Programmed cell death and heterolysis of larval epithelial cells by macrophage-like cells in the anuran small intestine in vivo and in vitro.

The degenerative processes in the larval small intestine of Xenopus laevis tadpoles during spontaneous metamorphosis and during thyroid hormone-induced metamorphosis in vitro were examined by electron microscopy. Around the beginning of spontaneous metamorphic climax (stages 59-61), both apoptotic bodies derived from larval epithelial cells and intraepithelial macrophage-like cells suddenly increase in number. The macrophage-like cells become rounded and enlarged because of numerous vacuoles containing the apoptotic bodies. Mitotic profiles of the macrophage-like cells, however, are localized in the connective tissue where different developmental stages of macrophage-like cells are present. After stage 62, the intraepithelial macrophage-like cells decrease in number, while large macrophage-like cells which include the apoptotic bodies and retain intact cell membranes and nuclei appear in the lumen. Degenerative changes similar to those during spontaneous metamorphosis described above could be reproduced in vitro. In tissue fragments isolated from the small intestine of stage 57 tadpoles and cultured in the presence of thyroid hormone, the number of intraepithelial macrophage-like cells reaches its maximum around the 3rd day of cultivation when the larval epithelial cells most rapidly decrease in number. These results suggest that the rapid degeneration of larval epithelial cells occurs not only because of apoptosis of the epithelial cells themselves but also from heterolysis by macrophages. The macrophages probably originate in the connective tissue, actively proliferate, migrate into the larval epithelium around the beginning of metamorphic climax, and are finally extruded into the lumen.     

Autophagocytosis in the larval midgut cells of Pieris brassicae during metamorphosis

Summary We observed three types of cells in the epithelial layer of the midgut of last instars of Pieris brassicae. The columnar and goblet cells degenerate during the second part of the last larval stage while the undifferentiated basal cells proliferate during this period and create the epithelium of the pupal midgut. The first morphological sign of involution is the formation of autophagic vacuoles and dense bodies in the cytoplasm of columnar and goblet cells which begins on day 4 of the stage. The number and size of autophagic vacuoles and dense bodies increase during the spinning period (85–96 h). Finally, at the end of the stage, the columnar and goblet cells become displaced by the growing pupal epithelium and reach the lumen where they disintegrate.Autophagocytosis was not seen in the cells during the feeding period (0–72 h). However, we observed many autophagic vacuoles in the columnar and goblet cells of 50-h-old instars 3 h after the administration of 30 g/g body weight of 20-hydroxyecdysone. The hormone treatment elevated by 100% the incorporation of ³H-leucine into the proteins of the midgut. Inhibitors of protein synthesis, cycloheximide and puromycin, in doses that supressed the incorporation of the amino acid by 60–70% either in hormone treated or untreated larvae, exerted diverse effects on the autophagic process. Puromycin did not block the hormone-induced formation of autophagic vacuoles while cycloheximide prevented it. Possible explanations for this diversity are discussed.     

Lepidopteran larval midgut during prepupal instar: digestion or self-digestion?

Programmed cell death (PCD) is crucial in body restructuring during metamorphosis of holometabolous insects (those that have a pupal stage between the final larval and adult stages). Besides apoptosis, an increasing body of evidence indicates that in several insect species programmed autophagy also plays a key role in these developmental processes. We have recently characterized the midgut replacement process in Heliothis virescens larva, during the prepupal phase, responsible for the formation of a new pupal midgut. We found that the elimination of the old larval midgut epithelium is obtained by a combination of apoptotic and autophagic events. In particular, autophagic PCD completely digests decaying tissues, and provides nutrients that are rapidly absorbed by the newly formed epithelium, which is apparently functional at this early stage. The presence of both apoptosis and autophagy in the replacement of midgut cells in Lepidoptera offers the opportunity to investigate the functional peculiarities of these PCD modalities and if they share any molecular mechanism, which may account for possible cross-talk between them.     

