A Genetic Mosaic Screen of Essential Zygotic Genes in Caenorhabditis Elegans

We have devised a simple genetic mosaic screen, which circumvents the difficulties posed by phenotypic analysis of early lethal mutants, to analyze essential zygotic genes in Caenorhabditis elegans. The screen attempts to distinguish genes involved in cell type and/or lineage specific processes such as determination, differentiation or morphogenesis from genes involved in general processes such as intermediary metabolism by using the pattern of gene function to classify genes: genes required in one or a subset of early blastomeres may have specific functions, whereas genes required in all early blastomeres may have general functions. We found that 12 of 17 genes examined function in specific early blastomeres, suggesting that many zygotic genes contribute to specific early processes. We discuss the advantages and limitations of this screen, which is applicable to other regions of the C. elegans genome.     

The in vivo differentiation of murine neuroblastoma

C1300 neuroblastoma was implanted with regenerating skeletal muscle to study the role of tissue interactions during tumor cell differentiation. Combined tumor-muscle implants, placed subcutaneously or within diffusion chambers were compared with control tumors implanted without muscle. Neuroblastoma implanted with injured muscle undergoes a partial neuronal differentiation. The tumor cells lose their normal round cell configuration and develop numerous cytoplasmic processes. Accompanying these outward changes are an increased content of microtubules in the neuritic processes; the appearance of glial-like processes containing abundant microfilaments; and the occurrence of growth vesicles identical to those of the growth cones of normal neurites. Although the implants usually contain large numbers of regenerated myofibers, tumor cell differentiation is not dependent upon the presence of these newly formed fibers. Tumor differentiation occurs equally well on the surfaces of degenerating muscle fragments, fibrin deposits and on the membrane surfaces of the diffusion chambers. These observations suggest that non-specific cell surface phenomena, rather than neuromuscular interactions were primarily responsible for the tumor cell differentiation in vivo.     

Tumor suppressor gene regulation of cell growth

The development of cancer involves a myriad of genetic changes that impact on multiple processes important for the orderly regulation of cell growth and differentiation. Genes whose protein products are disrupted during neoplastic transformation are termed “tumor suppressor genes” (TSGs). Many of these TSGs are associated with familial cancer predisposition syndromes, in which affected individuals have an increased risk of certain malignancies. Studies on the mechanism of action for known TSGs have revealed three intracellular loci of critical importance: environmental sensing and signal initiation, signal propagation and transduction, and cell cycle control. The neurofibromatosis 1 and neurofibromatosis 2 genes are discussed as illustrative examples of tumor suppressors that function at the levels of signal transduction and environmental sensing, respectively.     

组蛋白去乙酰化酶抑制剂影响的代谢相关基因的组学筛查及验证

组蛋白去乙酰化酶(Histone deacetylases, HDACs)催化组蛋白去乙酰化,与细胞增殖、分化及凋亡等诸多过程密切相关。HDAC抑制剂(HADC inhibitors, HADCIs)具有潜在的抗肿瘤作用,是近年药物筛查的热点之一。近期研究提示HDAC2可通过影响细胞代谢过程发挥抗肿瘤作用,但各类HDACIs调控代谢过程的机制尚待研究。本研究以肝细胞系(HepG2)为研究对象,整合比较了两种HDACIs(TSA和SAHA)的表达谱数据。在TSA处理组中,筛查到380个差异表达基因(DEGs)及35个DEGs富集的KEGG通路;SAHA处理组的表达分析印证了大多数DEGs(177/380)和富集通路(23/35)。比较分析发现,在这两类HDACIs共同影响的通路中,近一半通路(9/23)与代谢有关;近1/3共享DEGs(66/177)参与代谢过程。通过HDAC2 siRNA细胞实验证实了TSA和SAHA对代谢基因的影响。本研究结果显示HDACIs在治疗肿瘤等代谢性疾病方面具有潜在的应用 价值。     

