Encapsulation of Pseudomonas sp. ADP cells in electrospun microtubes for atrazine bioremediation

Electrospun hollow polymeric microfibers (microtubes) were evaluated as an encapsulation method for the atrazine degrading bacterium Pseudomonas sp. ADP. Pseudomonas sp. ADP cells were successfully incorporated in a formulation containing a core solution of polyethylene oxide dissolved in water and spun with an outer shell solution made of polycaprolactone and polyethylene glycol dissolved in a chloroform and dimethylformamide. The resulting microtubes, collected as mats, were partially collapsed with a ribbon-like structure. Following encapsulation, the atrazine degradation rate was low (0.03?±?0.01?mg atrazine/h/g fiber) indicating that the electrospinning process negatively affected cell activity. Atrazine degradation was restored to 0.5?±?0.1?mg atrazine/h/g fiber by subjecting the microtubes to a period of growth. After 3 and 7?days growth periods, encapsulated cells were able to remove 20.6?±?3 and 47.6?±?5.9?mg atrazine/g mat, respectively, in successive batches under non-growth conditions (with no additional electron donor) until atrazine was detected in the medium. The loss of atrazine degrading capacity was regained following an additional cell-growth period.     

Formation of gold nanoparticle decorated lysozyme microtubes

Gold nanoparticle decorated lysozyme microtubes, with the diameters of 1-2 μm and lengths on the order of millimeters, were spontaneously formed via a simple aging process of the lysozyme-gold nanoparticle aqueous solution under ambient conditions for 1 week. These novel microtubes were characterized by scanning electron microscopy (SEM), transmission electron microscopy (TEM), and energy-dispersive X-ray spectroscopy (EDX), as well as Fourier-transform infrared (FTIR) spectroscopy. It was confirmed that the microtubes were made up of the protein lysozyme. In addition, formation of the microtubes was accompanied by a decrease in lysozyme concentration in the sample solution, which also indicated that these microtubes originated from lysozyme. The formation of microtubes was attributed to the formation of hydrogen bonding networks between the lysozyme molecules. Partially unfolded lysozyme molecules on gold nanoparticles probably seed the formation of the lysozyme microtubes. These novel protein microtubes not only provide some useful insights for protein study but may also have the potential to be used in the biomedical field.     

Transport and survival of alginate-encapsulated and free lux-lac marked Pseudomonas aeruginosa UG2Lr cells in soil

Transport and survival of alginate-encapsulated and unencapsulated Pseudomonas aeruginosa UG2Lr through soil microcosms was examined. Bacterial cells encapsulated in alginate beads or mixed with soil were introduced into soil microcosms. Microbial cell survival and cell transport were monitored by destructive sampling and selective plating of the microcosms over a 9-week period. Survival rates were greatest when using encapsulated P. aeruginosa UG2Lr cells. Water flow increased microbial cell dispersal from the site of inoculation. After 3 weeks, encapsulated and free cells showed similar distribution patterns. However, after 9 weeks microbial cell distribution was more extensive throughout the soil in the encapsulated treatments under all conditions. Therefore, alginate encapsulation is a suitable method to enhance survival and distribution of microbial inocula in the soil environment.     

Effects of encapsulation of microorganisms on product formation during microbial fermentations

This paper reviews the latest developments in microbial products by encapsulated microorganisms in a liquid core surrounded by natural or synthetic membranes. Cells can be encapsulated in one or several steps using liquid droplet formation, pregel dissolving, coacervation, and interfacial polymerization. The use of encapsulated yeast and bacteria for fermentative production of ethanol, lactic acid, biogas, l-phenylacetylcarbinol, 1,3-propanediol, and riboflavin has been investigated. Encapsulated cells have furthermore been used for the biocatalytic conversion of chemicals. Fermentation, using encapsulated cells, offers various advantages compared to traditional cultivations, e.g., higher cell density, faster fermentation, improved tolerance of the cells to toxic media and high temperatures, and selective exclusion of toxic hydrophobic substances. However, mass transfer through the capsule membrane as well as the robustness of the capsules still challenge the utilization of encapsulated cells. The history and the current state of applying microbial encapsulation for production processes, along with the benefits and drawbacks concerning productivity and general physiology of the encapsulated cells, are discussed.     

