Permeabilization of lymphocytes with polyethylene glycol 1000. Discrimination of permeabilized cells by flow cytometry

Pushing the science forward: chitosan nanoparticles and functional repair of CNS tissue after spinal cord injury

BACKGROUND

We continue our exploration of the large polysaccharide polymer Chitosan as an acute therapy for severe damage to the nervous system. We tested the action of subcutaneously injected nanoparticles (~ 100 - 200 nanometers in diameter; 1 mg per ml) against control injections (silica particle of the same size and concentration) in a standardized in vivo spinal cord injury model. These functional tests used standardized physiological measurements of evoked potentials arriving at the sensorimotor cortex subsequent to stimulation of the tibial nerve of the contralateral hindlimb. We further explored the degree of acetylation and molecular weight of chitosan on the success of sealing cell damage using specific probes of membrane integrity.

RESULTS

Not one of the control group showed restored conduction of evoked potentials stimulated from the tibial nerve of the hindleg - through the lesion - and recorded at the sensorimotor cortex of the brain. Investigation if the degree of acetylation and molecular weight impacted "membrane sealing" properties of Chitosan were unsuccessful. Dye - exchange membrane probes failed to show a difference between the comparators in the function of Chitosan in ex vivo injured spinal cord tests.

CONCLUSIONS

We found that Chitosan nanoparticles effectively restore nerve impulse transmission through the crushed adult guinea pig spinal cord in vivo after severe crush/compression injury. The tests of the molecular weight (MW) and degree of acetylation did not produce any improvement in Chitosan's membrane sealing properties.

Effects of 4-nitroquinoline-1-oxide on population growth, cell-cycle compartmentalization and viability in human lymphoblastoid cells

The mechanism by which the carcinogen 4-nitroquinoline-1-oxide (4-NQO) kills mammalian cells is unclear; however, damage to DNA is presumed to be involved. We examined the relationship between the kinetics of cell death and alteration of cell-cycle compartmentalization after exposure of T5-1 human lymphoblastoid cells to 4-NQO (50 to 500 ng/ml) to establish whether cytotoxicity was related to the perturbation of DNA replication. Dose-dependent reductions in cell proliferation and cell viability were present from 1 day after treatment. Maximal reductions in viability were observed 2 days after exposure. Concentrations of 4-NQO of up to 175 ng/ml did not affect cell-cycle compartmentalization, but 250 ng 4-NQO/ml caused a transient accumulation of cells in S phase after 1 day. Only after 500 ng 4-NQO/ml was a marked and prolonged S-phase block observed from 1 day onwards. The lack of a strong correlation between S-phase block and cell death after exposure to 4-NQO suggests that responses to DNA damage in addition to perturbation of DNA replication entrain 4-NQO-induced cell lethality.

Affinity for, and localization of, PEG-functionalized silica nanoparticles to sites of damage in an ex vivo spinal cord injury model

Background

Traumatic spinal cord injury (SCI) leads to serious neurological and functional deficits through a chain of pathophysiological events. At the molecular level, progressive damage is initially revealed by collapse of plasma membrane organization and integrity produced by breaches. Consequently, the loss of its role as a semi-permeable barrier that generally mediates the regulation and transport of ions and molecules eventually results in cell death. In previous studies, we have demonstrated the functional recovery of compromised plasma membranes can be induced by the application of the hydrophilic polymer polyethylene glycol (PEG) after both spinal and brain trauma in adult rats and guinea pigs. Additionally, efforts have been directed towards a nanoparticle-based PEG application.

The in vivo and ex vivo applications of PEG-decorated silica nanoparticles following CNS injury were able to effectively and efficiently enhance resealing of damaged cell membranes.

Results

The possibility for selectivity of tetramethyl rhodamine-dextran (TMR) dye-doped, PEG-functionalized silica nanoparticles (TMR-PSiNPs) to damaged spinal cord was evaluated using an ex vivo model of guinea pig SCI. Crushed and nearby undamaged spinal cord tissues exhibited an obvious difference in both the imbibement and accumulation of the TMR-PSiNPs, revealing selective labeling of compression-injured tissues.

Conclusions

These data show that appropriately functionalized nanoparticles can be an efficient means to both 1.) carry drugs, and 2.) apply membrane repair agents where they are needed in focally damaged nervous tissue.

Functional implications of membrane modification with semenogelins for inhibition of sperm motility in humans

Semenogelin I and II (Sgs) are the major component of human semen coagulum. The protein is rapidly cleaved after ejaculation by a prostate-specific antigen, resulting in liquefaction of the semen coagulum and the progressive release of motile spermatozoa. Sgs inhibit human sperm motility; however, there is currently no information on its effect on the sperm membrane. This study investigated the role of Sgs on human sperm motility through regulation of membrane potential and membrane permeability. Fresh semen samples were obtained from normozoospermic volunteers, and studies were conducted using motile cells selected using the swim-up method. Sgs changed the characteristics of sperm motion from circular to straightforward as evaluated by a computer-assisted motility analyzer, and all parameters were decreased more than 2.5 mg/mL. The results demonstrate that Sgs treatment immediately hyperpolarized the membrane potential of swim-up-selected sperm, changed the membrane structure, and time-dependently increased membrane permeability, as determined through flow cytometric analysis. The biphasic effects of Sgs were time- and dose-dependent and partially reversible. In addition, a monoclonal antibody against Sgs showed positive binding to cell membrane proteins in fixed cells, observed with confocal fluorescence microscopy. These results demonstrate that Sgs modifies the membrane structure, indirectly inhibiting motility, and provides suggestions for a therapy for male infertility through selection of a functional sperm population using Sgs.

