Heme-Mediated Induction of CXCL10 and Depletion of CD34+ Progenitor Cells Is Toll-Like Receptor 4 Dependent

Plasmodium falciparum infection can cause microvascular dysfunction, cerebral encephalopathy and death if untreated. We have previously shown that high concentrations of free heme, and C-X-C motif chemokine 10 (CXCL10) in sera of malaria patients induce apoptosis in microvascular endothelial and neuronal cells contributing to vascular dysfunction, blood-brain barrier (BBB) damage and mortality. Endothelial progenitor cells (EPC) are microvascular endothelial cell precursors partly responsible for repair and regeneration of damaged BBB endothelium. Studies have shown that EPC’s are depleted in severe malaria patients, but the mechanisms mediating this phenomenon are unknown. Toll-like receptors recognize a wide variety of pathogen-associated molecular patterns generated by pathogens such as bacteria and parasites. We tested the hypothesis that EPC depletion during malaria pathogenesis is a function of heme-induced apoptosis mediated by CXCL10 induction and toll-like receptor (TLR) activation. Heme and CXCL10 concentrations in plasma obtained from malaria patients were elevated compared with non-malaria subjects. EPC numbers were significantly decreased in malaria patients (P < 0.02) and TLR4 expression was significantly elevated in vivo. These findings were confirmed in EPC precursors in vitro; where it was determined that heme-induced apoptosis and CXCL10 expression was TLR4-mediated. We conclude that increased serum heme mediates depletion of EPC during malaria pathogenesis.     

Erythrocytic Mobilization Enhanced by the Granulocyte Colony-Stimulating Factor Is Associated with Reduced Anthrax-Lethal-Toxin-Induced Mortality in Mice

Anthrax lethal toxin (LT), one of the primary virulence factors of Bacillus anthracis, causes anthrax-like symptoms and death in animals. Experiments have indicated that levels of erythrocytopenia and hypoxic stress are associated with disease severity after administering LT. In this study, the granulocyte colony-stimulating factor (G-CSF) was used as a therapeutic agent to ameliorate anthrax-LT- and spore-induced mortality in C57BL/6J mice. We demonstrated that G-CSF promoted the mobilization of mature erythrocytes to peripheral blood, resulting in a significantly faster recovery from erythrocytopenia. In addition, combined treatment using G-CSF and erythropoietin tended to ameliorate B. anthracis-spore-elicited mortality in mice. Although specific treatments against LT-mediated pathogenesis remain elusive, these results may be useful in developing feasible strategies to treat anthrax.     

鼠粒细胞集落刺激因子受体的纯化及鉴定

粒细胞集落刺激因子受体(G-CSFR)在鼠NFS-60细胞中有较高的含量,通过对NFS-60细胞的大规模培养,用CHAPS及超速离心抽提G-CSFR, 经G-CSF亲和层析纯化获得G-CSFR, 采用ABC-ELISA进行鉴定.     

Site-Specific Ubiquitination Determines Lysosomal Sorting and Signal Attenuation of the Granulocyte Colony-Stimulating Factor Receptor

Ubiquitination of cytokine receptors controls intracellular receptor routing and signal duration, but the underlying molecular determinants are unclear. The suppressor of cytokine signaling protein SOCS3 drives lysosomal degradation of the granulocyte colony-stimulating factor receptor (G-CSFR), depending on SOCS3-mediated ubiquitination of a specific lysine located in a conserved juxtamembrane motif. Here, we show that, despite ubiquitination of other lysines, positioning of a lysine within the membrane-proximal region is indispensable for this process. Neither reallocation of the motif nor fusion of ubiquitin to the C-terminus of the G-CSFR could drive lysosomal routing. However, within this region, the lysine could be shifted 12 amino acids toward the C-terminus without losing its function, arguing against the existence of a linear sorting motif and demonstrating that positioning of the lysine relative to the SOCS3 docking site is flexible. G-CSFR ubiquitination peaked after endocytosis, was inhibited by methyl-β-cyclodextrin as well as hyperosmotic sucrose and severely reduced in internalization-defective G-CSFR mutants, indicating that ubiquitination mainly occurs at endosomes. Apart from elucidating structural and spatio-temporal aspects of SOCS3-mediated ubiquitination, these findings have implications for the abnormal signaling function of G-CSFR mutants found in severe congenital neutropenia, a hematopoietic disorder with a high leukemia risk.     