Silica gel-encapsulated AtzA biocatalyst for atrazine biodegradation

Encapsulation of recombinant Escherichia coli cells expressing a biocatalyst has the potential to produce stable, long-lasting enzyme activity that can be used for numerous applications. The current study describes the use of this technology with recombinant E. coli cells expressing the atrazine-dechlorinating enzyme AtzA in a silica/polymer porous gel. This novel recombinant enzyme-based method utilizes both adsorption and degradation to remove atrazine from water. A combination of silica nanoparticles (Ludox TM40), alkoxides, and an organic polymer was used to synthesize a porous gel. Gel curing temperatures of 23 or 45 °C were used either to maintain cell viability or to render the cells non-viable, respectively. The enzymatic activity of the encapsulated viable and non-viable cells was high and extremely stable over the time period analyzed. At room temperature, the encapsulated non-viable cells maintained a specific activity between (0.44 ± 0.06) μmol/g/min and (0.66 ± 0.12) μmol/g/min for up to 4 months, comparing well with free, viable cell-specific activities (0.61 ± 0.04 μmol/g/min). Gels cured at 45 °C had excellent structural rigidity and contained few viable cells, making these gels potentially compatible with water treatment facility applications. When encapsulated, non-viable cells were assayed at 4 °C, the activity increased threefold over free cells, potentially due to differences in lipid membranes as shown by FTIR spectroscopy and electron microscopy.     

Probing the role of microenvironment for microencapsulated Sacchromyces cerevisiae under osmotic stress

Cell encapsulation opens a new avenue to the oral delivery of genetically engineered microorganism for therapeutic purpose. Osmotic stress is one of the universal chemical stress factors in the application of microencapsulation technology. In order to understand the effect and mechanism of the encapsulated microenvironment on protecting cells from hyper-osmotic stress, yeast cells of Saccharomyces cerevisiae Y800 were encapsulated in calcium alginate micro-gel beads (MB), alginate-chitosan-alginate (ACA) solid core microcapsules (SCM), and ACA liquid core microcapsules (LCM), respectively. The stress-induced intracellular components and enzyme activity including trehalose, glycerol and super oxide dismutase (SOD) were measured. Free cell culture was used as control. The survival of encapsulated cells and the cells released from MB, SCM and LCM after osmotic shock induced by NaCl solution (1, 2 and 3M) was evaluated. An analysis method was established to probe the effect of encapsulated microenvironment on the cell tolerance to osmotic stress. The results showed that LCM gave rise to the highest level of intracellular trehalose and glycerol, and SOD activity, as well as the highest survival rate of encapsulated cells or cells released from microcapsule. It was demonstrated that LCM was able to induce the highest stress response and stress tolerance of cells, which was adapted during culture, while SCM failed. The theoretical analysis revealed that it was the liquid alginate matrix in microcapsule that played a central role in domesticating the cells to adapt to hyper-osmotic stress. This finding provides a very useful guideline to cell encapsulation.     

A flow injection analysis system with encapsulated high-density <Emphasis Type="Italic">Saccharomyces cerevisiae</Emphasis> cells for rapid determination of biochemical oxygen demand

The biochemical oxygen demand (BOD) determination was studied using a novel flow injection analysis (FIA) system with encapsulated Saccharomyces cerevisiae cells and an oxygen electrode and was compared with conventional 5-day BOD tests. S. cerevisiae cells were packed in a calcium alginate capsule at a dry cell weight of 250 g/l of capsule core. The level of dissolved oxygen (DO) was reduced due to the enhanced respiratory activity of the microbial cells when the injected nutrient passed through the bioreactor. The decrease in DO (ΔDO) was intensified with the amount of microbial cells packed in the bioreactor. However, the specific ΔDO decreased as the amount of cells loaded in the bioreactor increased. The ΔDO value was dependent on the pH and temperature of the mobile phase and reached its maximum value at 35°C and pH 7–8. Also, ΔDO became larger at longer response times as the flow rate of the mobile phase decreased. The measurement of ΔDO was repeated more than six times consecutively using a 20-ppm standard glucose and glutamic acid solution, which confirmed the reproducibility with a standard deviation of 0.95%. A strong linear correlation between ΔDO and BOD was also observed. The 5-day BOD values of actual water and wastewater samples were in accordance with the BOD values obtained by this FIA method using encapsulated S. cerevisiae cells. Unlike the cell-immobilized bead system, there was no contamination of the bioreactor resulting from any leak of yeast cells from the sensor capsules during BOD measurements.     

