天然免疫分子乳铁蛋白抑制鼻咽癌的发生发展

鼻咽癌是一种多基因遗传性肿瘤,其发病与遗传因素和环境因素密切相关,基因与环境因素间存在复杂的交互作用. 本课题组通过全基因组杂合性丢失扫描及比较基因组杂交,发现鼻咽癌中3号染色体短臂存在高频缺失,通过鼻咽癌家系连锁分析,发现染色体3p21区域为鼻咽癌易感基因区,随后通过表型克隆策略在该染色体区域分离鉴定了鼻咽癌候选易感/抑瘤基因LTF. LTF基因编码的乳铁蛋白是一种广泛分布于哺乳动物乳汁、鼻咽分泌物、泪液等分泌液中的天然免疫分子,在正常鼻咽部高表达而在鼻咽癌组织中表达显著下调,且与鼻咽癌的临床进展及侵袭转移密切相关. 病例-对照关联分析发现LTF基因中2个单核苷酸多态位点与鼻咽癌发病风险密切相关,且多态性改变可影响LTF基因的表达水平. 我们发现乳铁蛋白能与EB病毒在人B细胞表面的受体CD21结合,阻断EB病毒入侵宿主B细胞,并抑制EB病毒由B细胞向鼻咽上皮细胞的传递,在鼻咽上皮的癌变过程中起保护作用. 我们还发现LTF能通过MAPK和AKT等通路抑制鼻咽癌细胞的增殖和侵袭转移. 这些结果表明乳汁中的天然成份乳铁蛋白在鼻咽癌等EB病毒相关疾病的防治中具有重要的应用前景.     

Endometrial stromal cells and decidualized stromal cells: Origins,transformation and functions

Decidualization of endometrium, which is characterized by endometrial stromal cell (ESC) decidualization, vascular reconstruction, immune cell recruitment, and plentiful molecule production, is a crucial step for uterus to become receptive for embryo. When implantation takes place, ESCs surround and directly interact with embryo. Decidualized stromal cells (DSCs) are of great importance in endometrial decidualization, having a broad function in regulating immune activity and vascular remodeling of uterus. DSCs are shown to have a higher metabolic level and looser cytoskeleton than ESCs. What's the origin of ESCs and how ESCs successfully transform into DSCs had puzzled scientists in the last decades. Breakthrough had been achieved recently, and many studies had elucidated some of the characters and functions of DSCs. However, several questions still remain unclear. This paper reviews current understanding of where ESCs come from and how ESCs differentiate into DSCs, summarizes some characters and functions of DSCs, analyzes current studies and their limitations and points out research areas that need further investigation.     

Antagonistic functional duality of cancer genes

Cancer evolution is a stochastic process both at the genome and gene levels. Most of tumors contain multiple genetic subclones, evolving in either succession or in parallel, either in a linear or branching manner, with heterogeneous genome and gene alterations, extensively rewired signaling networks, and addicted to multiple oncogenes easily switching with each other during cancer progression and medical intervention. Hundreds of discovered cancer genes are classified according to whether they function in a dominant (oncogenes) or recessive (tumor suppressor genes) manner in a cancer cell. However, there are many cancer “gene-chameleons”, which behave distinctly in opposite way in the different experimental settings showing antagonistic duality. In contrast to the widely accepted view that mutant NADP⁺-dependent isocitrate dehydrogenases 1/2 (IDH1/2) and associated metabolite 2-hydroxyglutarate (R)-enantiomer are intrinsically “the drivers” of tumourigenesis, mutant IDH1/2 inhibited, promoted or had no effect on cell proliferation, growth and tumorigenicity in diverse experiments. Similar behavior was evidenced for dozens of cancer genes. Gene function is dependent on genetic network, which is defined by the genome context. The overall changes in karyotype can result in alterations of the role and function of the same genes and pathways. The diverse cell lines and tumor samples have been used in experiments for proving gene tumor promoting/suppressive activity. They all display heterogeneous individual karyotypes and disturbed signaling networks. Consequently, the effect and function of gene under investigation can be opposite and versatile in cells with different genomes that may explain antagonistic duality of cancer genes and the cell type- or the cellular genetic/context-dependent response to the same protein. Antagonistic duality of cancer genes might contribute to failure of chemotherapy. Instructive examples of unexpected activity of cancer genes and “paradoxical” effects of different anticancer drugs depending on the cellular genetic context/signaling network are discussed.     

Modification of lactoferrin by peroxynitrite reduces its antibacterial activity and changes protein structure

Lactoferrin (LF) is a multifunctional protein that plays important physiological roles as one of the most concentrated proteins in many human and other mammalian fluids and tissues. In particular, LF provides antibacterial properties to human milk, saliva, and tear fluid. LF also protects against stress-induced lipid peroxidation at inflammation sites through its iron-binding ability. Previous studies have shown that LF can be efficiently nitrated via biologically relevant mediators such as peroxynitrite (ONOO⁻), which are also present at high intracellular concentrations during inflammation and nitrosative stress. Here, we examine changes in antibacterial properties and structure of LF following ONOO⁻ treatment. The reaction induces nitration of tyrosine and tryptophan residues, which are commonly used as biomarker molecules for several diseases. Treatment with ONOO⁻ at a 10/1 M ratio of ONOO⁻ to tyrosine inhibited all antibacterial activity exhibited by native LF. Secondary structural changes in LF were assessed using circular dichroism spectroscopy. Nitration products with and without the addition of Fe³⁺ show significant reduction in alpha-helical properties, suggesting partial protein unfolding. Iron-binding capacity of LF was also reduced after treatment with ONOO⁻, suggesting a decreased ability of LF to protect against cellular damage. LC-MS/MS spectrometry was used to identify LF peptide fragments nitrated by ONOO⁻, including tyrosine residue Y92 located in the iron-binding region. These results suggest that posttranslational modification of LF by ONOO⁻ could be an important pathway to exacerbate infection, for example, in inflamed tissues and to reduce the ability of LF to act as an immune responder and decrease oxidative damage.