Intracellular turnover of fluorescein diacetate. Influence of membrane ionic gradients on fluorescein efflux

The influence of the membrane ionic gradient on the efflux of Fluorescein after intracellular turnover of Fluorescein diacetate was studied in HeLa cells. The kinetics of Fluorescein efflux was monitored by determining with flow cytometry the decrease in fluorescence intensity of single cells. Alterations of the Na+ and K+ gradients were induced experimentally by using ouabain, ionophores or buffers in which the ion concentration was modified. The sodium gradient was also altered by using Na(+)-co-transported amino acids. Independent evidence of these changes was obtained with a potential-sensitive indicator, 3,3'-dihexyloxacarbocyanine iodide. Conditions inducing a reduction or dissipation of the ionic gradients caused a decrease in the rate constant of Fluorescein release. In contrast, enhancement of the gradients increased the efflux rate. These results indicate that the release of Fluorescein from living cells is influenced by the membrane potential. Thus, the turnover of Fluorescein diacetate may provide a useful technique for assessing changes in membrane permeability properties related to ionic gradients.

Light-induced permeabilization and merocyanine 540 staining of mouse spleen cells

Merocyanine 540 (M540) is a potential-sensitive, hydrophobic dye that preferentially incorporates into the 'fluid' domains of cellular membranes, distinguishing between hemopoietic cells according to their differentiation state. A bright staining with M540 is usually achieved by UV illumination of the cells during staining. We show by flow cytometric analysis that: (1) staining is greatly enhanced by UV illumination of mouse spleen cells before addition of the dye; (2) UV treatment causes an increased permeability toward propidium iodide and intracellular fluorescein as well; (3) the increment in M540 fluorescence precedes permeabilization to propidium iodide, while the latter precedes leakage of fluorescein. We also describe an overshoot and accelerated recovery of M540 fluorescence after photobleaching by a 514 nm laser beam. It is suggested that penetration of M540 to the more fluid inner membrane structures explains the fluorescence increment in both experiments.

S-phase block and cell death in human lymphoblasts exposed to benzo[a]pyrene diol epoxide or N-acetoxy-2-acetylaminofluorene

The relationship between perturbation of the cell cycle and induction of cell death by benzo[a]pyrene diol epoxide (BPDE) or N-acetoxy-2-acetylaminofluorene (AcAAF) in exponentially proliferating T5-1 human lymphoblastoid cells was studied. Both BPDE and AcAAF caused cells to accumulate in the S phase of the cell cycle. Perturbation of the cell cycle preceded reduction of cell viability and was associated with inhibition of population growth. Effects on each of the three parameters were noted during the first population doubling, suggesting that they occurred during the first cell cycle after exposure. BPDE-exposed cells accumulated initially in early to mid-S phase and then moved parasynchronously through the remainder of this phase. In contrast, AcAAF-exposed cells accumulated uniformly at all points of the S phase. High doses of either compound froze cell cycle progression, completely inhibited population growth, and killed nearly all cells in the population. Our results suggest that perturbation of DNA replication mediates cell death after exposure to doses of either chemical that cause less than complete inhibition of cell proliferation. However, additional processes, such as perturbation of transcription, may be involved in lethality after exposure to doses that immediately and completely inhibit population growth.

Osmotic forces in artificially induced cell fusion

The importance of cell swelling in the fusion of erythrocytes by three different chemical treatments has been investigated with cells that were cytoplasmically labelled with 6-carboxyfluorescein. Hen erythrocytes, which had been pre-incubated with ionophore A23187 and 5 mM Ca2+ to cause a proteolytic breakdown of the membrane skeleton, were induced to fuse by applying an osmotic shock. Human erythrocytes that had been incubated in an isotonic salt/buffer solution, which was progressively diluted and which contained 0.5 mM La3+ to minimise cell lysis, were also fused. In addition, the fusion of human erythrocytes by 40% poly(ethylene glycol) began only when the poly(ethylene glycol) was diluted, and it mostly occurred when the diluted polymer solution was subsequently replaced by isotonic buffer. In related experiments, the effect of an osmotic gradient on electrically induced cell fusion has been studied. Human erythrocytes in 150 mM erythritol fused more readily than less swollen cells in 200-400 mM erythritol when subjected to a 20 microseconds pulse of 3.5 kV X cm-1, indicating that the extent of cell fusion induced by the breakdown pulse is governed by the combined electrical-compressive and osmotic forces. Since osmotic phenomena are already known to be important in exocytosis, we suggest that these observations on cell fusion indicate that osmotic forces may provide the driving force for many membrane fusion reactions in biological systems.

Flow cytometric analysis of membrane permeability properties influencing intracellular accumulation and efflux of fluorescein

A flow cytometric investigation has been made on the membrane permeability properties that mediate intracellular turnover of fluorogenic substrates. The accumulation and efflux of fluorescein, consequent to the enzymatic turnover of fluorescein diacetate, were assessed in the presence of metabolic inhibitors and after treatment with membrane-active compounds. The metabolic poisons KCN and rotenone greatly inhibited only the fluorescein efflux, reducing the rate constant to as little as one-tenth in relation to control cells; in the presence of glucose such inhibition was partially removed. Glucose availability also affected fluorescein efflux: an increase of the rate constant was observed in cells treated with 20 mM glucose, and a decrease was measured in cells incubated for 1 hr in glucose-free buffer. Membrane-active compounds Triton X-100 and hydrocortisone reduced fluorescein accumulation. Hydrocortisone strongly blocked also the efflux; the addition of glucose did not restore the rate significantly. The major evidence of these results is that fluorescein efflux is dependent on membrane integrity and on availability of metabolic energy. Fluorescein accumulation is only partially related to permeability properties regulating FDA uptake, due to the influence that treatments exhibit at the same time on FDA hydrolysis and/or fluorescein release.