Inhibition of human telomerase activity by antisense phosphorothioate oligonucleotides encapsulated with the transfection reagent, FuGENE6, in HeLa cells

Telomerase, a ribonucleoprotein, synthesizes telomeric repeats (TTAGGG) onto the ends of chromosomes to maintain the constant length of the telomere DNA, and its activity is detectable in approximately 85%-90% of primary human cancers. Thus, it is postulated that human telomerase might be associated with malignant tumor development and could be a highly selective target for antitumor drug design. Antisense phosphorothioate oligonucleotides (S-ODN) were investigated for their abilities to inhibit telomerase activity in the HeLa cell line. The S-ODN were designed to be complementary to nucleotides within the RNA active site of telomerase. As a transfection reagent, FuGENE6 (Boehringer Mannheim, Mannheim, Germany) was used to enhance the cellular uptake of the oligonucleotides in cell cultures. The S-ODN encapsulated with FuGENE6 clearly inhibited telomerase activity in HeLa cells and showed sequence-specific inhibition. The encapsulated S-ODN-3 with a 19-nucleotide, (nt) chain length had inhibitory effects similar to those of the 21-mer and 23-mer S-ODN sequences (S-ODN-4 and 5), but the 15-mer and 17-mer S-ODN sequences (S-ODN-1 and 2) failed to satisfactorily prevent telomerase activity. However, apoptotic HeLa cell death was not associated with telomerase inhibition. Furthermore, the encapsulated S-ODN did not appear to be cytotoxic in terms of the cell growth rate. The oligonucleotides encapsulated with the transfection reagent had enhanced cellular uptake, and cytoplasmic and nuclear localizations were observed. However, weak fluorescent signals were observed within the cytoplasms of HeLa cells treated with the free S-ODN-3. Thus, the activities of the S-ODN were effectively enhanced by using the transfection reagent. The transfection reagent, FuGENE6, may thus be a potentially useful delivery vehicle for oligonucleotide-based therapeutics and transgenes and is appropriate for use in vitro and in vivo.     

Enhanced loading efficiency and retention of 225Ac in rigid liposomes for potential targeted therapy of micrometastases

Targeted alpha-particle emitters are promising therapeutics for micrometastatic disease. Actinium-225 has a 10-day half-life and generates a total of four alpha-particles per parent decay rendering (225)Ac an attractive candidate for alpha-therapy. For cancer cells with low surface expression levels of molecular targets, targeting strategies of (225)Ac using radiolabeled carriers of low specific radioactivities (such as antibodies) may not deliver enough alpha-particle emitters at the targeted cancer cells to result in killing. We previously proposed and showed using passive (225)Ac entrapment that liposomes can stably retain encapsulated (225)Ac for long time periods, and that antibody-conjugated liposomes (immunoliposomes) with encapsulated (225)Ac can specifically target and become internalized by cancer cells. However, to enable therapeutic use of (225)Ac-containing liposomes, high activities of (225)Ac need to be stably encapsulated into liposomes. In this study, various conditions for active loading of (225)Ac in preformed liposomes (ionophore-type, encapsulated buffer solution, and loading time) were evaluated, and liposomes with up to 73 +/- 9% of the initial activity of (225)Ac (0.2-200 microCi) were developed. Retention of radioactive contents by liposomes was evaluated at 37 degrees C in phosphate buffer and in serum-supplemented media. The main fraction of released (225)Ac from liposomes occurs within the first two hours of incubation. Beyond this two hour point, the encapsulated radioactivity is released from liposomes slowly with an approximate half-life of the order of several days. In some cases, after 30 days, (225)Ac retention as high as 81 +/- 7% of the initially encapsulated radioactivity was achieved. The (225)Ac loading protocol was also applied to immunoliposome loading without significant loss of targeting efficacy. Liposomes with surface-conjugated antibodies that are loaded with (225)Ac overcome the limitations of low specific activity for molecular carriers and are expected to be therapeutically useful against tumor cells having a low antigen density.     

Environmental applications of immobilized microbial cells: A review

Immobilized microbial cells have been used extensively in various industrial and scientific endeavours. However, immobilized cells have not been used widely for environmental applications. This review examines many of the scientific and technical aspects involved in using immobilized microbial cells in environmental applications, with a particular focus on cells encapsulated in biopolymer gels. Some advantages and limitations of using immobilized cells in bioreactor studies are also discussed.     

