意大利蜜蜂工蜂脂肪体胚后发育过程中细胞的增殖和凋亡

脂肪体是昆虫体内物质贮备和中间代谢的重要组织。本研究通过显微形态观察、 BrdU免疫组织化学和原位末端转移酶标记(TUNEL)细胞凋亡检测技术, 对意大利蜜蜂Apis mellifera ligustica工蜂脂肪体胚后发育过程中细胞的增殖和凋亡特点进行了比较研究。结果表明： 意大利蜜蜂工蜂脂肪体细胞数量的快速增加集中在幼虫发育前期（1-3龄）, 而细胞的凋亡则集中在蛹发育早期的2-3 d（预蛹-2日龄蛹）时间之内。在变态发育中, 工蜂幼虫脂肪体凋亡降解后重新组建形成成虫的脂肪体。本研究为昆虫脂肪体的功能研究以及昆虫组织细胞自噬和凋亡的机制研究提供一定的证据。     

基于免疫组织化学方法的中华蜜蜂蕈形体胚后发育过程中细胞增殖和凋亡的观察

蕈形体是昆虫学习和其他复杂行为的整合中心。本研究通过形态解剖、BrdU免疫组织化学和原位末端转移酶标记(TUNEL)细胞凋亡检测等技术, 对中华蜜蜂Apis cerana cerana蕈形体胚后发育过程中细胞的增殖和凋亡模式进行了比较研究。结果表明： 中华蜜蜂的蕈形体起源自幼虫早期脑背侧的几个大型的成神经细胞, 它们通过不对称的细胞分裂产生成神经细胞, 随后这些细胞经过多次对称分裂形成中增殖细胞群和侧增殖细胞群, 最终生成了所有的Kenyon细胞。蕈形体的蕈体柄出现在3龄幼虫; 蕈体冠体积的迅速增加发生在蛹期。蕈形体发育过程中, 细胞凋亡主要集中在蛹发育期的3-6 d内, 细胞凋亡的开始和细胞增殖的终止在时间和空间上非常一致。本研究为蜜蜂学习记忆等行为学研究提供了理论依据。     

中华蜜蜂视觉系统中神经胶质的组成和胚后发育

神经胶质作为视觉系统的重要成分之一, 对视觉系统的发育及功能起着重要的作用。本研究通过组织解剖观察、 免疫组织化学等技术, 对中华蜜蜂Apis cerana cerana幼虫和蛹的视觉系统中神经胶质的类型和发育过程进行了比较研究。研究表明： 在中华蜜蜂视觉系统中, 根据神经胶质的位置和形态主要分为表面神经胶质、 皮层神经胶质和神经纤维网神经胶质3种类型; 神经胶质主要来源于视柄和视叶中的神经胶质前体中心; 神经胶质细胞数量的增加一方面来自于细胞的迁移, 另一方面来自于神经胶质细胞自身的分裂增殖。本研究为昆虫神经胶质的发育以及功能研究提供理论基础。     

Organization and postembryonic development of glial cells in the visual system of the Chinese honeybee, Apis cerana cerana (Hymenoptera:Apidae )

神经胶质作为视觉系统的重要成分之一,对视觉系统的发育及功能起着重要的作用.本研究通过组织解剖观察、免疫组织化学等技术,对中华蜜蜂Apis cerana cerana幼虫和蛹的视觉系统中神经胶质的类型和发育过程进行了比较研究.研究表明:在中华蜜蜂视觉系统中,根据神经胶质的位置和形态主要分为表面神经胶质、皮层神经胶质和神经纤维网神经胶质3种类型;神经胶质主要来源于视柄和视叶中的神经胶质前体中心;神经胶质细胞数量的增加一方面来自于细胞的迁移,另一方面来自于神经胶质细胞自身的分裂增殖.本研究为昆虫神经胶质的发育以及功能研究提供理论基础.     