The Role of DNA Ploidy in the Differentiation of WEHI-3B D Leukemia Cells Transfected with the Granulocyte Colony-Stimulating Factor Receptor Gene

Granulocyte colony-stimulating factor (G-CSF) exerts various biological effects through occupancy of its receptor (G-CSFR). WEHI-3B D^- myelomonocytic leukemia cells do not express the G-CSFR, do not respond to G-CSF or to retinoic acid by the induction of granulocytic maturation, contain a near tetraploid content of DNA, and form tightly aggregated colonies. However, they still maintain the capacity to differentiate since they respond to vitamin D₃ by the formation of mature cells. Transfection of the G-CSFR gene into WEHI-3B D^- cells resulted in three major changes. G-CSFR-expressing clones (a) acquired the capacity to respond to the differentiation-inducing properties of G-CSF and retinoic acid, (b) formed colonies which exhibited a dispersed phenotype, and (c) exhibited near diploid DNA ploidy. In contrast, WEHI-3B D^- cells transfected with vector alone behaved like parental WEHI-3B D^- cells. The findings imply that the near diploid phenotype is required for WEHI-3B D^- leukemia cells to respond to certain inducers of differentiation.     

Cross Talk with Hematopoietic Cells Regulates the Endothelial Progenitor Cell Differentiation of CD34 Positive Cells

Introduction

Despite the crucial role of endothelial progenitor cells (EPCs) in vascular regeneration, the specific interactions between EPCs and hematopoietic cells remain unclear.

Methods

In EPC colony forming assays, we first demonstrated that the formation of EPC colonies was drastically increased in the coculture of CD34⁺ and CD34⁻ cells, and determined the optimal concentrations of CD34⁺ cells and CD34⁻ cells for spindle-shaped EPC differentiation.

Results

Functionally, the coculture of CD34⁺ and CD34⁻ cells resulted in a significant enhancement of adhesion, tube formation, and migration capacity compared with culture of CD34⁺ cells alone. Furthermore, blood flow recovery and capillary formation were remarkably increased by the coculture of CD34⁺ and CD34⁻ cells in a murine hind-limb ischemia model. To elucidate further the role of hematopoietic cells in EPC differentiation, we isolated different populations of hematopoietic cells. T lymphocytes (CD3⁺) markedly accelerated the early EPC status of CD34⁺ cells, while macrophages (CD11b⁺) or megakaryocytes (CD41⁺) specifically promoted large EPC colonies.

Conclusion

Our results suggest that specific populations of hematopoietic cells play a role in the EPC differentiation of CD34⁺ cells, a finding that may aid in the development of a novel cell therapy strategy to overcome the quantitative and qualitative limitations of EPC therapy.     

HIV Infection Is Associated with a Preferential Decline in Less-Differentiated CD56dim CD16+ NK Cells