Autophagy precedes apoptosis during the remodeling of silkworm larval midgut

Although several features of apoptosis and autophagy have been reported in the larval organs of Lepidoptera during metamorphosis, solid experimental evidence for autophagy is still lacking. Moreover, the role of the two processes and the nature of their relationship are still cryptic. In this study, we perform a cellular, biochemical and molecular analysis of the degeneration process that occurs in the larval midgut of Bombyx mori during larval-adult transformation, with the aim to analyze autophagy and apoptosis in cells that die under physiological conditions. We demonstrate that larval midgut degradation is due to the concerted action of the two mechanisms, which occur at different times and have different functions. Autophagy is activated from the wandering stage and reaches a high level of activity during the spinning and prepupal stages, as demonstrated by specific autophagic markers. Our data show that the process of autophagy can recycle molecules from the degenerating cells and supply nutrients to the animal during the non-feeding period. Apoptosis intervenes later. In fact, although genes encoding caspases are transcribed at the end of the larval period, the activity of these proteases is not appreciable until the second day of spinning and apoptotic features are observable from prepupal phase. The abundance of apoptotic features during the pupal phase, when the majority of the cells die, indicates that apoptosis is actually responsible for cell death and for the disappearance of larval midgut cells.     

Replacement of midgut epithelium in the greater wax moth,Galleria mellonela,during larval-pupal moult

The epithelium of larval midgut of the greater wax moth, Galleria mellonela, was replaced during the larval-pupal moult. The development of this moth was tentatively divided into 11 stages, from the full-grown larva of last instar to the 4-day-old pupa. The midgut at each stage was observed for (1) overall structure, (2) the position of goblet cells, and (3) the appearance of the yellow body. Light microscopy revealed that cell death in the midgut began in a cocoon-spinning larva (stage II), when pigments in the stemmata started to migrate. Before drastic remodeling started to occur, cytoplasmic projections in the goblet cavities were transformed. The larval midgut changed markedly at stage III, when the pigments left the stemmata. The epithelium of the larval midgut dropped as a whole into the lumen, transforming into the yellow body. Simultaneously, a pupal midgut epithelium developed. Electron microscopy of the columnar cells of a stage III larva showed that microvilli and mitochondria looked normal even though the nucleus with condensed heterochromatin resembled an apoptotic nucleus of vertebrate and higher plant cells. Caspase-3-like protease activity was restricted to the larval midgut and increased in parallel with the formation of the yellow body. The results indicate that the replacement of the larval midgut is facilitated by a typical apoptotic process.     

Lepidopteran Larval Midgut During Prepupal Instar: Digestion or Self-Digestion?

Programmed cell death (PCD) is crucial in body restructuring during metamorphosis of holometabolous insects (those that have a pupal stage between the final larval and adult stages). Besides apoptosis, an increasing body of evidence indicates that in several insect species programmed autophagy also plays a key role in these developmental processes. We have recently characterized the midgut replacement process in Heliothis virescens larva, during the prepupal phase, responsible for the formation of a new pupal midgut. We found that the elimination of the old larval midgut epithelium is obtained by a combination of apoptotic and autophagic events. In particular, autophagic PCD completely digests decaying tissues, and provides nutrients that are rapidly absorbed by the newly formed epithelium, which is apparently functional at this early stage. The presence of both apoptosis and autophagy in the replacement of midgut cells in Lepidoptera offers the opportunity to investigate the functional peculiarities of these PCD modalities and if they share any molecular mechanism, which may account for possible cross-talk between them.

