鲫Kaiso基因cDNA的克隆和表达分析

在爪蟾和斑马鱼中, Kaiso是一种在整个基因组范围内与甲基化CpG序列特异性结合的转录抑制因子, 在调控被甲基化基因表达的时间模式中起重要的作用。为深入研究DNA甲基化对我国重要养殖鱼类生殖和发育的影响, 我们克隆了鲫Kaiso基因的cDNA序列, 并对其时空表达模式进行了分析。该cDNA全长3145 bp, 5′-非翻译区132 bp, 3′-非翻译区1117 bp, 开放阅读框1896 bp, 编码631个氨基酸。鲫Kaiso蛋白与其他物种Kaiso蛋白的同源性分析表明, 与其他物种一样, 其 N端和C端分别有高保守性的BTB/POZ结构域和锌指结构域。整胚原位杂交结果显示, Kaiso mRNA在早期胚胎发育的各个时期均广泛表达, 信号均一, 但从尾芽期开始出现组织特异性表达差异。对不同发育阶段胚胎的实时定量PCR检测结果表明: 卵子中有高丰度的母源Kaiso mRNA存在; 在卵裂期至囊胚中期胚胎中Kaiso mRNA的丰度逐渐降低; 从囊胚中期至原肠早期都维持在最低水平状态; 原肠后期其表达水平又逐渐升高, 至尾芽期达到与未受精卵中相当的高水平后在器官发生期的整体水平又稍有下降。Kaiso mRNA丰度在胚胎发育早期的这种变化过程提示在卵裂期检测到的mRNA可能都是母源mRNA, 合子核Kaiso基因可能是在囊胚晚期后才开始转录。对成体不同组织的实时定量PCR检测结果表明Kaiso的表达存在明显的组织特异性差异, 在鲫肌肉、视网膜、心脏和脑中表达水平较高, 而在肾、胰、肝等器官中表达水平很低。Kaiso表达的时间和组织特异性提示其作为甲基化基因的转录抑制因子参与了胚胎和成体基因表达时空模式的调控。这些结果为进一步研究Kaiso和DNA甲基化修饰在鲫发育调控和遗传育种中的作用提供了基础资料。     

Kaiso/p120-catenin and TCF/beta-catenin complexes coordinately regulate canonical Wnt gene targets

Beta-catenin-dependent or canonical Wnt signals are fundamental in animal development and tumor progression. Using Xenopus laevis, we report that the BTB/POZ zinc finger family member Kaiso directly represses canonical Wnt gene targets (Siamois, c-Fos, Cyclin-D1, and c-Myc) in conjunction with TCF/LEF (TCF). Analogous to beta-catenin relief of TCF repressive activity, we show that p120-catenin relieves Kaiso-mediated repression of Siamois. Furthermore, Kaiso and TCF coassociate, and combined Kaiso and TCF derepression results in pronounced Siamois expression and increased beta-catenin coprecipitation with the Siamois promoter. The functional interdependency is underlined by Kaiso suppression of beta-catenin-induced axis duplication and by TCF-3 rescue of Kaiso depletion phenotypes. These studies point to convergence of parallel p120-catenin/Kaiso and beta-catenin/TCF signaling pathways to regulate gene expression in vertebrate development and possibly carcinogenesis.     

PLZF与哺乳动物雄性生殖干细胞的发育分化

早幼粒细胞白血病锌指蛋白（promyelocytic leukemia zinc finger,PLZF）,也被称为ZBTB16(zinc finger and BTB domain containing 16,ZBTB16)或锌指蛋白145(zinc finger protein 145,ZFP145),是我国学者发现与人类疾病相关的蛋白质.人类PLZF的是由673个氨基酸残基组成的转录抑制因子,属于蛋白质超家族. 该超家族以N端的BTB/POZ（bric-à-brac, tramtrack, brad complex(BTB)/poxvirus zinc finger (POZ) domain）结构为特征. PLZF蛋白的BTB/POZ结构与个体发育、胚胎发生、染色体的重构等事件相关.近年发现,PLZF在哺乳动物雄性生殖干细胞（male germline stem cells,mGSCs）发育分化过程中也发挥重要作用.探讨PLZF的生物学功能和作用机制,将有助于理解其在mGSCs发育过程中的重要作用. 本文就PLZF在维持mGSCs自我更新和在发育分化调控中的作用给予综述.     

Misregulation of the kinesin-like protein Subito induces meiotic spindle formation in the absence of chromosomes and centrosomes

Bipolar spindles assemble in the absence of centrosomes in the oocytes of many species. In Drosophila melanogaster oocytes, the chromosomes have been proposed to initiate spindle assembly by nucleating or capturing microtubules, although the mechanism is not understood. An important contributor to this process is Subito, which is a kinesin-6 protein that is required for bundling interpolar microtubules located within the central spindle at metaphase I. We have characterized the domains of Subito that regulate its activity and its specificity for antiparallel microtubules. This analysis has revealed that the C-terminal domain may interact independently with microtubules while the motor domain is required for maintaining the interaction with the antiparallel microtubules. Surprisingly, deletion of the N-terminal domain resulted in a Subito protein capable of promoting the assembly of bipolar spindles that do not include centrosomes or chromosomes. Bipolar acentrosomal spindle formation during meiosis in oocytes may be driven by the bundling of antiparallel microtubules. Furthermore, these experiments have revealed evidence of a nuclear- or chromosome-based signal that acts at a distance to activate Subito. Instead of the chromosomes directly capturing microtubules, signals released upon nuclear envelope breakdown may activate proteins like Subito, which in turn bundles together microtubules.     

Newly Characterized Region of CP190 Associates with Microtubules and Mediates Proper Spindle Morphology in Drosophila Stem Cells

CP190 is a large, multi-domain protein, first identified as a centrosome protein with oscillatory localization over the course of the cell cycle. During interphase it has a well-established role within the nucleus as a chromatin insulator. Upon nuclear envelope breakdown, there is a striking redistribution of CP190 to centrosomes and the mitotic spindle, in addition to the population at chromosomes. Here, we investigate CP190 in detail by performing domain analysis in cultured Drosophila S2 cells combined with protein structure determination by X-ray crystallography, in vitro biochemical characterization, and in vivo fixed and live imaging of cp190 mutant flies. Our analysis of CP190 identifies a novel N-terminal centrosome and microtubule (MT) targeting region, sufficient for spindle localization. This region consists of a highly conserved BTB domain and a linker region that serves as the MT binding domain. We present the 2.5 Å resolution structure of the CP190 N-terminal 126 amino acids, which adopts a canonical BTB domain fold and exists as a stable dimer in solution. The ability of the linker region to robustly localize to MTs requires BTB domain-mediated dimerization. Deletion of the linker region using CRISPR significantly alters spindle morphology and leads to DNA segregation errors in the developing Drosophila brain neuroblasts. Collectively, we highlight a multivalent MT-binding architecture in CP190, which confers distinct subcellular cytoskeletal localization and function during mitosis.     

The BTB domain of bric à brac mediates dimerization in vitro.

The gene bric à brac (bab) is required for the proper development of the limbs and ovary in Drosophila melanogaster. bab encodes a BTB domain (also called a POZ domain), an approximately 115-amino-acid conserved motif found primarily in the N termini of zinc finger proteins. In this paper, we show that the BTB domain of bab can mediate protein dimerization in vitro. In addition, we demonstrate that the first 51 amino acids of the bab BTB domain are sufficient for dimerization, and we identify amino acids within this region that are required for binding.