Monoclonal antibody against K562 cell line accelerates killing of the target cells by large granular lymphocytes

A monoclonal antibody (MoAb 11-4) was raised against K562, a human erythroleukemia cell line sensitive to natural killer cell-mediated cytotoxicity (NK-CMC). Immunological analysis revealed MoAb to be IgG_2b. Alone, the MoAb was not cytotoxic for K562 and did not bind to the effector cells, but the addition of this antibody to macrophage-depleted human peripheral blood lymphocytes increased killing of K562 in a 4-hr NK-CMC assay. The maximum increase in NK-CMC was observed when MoAb 11-4 was added to target cells prior to the formation of effector/target cell conjugates. This effect was dose dependent, was specific for K562, and, contrary to conventional antisera, occurred at very low concentrations of MoAb. When MoAb was added either to Percoll-purified large granular lymphocytes (LGL) or to LGL-depleted lymphocytes, only the latter demonstrated a significant increase in the killing of K562 in a 4-hr chromium release assay. Kinetics studies revealed that although the overall LGL-mediated lysis was only slightly increased at 4 hr, the maximum lytic activity was reached within 2 hr. These studies suggest that (1) human LGL and LGL-depleted cell populations bear Fc receptors for mouse IgG_2b and (2) although the cytotoxic activities of both cell populations are increased by treatment with MoAb 11-4, the kinetics of this increase are different.     

Mechanism of action of phorbol myristate acetate on human natural killer cell activity

We have investigated the kinetics of inhibition and regeneration of human natural killer (NK) cell-mediated lysis of K562, a human erythroleukemia cell line, by the potent tumor-promoting agent phorbol-12-myristate-13-acetate (PMA). It is shown that PMA inhibits NK cell-mediated cytotoxicity (CMC) in a dose-dependent manner whether the compound is present throughout the 4-hr cytotoxic assay or the effector cells (EC) are pretreated with PMA. Pretreatment of the target cells (TC) with PMA produced a different profile of NK activity suggesting that PMA inhibition of NK-CMC is primarily due to the inactivation of EC. PMA-induced inhibition of NK-CMC does not affect TC binding and is not circumvented by compounds that enhance intracellular levels of cyclic guanosine monophosphate (cGMP) or calcium. Furthermore, and contrary to a recent report, PMA-induced inhibition of NK-CMC is independent of monocytes. Finally, kinetic studies revealed that PMA-induced inhibition of NK-CMC occurs rapidly and is fully reversible provided that “regenerated EC” are thoroughly washed, prior to the cytotoxic assay, to rid the cell suspension of residual PMA. The potential implications of these results to the currently accepted theory of TC destruction by NK cells, the stimulus-secretion model, are discussed.     

Receptor modulation and early signal transduction events in cytotoxic T lymphocytes inactivated by sensitive target cells.

In previous studies, we demonstrated that NK cells and lymphokine-activated killer cells were inactivated early in the lytic process by susceptible but not by resistant target cells (TC). We examined the functional status of human MHC-restricted CTL, after interaction with sensitive TC. Two CTL lines were generated in vitro by stimulation with irradiated PAMO, an EBV-transformed cell line. CTL were incubated for up to 4 h with an equal number of PAMO, then separated by a SRBC rosette assay. CTL lost greater than 60% of their lytic activity during the first 30 min of incubation, and greater than 90% by 4 h as assessed by their inability to lyse fresh TC. Inactivated CTL had 35% less serine esterase activity than did control CTL. IL-2 restored the lytic potential and serine esterase activity to normal values within 72 h. Exposure of CTL to PAMO for 4 h induced the modulation of 22 to 44% of TCR/CD3, CD4/CD8, and class I Ag from the cell surface. In contrast, the expression of CD69, and class II Ag increased and there was no change in the expression of CD2, CD28, or LFA-1 Ag. Furthermore, early metabolic events that usually follow CTL-ligand interaction such as phosphatidylinositol metabolism and transient increase in intracellular calcium, did not occur in inactivated CTL upon challenge with PAMO. PMA and the calcium ionophore A23187, restored cytolytic activity, indicating that protein kinase C can be activated and translocated in inactivated CTL. Our data suggest that TC-induced inactivation of CTL may be due to the modulation of key membrane molecules and the lack of certain secondary messengers involved in signal transduction.     

