Lymphokine regulation of HLA-DR gene expression in human thyroid cell monolayers

Studies were conducted to examine the regulation of HLA class II gene expression in human thyroid cells in vitro. Normal human thyroid cells cultured in the absence of lectin or gamma-interferon stimulation lacked detectable HLA-DR cell surface antigen, although low levels of DR alpha-chain-specific mRNA were present. Cyclosporine A, known to inhibit lymphokine production, inhibited basal as well as lectin-mediated increases in levels of DR alpha-chain-specific mRNA and DR surface antigen expression on normal human thyrocytes. Cyclosporine had no effect on the induction of DR antigen gene expression by recombinant gamma-interferon. These data suggested that lectin enhancement of DR antigen expression in human thyroid cells may be mediated by a lymphokine(s) produced in primary human thyroid cell monolayers. This suggestion was confirmed by studies that demonstrated the abrogation of lectin responsiveness by antibody directed against gamma-interferon. Indirect immunofluorescence studies using flow cytometric analyses identified 1.6 +/- 0.2% (mean +/- SD) of cells in primary thyroid cultures as T lymphocytes, a potential source of lymphokine production. Cells derived from thyroid follicular adenomas and carcinomas demonstrated reduced lectin-mediated increases in DR antigen expression compared to normal thyroid cells. DR expression could be enhanced in these lectin-treated cells, however, by T cell coculture. Dose-response studies demonstrated that human thyroid cells were as sensitive to gamma-interferon induction of DR antigen expression as human monocyte/macrophages. These results indicate that human thyroid cell HLA-DR antigen gene expression is sensitive to low levels of lymphokines, such as gamma-interferon; an intrathyroidal T cell population, which may serve as a source of lymphokine(s), remains associated with thyroid epithelial cells in primary thyroid cultures; and lymphokine-thyroid cell interactions may be implicated in the immunopathology of human autoimmune thyroid disease.     

Optical measurement of cycle-dependent cell growth

Determining the growth patterns of single cells offers answers to some of the most elusive questions in contemporary cell biology: how cell growth is regulated and how cell size distributions are maintained. For example, a linear growth in time implies that there is no regulation required to maintain homeostasis; an exponential pattern indicates the opposite. Recently, there has been great effort to measure single cells using microelectromechanical systems technology, and several important questions have been explored. However, a unified, easy-to-use methodology to measure the growth rate of individual adherent cells of various sizes has been lacking. Here we demonstrate that a newly developed optical interferometric technique, known as spatial light interference microscopy, can measure the cell dry mass of many individual adherent cells in various conditions, over spatial scales from micrometers to millimeters, temporal scales ranging from seconds to days, and cell types ranging from bacteria to mammalian cells. We found evidence of exponential growth in Escherichia coli, which agrees very well with other recent reports. Perhaps most importantly, combining spatial light interference microscopy with fluorescence imaging provides a unique method for studying cell cycle-dependent growth. Thus, by using a fluorescent reporter for the S phase, we measured single cell growth over each phase of the cell cycle in human osteosarcoma U2OS cells and found that the G2 phase exhibits the highest growth rate, which is mass-dependent and can be approximated by an exponential.     

Translational regulation of XIAP expression and cell survival during hypoxia in human cholangiocarcinoma

BACKGROUND & AIMS: Tumor progression is promoted by the ability of tumor cells to resist adverse environmental conditions such as hypoxia. We have shown that translational dysregulation contributes to transformed cell growth in malignant cholangiocytes. Translational regulation of gene expression can contribute to an immediate and rapid response to environmental changes such as hypoxia. Thus, our aims were to assess translational mechanisms involved in cell survival during hypoxia and to identify specific translationally regulated proteins involved in the cellular response to hypoxia. METHODS: Cell viability and apoptosis in response to hypoxia were assessed in human cholangiocarcinoma cells. Translational processes were deregulated by cycloheximide or rapamycin or by targeted deletion of eukaryotic initiation factor (eIF)-4E, a rate-limiting translational initiation factor using small interfering RNA (siRNA). A protein antibody microarray was used to screen for eIF-4E-dependent proteins expressed during hypoxia. Expression of the X-linked inhibitor of apoptosis (XIAP) was decreased using siRNA. RESULTS: Malignant cholangiocytes are resistant to hypoxia-induced apoptosis. Furthermore, cell survival during hypoxia required protein translation. eIF-4E was over expressed in malignant cholangiocytes. Reduction in eIF-4E expression by siRNA decreased tumor cell resistance to hypoxia, increased caspase-3 activation and apoptosis, and decreased cell survival compared with controls. XIAP was identified as a translationally regulated protein expressed during hypoxia. Modulation of XIAP expression by siRNA decreases cell death during hypoxia in vitro and in vivo. CONCLUSIONS: Human cholangiocarcinoma cells are highly resistant to hypoxia. Translational regulation of survival proteins such as XIAP is a mechanism mediating cholangiocarcinoma survival during hypoxia.     

MiR-451作用于MIF对大肠癌细胞株LoVo的影响

目的:研究MicroRNA-451(MiR-451)作用于巨噬细胞迁移抑制因子(macrophage migration inhibitory factor,MIF)对人大肠癌细胞株LoVo的影响.方法:构建包含有MiR-451过表达的慢病毒(hsa-mir-451a),感染LoVo细胞株,采用实时荧光定量PCR及Western blot技术检测MIF mRNA及蛋白在人大肠癌细胞LoVo及人大肠上皮细胞FHC中的表达变化情况,MTT法检测各组细胞的增殖能力.结果:与未感染组及对照组相比,感染组中MIF在mRNA及蛋白水平的表达均显著降低,感染组细胞的增殖活性明显受到抑制.结论:MIF可能是miR-451的直接作用靶点,高表达miR-451可以有效抑制LoVo中MIF的表达,进而抑制了LoVo的增殖.     

Phosphorylation of TPP1 regulates cell cycle-dependent telomerase recruitment

Telomere maintenance is essential for organisms with linear chromosomes and is carried out by telomerase during cell cycle. The precise mechanism by which cell cycle controls telomeric access of telomerase and telomere elongation in mammals remains largely unknown. Previous work has established oligonucleotide/oligosaccharide binding (OB) fold-containing telomeric protein TPP1, formerly known as TINT1, PTOP, and PIP1, as a key factor that regulates telomerase recruitment and activity. However, the role of TPP1 in cell cycle-dependent telomerase recruitment is unclear. Here, we report that human TPP1 is phosphorylated at multiple sites during cell cycle progression and associates with higher telomerase activity at late S/G₂/M. Phosphorylation of Ser111 (S111) within the TPP1 OB fold appears important for cell cycle-dependent telomerase recruitment. Structural analysis indicates that phosphorylated S111 resides in the telomerase-interacting domain within the TPP1 OB fold. Mutations that disrupt S111 phosphorylation led to decreased telomerase activity in the TPP1 complex and telomere shortening. Our findings provide insight into the regulatory pathways and structural basis that control cell cycle-dependent telomerase recruitment and telomere elongation through phosphorylation of TPP1.