High IgM production by human-human hybridoma HB4C5 cells cultured in microtubes

HB4C5 cells, a human-human hybridoma, were cultured in microtubes. After 24 h of cultivation, growth of the cells cultured in microtubes was 1.2- to 1.5-fold that in culture dishes or 96-well culture plates. The production of IgM was 2.6- to 3.3-fold that in the 96-well culture plates.     

Use of silicate sol-gels to trap the R and T quaternary conformational states of pig kidney fructose-1,6-bisphosphatase.

Encapsulation of the homotetrameric pig kidney fructose-1,6-bisphosphatase (FBPase) in tetramethyl orthosilicate sol-gels was used to dramatically reduce the rate of the allosteric transition of the enzyme between the T and R allosteric states. When assayed in the absence of the allosteric inhibitor AMP, the enzyme encapsulated in the T-state exhibited little activity. The enzyme encapsulated in the R-state exhibited a 4-fold lower k(cat) and V(max) than the enzyme in solution, and the apparent K(m) for this enzyme was 350-fold higher than the corresponding value for the enzyme in solution. The [Mg(2+)](0.5) for the encapsulated enzyme was only 0.1 mM, compared to 0.54 mM for the normal enzyme. Magnesium activation, under both sets of conditions, was cooperative with a Hill coefficient of approximately 2. The activity of enzyme encapsulated in the R-state decreased to about 70% of initial activity within 1 min of adding AMP, it then decreased slowly to about 40% of initial activity over the following 7 h. Under the conditions tested, the encapsulated enzyme never became completely inactivated and AMP inhibition was no longer cooperative. For enzyme encapsulated in the T-state, activity was restored over approximately 7 h after removal of the AMP. The biphasic and slow responses to changing AMP levels suggest that encapsulated enzyme can be used to study the effects of local conformational changes distinct from the global quaternary conformational changes by slowing down the ability of the enzyme to carry out global rotations. The response to AMP exhibited by the encapsulated enzyme is consistent with the ability of AMP, at least partially, to directly influence the activity of the active site within each subunit.     

Functionally stable and phylogenetically diverse microbial enrichments from microbial fuel cells during wastewater treatment

Microbial fuel cells (MFCs) are devices that exploit microorganisms as biocatalysts to recover energy from organic matter in the form of electricity. One of the goals of MFC research is to develop the technology for cost-effective wastewater treatment. However, before practical MFC applications are implemented it is important to gain fundamental knowledge about long-term system performance, reproducibility, and the formation and maintenance of functionally-stable microbial communities. Here we report findings from a MFC operated for over 300 days using only primary clarifier effluent collected from a municipal wastewater treatment plant as the microbial resource and substrate. The system was operated in a repeat-batch mode, where the reactor solution was replaced once every two weeks with new primary effluent that consisted of different microbial and chemical compositions with every batch exchange. The turbidity of the primary clarifier effluent solution notably decreased, and 97% of biological oxygen demand (BOD) was removed after an 8-13 day residence time for each batch cycle. On average, the limiting current density was 1000 mA/m(2), the maximum power density was 13 mW/m(2), and coulombic efficiency was 25%. Interestingly, the electrochemical performance and BOD removal rates were very reproducible throughout MFC operation regardless of the sample variability associated with each wastewater exchange. While MFC performance was very reproducible, the phylogenetic analyses of anode-associated electricity-generating biofilms showed that the microbial populations temporally fluctuated and maintained a high biodiversity throughout the year-long experiment. These results suggest that MFC communities are both self-selecting and self-optimizing, thereby able to develop and maintain functional stability regardless of fluctuations in carbon source(s) and regular introduction of microbial competitors. These results contribute significantly toward the practical application of MFC systems for long-term wastewater treatment as well as demonstrating MFC technology as a useful device to enrich for functionally stable microbial populations.     