A robust KASP marker for selection of four pairs of linked leaf rust and stripe rust resistance genes introgressed on chromosome arm 5DS from different wheat genomes

Molecular Biology Reports - Stripe rust and leaf rust are among the most devastating diseases of wheat, limiting its production globally. Wheat wild relatives harbour genetic diversity for new...     

Mapping of flag smut resistance in common wheat

Flag smut, caused by Urocystis agropyri, has been a problem in wheat production, but its incidence has declined with the use of resistant varieties and seed dressing. Diamondbird, an Australian wheat cultivar that carries high levels of resistance to flag smut, was crossed with susceptible Chinese landrace TH3929 and a doubled haploid (DH) population was developed. A linkage map comprising 386 markers was used for detection of genomic regions controlling flag smut resistance. Composite interval mapping identified five quantitative trait loci (QTL) with significant effects for flag smut resistance. QTL QFs.sun-3AL, QFs.sun-6AS, QFs.sun-1BL and QFs.sun-5BS were contributed by Diamondbird. Although TH3929 was susceptible, it contributed a minor QTL QFs.sun-3AS. QTL QFs.sun-3AL and QFs.sun-6AS were detected in both seasons and each explained more than 17 % of the variation in flag smut response. Other QTL QFs.sun-3AS, QFs.sun-1BL and QFs.sun-5BS explained 5–10 % of the phenotypic variation. DH lines that showed low flag smut levels carried combinations of three or more QTL. This is the first report on chromosomal location of flag smut resistance in a modern common wheat cultivar.     

Expression of p58.2 or CD94/NKG2A inhibitory receptors in an NK-like cell line,YTINDY, leads to HLA Class I-mediated inhibition of cytotoxicity in the p58.2- but not the CD94/NKG2A-expressing transfectant

Natural killer cytotoxicity is down-regulated by HLA Class I-specific inhibitory receptors classified as killer inhibitory receptors (KIRs) or C-type lectins. The regulation of their inhibitory signaling pathways is not completely understood. The YTINDY NK-like cell line was transfected to express p58.2 KIR (YT/C143 transfectant) or CD94/NKG2A C-type lectin (YT/CD94 transfectant); and YT/C143, but not YT/CD94, cytotoxicity was down-regulated by Class I. YT/C143 and YT/CD94 expressed equally low p56(lck) levels, suggesting that p56(lck) is not absolutely required for p58.2 signaling but may be required for CD94/NKG2A signaling. Lower SHP-1 levels and activity were observed in YT/CD94 compared to YT/C143. However, increasing SHP-1 to equivalent levels in YT/C143 did not restore inhibition in YT/CD94. Our results suggest that the combination of low p56(lck) and SHP-1 levels may be responsible for the absent inhibitory signal in YT/CD94. In addition, the possible expression of CD94/NKG2C activating receptor may override inhibitory signals transduced through CD94/NKG2A.     

Effect of Fas+ and Fas− Target Cells on the Ability of NK Cells to Repeatedly Fragment DNA and Trigger Lysis via the Fas Lytic Pathway

We and others have recently shown that human NK cells express the Fas ligand (FasL) constitutively and that they can trigger the lysis of Fas positive (Fas+) target cells (TC) by apoptosis. We have also previously demonstrated that NK cells exposed to sensitive TC temporarily lose their ability to lyse sensitive TC via the granule-mediated pathway and that this loss is recovered when inactivated NK cells (NKi) are incubated in medium supplemented with IL-2, IL-12 or IL-15. In this study, we investigated the fate of the Fas-lytic pathway in NK cells exposed to either Fas+ or Fas– TC. To this end, we exposed NK cells to Jurkat (Fas–) or Jurkat (Fas+) TC for up to 6 h, separated NK cells from the TC and assessed the residual lytic activity against K562, a traditional human NK cell target, Jurkat Fas+ and Jurkat Fas– TC. Fas lytic activity was determined in calcium free medium, in the presence or absence of two distinct Fas-blocking monoclonal antibodies and a Fas.Fc fusion protein. In parallel experiments, the extent of DNA fragmentation in the three TCs was also assayed by the JAM test. Our results indicate that: (i) NK cells exposed to susceptible Fas+ TC temporarily lose most of their lytic potential due to the granule-mediated pathway, while only partially losing the Fas-lytic pathway. They also partially lose their ability to fragment DNA. (ii) NK cells exposed to Fas+ TC completely recover the Fas lytic pathway and the ability to fragment DNA via the Fas/Fas ligand when incubated in medium supplemented with IL-2 for 18 h.     

