果蝇肠道干细胞研究进展

对果蝇Drosophila melanogaster Meigen肠道干细胞的研究现已触及生物学的很多方面,目前对这类细胞的研究主要集中于干细胞的小生境、信号路径的调控和细胞的分化,本文阐述了果蝇肠道干细胞研究方面的最新进展。果蝇肠道干细胞和脊椎动物肠道干细胞有诸多类似之处,所以弄清果蝇肠道干细胞的机理,可以为复杂的脊椎动物肠道干细胞研究提供了一定的理论基础。     

肠道菌群：肠道干细胞增殖分化的调节者

肠道干细胞(intestinal stem cells, ISCs)是肠道各类上皮细胞的来源,通过平衡增殖与分化维持肠道稳态。同时,肠道菌群及其代谢物在维持宿主肠道稳态中也发挥着重要作用。随着技术的发展,研究者认识到ISCs与肠道菌群之间存在相互作用。研究表明,ISCs对上皮细胞亚型的调控影响肠道菌群的组成,并且肠道菌群及其代谢物也影响ISCs介导的上皮发育。本文阐述了ISCs分化对肠道菌群的影响,重点总结了肠道菌群及其代谢物调控ISCs增殖分化的研究进展,从菌群调控ISCs的角度探讨肠道损伤的治疗思路,并对未来可能的研究方向进行讨论。     

果蝇肠道共生菌对宿主作用的研究进展

肠道共生菌是动物体内的重要组成部分,在宿主的生长发育和健康等方面发挥着重要作用,近年来已成为国内外的研究热点.果蝇作为研究肠道微生物菌群功能的优秀模型,在肠道共生菌与宿主关系研究方面已取得许多重要进展.在本文中,我们首先对果蝇肠道微生物的组成和特征作了总结,然后对果蝇肠道共生菌在其生长发育、营养与代谢、行为反应、寿命以...     

基于果蝇口腔感染的肠道训练免疫模型研究（英文）

目的 利用果蝇作为遗传工具从个体和分子层面研究果蝇的训练免疫效应,并为后续深入研究其分子机制提供依据。方法 首先构建无菌果蝇模型,在此基础上构建果蝇成虫及跨发育阶段训练免疫模型,用两种革兰氏阴性菌——胡萝卜软腐欧文氏菌（Erwinia carotovora carotovora 15）及铜绿假单胞菌（Pseudomonas aeruginosa）分别经口腔感染果蝇。在第一次感染完全消退后进行再次感染,然后通过比较果蝇在两个感染阶段的存活率和细菌量来衡量训练免疫的潜在效果。通过实时荧光定量PCR检测相应先天免疫相关基因的表达水平,研究革兰氏阴性菌对免疫缺陷（IMD）通路的诱导作用。结果 果蝇成虫及幼虫初次感染均可提高二次感染后的生存率、细菌清除效率及死亡时能承受的最高细菌负荷;二次感染的果蝇中,IMD通路中免疫反应基因的基础表达比未感染的高,这提供了获得感染抗性的分子基础;果蝇的免疫反应主要发生在中肠,二次免疫比初次免疫的效应更迅速且剧烈;二次免疫的果蝇中,肠道干细胞的数量显著多于初次感染。结论 果蝇肠道中强大的训练免疫可由同源或异源革兰氏阴性菌口腔感染引发,且免疫记忆可在整个发育阶段持...     

肠道干细胞和潘氏细胞在肠道稳态和疾病中的作用

肠道是最复杂的器官之一,负责营养的吸收和消化。肠道具有多层结构保护整个肠道免受病原体的侵害。肠道上皮是由单层柱状上皮细胞组成,是抵抗病原体的第一道屏障。因此,肠上皮必须保持完整性以保护肠免受感染和毒性剂的侵害。上皮细胞分为两个谱系(吸收型与分泌型),并且每隔3~4天脱落至肠腔中。细胞的快速更替是由于肠道干细胞的存在,肠道干细胞排列在隐窝底部终极分化的潘氏细胞之间并沿隐窝绒毛轴分化成不同的上皮细胞。一旦肠道干细胞受到损伤,潘氏细胞将通过提供WNT配体和Notch刺激来补充肠道干细胞。因此,潘氏细胞充当辅助细胞以维持干细胞微环境,即生态位。该综述探讨了干细胞和潘氏细胞之间的相互作用,进一步探讨了维持肠道稳态的信号通路。     