HIV-1 infection is characterized by loss of CD56^dim CD16⁺ NK cells and increased terminal differentiation on various lymphocyte subsets. We identified a decrease of CD57⁻ and CD57^dim cells but not of CD57^bright cells on CD56^dim CD16⁺ NK cells in chronic HIV infection. Increasing CD57 expression was strongly associated with increasing frequencies of killer immunoglobulin-like receptors (KIRs) and granzyme B-expressing cells but decreasing percentages of cells expressing CD27⁺, HLA-DR⁺, Ki-67⁺, and CD107a. Our data indicate that HIV leads to a decline of less-differentiated cells and suggest that CD57 is a useful marker for terminal differentiation on NK cells.NK cells are effector cells of innate immunity which are pivotal as first-line defense against viral infections, such as HIV infection (14). Large genotypic studies demonstrated a delayed onset of AIDS in HIV-seropositive individuals carrying the activating receptor KIR3DS1 and/or alleles of the inhibiting receptor KIR3DL1 in conjunction with HLA-Bw4-80I (18, 19). Development of NK cells mainly takes place in the bone marrow, from which mature NK cells move out to reside and circulate in peripheral sites (13). Mature NK cells are characterized by granules which harbor granzymes and perforin. These NK cells are fully armed, “ready-to-go” effector cells (17).A number of NK cell abnormalities have been reported in HIV infection (9), including high activation status (2, 10), increased turnover (16), differential expression of activating and inhibitory receptors (20), impaired interaction with dendritic cells (12), and loss of CD56^dim CD16⁺ NK cells (23). CD56^dim CD16⁺ NK cells represent the largest NK cell subset in peripheral blood in healthy individuals. The expression of killer immunoglobulin-like receptors (KIRs) and CD57 are predominant features of this subpopulation (8, 15). CD57 expression on NK cells has been previously associated with replicative senescence on T and NK cells (4), raising the question of how HIV-1 infection alters CD57 expression on CD56^dim CD16⁺ NK cells.To the best of our knowledge, no one has addressed the phenotypic and functional properties of CD56^dim CD16⁺ NK cells that are preferentially lost during HIV infection. Here, we provide evidence that increasing CD57 expression indicates terminal differentiation in healthy individuals, as well in as HIV-infected subjects. We furthermore show that HIV infection is associated with preferential loss of less-differentiated cells, which are characterized by high activation status and turnover.In this study, blood samples from 37 HIV-seropositive individuals and 15 healthy subjects were analyzed; all HIV-infected patients were either antiretroviral therapy naïve or untreated for more than one year. The HIV-positive study cohort comprised 10 patients with a viral load of less than 2,000 copies/ml, 14 patients with a viral load ranging from 2,000/ml to 20,000 copies/ml, and 13 patients with a viral load above 20,000 copies/ml. CD4 T cell counts ranged from 180/μl to 1,355/μl, the average being 457.3/μl.The study was approved by the local ethics commission (Ethikkommission der Medizinischen Hochschule Hannover, Votum No. 3150), and all study participants gave informed written consent for their participation.Flow cytometric analysis was performed on cryopreserved peripheral blood mononuclear cells (PBMCs) as previously described (21, 22). A list of monoclonal antibodies employed in this study is available upon request. For intracellular analysis of granzyme B, perforin, and Ki-67, we used a fixation and permeabilization kit (Invitrogen). At least 1 million events were acquired for each sample, using either a FACSAria or LSR II flow cytometer (BD Biosciences). Data were analyzed with FlowJo (TreeStar). Lymphocytes were defined by forward and side scatter. CD3⁺, CD14⁺, CD19⁺, dead cells, and cell aggregates were removed from analysis based on peridinin chlorophyll protein and Viaprobe staining and gating on a plot of forward-scatter area versus forward-scatter height (Fig. ​(Fig.1A).1A). NK cells and their distinctive subpopulations were defined based on their CD56 and/or CD16 expression. Fluorescence-minus-one (FMO) staining was used to determine threshold values for the expression of specific markers.Open in a separate windowFIG. 1.HIV infection is associated with loss of CD57⁻ and CD57^dim but not CD57^bright CD56^dim CD16⁺ NK cells. (A) Representative gating scheme for identification of NK cells. NK cells were defined as CD3⁻ CD14⁻ CD19⁻ lymphocytes expressing either CD56 or CD16 or both. We divided CD56^dim CD16⁺ NK cells into three subsets based on their level of CD57 expression: CD57⁻, CD57^dim, and CD57^bright cells. Numbers on FACS plots indicate frequency of gated population. SSC-A, side scatter area; FSC-A, forward scatter area; FSC-W, forward scatter width. (B) Comparison of percentages of the CD57⁻, CD57^dim, and CD57^bright subpopulations in control subjects (n = 14) and HIV-seropositive individuals (n = 34) on CD56^dim CD16⁺ NK cells. ns, not significant (P > 0.05); **, P < 0.01; ***, P < 0.001. (C) Frequencies of CD57⁻, CD57^dim, and CD57^bright expressing CD56^dim CD16⁺ NK cells in relation to total NK cells in control subjects (n = 14) and HIV-seropositive individuals (n = 34). (D) Mean frequency of CD56^dim CD16⁺ NK cells in 14 control individuals and in 34 HIV-infected people and the distribution of CD57⁻, CD57^dim, and CD57^bright cells within CD56^dim CD16⁺ NK cells is shown. (E) Relationship between percentage of CD57^dim CD56^dim CD16⁺NK cells and percentage of CD56^neg CD16⁺ NK cells on total NK cells. Horizontal bars in dot plots show the means.NK cells as defined above were sorted from cryopreserved PBMCs on a FACSAria (purities ranged from 91% to 99%). An amount of 10⁵ NK cells was plated per well and stimulated with 10 ng/ml interleukin-15 (IL-15), 100 ng/ml IL-12, and 5 × 10⁴ K562 cells. A CD107a degranulation assay was performed as described previously (1, 12). GraphPad Prism (version 5.0) software was used for statistical evaluation of data. Correlation analysis was performed using the Pearson test. The unpaired t test