利用ChIP-seq技术研究转录因子EDAG在全基因组的结合谱

为揭示红系分化相关基因（erythroid differentiation associated gene, EDAG）在造血中的作用机制,利用ChIP-seq分析EDAG的全基因组结合谱.首先从产妇脐带血分离CD34+细胞,EPO诱导CD34+细胞培养5 d.利用EDAG抗体进行染色体免疫共沉淀（chromatin immunoprecipitation, ChIP）实验、Western 印迹法检测EDAG抗体的富集情况.将富集到的DNA样品进行高通量测序,最后利用生物信息学分析测序结果.成功富集染色体DNA,经高通量测序和生物信息学分析,共得到1 292个EDAG 结合位点的Peaks数目,代表了975个结合的基因且错误发现率(false discovery rate, FDR)小于00001. EDAG Peaks主要分布在基因间区和内含子区.进一步利用Q-PCR对ChIP-Seq数据进行了验证,证实EDAG可结合在检测的靶基因调控区上.将EDAG结合的基因进行基因功能（gene ontology, GO)注释,表明EDAG参与了细胞周期、细胞生长、细胞分化、细胞凋亡及信号通路等多种生物学过程.综上,利用ChIP-seq技术在促红细胞生成素（EPO）诱导分化的CD34+细胞中鉴定了1 292个EDAG结合的peaks对应975个基因,并对该结果进行了随机验证,提示EDAG广泛参与了多种生物学过程.该研究为揭示EDAG的功能及作用机制提供了线索.     

Profiling changes in gene expression during differentiation and maturation of monocyte-derived dendritic cells using both oligonucleotide microarrays and proteomics

Dendritic cells (DCs) are antigen-presenting cells that play a major role in initiating primary immune responses. We have utilized two independent approaches, DNA microarrays and proteomics, to analyze the expression profile of human CD14(+) blood monocytes and their derived DCs. Analysis of gene expression changes at the RNA level using oligonucleotide microarrays complementary to 6300 human genes showed that approximately 40% of the genes were expressed in DCs. A total of 255 genes (4%) were found to be regulated during DC differentiation or maturation. Most of these genes were not previously associated with DCs and included genes encoding secreted proteins as well as genes involved in cell adhesion, signaling, and lipid metabolism. Protein analysis of the same cell populations was done using two-dimensional gel electrophoresis. A total of 900 distinct protein spots were included, and 4% of them exhibited quantitative changes during DC differentiation and maturation. Differentially expressed proteins were identified by mass spectrometry and found to represent proteins with Ca(2+) binding, fatty acid binding, or chaperone activities as well as proteins involved in cell motility. In addition, proteomic analysis provided an assessment of post-translational modifications. The chaperone protein, calreticulin, was found to undergo cleavage, yielding a novel form. The combined oligonucleotide microarray and proteomic approaches have uncovered novel genes associated with DC differentiation and maturation and has allowed analysis of post-translational modifications of specific proteins as part of these processes.     

Terminal osteoblast differentiation, mediated by runx2 and p27KIP1, is disrupted in osteosarcoma

The molecular basis for the inverse relationship between differentiation and tumorigenesis is unknown. The function of runx2, a master regulator of osteoblast differentiation belonging to the runt family of tumor suppressor genes, is consistently disrupted in osteosarcoma cell lines. Ectopic expression of runx2 induces p27KIP1, thereby inhibiting the activity of S-phase cyclin complexes and leading to the dephosphorylation of the retinoblastoma tumor suppressor protein (pRb) and a G1 cell cycle arrest. Runx2 physically interacts with the hypophosphorylated form of pRb, a known coactivator of runx2, thereby completing a feed-forward loop in which progressive cell cycle exit promotes increased expression of the osteoblast phenotype. Loss of p27KIP1 perturbs transient and terminal cell cycle exit in osteoblasts. Consistent with the incompatibility of malignant transformation and permanent cell cycle exit, loss of p27KIP1 expression correlates with dedifferentiation in high-grade human osteosarcomas. Physiologic coupling of osteoblast differentiation to cell cycle withdrawal is mediated through runx2 and p27KIP1, and these processes are disrupted in osteosarcoma.     

