Fc receptors on human T lymphocytes. II. Cytotoxic capabilities of human T gamma, T mu, B, and L cells.

Subpopulations of human peripheral blood lymphocytes were prepared by rosetting techniques employing neuraminidase-treated sheep erythrocytes (SRBC_n), sheep erythrocytes coated with IgM and murine complement (EAC′), and bovine erythrocytes coated with IgG and IgM. The isolated subpopulations were tested in assays of natural cytotoxicity (NC), antibody-dependent cellular cytotoxicity (ADCC), and mitogen-induced cellular cytotoxicity (MICC). B cells (SRBC_n?, EAC′+) did not mediate cytotoxicity. L cells (SRBC_n?, EAC′?) mediated NC and ADCC but not MICC. T cells (SRBC_n+) mediated NC, ADCC, and MICC. Separation of T cells into Fc-IgG (Tγ) and Fc-IgM (Tμ) subsets revealed that Tγ cells mediated NC, ADCC, and MICC while Tμ cells mediated only MICC. Thus MICC but not NC or ADCC was solely T-cell mediated. Tγ and L cells were functionally distinguishable in that Tγ cells but not L cells mediated MICC. Tγ cells and Tμ cells differed with regard to NC and ADCC effector function while both subsets mediated MICC.     

Enrichment of the Murine Natural Killer (NK) and Mitogen Induced Cellular Cytotoxicity (MICC) Cells Using Preparative Free-Flow High Voltage Electrophoresis

A procedure using preparative free-flow high voltage electrophoresis is described for the fractionation of murine spleen and bone marrow cells so as to obtain cell subpopulations that are either enriched in or depleted of “natural killer” (NK) cells and “mitogen-induced cellular cytotoxicity” (MICC) effector cells. A nearly three fold enrichment in the NK and MICC activities of spleen cells was achieved. The enrichment in these cells could be further increased if the phagocytic cells were removed prior to electrophoresis. When bone marrow cells were fractionated a two and a half fold increase of NK activity, and a one and a half fold enrichment of MICC activity was achieved. In both cases, other fractions were nearly devoid of NK and MICC activity. The cell recovery after electrophoresis averages 70% of the cells applied, and at least 90% of these cells were viable. MICC and NK effector cells could not be separated to a useful extent electro-phoretically but were found to be separable using Sephadex G-10 gel filtration columns. The MICC but not the NK cells were retained on these columns.     

Enrichment of the murine natural killer (NK) and mitogen induced cellular cytotoxicity (MICC) cells using preparative free-flow high voltage electrophoresis.

A procedure using preparative free-flow high voltage electrophoresis is described for the fractionation of murine spleen and bone marrow cells so as to obtain cell subpopulations that are either enriched in or depleted of "natural killer" (NK) cells and "mitogen-induced cellular cytotoxicity" (MICC) effector cells. A nearly three fold enrichment in the NK and MICC activities of spleen cells was achieved. The enrichment in these cells could be further increased if the phagocytic cells were removed prior to electrophoresis. When bone marrow cells were fractionated a two and a half fold increase of NK activity, and a one and a half fold enrichment of MICC activity was achieved. In both cases, other fractions were nearly devoid of NK and MICC activity. The cell recovery after electrophoresis averages 70% of the cells applied, and at least 90% of these cells were viable. MICC and NK effector cells could not be separated to a useful extent electrophoretically but were found to be separable using Sephadex C-10 gel filtration columns. The MICC but not the NK cells were retained on these columns.     

The nature of the effector cells mediating mitogen-induced cellular cytotoxicity (MICC) and antibody-dependent cellular cytotoxicity (ADCC).