was performed when two groups were compared, and all t tests were two tailed. Comparison of more than two groups was performed using one-way analysis of variance followed by Tukey''s post-hoc test. P values of less than 0.05 were considered significant.We found that CD57 on NK cells was predominantly expressed on the CD56^dim CD16⁺ population (Fig. ​(Fig.1A).1A). The expression patterns of CD57 allowed us to differentiate between three subfractions within CD56^dim CD16⁺ NK cells, namely, CD57⁻, CD57^dim, and CD57^bright cells. The frequency of the CD57^bright subpopulation on CD56^dim CD16⁺ NK cells was increased compared to the frequency of the CD57^dim subpopulation on CD56^dim CD16⁺ NK cells in HIV-seropositive patients but not in HIV-seronegative control subjects (Fig. ​(Fig.1B).1B). This relative increase was associated with substantial reductions of the CD57⁻ CD56^dim and the CD57^dim CD56^dim NK cell subpopulations of total NK cells in our HIV-seropositive cohort compared to these subpopulations in healthy control subjects (means, 36.6% versus 24.8% [P = 0.0002] and 22.4% versus 15.4% [P = 0.0001]), but the frequencies of CD57^bright CD56^dim NK cells within total NK cells were similar between HIV-infected patients and HIV-seronegative individuals (Fig. ​(Fig.1C).1C). In accordance with previously published data (3, 23), we could confirm that there is a relative loss of CD56^dim CD16⁺ NK cells in HIV infection (mean, 84.3% versus 67.0%, P = 0.0004) (Fig. ​(Fig.1D).1D). Our data indicate that this loss is predominantly due to decreased numbers of CD57⁻ CD56^dim and CD57^dim CD56^dim NK cells, leading to a relative overrepresentation of CD57^bright cells within CD56^dim CD16⁺ NK cells in HIV infection (Fig. ​(Fig.1C).1C). There was no significant correlation between the relative loss of CD57⁻ and CD57^dim NK cells and absolute numbers of CD56^dim CD16⁺ NK cells, but there was a significant inverse correlation between loss of CD57^dim NK cells and increasing percentages of CD56⁻ CD16⁺ cells (Pearson r = −0.54, P = 0.001) (Fig. ​(Fig.1E1E).To determine whether the relative decrease of CD57⁻ and CD57^dim NK cells was associated with parameters of HIV disease progression, we performed correlation analysis of the percentages of CD57⁻ or CD57^dim cells with viral load and CD4 T cell counts. We found no such correlations (Pearson r < 0.2 and P > 0.05 for all) (data not shown). A recent cross-sectional and longitudinal study demonstrated that changes in the NK cell compartment, as shown by down-modulation of Siglec-7 on CD56^dim NK cells, are associated with HIV viremia (5). The longitudinal data in the study indicated that the full restoration of NK cell pathologies required 24 months of antiviral treatment. This suggests that alterations in the NK cell compartment can be driven by HIV viral load but that these changes seem to require a significant amount of time.We next investigated the phenotypic and functional properties of the CD57⁻, CD57^dim, and CD57^bright subpopulations on CD56^dim CD16⁺ NK cells. For KIR2DL2/DL3/DS2, we detected increasing prevalences of KIR-expressing NK cells with increasing expression of CD57 in both healthy control subjects and HIV-infected blood donors (Fig. ​(Fig.2A).2A). As for KIR3DS1/DL1, we found an increase of KIR⁺-expressing NK cells between CD57⁻ and CD57^bright cells in control individuals and significant differences in percentages of KIR3DS1/DL1-expressing NK cells between CD57⁻ and CD57^dim, as well as between CD57⁻ and CD57^bright, NK cells in our HIV-positive cohort (Fig. ​(Fig.2A).2A). These results suggest that increasing CD57 expression is associated with higher numbers of KIR-expressing NK cells in control subjects and HIV-infected subjects.Open in a separate windowFIG. 2.Phenotypic characterization of the CD57⁻, CD57^dim, and CD57^bright subpopulations of CD56^dim CD16⁺ NK cells. Representative flow cytometry plots for one control and one HIV-infected subject and summary data for all individuals whose PBMCs were analyzed are shown. CD57⁻, CD57^dim, and CD57^bright NK cells are concatenated to visualize them in a single dot plot. Numbers in contour plots indicate percentages of gated events of the respective subset. (A) Percentages of KIR2DL2/DL3/DS2 and KIR3DS1/DL1-expressing CD57⁻, CD57^dim, and CD57^bright cells were analyzed in control individuals (n = 15) and HIV-infected subjects (n = 37). (B) Numbers of HLA-DR-expressing and CD27-expressing CD57⁻, CD57^dim, and CD57^bright cells in control individuals'' (n = 15) and HIV-infected subjects'' (n = 37) PBMCs were analyzed. Horizontal bars in dot plots show the means. ns, not significant (P > 0.05); *, P < 0.05; **, P < 0.01; ***, P < 0.001.We next addressed the question of whether increasing CD57 expression is linked to differential phenotypic properties of NK cells and analyzed the HLA-DR and CD27 expression of the CD57⁻, CD57^dim, and CD57^bright subpopulations on CD56^dim CD16⁺ NK cells. A significantly higher fraction of NK cells expressed HLA-DR in the CD57⁻ than in the CD57^bright subset in both healthy control individuals and HIV-infected subjects (Fig. ​(Fig.2B).2B). A considerably higher portion of NK cells was positive for HLA-DR in HIV-infected individuals than in control subjects (means, 3.2% versus 13.2% [P < 0.0001], 1.8% versus 10.4% [P = 0.001], and 0.9% versus 6.5% [P = 0.005] for CD57⁻, CD57^dim, and CD57^bright subpopulations, respectively). We furthermore detected marked differences in frequencies of cells expressing CD27, a member of the tumor necrosis factor (TNF) receptor family (24). CD57⁻ NK cells displayed the highest percentages of CD27⁺ cells, whereas CD57^bright cells were almost all negative for CD27, in both control individuals and HIV-seropositive subjects (Fig. ​(Fig.2B).2B). We thus show that increasing expression of CD57 is associated with differential activation status and differential phenotype.Next, we sought to determine whether CD57 is linked to differential functional phenotypes by assessing the intracellular expression of granzyme B, perforin, and Ki-67. The frequencies of perforin-expressing NK cells did not vary within the different CD57 subsets of CD56^dim CD16⁺ NK cells (Fig. ​(Fig.3A).3A). However, we found that CD57^bright cells displayed the highest frequencies of granzyme B⁺ in both control and HIV-seropositive subjects, whereas CD57⁻ cells exhibited the lowest percentages for granzyme B⁺ cells (Fig. ​(Fig.3A).3A). Conversely, when we studied the expression of Ki-67, we identified the opposite trend: less than 5% of CD57^bright cells in control individuals and less than 10% of CD57^bright cells in HIV-infected study subjects expressed Ki-67 (Fig. ​(Fig.3B).3B). The highest numbers of Ki-67⁺ cells were found in the CD57⁻ population.Open in a separate windowFIG. 