Addendum to:

Programmed Cell Death and Stem Cell Differentiation are Responsible for Midgut Replacement in Heliothis virescens During Prepupal Instar

G. Tettamanti, A. Grimaldi, M. Casartelli, E. Ambrosetti, B. Ponti, T. Congiu, R. Ferrarese, M.L. Rivas-Pena, F. Pennacchio and M.D. Eguileor

Cell Tissue Res 2007; In press     

Metamorphosis of midgut epithelial cells in the silkworm (Bombyx Mori L.) with special regard to the calcium salt deposits in the cytoplasm. I. light microscopy

The morphological changes of the metamorphosing midgut cell in the silkworm were traced light-microscopically. The regenerative cells of the larval midgut proliferate rapidly during larval-pupal molt and finally replace the larval midgut, establishing new pupal midgut tissue composed of only one cell type. Pupal midgut cells contain numerous basophilic granules which are believed on histological grounds to be the deposits of calcium salts. Calcium seems to be transported from hemolymph to the pupal midgut cells and stored there temporarily as insoluble salts such as phosphate or carbonate, and then finally discharged into the lumen in a merocrine fashion. The midgut cells of the adult no longer contain calcium deposits.     

Cell death in the midgut epithelium of the worker honey bee (Apis mellifem carnica) during metamorphosis

Summary The types of cell death in the midgut epithelium of the worker honey bee during the larva-to-pupa transformation were analyzed by light and electron microscopes. The metamorphosis begins with an increase in the number of autophagic vacuoles in larval epithelial cells and terminates with lytic destruction of the whole intestinal epithelium. Apoptosis seems to be independent of cell age, but important in fashioning of the new organ. Even in the cells in the regenerative nests of the larval epithelium, from which the pupal epithelium develops, apoptotic death occurs. Single apoptotic cells are eliminated gradually from the primary multilayer tissue until the monolayer pupal epithelium is formed. Some of the apoptotic cells are endocytosed by sister epithelial cells.     

Stem cells from midguts of Lepidopteran larvae: clues to the regulation of stem cell fate

Previously, we showed that isolated stem cells from midguts of Heliothis virescens can be induced to multiply in response to a multiplication protein (MP) isolated from pupal fat body, or to differentiate to larval types of mature midgut cells in response to either of 4 differentiation factors (MDFs) isolated from larval midgut cell-conditioned medium or pupal hemolymph. In this work, we show that the responses to MDF-2 and MP in H. virescens stem cells decayed at different time intervals, implying that the receptors or response cascades for stem cell differentiation and multiplication may be different. However, the processes appeared to be linked, since conditioned medium and MDF-2 prevented the action of MP on stem cells; MP by itself appeared to repress stem cell differentiation. Epidermal growth factor, retinoic acid, and platelet-derived growth factor induced isolated midgut stem cells of H. virescens and Lymantria dispar to multiply and to differentiate to mature midgut cells characteristic of prepupal, pupal, and adult lepidopteran midgut epithelium, and to squamous-like cells and scales not characteristic of midgut tissue instead of the larval types of mature midgut epithelium induced by the MDFs. Midgut stem cells appear to be multipotent and their various differentiated fates can be influenced by several growth factors.     

A novel tissue in an established model system: the <Emphasis Type="Italic">Drosophila</Emphasis> pupal midgut

The Drosophila larval and adult midguts are derived from two populations of endodermal progenitors that separate from each other in the early embryo. As larval midgut cells differentiate into an epithelial layer, adult midgut progenitors (AMPs) remain as small clusters of proliferating, undifferentiated cells attached to the basal surface of the larval gut epithelium. During the first few hours of metamorphosis, AMPs merge into a continuous epithelial tube that overgrows the larval layer and differentiates into the adult midgut; at the same time, the larval midgut degenerates. As shown in this paper, there is a second, transient pupal midgut that develops from the AMPs at the beginning of metamorphosis and that intercalates between the adult and larval midgut epithelia. Cells of the transient pupal midgut form a multilayered tube that exhibits signs of differentiation, in the form of septate junctions and rudimentary apical microvilli. Some cells of the pupal midgut develop as endocrine cells. The pupal midgut remains closely attached to the degenerating larval midgut cells. Along with these cells, pupal midgut cells are sequestered into the lumen where they form the compact “yellow body.” The formation of a pupal midgut has been reported from several other species and may represent a general feature of intestinal metamorphosis in insects.     