The nature of the cell types capable of mediating mitogen-induced cellular cytotoxicity (MICC) and antibody-dependent cellular cytotoxicity (ADCC) was investigated utilizing effector cells from athymic nude and euthymic heterozygous control littermate mice as well as Sephadex anti-Fab immunoabsorbent column purified spleen cell populations from normal (CS7BL/6) mice. Chicken erythrocytes (CRBC) and the mouse lymphoma, EL-4, were used as target cells in both cytotoxicity assays. MICC utilizing CRBC targets was mediated by several effector cell types whereas MICC utilizing EL-4 lymphoma targets was T-cell dependent. ADCC against both CRBC and EL-4 lymphoma targets occurred independently of the presence of T-cells. In addition, effector cell populations incapable of mediating MICC against EL-4 lymphoma targets were capable of mediating ADCC against the same EL-4 targets. Thus, utilizing the appropriate target cells, EL-4 but not CRBC, a sharp distinction can be made between the effectors for ADCC and MICC: ADCC is T-cell independent while MICC is dependent on the presence of mature thymus-derived cells. Furthermore these studies demonstrate that the nature of the target cell employed in MICC and ADCC reactions plays a critical role in defining the types of effector cells capable of mediating these cytotoxicity reactions.     

Electrochromatographic separation of hydrophobic amino acid enantiomers by molecularly imprinted capillary columns

In the present study, the enantiomeric forms of hydrophobic amino acids (l-tryptophan, l-tyrosine, and l-phenylalanine) were separated by molecularly imprinted capillary columns (MICC) via Capillary Electrochromatography (CEC) for the first time. The monomer ratio, crosslinker ratio, template molecule ratio, the porogen ratio and type, polymerization time, and also the effect of temperature were examined to increase the permeability properties of MICC. FTIR, SEM and BET analyses were realized for the characterization of MICC. The effect of the electric field, organic solvent ratio, and pressure were carried out experimentally to determine the optimum conditions. The separation performances of MICC and the non-imprinted capillary columns (NICC) were compared electrochromatographically.     

Mitogen induced cellular cytotoxic activity as a monocyte function in human peripheral blood preparations

The effector cell population in man responsible for mitogen induced cellular cytotoxicity (MICC) of chicken erythrocytes was investigated using several separation techniques, including free flow electrophoresis. Electrophoresis produced substantial monocyte enrichment in some fractions with substantial depletion in others. MICC activity was seen to correlate with monocyte content in these fractions. Furthermore, removal of phagocytic cells with carbonyl iron and removal of adherent cells on plastic petri dishes depleted preparations of MICC activity. Thus it is suggested that under conditions described in this paper, the effector cell of the MICC assay in man appears to be a monocyte. This MICC effector cell was shown to be different from the effector cell in the natural killing (NK cells) of RPMI 6410 cells.     

Surface receptors and immune activity of purified human circulating mononuclear cells. III. The mechanisms of lysis, by lymphocytes and monocytes, of target cells in the lymphocyte-dependent and monocyte-dependent ADCC, NK, NOCC, and MICC cytotoxic reactions

The abilities of unfractionated mononuclear cells (MNC), monocytes (98-99% pure), and lymphocytes (98-99% pure) to carry out the lysis of target cells in the ADCC, NK, NOCC, and MICC assays were compared. Lymphocytes by themselves were able to lyse the CRBC (ADCC), K-562 (NK), and RRBC (MICC) target cells. The monocytes were very effective in the lysis of the CRBC (MICC) target cells. However, the lysis of two other target cells--RRBC (NOCC) and HRBC (ADCC)--required the simultaneous presence of both lymphocytes and monocytes in order to effect optimal lysis. Soluble factor(s) secreted by the cytotoxic cells capable of lysing the target cells were detected only in the NK assay. The activity of the soluble cytotoxic factor (NKCF) was only 25-40% of that exhibited by the cytotoxic NK cells and it was secreted by the cytotoxic cells after 48 hr of culture and not 24 hr of culture which is the usual assay condition. The NKCF was cytotoxic only to the NK target cells and not to the target cells used in the ADCC, NOCC, and MICC cytotoxic assays. Different classes of lymphocytes were cytotoxic in the monocyte-independent assays [ADCC (CRBC), NK (K-562), and MICC (RRBC)]. The null lymphocytes and the T lymphocytes were the primary cytotoxic cells in the ADCC and MICC assays, respectively, whereas the T, B, and null cells were almost equally cytotoxic in the NK assay. With respect to the monocyte-dependent assays [ADCC (HRBC), NOCC (RRBC), and MICC (CRBC)], the cytotoxic activity of any one class of lymphocytes failed to approach that of the unfractionated MNC. The T cells were the most cytotoxic; the B cells exhibited limited cytotoxic activity in only the ADCC assay and the null cells showed no cytotoxic activity. However, the combination of T and non-T cells and, to a lesser extent, T and B cells, exhibited much greater cytotoxic activity than the individual cells and together were as cytotoxic as the unfractionated MNC. It is concluded that, depending upon the selection of the target cells, lysis in the ADCC, NK, NOCC, and MICC assays may be effected by lymphocytes only, by monocytes only, by both monocytes and lymphocytes, or as a result of lymphocyte-monocyte collaboration. In the latter instance more than one class of lymphocytes must be present in order for maximum cytotoxic activity to be expressed.     