肠道哈夫尼菌促进黑腹果蝇的发育

目的分离和鉴定黑腹果蝇肠道共生微生物,并研究其促进果蝇身体发育的功能。方法利用Hungate滚管技术,分离厌氧细菌;运用定植实验证明其为果蝇肠道共生菌;用悉菌实验来检测细菌对果蝇发育的影响。结果本研究从野外捕获的果蝇体内分离到蜂房哈夫尼菌(Hafnia alvei),而且证实它能够在果蝇肠道内有效地定植并且能在培养基中稳定持续地存在,说明蜂房哈夫尼菌是果蝇肠道共生菌。此外,蜂房哈夫尼菌能显著地缩短无菌果蝇的发育周期及提高生长速率。结论证明了蜂房哈夫尼菌是果蝇肠道的共生菌,并且其可以有效地促进果蝇的生长发育。     

食物营养对黑腹果蝇中肠干细胞的影响

【目的】研究市场上常见的几种儿童、青少年较为喜爱的小食品的主要营养成分,及其对黑腹果蝇Drosophila melanogaster的体重、发育等的影响,进而探讨膳食中营养均衡的重要性。【方法】采用双缩脲法、苏丹Ⅲ染色法及碘酒染色法分别对食物中的蛋白质、脂肪及淀粉含量进行测定。分别用基础培养基或实验用食品配制的培养基培养黑腹果蝇,待果蝇卵孵化后,取一定数量果蝇个体进行称重,并对果蝇中肠进行解剖和免疫荧光染色,观察果蝇肠道发育情况。【结果】基础食物(培养基)中的蛋白质、脂肪及淀粉含量配比较为均衡,而实验用零食有些脂肪含量较高,有些蛋白质含量较高,有些淀粉含量较高,配比严重失衡。淀粉及脂肪含量均较高的食物能引起果蝇体重超重;同时果蝇肠道细胞Arm/Pros的染色显著增加,显示肠道干细胞数目显著增加,另外果蝇肠壁明显加厚;而食物中淀粉或蛋白质严重缺失的食物则引起果蝇发育障碍。其中,在高碳水化合物但几乎没有蛋白质存在的食物中,果蝇干细胞数目同样增加很多,肠壁加厚,但其体重显著降低,同时发育迟缓。在高蛋白高脂肪低碳水化合物的食物中,中肠干细胞数目明显减少,果蝇肠壁变薄,发育受到影响。将几种实验组食物按照基础食物的蛋白质、脂肪及淀粉含量进行配比混合,模拟营养的均衡配比,喂养果蝇后发现,营养成分配比均衡极大地缓解配比失衡后所造成的中肠损伤,并使果蝇的个体发育恢复均衡。【结论】食物中的营养失衡会显著影响果蝇的体重以及肠壁和肠道干细胞的数目,导致果蝇体重下降或上升,肠道细胞增殖功能紊乱,对果蝇发育产生严重影响。这些结果提示了儿童偏好零食引起的营养不良和过度肥胖及肠道功能障碍,因此建议青少年儿童不能偏好零食,要做到合理膳食,营养均衡。     

昆虫肠道微生物稳态的调控机制

稳定的肠道微生物内环境是肠道微生物与肠道免疫反应相互作用的结果。在不断的进食过程中,昆虫肠道微生物种类和数量不断发生变化,肠道微生物与肠道上皮细胞之间形成了复杂的、动态的平衡机制。昆虫肠道上皮细胞可以感知有益和有害条件并利用免疫调控通路来实现微生物种群稳态的动态调节,例如双重氧化酶-活性氧(dual oxidase-reactive oxygen species, Duox-ROS)系统和免疫缺陷(immunodeficiency, Imd)信号通路可以感知肠道微生物数量变化并参与到肠道微生物稳态调节过程。除此之外,肠道微生物群也会通过群体感应(quorum sensing, QS)释放相应的效应因子来调节菌群行为,间接性起到稳态调节的作用。因此,本文综述了昆虫肠道中物理防御、免疫信号通路以及肠道微生物通过QS在昆虫肠道微生物稳态维持中的作用,加深对肠道组织与肠道微生物互作关系的认识。未来将继续对更多种类昆虫体内微生物的稳态调控机制及调控机制间的作用关系进行研究,并基于调控机制设计开发改变肠道微生物稳态的新型农药,为实现有效害虫防治提供新的靶标和思路。     