Effect of free and encapsulated Pseudomonas putida CC-FR2-4 and Bacillus subtilis CC-pg104 on plant growth under gnotobiotic conditions

A study was performed to investigate the efficiency of microbial inoculants after encapsulating in alginate supplemented with humic acid on plant growth. Two promising plant growth promoting rhizobacteria were identified by 16S rDNA sequencing as Pseudomonas putida CC-FR2-4 and Bacillus subtilis CC-pg104, which were further characterized by biochemical analyses and inoculated to Lectuca sativa L. seedlings as free cells and entrapped in beads. Significant increase in shoot height after 21 days of growth was observed with encapsulated CC-pg104 inoculated plants. Highest increase in root length was observed with CC-pg104 free-cell inoculated plants, followed by plants inoculated with encapsulated CC-pg104. Results clearly demonstrated that inoculation of the encapsulated bacterial isolates promoted plant growth similar to their respective free cells and could be a novel and feasible technique for application in agricultural industry.     

Immobilization in polyelectrolyte complex capsules: Encapsulation of a gluconate-oxidizing Serratia marcescens strain

In previous papers, it was shown that eukaryotic microbial systems can be encapsulated in polyelectrolyte complexes (PEC) prepared from sodium cellulose sulfate and poly(dimethyldiallylammonium chloride) with maintainance of vitality. In the present study, prokaryotic cells were successfully encapsulated in these PEC. Serratia marcescens B345 (IMET 11312) was chosen as a model organism. This strain converts gluconic acid to 2-ketogluconic acid. Since the 2-ketogluconic acid produced has very strong complexing properties, the number of applicable immobilization methods is restricted. Due to the high stability of PEC towards complexing agents, these problems can be overcome by the described method.

As already described in previous papers, a preimmobilization of cells in a PEC coprecipitate prior to capsule formation proved to be advantageous also for encapsulation of bacilli. The mean productivity of the encapsulated S. marcescens cells was 1–4.4 g l⁻¹ h⁻¹ in comparison to 5 g l⁻¹ h⁻¹ for free cells. The productivity was highly dependent on the flow rate of the reactor. The encapsulated cells were used for 1,200 h in a continuous biotransformation process for the production of 2-ketogluconic acid.     

Physiological comparison of cells with high and low alcohol dehydrogenase activities in bacterial populations consuming ethanol

Measuring the physiological heterogeneity of natural and industrial microbial populations is essential to studying, modelling and monitoring of microbial populations. It was discovered that populations of Escherichia coli and Bacillus megaterium growing in medium with ethanol as an external source of energy have two actively respiring but physiologically different subpopulations. Cells of one subpopulation have negligibly low alcohol dehydrogenase (ADH) activity (ADH-L cells) and cells of the other have high ADH activity (ADH-H cells). The subpopulation of ADH-H bacterial cells was measured using 10 min incubations of cells in a 1% solution of allyl alcohol for fast selective killing of cells with high activity of ADH and flow cytometry detection of dead cells after this incubation. The content of ADH-H cells during exponential phase of batch culture varied from 9 % to 90 % and lowered to zero for a few hours during starvation of the population. ADH-L cells are actively respiring cells and not depolarized cells. The simultaneous presence of ADH-L and ADH-H cells growing in the medium with ethanol can be explained by the fact that ADH-H cells oxidize actively external ethanol whereas ADH-L cells oxidize only intracellular storage carbohydrates. The method for enumeration of cells with high ADH activity can be used to monitor the heterogeneity of bacterial populations consuming ethanol as a sole source of carbon and energy.     

Slow-release inoculation allows sustained biodegradation of gamma-hexachlorocyclohexane

This study investigated the feasibility of a slow-release inoculation approach as a bioaugmentation strategy for the degradation of lindane (gamma-hexachlorocyclohexane [gamma-HCH]). Slow-release inoculation of Sphingomonas sp. gamma 1-7 was established in both liquid and soil slurry microcosms using open-ended silicone tubes in which the bacteria are encapsulated in a protective nutrient-rich matrix. The capacity of the encapsulated cells to degrade lindane under aerobic conditions was evaluated in comparison with inoculation of free-living cells. Encapsulation of cells in tubes caused the removal of lindane by adsorption to the silicone tubes but also ensured prolonged biodegradation activity. Lindane degradation persisted 2.2 and 1.4 times longer for liquid and soil slurry microcosms, respectively, than that for inoculation with free cells. While inoculation of free-living cells led to a loss in lindane-degrading activity in limited time intervals, encapsulation in tubes allowed for a more stable actively degrading community. The loss in degrading activity was linked to the loss of the linA gene, encoding gamma-HCH dehydrochlorinase (LinA), which is involved in the initial steps of the lindane degradation pathway. This work shows that a slow-release inoculation approach using a catabolic strain encapsulated in open-ended tubes is a promising bioaugmentation tool for contaminated sites, as it can enhance pollutant removal and can prolong the degrading activity in comparison with traditional inoculation strategies.     