Molecularly imprinted composite cryogels for hemoglobin depletion from human blood

A molecularly imprinted composite cryogel (MICC) was prepared for depletion of hemoglobin from human blood prior to use in proteome applications. Poly(hydroxyethyl methacrylate) based MICC was prepared with high gel fraction yields up to 90%, and characterized by Fourier transform infrared spectrophotometer, scanning electron microscopy, swelling studies, flow dynamics and surface area measurements. MICC exhibited a high binding capacity and selectivity for hemoglobin in the presence of immunoglobulin G, albumin and myoglobin. MICC column was successfully applied in fast protein liquid chromatography system for selective depletion of hemoglobin for human blood. The depletion ratio was highly increased by embedding microspheres into the cryogel (93.2%). Finally, MICC can be reused many times with no apparent decrease in hemoglobin adsorption capacity. Copyright © 2014 John Wiley & Sons, Ltd.     

Mitogen induced cellular cytotoxicity (MICC) in multiple myeloma.

Mitogen induced cellular cytotoxicity (MICC) was noted to be markedly increased in patients with multiple myeloma as compared to normal controls and to patients with chronic lymphocytic leukemia (CLL). Enhanced MICC was present at various effector-to-target cell ratios and at several mitogen concentrations. Removal of adherent, phagocytic cells by carbonyl iron, glass wool, or rayon columns abolished the MICC response from the peripheral blood of both multiple myeloma patients and normal controls. Thus, the effector cell mediating MICC may be monocytic in origin and closely resembles the suppressor cell for immunoglobulin synthesis described in patients with multiple myeloma. Our data suggest that the MICC assay with chicken red blood cells as targets may provide a convenient method for identifying pathologic conditions where this cytotoxic effector cell population plays an active role.     

Monocyte involvement in PHA induced cytotoxicity of chicken erythrocytes in man.

Phytohemagglutinin (PHA) induced cell cytotoxicity was studied in man using chromated chicken red blood cells (CRBC) as target cells. A phagocytic, adherent monocyte was found to be necessary for lysis of target cells. Results using E rosette depletion showed that this procedure markedly increased mitogen-induced cellular cytotoxicity (MICC). Carbonyl iron treatment of peripheral blood cell suspensions to remove phagocytic cells abolished MICC, as did removal of adherent cells by glass wool columns. Complement mediated lysis of B cells did not substantially reduce MICC. However, pretreatment of cells with silica or hydrocortisone did reduce MICC. The mechanism of mitogen-induced lysis appears to require direct cell contact between effector cells and target cells.     

Differential effects of ouabain on human cell-mediated cytotoxicity. I. Inhibition of mitogen-induced cellular cytotoxicity and antibody-dependent cellular cytotoxicity against chicken red cell targets.