中华蜜蜂工蜂视叶胚后发育过程中的细胞凋亡

本研究通过形态解剖和原位末端标记法(TUNEL),对中华蜜蜂Apis cerana cerana视叶胚后发育过程中的细胞凋亡进行了研究,结果表明:视叶内的细胞程序性死亡开始出现在1龄幼虫末期,随后凋亡细胞数量逐渐增加;在视叶的胚后发育过程中,细胞凋亡经历了3个高峰期,即2龄幼虫、5龄幼虫和蛹发育的第2天;在视叶3个部分的发育中,视髓层中细胞凋亡的数量远远多于视小叶和视神经节层,而视神经节层最少,说明了细胞凋亡的数量和位置与各部分结构发育的时间以及神经投射有关。广泛的细胞凋亡是蜜蜂视叶发育过程中的一个显著特征。     

中华蜜蜂工蜂咽下腺胚后发育过程中细胞的增殖和凋亡

【目的】咽下腺(hypopharyngeal gland)是蜜蜂重要的外分泌腺,是工蜂合成和分泌蜂王浆的主要腺体。本研究的目的在于了解中华蜜蜂Apis cerana cerana工蜂咽下腺的胚后发育特点。【方法】通过组织形态学、Brd U免疫组织化学和TUNEL细胞凋亡检测等技术,对中华蜜蜂工蜂咽下腺的胚后发育过程及组织结构特点进行了比较研究。【结果】中华蜜蜂工蜂的咽下腺起源自预蛹阶段口器内壁的陷入,细胞分裂活动的高峰期集中在蛹发育的前3 d,随后分裂细胞数减少,并一直持续到蛹发育的第7天左右结束;分泌腺泡的出现大约在蛹发育的第5天。到蛹发育的末期,咽下腺已基本形成,但是没有发育完全;哺育蜂的咽下腺高度发育,分泌活动旺盛;采集蜂的咽下腺中有许多分泌细胞凋亡。【结论】本研究揭示了中蜂工蜂咽下腺胚后发育过程中细胞增殖和凋亡的模式,为昆虫咽下腺的发育和功能研究提供了一定的理论依据。     

中华蜜蜂工蜂嗅叶的胚后发育

通过形态解剖、免疫组织化学、原位细胞凋亡检测技术,对中华蜜蜂工蜂嗅叶的胚后发育过程进行了系统的比较研究.结果表明:(1)中华蜜蜂工蜂的嗅叶由神经纤维网区和外围的中脑神经细胞体层组成,在幼虫早期,神经纤维网的腹外侧和背外侧区内有几个大型的成神经细胞,呈现出典型的不对称分裂模式;在随后的发育过程中,神经纤维网的体积逐渐增加,神经细胞逐渐分散,细胞层变薄;分裂细胞主要集中在背外侧细胞区;在3龄幼虫期 ,触角嗅觉神经元的传入纤维开始进入嗅叶;在蛹发育的第3天,神经纤维网内的神经纤维球开始出现;(2)嗅叶发育过程中的细胞凋亡发生较少,增殖细胞和凋亡细胞数量的相对比率基本恒定;细胞凋亡的高峰期出现在幼虫末期;蛹发育的第4天左右,凋亡细胞完全消失 ;(3)中华蜜蜂的嗅叶存在雌雄异形现象[动物学报 54(3):546-554,2008].     

中华蜜蜂中央复合体的结构及胚后发育

中央复合体是昆虫脑中一个非常特殊的结构,与昆虫的视觉认知学习等许多复杂的行为有关。本研究通过形态解剖、免疫组织化学等技术,对中华蜜蜂中央复合体的组织结构以及胚后发育过程进行了比较研究。结果表明,中华蜜蜂的中央复合体包括前脑桥、中心体和2个球形的小结;中央复合体的发育从1龄幼虫开始,中心体上区的发育在末龄幼虫基本完成,前脑桥和中心体下区的发育集中在蛹发育早期;中央复合体中神经胶质数量的快速增加集中在预蛹期。本研究为昆虫中央复合体的发育以及功能研究提供理论基础。     