Effects of phytohemagglutinin (PHA) on the structure of midgut epithelial cells and localization of its binding sites in western tarnished plant bug, Lygus hesperus Knight

Two histological techniques, bright-field microscopy and immunofluoresecent staining were used to elucidate the lethal effect, target tissues and binding sites of phytohemagglutinin (PHA), a lectin from Phaseolus vulgaris L., on the western tarnished plant bug. Bright-field microscopy showed that the nuclei of the foregut epithelial cells were slightly disrupted and elongated but the lumen of the gut was open. The midgut epithelial cells also showed severe disruption. However, the cells of the first and the third ventriculus were much more sensitive to PHA than those in the second ventriculus. The epithelial cells in these two regions were severely disrupted and swollen toward the lumen, resulting in complete closure of the gut. Most of the cells in these regions contained two nuclei. Also, interestingly, the epithelial cells of the hindgut were drastically disrupted leading to complete closure of the lumen. Immunofluoresecent images from the midgut showed that strong binding occurred on brush-border microvilli of the epithelial cells only within the first and third ventriculi, and some signals within their cytoplasm. Thus, immunofluoresecent studies showed that PHA binds preferentially to the midgut region which demonstrates the most severe effects, and that these cells may endocytose the bound PHA.     

Mechanisms of midgut remodeling: juvenile hormone analog methoprene blocks midgut metamorphosis by modulating ecdysone action

In holometabolous insects such as mosquito, Aedes aegypti, midgut undergoes remodeling during metamorphosis. Insect metamorphosis is regulated by several hormones including juvenile hormone (JH) and 20-hydroxyecdysone (20E). The cellular and molecular events that occur during midgut remodeling were investigated by studying nuclear stained whole mounts and cross-sections of midguts and by monitoring the mRNA levels of genes involved in 20E action in methoprene-treated and untreated Ae. aegypti. We used JH analog, methoprene, to mimic JH action. In Ae. aegypti larvae, the programmed cell death (PCD) of larval midgut cells and the proliferation and differentiation of imaginal cells were initiated at about 36h after ecdysis to the 4th instar larval stage (AEFL) and were completed by 12h after ecdysis to the pupal stage (AEPS). In methoprene-treated larvae, the proliferation and differentiation of imaginal cells was initiated at 36h AEFL, but the PCD was initiated only after ecdysis to the pupal stage. However, the terminal events that occur for completion of PCD during pupal stage were blocked. As a result, the pupae developed from methoprene-treated larvae contained two midgut epithelial layers until they died during the pupal stage. Quantitative PCR analyses showed that methoprene affected midgut remodeling by modulating the expression of ecdysone receptor B, ultraspiracle A, broad complex, E93, ftz-f1, dronc and drice, the genes that are shown to play key roles in 20E action and PCD. Thus, JH analog, methoprene acts on Ae. aegypti by interfering with the expression of genes involved in 20E action resulting in a block in midgut remodeling and death during pupal stage.     

Metamorphosis of midgut epithelial cells in the silkworm (Bombyx mori L.) with special regard to the calcium salt deposits in the cytoplasm. II. Electron microscopy

The mode of formation and fate of calcium salt deposits (calcospherites) appearing in the pupal midgut cells of the silkworm Bombyx mori was followed in the electron microscope. The larval midgut absorbs calcium ions from the haemolymph primarily via the goblet cells, while in the pupal midgut this occurs throughout the entire tissue. Part of the calcium absorbed by the pupal midgut accumulates in small vesicles, probably derived from the Golgi body and these develop into the concentrically laminated calcospherites. Late in the pupal period, these are discharged into the midgut lumen in a merocrine fashion. The midgut in the adult insect retains only a few poorly defined calcospherites in the cytoplasm.     

