Microfluidic-based cell sorting of Francisella tularensis infected macrophages using optical forces.

We have extended the principle of optical tweezers as a noninvasive technique to actively sort hydrodynamically focused cells based on their fluorescence signal in a microfluidic device. This micro fluorescence-activated cell sorter (microFACS) uses an infrared laser to laterally deflect cells into a collection channel. Green-labeled macrophages were sorted from a 40/60 ratio mixture at a throughput of 22 cells/s over 30 min achieving a 93% sorting purity and a 60% recovery yield. To rule out potential photoinduced cell damage during optical deflection, we investigated the response of mouse macrophage to brief exposures (<4 ms) of focused 1064-nm laser light (9.6 W at the sample). We found no significant difference in viability, cell proliferation, activation state, and functionality between infrared-exposed and unexposed cells. Activation state was measured by the phosphorylation of ERK and nuclear translocation of NF-kappaB, while functionality was assessed in a similar manner, but after a lipopolysaccharide challenge. To demonstrate the selective nature of optical sorting, we isolated a subpopulation of macrophages highly infected with the fluorescently labeled pathogen Francisella tularensis subsp. novicida. A total of 10,738 infected cells were sorted at a throughput of 11 cells/s with 93% purity and 39% recovery.

[The interaction of dynamic speckles with suspensions of gram-negative cells].

The role of temporal coherence at photodynamic action of light on living cells was investigated. A mathematical model describing the interaction of low-coherent speckles with bacterial cells was suggested and its parameters were determined based on experimental data. The interrelation between the life time of dynamic optical speckles and the degree of photodestruction of illuminated cells was established by computer simulations. The conditions were determined under which the photoinactivation of cells of the vaccine strain of the causative agent of F. tularensis 15 NIIEG occurs.

Natural killer and CD8 T cells dominate the response by human peripheral blood mononuclear cells to inactivated Francisella tularensis live vaccine strain.

Francisella tularensis is a category A biothreat agent, and as a result, it has recently generated much research interest. F. tularensis live vaccine strain (LVS) is an attenuated form of the virulent F. tularensis organism and has previously been used as a vaccine. However, because of safety concerns, it is no longer approved for this purpose. Thus, the use of inactivated organisms is preferable for vaccine purposes. Although many studies have been performed that examine human peripheral blood mononuclear cells (PBMC), and in particular CD4 T cells, responses to inactivated F. tularensis, there has been no study identifying the individual human cell populations within a mixed PBMC population that respond to this organism. We sought to address this deficit. Our results indicate that natural killer and CD8 T cells comprise the majority of cells responding to F. tularensis LVS. In addition, data suggest CD8 T cell responses are maximal when antibiotic-treated organisms are used and are minimal when formaldehyde-fixed organisms are used. Given the belief that CD8 T cells can play an important role in protection against F. tularensis infection, these studies have direct relevance to the development of F. tularensis vaccines that use inactivated organisms. In addition, important new knowledge is added to our understanding of the human immune response to F. tularensis LVS.

Toxicity of Pasteurella tularensis killed by ionizing radiation.

Approximately 2 x 10(11) viable Pasteurella tularensis cells per ml, contained in suspensions, were killed by exposure to 10(6) r of gamma-radiation. When injected intraperitoneally into mice, the irradiated suspensions initially contained about 10 ld(50) per ml, and immunized mice against challenge with fully virulent strains of P. tularensis. Toxicity and immunizing activity of the suspensions decreased significantly within a few days at 5 C. Mice were protected against the toxin by immune serum or by prior injection of endotoxin of Escherichia coli. Cortisone did not protect against the newly prepared suspension, but was effective against the aged suspension. Lethal doses of newly prepared suspension for guinea pigs and rabbits were approximately 0.5 ml and 2 ml, respectively. Cortisone protected rabbits, but not guinea pigs, against lethal challenge. Pyrogenic effects resembling those shown by endotoxin-containing suspensions were demonstrated in rabbits. The results suggested that two toxins are responsible for the toxicity of irradiated suspensions of P. tularensis: one labile and associated with the immunizing activity of the suspension, the other more stable and resembling classical endotoxin.