不同月龄大鼠空肠粘膜上皮细胞的形态、增殖及凋亡

为研究雄性大鼠空肠在发生、发育和衰老过程中上皮细胞增殖与凋亡形态学的变化,本实验采用增殖细胞核抗原(PCNA)免疫细胞化学染色、原位末端标记(TUNEL)法检测了不同生长发育阶段SD大鼠空肠绒毛粘膜上皮及小肠腺上皮的细胞增殖、凋亡的变化情况,并统计测量了不同发育阶段大鼠空肠绒毛的高度、肌层厚度及绒毛杯形细胞、肠腺杯形细胞的数量变化。观察到大鼠空肠肠腺隐窝增殖细胞的阳性着色表达从出生后开始增强,到3月龄时达最高峰,12月龄时增殖细胞阳性染色又减弱;凋亡细胞主要分布于固有层,凋亡阳性细胞数在3月龄最多;大鼠空肠绒毛的高度从初生后开始增加,到3月龄达顶峰,而后开始变矮;空肠肌层在3周龄、12月龄较厚;杯形细胞数量于生后3周迅速增长,不同发育阶段的大鼠空肠肠腺隐窝的杯形细胞数量与年龄呈正相关。     

意大利蜜蜂工蜂中肠的环状RNA及其调控网络分析

【目的】环状RNA(circRNA)在可变剪接、转录调控和来源基因的表达调控等方面具有重要功能。本研究旨在分析意大利蜜蜂Apis mellifera ligustica工蜂中肠circRNA的数量、种类、结构特征和作用,并通过构建和分析circRNA的调控网络探索circRNA的调控功能。【方法】在实验室条件下人工饲养意大利蜜蜂工蜂,利用circRNA-seq技术对意大利蜜蜂7和10日龄成年工蜂中肠样品进行深度测序。利用find_circ软件从质控后的数据中预测circRNA。通过BLAST比对GO和KEGG数据库,对circRNA的来源基因进行功能和代谢通路注释。利用TargetFinder软件预测circRNA靶向结合的miRNA及miRNA靶向结合的mRNA,通过Cytoscape v.3.2.1软件对circRNA-miRNA和circRNA-miRNA-mRNA调控网络进行构建及可视化。通过设计背靠背引物和线性扩增引物RT-PCR对预测出的circRNA进行验证。【结果】意大利蜜蜂工蜂中肠样品的测序平均得到136 463 071条clean reads,去除rRNA后各样品的anchor reads均在136 779 122条及以上。共预测出10 833个circRNA,长度主要介于15~1 000 nt;上述circRNA的类型丰富,其中已注释的外显子circRNA数量最多,分布在西方蜜蜂1号染色体的circRNA数量最多,其次为8号染色体。CircRNA的来源基因可注释到包括结合、细胞进程和细胞在内的45个GO条目,以及包括内吞作用、内质网蛋白加工及核糖体在内的121条KEGG代谢通路,表明circRNA在意大利蜜蜂工蜂中肠的生长、发育、新陈代谢和细胞生命活动等生物学过程中发挥重要作用。进一步构建circRNA-miRNA和circRNA-miRNA-mRNA调控网络,分析结果显示部分circRNA可能作为竞争性内源RNA吸附结合microRNA,从而调控基因的表达水平。最后,对随机选择的3个circRNA的RT-PCR结果验证了其真实存在。【结论】本研究对意大利蜜蜂工蜂中肠中的circRNA进行预测、分析及鉴定。研究结果提供了中肠circRNA的数量、种类、结构特征、作用和调控网络的信息,揭示了circRNA可能通过作用于来源基因和作为竞争性内源RNA在意大利蜜蜂工蜂中肠的生长发育和免疫防御中发挥作用,为深入研究circRNA在意大利蜜蜂中肠发育及胁迫响应过程中的功能奠定了基础。     

Degeneration and cell regeneration in the midgut of Podisus nigrispinus (Heteroptera: Pentatomidae) during post-embryonic development

Cell death, proliferation, and differentiation in some developmental stages of insects have been studied in the midgut of ametabolous, which undergo only continuous growth, and holometabolous, which undergo complete metamorphosis. However, in hemimetabolous insects, evolutionarily intermediate between ametabolous and holometabolous, midgut reorganization during the post-embryonic development has been poorly studied. The present study evaluates the post-embryonic development of the midgut of a hemimetabolous insect, Podisus nigrispinus, to test the hypothesis that these insects have programmed cell death and proliferation followed by differentiation of regenerative cells during midgut growth from nymphs to adult. The morphometrical data showed a 6-fold increase in midgut length from the first instar nymph to the adult, which did not result from an increase in the size of the midgut cells, suggesting that the growth of the midgut occurs by an increase in cell number. Cell death was rarely found in the midgut, whereas proliferation of regenerative cells occurred quite frequently. The growth of the midgut of P. nigrispinus appears to result from the proliferation of regenerative cells present in the epithelium; unlike ametabolous and holometabolous insects, the midgut of P. nigrispinus does not undergo extensive remodeling, as shown by the low frequency of digestive cell death.     

