Rapid and highly efficient gene transfer into natural killer cells by nucleofection

Natural killer (NK) cells are important mediators of virus- and tumor-specific immune responses. The transfection of genes into NK cells has been proven difficult and so far requires infection with virus-based vectors. Here, the application of a novel nonviral, electroporation-based gene transfer method is described for the rapid and highly efficient transient transfection of NK cell lines as well as freshly isolated NK cells. In contrast to conventional methods, this technique, termed nucleofection, leads to direct transfer of DNA into the nucleus. Using reporter proteins H-2K(k), luciferase+, and enhanced yellow green fluorescent protein (EYFP) as independent read-out systems, transfection efficiencies of well over 50% were achieved in transient transfection assays. The highest luciferase activity could be measured only 4 h after transfection, whereas EYFP, when analyzed by flow cytometry, showed expression peaks after 28 h. Interestingly, best transfection efficiencies were achieved with non-dividing NK cells. The novel nuclear gene transfer method presented here is highly useful for the analysis of NK cell-specific gene regulation and should facilitate the development of NK cell-based gene therapy approaches.     

Cost efficient and effective gene transfer into the human natural killer cell line, NK92

Introducing genes into cells is a crucial step in many fields of basic research, as well as for the development of new drugs and therapies. Many cell types are resistant to normal methods of gene delivery, such as lipid based transfection and electroporation. Delivery to resistant cell lines can be costly or inefficient. Natural killer (NK) cells are highly resistant to transfection. We have developed a novel method to deliver exogenous genes in the NK cell line, NK92. Using a combination of electroporation and a defined buffer, we were able to obtain an electroporation efficiency of 40% in NK92 cells. Using RNAi, we show significant reduction of an endogenous protein (ETS1) using this optimized buffer and electroporation conditions. Taken together, the results show a functional and cost effective method for the expression of exogenous genes in NK cells.     

Retroviral transfer of HSV1-TK gene into human lung cancer cell line

We used a recombinant retrovirus as one of the potential vectors for human gene therapy to transfer a drug sensitivity gene into human lung cancer cells. The gene encoding the thymidine kinase (TK) of herpes simplex virus type 1 (HSV1) was used as the drug sensitivity gene. The antiherpes drugs acyclovir (ACV) and ganciclovir (GCV) were chosen to test the HSV1-TK activity transferred into the human lung cancer cell lines. The rationale for this approach was that ACV and GCV are nucleoside analogs specifically converted by HSV1-TK to a toxic form capable of inhibiting DNA synthesis or disrupting cellular DNA replication. The results obtained from our experiments demonstrate that the retroviral vector-mediated HSV1-TK gene transfer leads to ACV- and GCV-dependent cytotoxicity in human lung cancer cell lines, including both small-cell carcinoma and nonsmall-cell carcinoma. Although the gene transfer of HSV1-TK gene into tumor cells would be one model for gene therapy to control lung cancer, further investigations are necessary for the proper choice of the therapeutic gene and vector targeting such as tumor cell specific delivery of the gene or tumor cell specific expression of the transduced gene.Abbreviations ACV Acyclovir - GCV Ganciclovir - HSV1 Herpes simplex virus type 1 - LTR Long terminal repeat - TK Thymidine kinase     

Kinetics of cellular cytotoxicity mediated by a cloned human natural killer cell line

The kinetics of natural killer (NK) cytotoxicity mediated by the cloned interleukin 2 (IL 2)-dependent human natural killer cell line NK3.3 has been investigated. This cloned cell line exhibits strong cytotoxic activity that is restricted to NK target cells. The initial rate of lysis of K-562 target cells by these cloned NK cells was, as anticipated, substantially greater than that previously reported for human peripheral blood NK cell preparations. However, in contrast to the kinetics of NK cytolysis mediated by fresh peripheral NK cells, the rate of 51Cr-release declined substantially within 1 to 3 h after initiation of assays involving NK3.3 cells and reached a plateau value in experiments conducted for longer periods. The data obtained suggest that NK3.3 cells cannot readily recycle and kill multiple target cells. Based on a model involving one lethal hit per active NK3.3 cell, estimates for the frequency of cytolytic cells in NK3.3 cultures were computed and compared to estimates obtained by the application of a kinetic model previously described. The cytotoxic activity of the NK3.3 cells was also found to be highly dependent on the conditions used for propagation and assay of these cells and, when cultured under "standard" conditions, only a fraction of the cloned NK3.3 cells was capable of effecting lysis of K-562 target cells. However, for the most optimal conditions developed to date, each NK cell killed an average of 1 to 2 target cells before inactivation. Although no significant differences in viability or growth rate were observed for the three different conditions described, up to 300-fold differences in lytic activity were observed. The observed strong dependence of the lytic function of NK3.3 cells on culture conditions should prove valuable for further investigations of mechanisms governing the regulation and function of human NK cells.     