3.Functional characterization of CD57⁻, CD57^dim, and CD57^bright cells within the CD56^dim CD16⁺ NK cell population. (A) Representative staining results for granzyme B and perforin and summary data for control (n = 14) and HIV-seropositive subjects (n = 36). Numbers in the concatenated contour plots indicate percentages of gated events of the respective subset. B cells were defined as the negative control for granzyme and perforin staining. (B) Percentages of Ki-67⁺ and CD107a⁺ cells on CD57⁻, CD57^dim, and CD57^bright cells within the CD56^dim NK cell population in control (n = 14 and n = 9, respectively) and HIV-seropositive (n = 36 and n = 21, respectively) subjects'' PBMCs were analyzed. Horizontal bars in dot plots show the means. NC, negative control; ns, not significant (P > 0.05); *, P < 0.05; **, P < 0.01; ***, P < 0.001.We also assessed the presence of the degranulation marker CD107a on CD57⁻, CD57^dim, and CD57^bright subpopulations of CD56^dim CD16⁺ NK cells after stimulation with IL-12 and IL-15 and exposure to K562 cells. Similarly to what we had observed for Ki-67 expression, CD57⁻ cells were the most efficient at degranulation when compared with CD57^dim and CD57^bright cells in HIV-infected individuals. Comparison to healthy controls revealed that there was a higher expression of CD107a in HIV-seropositive subjects for each CD57 subset. However, the most effective degranulation occurred in the CD57⁻ and CD57^dim subsets, which are preferentially depleted in HIV infection.We focused our analysis on CD56^dim CD16⁺ NK cells because they constitute the largest NK cell subset in peripheral blood, they are the major NK cell subset expressing CD57 and KIRs, and they are the most prominent subpopulation for cytolytic activity. CD56^dim CD16⁺ cells but not CD56^bright CD16⁻ NK cells were reported to be decreased in HIV-infected subjects (23), which we could confirm in our experiments (data not shown). We did not find CD57 on CD56^bright CD16⁻ NK cells either in healthy or in HIV-infected individuals. CD57 has been described as a marker for replicative senescence, and its expression has been associated with shorter telomeres and diminished proliferative capacities on T and NK cells (4). The presence of this marker on CD56^dim CD16⁺ but not on CD56^bright CD16⁺ NK cells might explain why the latter subset was shown to proliferate more efficiently upon cytokine stimulation (6). We demonstrated that increasing CD57 expression on NK cells was associated with lower numbers of CD27-expressing cells, a marker which is mainly expressed by CD56^bright CD16⁻ NK cells (24). CD56^bright CD16⁻ cells were suggested to be early NK cells, which differentiate from CD34^dim CD45RA⁺ hematopoietic precursor cells with high expression of integrin α₄β₇ (11). These cells can furthermore give rise to CD56^dim CD16⁺ NK cells (7). Our data support this hypothesis, as we show that CD57 can be found on CD56^dim CD16⁺ NK cells but not on CD56^bright NK cells, whereas the opposite is observed for CD27.We demonstrate that differential CD57 expression is associated with distinct functional characteristics. We show for the first time that increasing expression of CD57 on CD56^dim CD16⁺ NK cells is associated with increasing prevalence of KIR⁺ and granzyme B⁺ cells. These cells appear to be more mature and differentiated in terms of KIR and granzyme B expression but less functionally active, as shown by decreased expression of Ki-67 and CD107a. We therefore propose that CD57 is not only a marker for replicative senescence but, in addition, a marker for terminal differentiation on NK cells, which is characterized by increased expression of KIR and higher granzyme B content and “counterbalanced” by decreased degranulation (CD107a) and decreased proliferation (Ki-67).Notably, we observed consistently higher frequencies of granzyme B⁺ cells in all three subsets within CD56^dim CD16⁺ NK cells from HIV-seropositive individuals than in healthy control subjects (means, 52.9% versus 78.7% [P < 0.0001], 65.3% versus 89.6% [P < 0.0001], and 76.5% versus 95.0% [P < 0.0001]for CD57⁻, CD57^dim, and CD57^bright subpopulations, respectively) (Fig. ​(Fig.1C).1C). Furthermore, HIV infection was associated with higher numbers of Ki-67-expressing NK cells (means, 8.4% versus 16.1% [P = 0.0005], 5.3% versus 11.6% [P = 0.0016], and 4.1% versus 6.2% [P = 0.04]) (Fig. ​(Fig.1C).1C). These changes, including the strong increase in HLA-DR-expressing NK cells, probably reflect the systemic immune activation in HIV-infected individuals.In summary, these findings support a view of a differential regulation of NK function and are in concordance with maturation of NK cells with high expression of CD57 on NK cells with a more terminally differentiated phenotype. Our data indicate that high turnover; activation status; and active degranulation as characterized by the expression of Ki-67, HLA-DR, and CD107a are mainly features of CD57⁻ and much less of CD57^dim NK cells. HIV infection is associated with increased activation, proliferation, and cytotoxicity during “early” stages of CD56^dim CD16⁺ NK cell differentiation compared to their occurrence in healthy controls, but those are the very cells that are significantly decreased in chronic HIV infection. A loss of these functionally more active NK cells may be a yet-unappreciated factor in overall NK cell pathology and a further possible explanation for the impairment of NK cells in their contribution to viral control in HIV infection.     