Generation and characterization of a lipopolysaccharide-specific murine monoclonal antibody to <Emphasis Type="Italic">Proteus vulgaris</Emphasis> OX19

The three strains of non-pathogenic Proteus species namely, Proteus vulgaris OX2, P. vulgaris OX19 and Proteus mirabilis OXK used in the Weil–Felix test are the group-specific cross-reactive antigens for Rickettsia and Orientia species. Earlier studies have revealed that the group specific and cross-reactive antigens responsible for the Weil–Felix test lie mostly in the lipopolysaccharide (LPS) moiety of the bacterial cell wall [Amano et al. (1993a) Infect Immun 61:4350–4355, (1993b) Microbiol Immunol 37:927–933, (1998) Infect Immun 66:923–926]. The three Proteus strains (OX2, OX19 and OXK) were used to raise murine monoclonal antibodies (MAbs) by hybridoma technology. Several MAb-producing hybridomas could be stabilized following limiting dilution. Affinity and specificity of these MAbs were checked by indirect ELISA using a battery of homologous and heterologous antigens including LPS. Amongst these, one MAb was found to be specific for P. vulgaris OX19 LPS. Since the Weil–Felix reaction is based on the cross-reactivity between the LPS based epitopes, this MAb could be of potential use in mapping of epitopes on the cross-reactive LPS and may also be useful as a potential diagnostic reagent.     

Thidiazuron-induced morphogenesis in tamarind seedlings

Summary Germination of tamarind seeds in medium containing thidiazuron (TDZ) resulted in induction of nodular protrusions in and around the cotyledonary node meristem. The structures developed radially in well-defined circles and subsequently spread towards the cotyledonary bridge and also in the proximal part of the hypocotyl. The structures developed into shoots on transfer to medium devoid of growth regulators. Histological studies revealed that the protrusions initiated from the nodal meristem and extended to the non-meristematic region between the two meristems and also in the proximal part of the hypocotyl in seedlings germinated in 9.08 μM TDZ. Newly formed cell layers and less-differentiated meristematic protrusions were also seen. With the increase in the distance from the meristem, the buds were less differentiated; in the proximal part of the hypocotyl only the multiple layers of meristematic cells were noted. With extension of the period of incubation, the TDZ-induced meristematic activity extended laterally in circles towards the neighboring region. The radial spread of the meristematic activity from the center of the nodal meristem was also evident at 18.16 μM TDZ. From the pattern of the morphogenic development and the histological studies it may be hypothesized that in tamarind, TDZ influences the existing meristems specifically. Subsequently de novo organogenesis is triggered in the neighboring cells.     

Skeletal growth, ultrastructure and composition of the azooxanthellate scleractinian coral Balanophyllia regia

The biomineralization process and skeletal growth dynamics of azooxanthellate corals are poorly known. Here, the growth rate of the shallow-water dendrophyllid scleractinian coral Balanophyllia regia was evaluated with calcein-labeling experiments that showed higher lateral than vertical extension. The structure, mineralogy and trace element composition of the skeleton were characterized at high spatial resolution. The epitheca and basal floor had the same ultrastructural organization as septa, indicating a common biological control over their formation. In all of these aragonitic skeletal structures, two main ultrastructural components were present: “centers of calcification” (COC) also called rapid accretion deposits (RAD) and “fibers” (thickening deposits, TD). Heterogeneity in the trace element composition, i.e., the Sr/Ca and Mg/Ca ratios, was correlated with the ultrastructural organization: magnesium was enriched by a factor three in the rapid accretion deposits compared with the thickening deposits. At the interface with the skeleton, the skeletogenic tissue (calicoblastic epithelium) was characterized by heterogeneity of cell types, with chromophile cells distributed in clusters regularly spaced between calicoblasts. Cytoplasmic extensions at the apical surface of the calicoblastic epithelium created a three-dimensional organization that could be related to the skeletal surface microarchitecture. Combined measurements of growth rate and skeletal ultrastructural increments suggest that azooxanthellate shallow-water corals produce well-defined daily growth steps.