The biology of the human natural killer cell

Natural killer (NK) cells in the human are a population of large granular lymphocytes (LGL) with at least one unique surface antigen not expressed on cells of other lineages. NK-target-cell interaction appears to involve carbohydrate recognition and, following binding, the NK cells are induced to generate O₂ ^–, transmethylate membrane phospholipids, and activate phospholipase A₂. Some or all of these activities trigger a cascade of events which ultimately leads to the secretion of a substance toxic to the target cell. A variety of genes controls various steps in this cytolytic pathway. There is a good deal of evidence in the mouse, and some in the human, that NK cells play a role in host surveillance against tumor development, resistance to viral infections, and, possibly, hematopoietic regulation.     

Thymic stromal lymphopoietin augments the cytolytic activity of the human natural killer cell line NK-92

Culturing the human natural killer cell line NK-92 for 24 h in the presence of thymic stromal lymphopoietin (TSLP) potentiated its cytotoxic capacity against the erythroleukemia cell line K562. Longer incubation times did not augment the NK activity any further. No synergistic effects with respect to either proliferation or cytotoxicity were observed when TSLP was mixed with suboptimal concentrations of IL-2. FACS analysis of the NK-92 cells indicated expression of TSLPR but not the other component of the TSLP receptor complex, namely IL-7Ralpha. Some of the surface molecules known to be involved in NK cell-mediated cytotoxicity were also monitored. None of the receptors analyzed altered their expression to any major extent upon culture in TSLP or IL-2. However, a limited number of NK-92 cells were observed that had a rather low CD94/NKG2A expression, which increased upon stimulation with TSLP or IL-2.     

人自然杀伤细胞抑制性受体P58.1基因的克隆与鉴定

目的 克隆及鉴定P58.1基因。方法 采用RT-PCR技术,从正常人外周血单个核细胞中扩增P58.1基因全长cDNA,经酶切后构建重组克隆载体,测序鉴定。结果 RT-PCR获得预期的扩增产物P58.1全长cDNA,成功构建pSPORT1-P58.1重组克隆载体,酶切、酶谱分析与预期结果相符。DNA测序结果与GenBank登记的人P58.1cDNA全长碱基序列一致。结论 pSPORT1-58.1重组克隆载体构建成功;P58.1基因序列与文献报道一致,为下一步构建表达载体和基因转染等工作打下良好的基础。     

A high-efficiency system of natural killer cell cloning

The culture of human natural killer (NK) cell clones has traditionally been a long, laborious process with an efficiency of only 1-2%. Recently, a stem cell growth medium (SCGM) has been described to expand preferentially polyclonal NK cells from peripheral blood. We have tested SCGM in a single cell sorting system and shown a 4-5 fold increase in the number of proliferating NK clones compared to standard RPMI media. The cloning efficiency was further enhanced by the provision of irradiated feeder cells derived from multiple donors combined with the addition of the anti-CD3 antibody, OKT3. The combination of SCGM, single cell sorting and these multiple optimisations enhanced NK cloning efficiency by more than tenfold to greater than 20% for short-term cultures when deriving 10(5) cells and as high as 10% for longer term cultures when deriving more than 2 x 10(6) cells. This novel system thus facilitates the generation of NK clones and allows larger scale studies of NK function that were beyond the scope of previous methodology.     

Expression of killer cell inhibitory receptors on human uterine natural killer cells

The establishment of the human placenta in early pregnancy is characterized by the presence of large numbers of natural killer (NK) cells within the maternal decidua in close proximity to the fetally-derived invading extravillous trophoblast which expresses at least two HLA class I molecules, HLA-G and HLA-C. These NK cells have an unusual phenotype, CD56^bright CD16, distinguishing them from adult peripheral blood NK cells. They may control key events in trophoblast migration and therefore placentation. Human NK cells in peripheral blood express receptors for polymorphic HLA class I molecules. This family of receptors, known as killer cell inhibitory receptors (KIR), are expressed on overlapping subsets of NK cells to give an NK cell repertoire which differs between individuals. Using a panel of monoclonal antibodies to several members of the KIR family and analysis by flow cytometry, we have found that KIR are expressed by decidual NK cells. There is variation in both the percentage of cells expressing a particular receptor and the density of receptor expression between decidual NK cells from different individuals. Comparison of NK cells from decidua and peripheral blood of the same individual showed that NK cells from these two different locations express different repertoires of KIR. Receptors are present in individuals who do not possess the relevant class I ligand, raising the possibility that these NK receptors may be involved in recognition of the allogeneic fetus by the mother at the implantation site.     

