that this reflects a weaker activation.

Changes in macrophage membrane properties during early Leishmania amazonensis infection differ from those observed during established infection and are partially explained by phagocytosis

Understanding the impact of intracellular pathogens on the behavior of their host cells is key to designing new interventions. We are interested in how Leishmania alters the electrical function of the plasma membrane of the macrophage it infects. The specific question addressed here is the impact of Leishmania infection on macrophage membrane properties during the first 12h post-infection. A decrease of 29% in macrophage membrane capacitance at 3h post-infection indicates that the phagolysosome membrane is donated on entry by the macrophage plasma membrane. Macrophage membrane potential depolarized during the first 12h post-infection, which associated with a decreased inward potassium current density, changed in inward rectifier conductance and increased outward potassium current density. Decreased membrane capacitance and membrane potential, with no changes in ion current density, were found in macrophages after phagocytosis of latex beads. Therefore we suggest that the macrophage membrane changes observed during early Leishmania infection appear to be associated with the phagocytic and activation processes.

Leishmania (Viannia) braziliensis growth in vitro culture relies more on folic acid availability than Leihsmania (Leishmania) amazonensis

We compared the in vitro growth of promastigotes from two Leishmania species in TC-100 and Schneider media. Leishmania (Leishmania) amazonensis replication rates were similar in both tissue culture media and reached maximum rates by 48 h. In contrast Leishmania (Viannia) braziliensis growth was significantly greater in TC-100 but maximum rates were achieved by 96 h. Folic acid appears to be the limiting factor and supplementation of Schneider media with this nutrient improved L. (V.) braziliensis replication rates and decreased the time of maximum replication to 48 h.

Bufo marinus Oocytes as a Model for Ion Channel Protein Expression and Functional Characterization for Electrophysiological Studies

Oocytes from Xenopus laevis are commonly used as an expression system for ion channel proteins. The aim of this study was to determine whether oocytes from the Colombian native toad, Bufo marinus, could be used as an alternative expression system for ion channel protein expression and functional characterization using the two-microelectrode voltage clamp method. B. marinus oocytes and X. laevis were isolated and cultured in similar conditions. The mean resting membrane potential of B. marinusoocytes was similar to that of X. laevis oocytes as well as the whole-cell basal currents. The potassium ion channel Kv1.1 was successfully expressed in B. marinus oocytes and showed a typical outward rectifying current. Potassium channel blockers reduced these currents. The similarities on electrical properties and expression of ion channel proteins show that B. marinus oocytes can be used effectively to express these proteins, making these cells a viable heterologous system for the expression of ion channel proteins and their electrophysiological characterization.

Acute hydrodynamic damage induced by SPLITT fractionation and centrifugation in red blood cells.

Though blood bank processing traditionally employs centrifugation, new separation techniques may be appealing for large scale processes. Split-flow fractionation (SPLITT) is a family of techniques that separates in absence of labelling and uses very low flow rates and force fields, and is therefore expected to minimize cell damage. However, the hydrodynamic stress and possible consequent damaging effects of SPLITT fractionation have not been yet examined. The aim of this study was to investigate the hydrodynamic damage of SPLITT fractionation to human red blood cells, and to compare these effects with those induced by centrifugation. Peripheral whole blood samples were collected from healthy volunteers. Samples were diluted in a buffered saline solution, and were exposed to SPLITT fractionation (flow rates 1-10 ml/min) or centrifugation (100-1500 g) for 10 min. Cell viability, shape, diameter, mean corpuscular hemoglobin, and membrane potential were measured. Under the operating conditions employed, both SPLITT and centrifugation maintained cell viability above 98%, but resulted in significant sublethal damage, including echinocyte formation, decreased cell diameter, decreased mean corpuscular hemoglobin, and membrane hyperpolarization which was inhibited by EGTA. Wall shear stress and maximum energy dissipation rate showed significant correlation with lethal and sublethal damage. Our data do not support the assumption that SPLITT fractionation induces very low shear stress and is innocuous to cell function. Some changes in SPLITT channel design are suggested to minimize cell damage. Measurement of membrane potential and cell diameter could provide a new, reliable and convenient basis for evaluation of hydrodynamic effects on different cell models, allowing identification of optimal operating conditions on different scales.

Separation of Leishmania-infected macrophages by step-SPLITT fractionation

After a primary infection protocol of macrophages with Leishmania amazonensis, the percentage of infection drops as infection progresses and the uninfected population of macrophages mask the effects of infection for electrophysiological studies. In order to increase or maintain the infection percentage, we introduce an enrichment process after primary infection, which increases the possibility of following the infection longer times than any known process. A membraneless separation technique, step-SPLITT fractionation, implying flow and transverse gravity field in a ribbon-like channel, was used for enriching samples of macrophages infected with particles and with L. amazonensis. We demonstrate the capability of the s-SPLITT of generating, from a mixture resulting from a primary infection, an enriched and a depleted fraction with infected cells, without using any selective labeling pre-processing. It is also shown that a continuous sorting is possible without damaging cells and the losses of matter into the separation chamber is minimal.