Tumor Necrosis Factor Receptor Expression in HIV-1-Infected CD4+ T Cells

We investigated whether HIV-1 can regulate tumor necrosis factor receptor (TNFR) expression in SupT-1, a CD4 + T-cell line. The cells were infected with HIV-1 containing 1,000 cpm RT activity, as early as day 3 after infection and all along the culture the supernatant level of core protein p24 was >250 pg/ml, and on days 6 and 9 after infection, p24 was found in 10 % of the cells as determined by indirect immunofluorescence assay. The cells were growing without loss of viability. The study of TNFR expression was based on a microassay for measurement of binding of ¹²⁵I-TNFα to cells, in which free and cell-bound ligand separation was performed by centrifugation through oil. Scatchard analysis of TNFα binding on days 6 and 9 after infection revealed a 90 % increase in the expression of high-affinity membrane receptors in HIV + SupT-1 culture compared with uninfected cells (mean +/-S.D. = 501 +/-148.5 vs. 263 +/-77.8 receptors/cell, n = 9, P< 0.001) with no change in dissociation constants (mean +/? S.D. = 4.36 +/?1.06 vs. 4.00 +/?1.12 × 10^?10 m ).     

Differential Gene Expression of Human CD34+ Hematopoietic Stem and Progenitor Cells Before and After Culture

Ex vivo expanded CD34⁺ hematopoietic stem and progenitor cells (HSPCs) have compromised homing and engraftment capacities. To investigate underlying mechanisms for functional changes of expanded HSPCs, we compared gene expression profiling of cultured and fresh CD34⁺ cells derived from cord blood using SMART-PCR and cDNA array: 20 genes were up-regulated while 25 genes were down-regulated in cultured CD34⁺ HSPCs. These differentially expressed genes are involved primarily in proliferation, differentiation, apoptosis, and homing. Revisions requested 27 September 2005; Revisions received 14 December 2005     

重组人粒细胞集落刺激因子(rhG-CSF)基因在鱼腥藻中的克隆

为了将rhG-CSF基因在鱼腥藻PCC 7120中克隆,用于制备口服制剂,利用DNA重组技术,在不改变阅读杠的前提下,将hG-CSF基因进行突变,并插入到pUC-19载体上,构建中间载体pUC=G-CSF;将pUC-G-CSF插入到pRL-489的启动子PpsbA的下游,构建穿梭表达载体pRL-G-CSF;通过三亲接合转移方法,将pRL-G-CSF转入丝状体蓝藻鱼腥藻PCC 7120内。本试验得到了有抗生素性的鱼腥藻,并用PCR技术检测到rhG-CSF基因在转基因鱼腥藻中存在。     

Expansion in CD39+ CD4+ Immunoregulatory T Cells and Rarity of Th17 Cells in HTLV-1 Infected Patients Is Associated with Neurological Complications