Impaired natural killer cell subset phenotypes in human obesity

Obesity is associated with alterations in functionality of immune cells, like macrophages and natural killer (NK) cells, leading to an increased risk for severe infections and several cancer types. This study aimed to examine immune cell populations and functional NK cell parameters focusing on NK cell subset phenotypes in normal-weight and obese humans. Therefore, peripheral blood mononuclear cells (PBMCs) were isolated from normal-weight and obese individuals and analyzed by flow cytometry. Results show no significant changes in the frequency of monocytes, B lymphocytes, or NKT cells but a significantly increased frequency of T lymphocytes in obesity. The frequency of total NK cells was unaltered, whereas the number of low cytotoxic CD56^bright NK cell subset was increased, and the number of high cytotoxic CD56^dim NK cell subset was decreased in obese subjects. In addition, the frequency of CD56^bright NK cells expressing the activating NK cell receptor NKG2D as well as intracellular interferon (IFN)-γ was elevated in the obese study group. In contrast, the frequency of NKG2D- and IFN-γ-positive CD56^dim NK cells was lower in obesity compared to normal-weight individuals. Moreover, the expression of the activation marker CD69 was decreased in NK cells, which can be attributed to a reduction of CD69-positive CD56^dim NK cells in obese subjects. In conclusion, data reveal an impaired NK cell phenotype and NK cell subset alterations in obese individuals. This NK cell dysfunction might be one link to the higher cancer risk and the elevated susceptibility for viral infections in obesity.     

The natural killer gene complex: a genetic basis for understanding natural killer cell function and innate immunity

Summary: The natural killer gene complex encodes proteins, some of which are structurally unrelated, that impact on NK-cell function. Detailed analyses have indicated that these molecules are involved in NK-cell recognition, activation, and inhibition. The importance of this genomic region is highlighted by studies indicating that NKC-associated genes significantly influence NK cell-mediated innate host defense against life-threatening pathogens and that the NKC is conserved among diverse species. Thus, further elucidation of the NKC and its gene products will provide a genetic basis for understanding innate immunity and NK-cell activity at the molecular level.     

Embryonic neural cell adhesion molecules on human natural killer cells

The neural cell adhesion molecules (NCAM) are surface glycoproteins that were first described in brain tissue. NCAM mediate adhesion in a variety of cell-cell interactions. In the present study we show that the so-called "embryonic" NCAM, i.e., the highly polysialylated forms of these proteins, are expressed on natural killer cells and some CD3+ cells in man. Homotypic binding of NCAM, believed to be of importance for cell-cell adhesion in neural tissues, appears not to be essential for NK cell-mediated killing. Yet, NCAM might be involved in NK cell migration, homing or related functions.     

Inhibition of human natural killer cell activity by polyclonal IgM

Pretreatment of effector cells with normal human IgM induced strong dose-dependent inhibition of NK activity. The degree of inhibition by normal IgM was stronger than that induced by monomeric IgG, which has previously been reported to be a negative regulator of NK activity. For 100% inhibition, 1.1 × 10⁻⁶ M of IgM was required, whereas 66.6 × 10⁻⁶ M of IgG was needed to abolish NK activity. This inhibitory property of polyclonal IgM appeared to be localized in the Fc region of the molecule, and also was significantly reduced upon mild reduction of disulfide bonds. Monoclonal IgM purified from sera of five patients with Waldenström's macroglobulinemia and tested in parallel with normal IgM lacked or had a decreased capacity to inhibit the cytotoxic reaction. As with IgG, IgM interfered mainly with the lytic event, after binding of effector cells to target cells. The inhibition by IgM appeared to be a direct effect on NK cells, since similar effects were observed with purified large granular lymphocytes as with non-adherent lymphocytes. These results indicate a new mechanism for negative regulation of NK cells and suggest the presence of Fcμ receptors on these effector cells.     

Inhibition of human natural killer cell activity byLegionella pneumophila protease

The present study was undertaken to define the effect ofLegionella pneumophila protease on natural killer (NK) cell function in vitro. Lysis of target cells by human NK cells was determined using a⁵¹Cr-release assay. The protease inhibited the NK cell cytolytic activity in a concentration- and time-dependent manner. The inhibitory effect of the protease was not affected by alpha interferon or interleukin 2.Legionella pneumophila protease partly inhibited the binding of effector cells to target cells as studied in a single cell agarose assay of monocyte-depleted cell populations. This effect of the protease on the binding of NK cells to target cells could interfere with the previously described enhanced NK cell activity induced byLegionella pneumophila. We could demonstrate in vitro inhibition of NK cell activity byLegionella pneumophila protease at very low concentrations, suggesting a possible relevance of this mechanism in the pathogenesis of Legionnaires' disease.     

Regional sublocalization of the human CD69 gene to chromosome bands 12p12.3-p13.2, the predicted region of the human natural killer cell gene complex

The early activation antigen CD69 is a member of a supergene family of type II integral membrane proteins with a C-type lectin domain. In recent reports the genes encoding the natural killer (NK) cell-related molecules of this supergene family, NKR-P1, NK1.1 and Ly-49, were shown to be clustered in a chromosomal region in mouse, termed the NK gene complex. The human homologue of this complex is likely to reside on chromosome 12 near the PRP locus (12p13.2). By analyzing T cell hybrids, the CD69 gene was previously mapped to human chromosome 12. Here we report the regional sublocalization of the human CD69 gene to chromosome bands 12p12.3-p13.2, suggesting that CD69 belongs to one linkage group together with different cell surface molecules on NK cells.