The ultrastructure of the midgut epithelium in millipedes (Myriapoda,Diplopoda)

The midgut epithelia of the millipedes Polyxenus lagurus, Archispirostreptus gigas and Julus scandinavius were analyzed under light and transmission electron microscopies. In order to detect the proliferation of regenerative cells, labeling with BrdU and antibodies against phosphohistone H3 were employed. A tube-shaped midgut of three millipedes examined spreads along the entire length of the middle region of the body. The epithelium is composed of digestive, secretory and regenerative cells. The digestive cells are responsible for the accumulation of metals and the reserve material as well as the synthesis of substances, which are then secreted into the midgut lumen. The secretions are of three types – merocrine, apocrine and microapocrine. The oval or pear-like shaped secretory cells do not come into contact with the midgut lumen and represent the closed type of secretory cells. They possess many electron-dense granules (J. scandinavius) or electron-dense granules and electron-lucent vesicles (A. gigas, P. lagurus), which are accompanied by cisterns of the rough endoplasmic reticulum. The regenerative cells are distributed individually among the basal regions of the digestive cells. The proliferation and differentiation of regenerative cells into the digestive cells occurred in J. scandinavius and A. gigas, while these processes were not observed in P. lagurus. As a result of the mitotic division of regenerative cells, one of the newly formed cells fulfills the role of a regenerative cell, while the second one differentiates into a digestive cell. We concluded that regenerative cells play the role of unipotent midgut stem cells.     

Comparative midgut ultrastructure of unfed larvae and adult mites of Platytrombidium fasciatum (C.L. Koch, 1836) and Camerotrombidium pexatum (C.L. Koch, 1837) (Acariformes: Microtrombidiidae)

The midgut of unfed larvae and adult mites of Platytrombidium fasciatum (C.L. Koch, 1836) and Camerotrombidium pexatum (C.L. Koch, 1937) (Acariformes: Microtrombidiidae) was investigated by electron microscopy. The sac-like midgut occupies the entire body volume, ends blindly and is not divided into functionally differentiated diverticula or caeca. The midgut walls are composed of one type of digestive cell that greatly varies in shape and size. In larvae, the lumen of the midgut is poorly recognizable and its epithelium is loosely organized, although yolk granules are already utilized. In adults, the midgut forms compartments as a result of deep folds of the midgut walls, and the lumen is well distinguished. The epithelium is composed of flat, prismatic or club-like cells, which may contain nutritional vacuoles and residual bodies in various proportions that depend on digestive stages. In both larvae and adult mites, parts of cells may detach from the epithelium and float within the lumen. The cells contain a system of tubules and vesicles of a trans-Golgi network, whereas the apical surface forms microvilli as well as pinocytotic pits and vesicles. Lysosome-like bodies, lipid inclusions and some amount of glycogen particles are also present in the digestive cells. Spherites (concretions) are not found to be a constant component of the digestive cells and in adult mites occur for the most parts in the midgut lumen.     

Peritrophic membrane role in enhancing digestive efficiency. Theoretical and experimental models