Improved activity of streptozotocin-selected insulinoma cells following microencapsulation and transplantation into diabetic mice

We have recently shown that repeated streptozotocin (STZ) treatment induces the selection of insulinoma cells (RINmS) with both improved resistance to diabetogenic toxins and functional activity, compared to parental RINm cells. The aim of the present study was to estimate the potential of RINmS cells to maintain their engineered characteristics during in vivo hyperglycemic conditions. It was found that microencapsulation and transplantation into diabetic mice preserved a three-fold higher level of insulin content in selected RINmS cells when compared to the parental ones. Retrieval of transplanted encapsulated cells from the peritoneal cavity of diabetic mice had a significantly higher insulin content and a more intense insulin response to secretogogues in selected RINmS cells when compared to retrieved RINm cells. In conclusion, our results show that RINmS cells do not lose their improved functional characteristics after encapsulation and transplantation into diabetic mice.     

Preparation and characterization of urease-encapsulated biosensors in poly(vinyl alcohol)-modified silica sol-gel materials

The microenvironments of the sol-gel-derived urease biosensors in terms of elemental ratio, surface morphology, specific surface area and pore size were investigated to characterize the physicochemical properties of poly(vinyl alcohol) (PVA)-modified sol-gel materials. X-ray photoelectron spectroscopy (XPS), atomic force microscopy (AFM) and surface area analyzer were used to identify the surface species, topography and pore distribution of the organically doped sol-gel network. XPS results showed that stoichiometric ratios of oxygen-to-silicon in sol-gel materials were in the range 2.08-2.11. The sol-gel materials were partially dried and negatively charged, which retained 6-8% water content to maintain urease activity. The surface morphology of the sol-gel altered obviously when macromolecules were encapsulated, resulting in the increase in surface mean roughness from 0.207 to 2.636 nm. The specific surface area decreased dramatically after the immobilization of biomolecules and organic additives, which clearly depicts that PVA and urease were co-encapsulated into the sol-gel network. However, there still exist enough pore volumes for analytes to mass transport. The apparent Michaelis-Menten constant value (Km) of the encapsulated urease was similar to that in solution and the overall catalytic efficiency in PVA-doped sol-gel-derived glasses only decreased by a factor of 3.2 relative to the value in solution. In addition, the analytical performance of the entrapped urease in PVA-doped sol-gel materials was examined by determining the Cu(II) concentration in aqueous solution. The analytical range of Cu(II) was in the range 2x10(-6) to 2x10(-2) M with a detection limit of 1.5 microg L(-1). Results obtained in this study demonstrate a strategy for maintaining urease activity for biomedical and environmental applications.     

Role of serum factors in the phagocytosis of weakly or heavily encapsulated Cryptococcus neoformans strains by guinea pig peripheral blood leukocytes

We investigated the opsonic activity of the serum factors affecting phagocytosis of Cryptococcus neoformans in vitro to elucidate the role of humoral factors in the host defense mechanisms against cryptococcosis. Two strains of C. neoformans, one heavily and one weakly encapsulated, were used. Guinea pig peripheral blood leukocytes (PBLs) were used for phagocytosis. The viable weakly encapsulated cells were ingested effectively by PBLs, in the presence of guinea pig normal fresh serum, while the heavily encapsulated cells were not ingested. Neither immune serum, its IgG fraction alone, nor heated serum promoted the phagocytosis of either the weakly or heavily encapsulated strain. On the other hand, immune serum promoted adherence of PBLs to viable cells of the heavily encapsulated strain, forming rosettes in the presence of fresh serum. A substantial amount of C3b component was detected on yeast cells when weakly encapsulated cells were incubated with human fresh serum, or heavily encapsulated cells were incubated with rabbit immune serum together with human fresh serum. Serum chelation experiments also indicated that the factors involved in the alternative complement pathway are opsonins for the weakly encapsulated strain. These results suggest that the alternative pathway plays an important normal opsonic role for weakly encapsulated strains and that specific antibody plays an immune opsonic role for heavily encapsulated strains of C. neoformans via the classical pathway of complement activation.