The effects of ouabain, a known inhibitor of lymphoproliferation, were studied in relation to the cytotoxic effector function of human peripheral blood mononuclear leukocytes (MNL) against chicken red blood cell (CRC) targets. MNL effectors lysed ⁵¹Cr-labeled CRC targets in the presence of PHA (mitogen-induced cellular cytotoxicity—MICC) or rabbit anti-CRC antibody (antibody-dependent cellular cytotoxicity—ADCC) in the absence of ouabain. The addition of ouabain to the cytotoxic reaction caused profound diminution of MICC with greater than 90% suppression of killing at ouabain concentrations of 5 × 10^?4M; ADCC was much more resistant to the effects of ouabain with only 60 to 70% inhibition of killing at similar ouabain concentrations (P < 0.01). Similar ouabain inhibition of MICC occurred whether the effector cell populations were unseparated MNL, depleted of monocytes, enriched for T cells, or depleted of T cells, suggesting a generalized activity by ouabain against all effector cells active in MICC. Ouabain inhibition of MICC could be overcome by increasing PHA concentrations, indicating that ouabain inhibition was not due to irreversible toxic effects on effector cells. Increasing the concentration of anti-CRC antibody resulted in increased killing in this ADCC system and, paradoxically, ADCC cultures with the highest antibody concentrations were more completely inhibited by ouabain. This enhanced inhibitory effect of ouabain on ADCC cultures with the highest antibody concentrations was not observed when the effector cell population was first depleted of phagocytic cells, suggesting a preferential inhibitory action by ouabain against monocyte effectors in ADCC. Thus, the differential inhibitory effects of ouabain on MICC and ADCC against CRC targets may be in part explained by the differing ouabain sensitivities of the various effector cell subpopulations involved in these cell-mediated cytotoxic events.     

Differential effects of ouabain on human cell-mediated cytotoxicity. II. Stimulation of monocyte-mediated, spontaneous cytotoxicity against chicken red cell targets.

We have previously shown that ouabain inhibits mitogen-induced cellular cytotoxicity (MICC) and antibody-dependent cellular cytotoxicity (ADCC) against chicken red cell (CRC) targets. We now report that ouabain increases spontaneous killing of CRC targets in the absence of mitogen or antibody. Spontaneous cytotoxicity by fresh mononuclear leukocytes (MNL) was enhanced by ouabain in a dose-dependent fashion and was maximal at a ouabain concentration of 5 × 10^?5M. Removal of phagocytic cells from the MNL effector cell population abrogated ouabain-induced spontaneous cytotoxicity, suggesting that the effector cell activated by ouabain was a monocyte. Ouabain-induced spontaneous cytotoxicity was relatively inefficient compared to MICC or ADCC and was only demonstrated consistently at effector:target cell ratios higher than those routinely employed for MICC and ADCC. Very low concentrations of ouabain (5 × 10^?9M) also enhanced spontaneous cytotoxicity of MNL precultured for 7 days, when added at either Day 0 or Day 6 of preculture. The cell effecting spontaneous cytotoxicity after 7 days of culture has been previously shown to be a monocyte. Thus, ouabain has opposing effects on cell-mediated cytotoxic functions: it inhibits MICC and ADCC against CRC targets, but stimulates spontaneous, monocyte-mediated cytotoxicity against the same targets.     

Reviewing microbial electrical systems and bacteriophage biocontrol as targeted novel treatments for reducing hydrogen sulfide emissions in urban sewer systems

Microbially induced concrete corrosion (MICC) is a costly, and ongoing problem affecting the infrastructure of water utilities worldwide. Traditionally MICC has been treated with chemicals and physical techniques that inhibit the release of hydrogen sulfide (H₂S), preventing sulfuric acid formation and the consequent corrosion. However, these methods require continual dosing and monitoring to ensure process efficiency and prevent undue costs. This review focuses on recent research into two potential novel treatments for MICC: re-engineering the sewer sulfur cycle by removing sulfide using electrodes in microbial electrical systems as an alternative electron acceptor and; altering the microbial community using targeted bacteriophage biocontrol to reduce specific sulfide-producing bacteria. These novel treatments hold the potential to reduce water utilities reliance on continual chemical dosing providing a long-lasting treatment I believe necessitates further laboratory and field-trial investigation.     