益生菌抑制肠道慢性炎症及维持肠道稳态的研究进展

益生菌在维护健康和预防疾病方面起着重要作用。近30年来,人们对益生菌的特性、分类、分布与营养等方面的研究很多,特别是益生菌抑制肠道慢性炎症及维持肠道稳态方面的作用引起了国内外学者的广泛关注。近几年来,随着分子生物学技术的迅速发展,关于益生菌抑制肠道慢性炎症及维持肠道稳态方面的作用机制成为当前研究的热点,并取得了一定的成果。本文目的在于对益生菌抑制肠道慢性炎症及维持肠道稳态的作用进行分析。     

RagA和Nprl2在果蝇肠道发育中的调节作用关系

动物胃肠道是食物消化和营养吸收器官,对机体健康至关重要。果蝇与哺乳动物的肠道在细胞组成、遗传调控等方面高度相似,是研究肠道发育的良好模型。体外培养细胞中的研究发现,Nprl2通过作用于Rag GTPase,抑制雷帕霉素靶点复合物1(target of rapamycin complex 1,TORC1)的活性,参与细胞代谢的调节。前期报道nprl2突变果蝇具有前胃增大、消化能力降低等肠道衰老相关表型。但对于Nprl2是否通过Rag GTPase调控肠道发育等方面尚不清楚。为了探究Rag GTPase在Nprl2调控果蝇肠道发育中的作用,本研究利用遗传杂交结合免疫荧光等方法对RagA敲减和nprl2突变果蝇的肠道形态、肠道细胞组成等方面进行研究。发现单独敲减RagA可以引起肠变粗、前胃增大等表型,敲减RagA能挽救nprl2突变体中肠道变细、分泌型细胞减少的表型,但并不能挽救nprl2突变体中前胃增大的表型。以上结果表明,RagA在肠道发育中发挥重要作用,Nprl2通过作用于Rag GTPase调节肠道细胞分化和肠道形态,但Nprl2对前胃发育和肠道的消化功能的调节可能通过不依赖于Rag GTPase的机制实现。     

Intestinal stem cells in the adult Drosophila midgut

Drosophila has long been an excellent model organism for studying stem cell biology. Notably, studies of Drosophila's germline stem cells have been instrumental in developing the stem cell niche concept. The recent discovery of somatic stem cells in adult Drosophila, particularly the intestinal stem cells (ISCs) of the midgut, has established Drosophila as an exciting model to study stem cell-mediated adult tissue homeostasis and regeneration. Here, we review the major signaling pathways that regulate the self-renewal, proliferation and differentiation of Drosophila ISCs, discussing how this regulation maintains midgut homeostasis and mediates regeneration of the intestinal epithelium after injury.     

Characterization of midgut stem cell‐ and enteroblast‐specific Gal4 lines in drosophila

The homeostasis of Drosophila midgut is maintained by multipotent intestinal stem cells (ISCs), each of which gives rise to a new ISC and an immature daughter cell, enteroblast (EB), after one asymmetric cell division. In Drosophila, the Gal4‐UAS system is widely used to manipulate gene expression in a tissue‐ or cell‐specific manner, but in Drosophila midgut, there are no ISC‐ or EB‐specific Gal4 lines available. Here we report the generation and characterization of Dl‐Gal4 and Su(H)GBE‐Gal4 lines, which are expressed specifically in the ISCs and EBs separately. Additionally, we demonstrate that Dl‐Gal4 and Su(H)GBE‐Gal4 are expressed in adult midgut progenitors (AMPs) and niche peripheral cells (PCs) separately in larval midgut. These two Gal4 lines will serve as invaluable tools for navigating ISC behaviors. genesis 48:607–611, 2010. Published 2010 Wiley‐Liss, Inc.     

rgn gene is required for gut cell homeostasis after ingestion of sodium dodecyl sulfate in Drosophila