HTLV-1 infection is associated with several inflammatory disorders, including the neurodegenerative condition HTLV-1-associated myelopathy/tropical spastic paraparesis (HAM/TSP). It is unclear why a minority of infected subjects develops HAM/TSP. CD4⁺ T cells are the main target of infection and play a pivotal role in regulating immunity to HTLV and are hypothesized to participate in the pathogenesis of HAM/TSP. The CD39 ectonucleotidase receptor is expressed on CD4⁺ T cells and based on co-expression with CD25, marks T cells with distinct regulatory (CD39⁺CD25⁺) and effector (CD39⁺CD25⁻) function. Here, we investigated the expression of CD39 on CD4⁺ T cells from a cohort of HAM/TSP patients, HTLV-1 asymptomatic carriers (AC), and matched uninfected controls. The frequency of CD39⁺ CD4⁺ T cells was increased in HTLV-1 infected patients, regardless of clinical status. More importantly, the proportion of the immunostimulatory CD39⁺CD25⁻ CD4⁺ T-cell subset was significantly elevated in HAM/TSP patients as compared to AC and phenotypically had lower levels of the immunoinhibitory receptor, PD-1. We saw no difference in the frequency of CD39⁺CD25⁺ regulatory (Treg) cells between AC and HAM/TSP patients. However, these cells transition from being anergic to displaying a polyfunctional cytokine response following HTLV-1 infection. CD39⁻CD25⁺ T cell subsets predominantly secreted the inflammatory cytokine IL-17. We found that HAM/TSP patients had significantly fewer numbers of IL-17 secreting CD4⁺ T cells compared to uninfected controls. Taken together, we show that the expression of CD39 is upregulated on CD4⁺ T cells HAM/TSP patients. This upregulation may play a role in the development of the proinflammatory milieu through pathways both distinct and separate among the different CD39 T cell subsets. CD39 upregulation may therefore serve as a surrogate diagnostic marker of progression and could potentially be a target for interventions to reduce the development of HAM/TSP.     

Fibroblast Growth Factor Receptor 4 Polymorphism Is Associated with Liver Cirrhosis in Hepatocarcinoma

Background

Fibroblast growth factor receptor 4 (FGFR4) polymorphisms are positively correlated with tumor progression in numerous malignant tumors. However, the association between FGFR4 genetic variants and the risk of hepatocellular carcinoma (HCC) has not yet been determined. In this study, we investigated the potential associations of FGFR4 single nucleotide polymorphisms (SNPs) with HCC susceptibility and its clinicopathological characteristics.

Methodology/Principal Findings

Four SNPs in FGFR4 (rs1966265, rs351855, rs2011077, and rs7708357) were analyzed among 884 participants, including 595 controls and 289 patients with HCC. The samples were further analyzed to clarify the associations between these gene polymorphisms and the risk of HCC, and the impact of these SNPs on the susceptibility and clinicopathological characteristics of HCC. After adjusting for other covariants, HCC patients who carrying at least one A genotype (GA and AA) at rs351855 were observed to have a higher risk of liver cirrhosis compared with those carrying the wild-type genotype (GG) (OR: 2.113, 95% CI: 1.188–3.831). Moreover, the patients with at least one A genotype were particularly showed a high level of alpha-fetoprotein (AFP).

Conclusions

Our findings suggest that genetic polymorphism in FGFR4 rs351855 may be associated with the risk of HCC coupled with liver cirrhosis and may markedly increase the AFP level in Taiwanese patients with HCC. In addition, this is the first study that evaluated the risk factors associated with FGFR4 polymorphism variants in Taiwanese patients with HCC.     

PyNTTTTGT and CpG Immunostimulatory Oligonucleotides: Effect on Granulocyte/Monocyte Colony-Stimulating Factor (GM-CSF) Secretion by Human CD56+ (NK and NKT) Cells

CD56⁺ cells have been recognized as being involved in bridging the innate and acquired immune systems. Herein, we assessed the effect of two major classes of immunostimulatory oligonucleotides (ODNs), PyNTTTTGT and CpG, on CD56⁺ cells. Incubation of human peripheral blood mononuclear cells (hPBMC) with some of these ODNs led to secretion of significant amounts of interferon gamma (IFN-γ), tumor necrosis factor alpha (TNF-α) and granulocyte/monocyte colony-stimulating factor (GM-CSF), but only if interleukin 2 (IL2) was present. IMT504, the prototype of the PyNTTTTGT ODN class, was the most active. GM-CSF secretion was very efficient when non-CpG ODNs with high T content and PyNTTTTGT motifs lacking CpGs were used. On the other hand, CpG ODNs and IFNα inhibited this GM-CSF secretion. Selective cell type removal from hPBMC indicated that CD56⁺ cells were responsible for GM-CSF secretion and that plasmacytoid dendritic cells (PDCs) regulate this process. In addition, PyNTTTTGT ODNs inhibited the IFNα secretion induced by CpG ODNs in PDCs by interference with the TLR9 signaling pathway. Since IFNα is essential for CD56⁺ stimulation by CpG ODNs, there is a reciprocal interference of CpG and PyNTTTTGT ODNs when acting on this cell population. This suggests that these synthetic ODNs mimic different natural alarm signals for activation of the immune system.     