Error removal in microchip-synthesized DNA using immobilized MutS

The development of economical de novo gene synthesis methods using microchip-synthesized oligonucleotides has been limited by their high error rates. In this study, a low-cost, effective and improved-throughput (up to 32 oligos per run) error-removal method using an immobilized cellulose column containing the mismatch binding protein MutS was produced to generate high-quality DNA from oligos, particularly microchip-synthesized oligonucleotides. Error-containing DNA in the initial material was specifically retained on the MutS-immobilized cellulose column (MICC), and error-depleted DNA in the eluate was collected for downstream gene assembly. Significantly, this method improved a population of synthetic enhanced green fluorescent protein (720 bp) clones from 0.93% to 83.22%, corresponding to a decrease in the error frequency of synthetic gene from 11.44/kb to 0.46/kb. In addition, a parallel multiplex MICC error-removal strategy was also evaluated in assembling 11 genes encoding ∼21 kb of DNA from 893 oligos. The error frequency was reduced by 21.59-fold (from 14.25/kb to 0.66/kb), resulting in a 24.48-fold increase in the percentage of error-free assembled fragments (from 3.23% to 79.07%). Furthermore, the standard MICC error-removal process could be completed within 1.5 h at a cost as low as $0.374 per MICC.     

Cytotoxic effector cell function in organized gut-associated lymphoid tissue (GALT).

Lymphocytes from the organized gut-associated lymphoid tissues (GALT) of adult guinea pigs were examined for surface markers characteristic of T and B lymphocytes and for their capacity to function as effector cells in mitogen-induced cellular cytotoxicity (MICC) and antibody-dependent cellular cytotoxicity (ADCC) reactions. GALT lymphocytes formed rosettes with rabbit erythrocytes, a T-cell marker, and underwent proliferative responses in vitro in the presence of phytohemagglutinin (PHA), concanavalin A (Con A), and pokeweed mitogen (PWM). GALT lymphocytes were cytotoxic in vitro for erythrocyte and DBA mastocytoma targets in the presence of PHA. A population of GALT lymphocytes bound aggregated γ-globulin; however, they functioned poorly in ADCC reactions. Thus, organized GALT in the guinea pig contains lymphocytes capable of functioning in T-cell-dependent MICC reactions but either lacks the effector cell population which mediates ADCC or contains an effector cell which functions poorly in ADCC.     

Succession of sulfur-oxidizing bacteria in the microbial community on corroding concrete in sewer systems

Microbially induced concrete corrosion (MICC) in sewer systems has been a serious problem for a long time. A better understanding of the succession of microbial community members responsible for the production of sulfuric acid is essential for the efficient control of MICC. In this study, the succession of sulfur-oxidizing bacteria (SOB) in the bacterial community on corroding concrete in a sewer system in situ was investigated over 1 year by culture-independent 16S rRNA gene-based molecular techniques. Results revealed that at least six phylotypes of SOB species were involved in the MICC process, and the predominant SOB species shifted in the following order: Thiothrix sp., Thiobacillus plumbophilus, Thiomonas intermedia, Halothiobacillus neapolitanus, Acidiphilium acidophilum, and Acidithiobacillus thiooxidans. A. thiooxidans, a hyperacidophilic SOB, was the most dominant (accounting for 70% of EUB338-mixed probe-hybridized cells) in the heavily corroded concrete after 1 year. This succession of SOB species could be dependent on the pH of the concrete surface as well as on trophic properties (e.g., autotrophic or mixotrophic) and on the ability of the SOB to utilize different sulfur compounds (e.g., H2S, S0, and S2O3(2-)). In addition, diverse heterotrophic bacterial species (e.g., halo-tolerant, neutrophilic, and acidophilic bacteria) were associated with these SOB. The microbial succession of these microorganisms was involved in the colonization of the concrete and the production of sulfuric acid. Furthermore, the vertical distribution of microbial community members revealed that A. thiooxidans was the most dominant throughout the heavily corroded concrete (gypsum) layer and that A. thiooxidans was most abundant at the highest surface (1.5-mm) layer and decreased logarithmically with depth because of oxygen and H2S transport limitations. This suggested that the production of sulfuric acid by A. thiooxidans occurred mainly on the concrete surface and the sulfuric acid produced penetrated through the corroded concrete layer and reacted with the sound concrete below.     