Resistance and resilience constitute the two complementary aspects of epithelial host defenses in Drosophila. Epithelial cell homeostasis is necessary for the recovery of damages caused by stress or infections. However, the genes responsible for gut epithelial homeostasis remain poorly understood. Here, we show that rgn^G4035 mutant flies have higher mortality than wild-type flies after ingestion of sodium dodecyl sulfate (SDS). Excessive melanization and increased necrotic cells in the gut contribute to the reduced survival of rgn^G4035 mutant flies following SDS ingestion. rgn mutant flies have a defect in the replenishment of intestinal stem cells (ISCs) following gut damage. The antimicrobial peptide (AMP) expression is affected in rgn^G4035 mutant fly guts. Together, our study provides evidence that rgn gene is essential for gut cell homeostasis following damage in Drosophila.     

PERK Limits Drosophila Lifespan by Promoting Intestinal Stem Cell Proliferation in Response to ER Stress

Intestinal homeostasis requires precise control of intestinal stem cell (ISC) proliferation. In Drosophila, this control declines with age largely due to chronic activation of stress signaling and associated chronic inflammatory conditions. An important contributor to this condition is the age-associated increase in endoplasmic reticulum (ER) stress. Here we show that the PKR-like ER kinase (PERK) integrates both cell-autonomous and non-autonomous ER stress stimuli to induce ISC proliferation. In addition to responding to cell-intrinsic ER stress, PERK is also specifically activated in ISCs by JAK/Stat signaling in response to ER stress in neighboring cells. The activation of PERK is required for homeostatic regeneration, as well as for acute regenerative responses, yet the chronic engagement of this response becomes deleterious in aging flies. Accordingly, knocking down PERK in ISCs is sufficient to promote intestinal homeostasis and extend lifespan. Our studies highlight the significance of the PERK branch of the unfolded protein response of the ER (UPR^ER) in intestinal homeostasis and provide a viable strategy to improve organismal health- and lifespan.     

Mathematical modelling and experiments for the proliferation and differentiation of Drosophila intestinal stem cells II

The Drosophila posterior midgut epithelium mainly consists of intestinal stem cells (ISCs); semi-differentiated cells, i.e. enteroblasts (EBs); and two types of fully differentiated cells, i.e. enteroendocrine cells (EEs) and enterocytes (ECs), which are controlled by signalling pathways. In [M. Kuwamura, K. Maeda, and T. Adachi-Yamada, Mathematical modeling and experiments for the proliferation and differentiation of Drosophila intestinal stem cells I, J. Biol. Dyn. 4 (2009), pp. 248–257], on the basis of the functions of the Wnt and Notch signalling pathways, we studied the regulatory mechanism for the proliferation and differentiation of ISCs under the assumption that the Wnt proteins are supplied from outside the cellular system of ISCs. In this paper, we experimentally show that the Wnt proteins are specifically expressed in ISCs, EBs, and EEs, and theoretically show that the cellular system of ISCs can be self-maintained under the assumption that the Wnt proteins are produced in the cellular system of ISCs. These results provide a useful basis for determining whether an environmental niche is required for maintaining the cellular system of tissue stem cells.     

Robust intestinal homeostasis relies on cellular plasticity in enteroblasts mediated by miR‐8–Escargot switch

The intestinal epithelium is remarkably robust despite perturbations and demand uncertainty. Here, we investigate the basis of such robustness using novel tracing methods that allow simultaneously capturing the dynamics of stem and committed progenitor cells (called enteroblasts) and intestinal cell turnover with spatiotemporal resolution. We found that intestinal stem cells (ISCs) divide “ahead” of demand during Drosophila midgut homeostasis. Their newborn enteroblasts, on the other hand, take on a highly polarized shape, acquire invasive properties and motility. They extend long membrane protrusions that make cell–cell contact with mature cells, while exercising a capacity to delay their final differentiation until a local demand materializes. This cellular plasticity is mechanistically linked to the epithelial–mesenchymal transition (EMT) programme mediated by escargot, a snail family gene. Activation of the conserved microRNA miR‐8/miR‐200 in “pausing” enteroblasts in response to a local cell loss promotes timely terminal differentiation via a reverse MET by antagonizing escargot. Our findings unveil that robust intestinal renewal relies on hitherto unrecognized plasticity in enteroblasts and reveal their active role in sensing and/or responding to local demand.