The peritrophic membrane (PM) is an anatomical structure surrounding the food bolus in most insects. Rejecting the idea that PM has evolved from coating mucus to play the same protective role as it, novel functions were proposed and experimentally tested. The theoretical principles underlying the digestive enzyme recycling mechanism were described and used to develop an algorithm to calculate enzyme distributions along the midgut and to infer secretory and absorptive sites. The activity of a Spodoptera frugiperda microvillar aminopeptidase decreases by 50% if placed in the presence of midgut contents. S. frugiperda trypsin preparations placed into dialysis bags in stirred and unstirred media have activities of 210 and 160%, respectively, over the activities of samples in a test tube. The ectoperitrophic fluid (EF) present in the midgut caeca of Rhynchosciara americana may be collected. If the enzymes restricted to this fluid are assayed in the presence of PM contents (PMC) their activities decrease by at least 58%. The lack of PM caused by calcofluor feeding impairs growth due to an increase in the metabolic cost associated with the conversion of food into body mass. This probably results from an increase in digestive enzyme excretion and useless homeostatic attempt to reestablish destroyed midgut gradients. The experimental models support the view that PM enhances digestive efficiency by: (a) prevention of non-specific binding of undigested material onto cell surface; (b) prevention of excretion by allowing enzyme recycling powered by an ectoperitrophic counterflux of fluid; (c) removal from inside PM of the oligomeric molecules that may inhibit the enzymes involved in initial digestion; (d) restriction of oligomer hydrolases to ectoperitrophic space (ECS) to avoid probable partial inhibition by non-dispersed undigested food. Finally, PM functions are discussed regarding insects feeding on any diet.     

Digestive morphophysiology of Gryllodes sigillatus (Orthoptera: Gryllidae)

The evolution of the digestive system in the Order Orthoptera is disclosed from the study of the morphophysiology of the digestive process in its major taxa. This paper deals with a cricket representing the less known suborder Ensifera. Most amylase and trypsin activities occur in crop and caeca, respectively. Maltase and aminopeptidase are found in soluble and membrane-bound forms in caeca, with aminopeptidase also occurring in ventriculus. Amaranth was orally fed to Gryllodes sigillatus adults or injected into their haemolymph. The experiments were performed with starving and feeding insects with identical results. Following feeding of the dye the luminal side of the most anterior ventriculus (and in lesser amounts the midgut caeca) became heavily stained. In injected insects, the haemal side of the most posterior ventriculus was stained. This suggested that the anterior ventriculus is the main site of water absorption (the caeca is a secondary one), whereas the posterior ventriculus secretes water into the gut. Thus, a putative counter-current flux of fluid from posterior to anterior ventriculus may propel digestive enzyme recycling. This was confirmed by the finding that digestive enzymes are excreted at a low rate. The fine structure of midgut caeca and ventriculus cells revealed that they have morphological features that may be related to their involvement in secretion (movement from cell to lumen) and absorption (movement from lumen to cell) of fluids. Furthermore, morphological data showed that both merocrine and apocrine secretory mechanisms occur in midgut cells. The results showed that cricket digestion differs from that in grasshopper in having: (1) more membrane-bound digestive enzymes; (2) protein digestion slightly displaced toward the ventriculus; (3) midgut fluxes, and hence digestive enzyme recycling, in both starved and fed insects.     

Monitoring stem cell proliferation and differentiation in primary midgut cell cultures from Heliothis virescens larvae using flow cytometry

In the midgut of Heliothis virescens larvae, proliferation and differentiation of stem cell populations allow for midgut growth and regeneration. Basic epithelial regenerative function can be assessed in vitro by purifying these two cell type populations, yet efficient high throughput methods to monitor midgut stem cell proliferation and differentiation are not available. We describe a flow cytometry method to differentiate stem from mature midgut cells and use it to monitor proliferation, differentiation and death in primary midgut stem cell cultures from H. virescens larvae. Our method is based on differential light scattering and vital stain fluorescence properties to distinguish between stem and mature midgut cells. Using this method, we monitored proliferation and differentiation of H. virescens midgut cells cultured in the presence of fetal bovine serum (FBS) or AlbuMAX II. Supplementation with FBS resulted in increased stem cell differentiation after 5 days of culture, while AlbuMAX II-supplemented medium promoted stem cell proliferation. These data demonstrate utility of our flow cytometry method for studying stem cell-based epithelial regeneration, and indicate that AlbuMAX II-supplemented medium may be used to maintain pluripotency in primary midgut stem cell cultures.     

Intestinal stem cell function in Drosophila and mice

Epithelial cells of the digestive tracts of most animals are short-lived, and are constantly replenished by the progeny of long-lived, resident intestinal stem cells. Proper regulation of intestinal stem cell maintenance, proliferation and differentiation is critical for maintaining gut homeostasis. Here we review recent genetic studies of stem cell-mediated homeostatic growth in the Drosophila midgut and the mouse small intestine, highlighting similarities and differences in the mechanisms that control stem cell proliferation and differentiation.     