Upregulation of miR-760 and miR-186 Is Associated with Replicative Senescence in Human Lung Fibroblast Cells

We have previously shown that microRNAs (miRNAs) miR-760, miR-186, miR-337-3p, and miR-216b stimulate premature senescence through protein kinase CK2 (CK2) down-regulation in human colon cancer cells. Here, we examined whether these four miRNAs are involved in the replicative senescence of human lung fibroblast IMR-90 cells. miR-760 and miR-186 were significantly upregulated in replicatively senescent IMR-90 cells, and their joint action with both miR-337-3p and miR-216b was necessary for efficient downregulation of the α subunit of CK2 (CK2α) in IMR-90 cells. A mutation in any of the four miRNA-binding sequences within the CK2α 3′-untranslated region (UTR) indicated that all four miRNAs should simultaneously bind to the target sites for CK2α downregulation. The four miRNAs increased senescence-associated β-galactosidase (SA-β-gal) staining, p53 and p21^Cip1/WAF1 expression, and reactive oxygen species (ROS) production in proliferating IMR-90 cells. CK2α over-expression almost abolished this event. Taken together, the present results suggest that the upregulation of miR-760 and miR-186 is associated with replicative senescence in human lung fibroblast cells, and their cooperative action with miR-337-3p and miR-216b may induce replicative senescence through CK2α downregulation-dependent ROS generation.     

Use of Granulocyte Colony-Stimulating Factor for the Treatment of Thin Endometrium in Experimental Rats

Granulocyte colony-stimulating factor (G-CSF) induces stem cells to mobilize to the injury site, which have beneficial effect on tissue repair. The aim of this study was to investigate the effect of G-CSF on the thin endometrium in rat models. In the present study, rats with thin endometrium were divided into 4 groups (experimental group I: administrated with G-CSF (40 µg/kg/d) 4–6 hours post-modeling; control group I: administrated with saline 4–6 hours post-modeling; experimental group II: administrated with G-CSF (40 µg/kg/d) 12 days post-modeling; control group II: administrated with saline 12 days post-modeling. The agentia was given once daily and last for 5 days. Endometrial morphology was analyzed by Hematoxylin-Eosin staining, and the regeneration of endometrial cells was evaluated by immunohistochemistry and western-blot with cytokeratin and vimentin. We found that endometrial thickness and morphology presented a significant difference between experimental groups and control groups. No matter when we start with G-CSF, there was a significantly thicker endometrium and stronger expression of cytokeratin/vimintin in the experimental groups compared with the control groups (P<0.01). There were significant thicker endometrial lining and stronger expression of cytokeratin/vimintin in experimental group I than that of experimental group II (P<0.05), but there was no difference in the endometrial lining and the expression of cytokeratin/vimintin between the two control groups (P>0.05). In conclusion, G-CSF can promote the regeneration of endometrial cells in animal research, especially when the G-CSF was administrated earlier.     

Mobilization of CD34+-Progenitor Cells in Patients with Severe Trauma

Circulating CD34+ progenitor cells () gained importance in the field of regenerative medicine due to their potential to home in on injury sites and differentiate into cells of both endothelial and osteogenic lineages. In this study, we analyzed the mobilization kinetics and the numbers of CD34+, CD31+, CD45+, and CD133+ cells in twenty polytrauma patients (n = 13 male, n = 7 female, mean age 46.5±17.2 years, mean injury severity score (ISS) 35.8±12.5 points). In addition, the endothelial differentiation capacity of enriched CD34+cells was assessed by analyzing DiI-ac-LDL/lectin uptake, the expression of endothelial markers, and the morphological characteristics of these cells in Matrigel and spheroid cultures. We found that on days 1, 3, and 7 after a major trauma, the number of CD34+cells increased from 6- up to 12-fold (p<0.0001) over the number of CD34+cells from a control population of healthy, age-matched volunteers. The numbers of CD31+ cells were consistently higher on days 1 (1.4-fold, p<0.01) and 7 (1.3-fold, p<0.01), whereas the numbers of CD133+ cell did not change during the time course of investigation. Expression of endothelial marker molecules in CD34+cells was significantly induced in the polytrauma patients. In addition, we show that the CD34+ cell levels in severely injured patients were not correlated with clinical parameters, such as the ISS score, the acute physiology and chronic health evaluation II score (APACHE II), as well as the sequential organ failure assessment score (SOFA-2). Our results clearly indicate that pro-angiogenic cells are systemically mobilized after polytrauma and that their numbers are sufficient for the development of novel therapeutic models in regenerative medicine.