p130/p107 expression distinguishes adipogenic potential in primary myoblasts based on age

Recent investigations have provided significant evidence that many mesodermally derived tissues contain stem cell-like precursors capable of being stimulated to undergo differentiation into a variety of cellular lineages. We have recently reported that primary myoblasts isolated from 23-month-old mice have an increased adipogenic potential when compared to their 8-month-old counterparts. To further characterize the degree of adipocyte differentiation in these myoblasts, we examined early and late markers of adipocyte differentiation. Within the first 24h of adipocyte differentiation, expression of p130 and p107, two members of the retinoblastoma tumor suppressor gene family, are regulated and this event is an important one early in adipogenesis. Consistent with the increased adipogenic potential of the older myoblasts and in contrast to the younger cells, the p130:p107 pattern of expression is very similar to that observed in adipogenesis where there is a transient increase in p107 expression accompanied by a decrease in p130 expression. Interestingly, while these older cells accumulated lipid and expressed genes associated with lipid metabolism, they failed to express adipsin and leptin, two well-established markers of terminal adipocyte differentiation. These results suggest that older myoblasts are capable of initiating and progressing through the adipogenic program to a point where they express genes associated with lipid metabolism, but do not reach a terminally differentiated state. This finding may have important metabolic implications in the aging population.     

Factors that determine cell-specific gene expression in pancreatic endocrine tumor cells

Phenotypically distinct islet tumor cell lines may recapitulate certain of the developmental pathways of normal islet cell differentiation by expressing a combinatorial set of positively and negatively acting DNA-binding proteins to allow for the programmed expression of genes encoding polypeptide hormones. The structure of one of these DNA-binding proteins, a cyclic AMP-responsive protein (CREB) that binds specific DNA regulatory elements in the somatostatin gene, has been deduced from the sequence of a cloned cDNA. The CREB protein contains a DNA-binding domain separate from a cAMP-dependent protein kinase A activation domain. Further characterizations of the genes encoding the DNA-binding proteins should help to elucidate the cellular processes involved in islet cell differentiation and the genesis of tumors.     

Autophagy-associated circular RNA hsa_circ_0007813 modulates human bladder cancer progression via hsa-miR-361-3p/IGF2R regulation

Circular RNAs (circRNAs) drive several cellular processes including proliferation, survival, and differentiation. Here, we identified a circRNA hsa_circ_0007813, whose expression was upregulated in bladder cancer. High hsa_circ_0007813 expression was associated with larger tumor size, higher primary tumor T stage, and higher pathologic grade. Survival analysis showed that patients with high hsa_circ_0007813 expression levels had a poorer prognosis. Based on these findings from clinical tissue samples and cell lines, we assumed that hsa_circ_0007813 functioned a vital role in bladder cancer progression. Next, functional experiments revealed that knockdown of hsa_circ_0007813 inhibited proliferation, migration, and invasiveness of bladder cancer cells both in vitro and in vivo. Through extensive bioinformatic prediction and RNA pull-down assays, we identified hsa-miR-361-3p as a competing endogenous RNA of hsa_circ_0007813. Further bioinformatic studies narrowed targets to 35 possible downstream genes. We then found that knockdown of hsa_circ_0007813 led to altered cell autophagy, bringing our attention to IGF2R, one of the possible downstream genes. IGF2R was also known as cation-independent mannose-6-phosphate receptor (CI-M6PR), was discovered to participate in both autophagy and tumor biology. Regarding autophagy has a dominant role in the survival of tumor cells overcoming cellular stress and correlates with tumor progression, investigations were made to prove that hsa_circ_0007813 could regulate IGF2R expression via hsa-miR-361-3p sponging. The potential of hsa_circ_0007813 in regulating IGF2R expression explained its influence on cell behavior and clinical outcomes. Collectively, our data could offer new insight into the biology of circRNA in bladder cancer.Subject terms: Cancer metabolism, Bladder cancer, Macroautophagy, Cell growth, Cell invasion