Surface receptors and immune activity of purified human circulating mononuclear cells: IV. The demonstration of seven subclasses of T cells in the circulation of the normal individual: The cytotoxic activities of these cells

T lymphocytes were isolated from monocyte-depleted mononuclear cells of normal individuals by rosetting them with sheep erythrocytes. These purified T cells were preferentially depleted of cells with receptors for FcG (T_G cells), FcM (T_M cells), or C3 (T_C cells) by rosette formation with EA(G), EA(M), and EAC, respectively, before or after incubation for 24 hr in medium 199 fortified with fetal calf serum (20%). The unfractionated lymphocytes and the purified and the depleted T cells were analyzed for receptors to FcG, FcM, and C3 and for cytotoxic activity in the natural killer (NK), antibody dependent cell-mediated cytotoxicity (ADCC), and mitogen-induced cell-mediated cytotoxicity (MICC) assays. The T_G and T_C cells were detected among the freshly isolated T cells, whereas the T_M cells were detected only following 24 hr of incubation. Removal of T_C cells from the 24-hr-cultured T cells resulted in removal of all the T_C cells and in the concomitant removal of the majority of T_M cells. Similarly, removal of T_M cells from the 24-hr-cultured T cells resulted in the elimination of all T_M cells as well as the majority of T_C cells. These results demonstrate the in vitro generation of T cells with receptors for both FcM and C3 (T_M+C cells). Ten percent of the freshly isolated T_G cells possessed detectable receptors for C3 and/or FcM. These cells constitute the T_G+C and T_G+M lymphocytes. Support for consideration of these receptor-bearing cells as unique and stable cells is provided by the finding that T_M and T_C cells maintained in culture for up to 72 hr do not generate other receptors but retain the single receptor which characterizes each of these cells. Only a small percentage of cultured T_G cells generate receptors for C3 and FcM. It may therefore be concluded that the T_G, T_M, and T_C cells are stable unireceptor-bearing cells. The T_G, T_M, T_C, T_G+C, T_G+M, and T_M+C lymphocytes account for approximately 50% of the circulating lymphocytes. Whether the remaining cells, the T null or T_N cells, constitute the precursors for any or all of the receptor-bearing T cells remains to be determined. Unfractionated freshly isolated T cells were highly cytotoxic in the NK and PWM-mediated MICC assays but were relatively inactive in the ADCC, naturally occurring cell-mediated cytotoxicity (NOCC), and PHA- and Con-A-mediated MICC assays. In contradistinction, T cells incubated for 24 hr displayed marked cytotoxic activity in the ADCC and PHA-mediated MICC assays; they were inactive in the NOCC and Con-Amediated MICC assays. The T_G cells were the predominant cytotoxic cells in the ADCC, NK, and MICC cytotoxic assays since their selective elimination from either the freshly isolated or 24-hr-incubated T cells resulted in almost total loss of cytotoxic activity of the remaining cells. Removal of the T_G+C cells from the freshly isolated or 24-hr-incubated T cells resulted in a significant decrease in PHA- and PWM-mediated MICC cytotoxic activity. T cells depleted of T_M, T_M+C, and T_C cells exhibited the same cytotoxic activity as did the unfractionated T cells. These results suggest that the predominant cytotoxic T cells in all the assays investigated are the T_G cells, that limited cytotoxic activity is also displayed by the T_G+C cells, and that the T_M, T_M+C, T_C, and T_N cells display no cytotoxic activity in the assays utilized in this investigation.     

Succession of Sulfur-Oxidizing Bacteria in the Microbial Community on Corroding Concrete in Sewer Systems