Digestive enzymes associated with the glycocalyx,microvillar membranes and secretory vesicles from midgut cells of Tenebrio molitor larvae

Acetylglucosaminidase, amylase, cellobiase and maltase are more active in anterior midgut cells, whereas aminopeptidase, carboxypeptidase and trypsin are more active in posterior midgut cells of Tenebrio molitor larvae. Differential centrifugation of midgut homogenates prepared in saline (or mannitol) isotonic buffered solutions revealed that aminopeptidase is associated with membranes, which occur in subcellular fractions displaying many microvilli. Carboxypeptidase, trypsin and the carbohydrases are mostly found in the soluble fraction, although significant amounts sediment together with cell vesicles. Data on differential calcium precipitation of midgut homogenates and on partial ultrasound disruption of midgut tissue suggest that aminopeptidase is a microvillar enzyme and that the digestive enzymes recovered in the soluble fraction of cells are loosely bound to the cell glycocalyx. About 5% of the non-absorbable dye amaranth fed to T. molitor larvae remains in the midgut tissue after rinsing. Most dye was recovered in the soluble fraction of midgut cells. This provided further support for the hypothesis that the digestive enzymes found in the soluble fraction are actually extracellular and that the true intracellular enzymes are those associated with cell vesicles. The results suggest that the carbohydrases are secreted by exocytosis from the anterior midgut and carboxypeptidase and trypsin from the posterior midgut.     

Ultrastructure and regeneration of midgut epithelial cells in Lithobius forficatus (Chilopoda,Lithobiidae)

Lithobius forficatus (Myriapoda, Chilopoda, Lithobiidae) is a widespread species of centipede that is common across Europe. Its midgut epithelial cells are an important line of defense against toxic substances that originate in food, such as pathogens and metals. Despite this important role, the biology of the midgut epithelium is not well known. Here we describe the ultrastructure of the midgut epithelium, as well as the replacement of degenerated midgut epithelial cells. The midgut epithelium of L. forficatus is composed of digestive, secretory, and regenerative cells. The cytoplasm of digestive cells shows regionalization in organelle distribution, which is consistent with the role of these cells in secretion of enzymes, absorption of nutrients, and accumulation of lipids and glycogen. Secretory cells, which do not reach the luminal surface of the midgut epithelium, possess numerous electron‐dense and electron‐lucent granules and may have an endocrine function. Hemidesmosomes anchor secretory cells to the basal lamina. Regenerative cells play the role of midgut stem cells, as they are able to proliferate and differentiate. Their proliferation occurs in a continuous manner, and their progeny differentiate only into digestive cells. The regeneration of secretory cells was not observed. Mitotic divisions of regenerative cells were confirmed using immunolabeling against BrdU and phosphohistone H3. Hemocytes associate with the midgut epithelium, accumulating between the visceral muscles and beneath the basal lamina of the midgut epithelium. Hemocytes also occur among the digestive cells of the midgut epithelium in animals infected with Rickettsia‐like microorganisms. These hemocytes presumably have an immunoprotective function in the midgut.     

Injury-induced BMP signaling negatively regulates Drosophila midgut homeostasis

Although much is known about injury-induced signals that increase rates of Drosophila melanogaster midgut intestinal stem cell (ISC) proliferation, it is largely unknown how ISC activity returns to quiescence after injury. In this paper, we show that the bone morphogenetic protein (BMP) signaling pathway has dual functions during midgut homeostasis. Constitutive BMP signaling pathway activation in the middle midgut mediated regional specification by promoting copper cell differentiation. In the anterior and posterior midgut, injury-induced BMP signaling acted autonomously in ISCs to limit proliferation and stem cell number after injury. Loss of BMP signaling pathway members in the midgut epithelium or loss of the BMP signaling ligand decapentaplegic from visceral muscle resulted in phenotypes similar to those described for juvenile polyposis syndrome, a human intestinal tumor caused by mutations in BMP signaling pathway components. Our data establish a new link between injury and hyperplasia and may provide insight into how BMP signaling mutations drive formation of human intestinal cancers.