Microbially induced concrete corrosion (MICC) in sewer systems has been a serious problem for a long time. A better understanding of the succession of microbial community members responsible for the production of sulfuric acid is essential for the efficient control of MICC. In this study, the succession of sulfur-oxidizing bacteria (SOB) in the bacterial community on corroding concrete in a sewer system in situ was investigated over 1 year by culture-independent 16S rRNA gene-based molecular techniques. Results revealed that at least six phylotypes of SOB species were involved in the MICC process, and the predominant SOB species shifted in the following order: Thiothrix sp., Thiobacillus plumbophilus, Thiomonas intermedia, Halothiobacillus neapolitanus, Acidiphilium acidophilum, and Acidithiobacillus thiooxidans. A. thiooxidans, a hyperacidophilic SOB, was the most dominant (accounting for 70% of EUB338-mixed probe-hybridized cells) in the heavily corroded concrete after 1 year. This succession of SOB species could be dependent on the pH of the concrete surface as well as on trophic properties (e.g., autotrophic or mixotrophic) and on the ability of the SOB to utilize different sulfur compounds (e.g., H₂S, S⁰, and S₂O₃²⁻). In addition, diverse heterotrophic bacterial species (e.g., halo-tolerant, neutrophilic, and acidophilic bacteria) were associated with these SOB. The microbial succession of these microorganisms was involved in the colonization of the concrete and the production of sulfuric acid. Furthermore, the vertical distribution of microbial community members revealed that A. thiooxidans was the most dominant throughout the heavily corroded concrete (gypsum) layer and that A. thiooxidans was most abundant at the highest surface (1.5-mm) layer and decreased logarithmically with depth because of oxygen and H₂S transport limitations. This suggested that the production of sulfuric acid by A. thiooxidans occurred mainly on the concrete surface and the sulfuric acid produced penetrated through the corroded concrete layer and reacted with the sound concrete below.     

Studies of complement receptors on cytotoxic effector cells in human peripheral blood

The question of whether cells bearing complement receptors (CR) mediate cytotoxicity in vitro against allogeneic Chang liver cell targets was investigated by assessing peripheral blood mononuclear cells (PBMC) from normal humans for cell surface characteristics and cytotoxic capacity before and after depletion of CR+ cells capable of forming rosettes with sheep erythrocytes coated with 19S antibody and mouse complement (EAC) and depletion of Fc receptor-bearing cells capable of forming rosettes with human O+ erythrocytes coated with Ripley antibody (EA-Ripley). PBMC depleted of CR+ cells by density centrifugation contained markedly reduced proportions of phagocytes and sIg + cells and increased proportions of both sIg ?, FcR+ cells as well as cells forming rosettes with sheep erythrocytes (E). PBMC depleted of CR+ cells mediated cytotoxicity to an extent equal to or greater than that mediated by unfractionated PBMC in assays of spontaneous cell-mediated cytotoxicity (SCMC), antibody-dependent cellular cytotoxicity (ADCC), and mitogen-induced cellular cytotoxicity (MICC). Cells harvested from the EAC-rosette enriched pellet mediated cytotoxicity 5- to 10-fold less than unfractionated PBMC; however, the cytotoxic activity of the pellet could not be attributed to CR + effector cells since similar cytotoxic activity was present in cell pellets obtained by density centrifugation of PBMC which had been incubated with E coated with 19S antibody or E alone. PBMC depleted of EA-Ripley rosette-forming cells contained decreased proportions of sIg?, FcR+ cells and increased proportions of CR+ cells; PBMC so depleted contained virtually no SCMC and ADCC effector cell activity. These findings indicate that at least the majority of effector cells which mediate SCMC, ADCC, and MICC do not bear CR.     

Pseudomonas aeruginosa as a Potential Probiont and Pigment Enhancer in the Ornamental Cichlid, Pseudotropheus lombardoi

Probiotics are a cultured product or live microbial feed supplement, which beneficially affects the host by improving its intestinal balance and health of the host. In the present study an attempt was made to study the effect of Pseudomonas aeruginosa (MICC 741) as a colour enhancing probiont in addition to growth and disease resistance in the ornamental cichlid, Pseudotropheus lombardoi. The experimental fishes were fed with different concentrations of P. aeruginosa. Incorporation of P. aeruginosa to the maximum of 30 mL (10³ CFU/mL) resulted in the gain of carotenoid pigment to the tune of 400 % over the control (p < 0.05) which again showed a significant increase in the growth rate of P. lombardoi. Disease resistance against the pathogens Vibrio parahaemolyticus and Bacillus cereus which were isolated from a diseased P. lombardoi were measured by zone of inhibition. Pseudomonas aeruginosa was found to be significantly effective in controlling both the pathogens. The investigation on P. aeruginosa proved that it not only improves the pigmentation, but also promotes growth and immunity to P. lombardoi.