L-Glutamate retrieved with the moulting fluid is processed by a glutamine synthetase in the pupal midgut of Calpodes ethlius

From apolysis until pupal ecdysis, the pharate pupa of the Brazilian Skipper (Calpodes ethlius) lies wrapped in a prepupal shell composed of the larval cuticle and an ecdysial space (ES) filled with enzyme-rich moulting fluid (MF). In the 4h before ecdysis the pharate pupa drinks the moulting fluid through its mouth and anus, and transfers the cuticular degradation products to its midgut (MG). At the same time, extra fluid passes across the body wall of the pharate pupa and flushes out the ES. The MF is recovered at an overall rate of 70μl/h and reabsorbed across the pharate pupal midgut at about 26μl/h. L-Glutamate was found to be the dominant amino acid in the moulting fluid. Total MF glutamate peaked at 850nmol about 8h before pupal ecdysis (P-8), but by ecdysis it had dropped to nearly zero as the MF became diluted with new fluid and was consumed. The drop in glutamate in the ES coincided with a rise in the glutamine content of the fluid in the midgut lumen. The highest rate of glutamine synthesis occurred in midguts isolated from pharate pupae actively drinking MF (P相似文献   

Degeneration of the midgut epithelium in Allacma fusca L. (Insecta, Collembola, Symphypleona): apoptosis and necrosis

Apoptotic and necrotic changes in the midgut epithelium cells of Allacma fusca (Collembola, Symphypleona) are described at the ultrastructural level. The morphological sign indicating the beginning of the apoptotic process in these cells is their shrinkage and the transformation of their mitochondria. The nucleus assumes a lobular shape and finally undergoes fragmentation. The intercellular junctions between an apoptotic cell and adjacent epithelial cells gradually disappear. Apoptotic cells are discharged into the midgut lumen just beneath the peritrophic membrane, where they are initially distributed singly but ultimately form a single layer. No phagocytosis was observed, so no apoptotic bodies are formed. Only young midgut epithelium shows apoptosis; as cells age, necrosis accompanies apoptosis, and necrosis finally completely replaces apoptosis.     

褐飞虱若虫中肠凋亡细胞的检测

为揭示褐飞虱Niloparvata lugens Stl若虫在发育过程中中肠的凋亡细胞,使用末端脱氧核苷酸转移酶介导的dUTP-生物素断端标记法(TUNEL)进行中肠组织切片检测,结果表明,1～5龄若虫中肠分别存在2%～5%的凋亡细胞。利用4′,6-二脒基-2-苯基吲哚二盐酸(DAPI)染色法检测表明,存在Ⅰ,Ⅱa和Ⅱb期凋亡的细胞核,其特征包括染色体浓缩、边缘化及细胞核碎裂。透射电子显微镜检测结果表明,早期凋亡的细胞呈现染色质浓缩、边缘化特征,晚期凋亡的细胞出现细胞核碎裂、形成凋亡小体及细胞质空泡化等。本研究揭示了在正常发育过程中褐飞虱若虫中肠有少量的细胞发生了凋亡。通过人工干预的方式调控中肠细胞的凋亡进程有可能使之成为防治该水稻害虫的新靶标。     

Molecular characterization of an inhibitor of apoptosis in the Egyptian armyworm, Spodoptera littoralis, and midgut cell death during metamorphosis

The cDNA corresponding to an inhibitor of apoptosis (IAP) from the Egyptian armyworm, Spodoptera littoralis, was cloned by RT-PCR. Sequence analysis showed that the IAP of S. littoralis (SlIAP) contains two baculoviral IAP repeat (BIR) motifs, followed by a RING finger, an organization which is very similar to that of other lepidopteran IAPs. SlIAP mRNA was detected in ovary, testis, salivary gland, fat body, epidermis, brain and midgut of S. littoralis. During the last larval instar, prepupal and pupal stages, brain mRNA levels remained approximately constant, whereas those of midgut showed a large peak centred in the prepupal stage. Midgut morphology changed during metamorphosis from a semi-transparent, cylindrical structure in last instar larvae to a brownish globular mass in pupae. TUNEL assays, LysoTracker staining and caspase-3 immunohistochemistry, indicated that programmed cell death in midgut starts actively at the onset of pupation process, coinciding with the dramatic decrease of SlIAP mRNA levels observed at the same time.     

Epithelial cells remove apoptotic epithelial cells during post-lactation involution of the mouse mammary gland

Following the cessation of lactation, the mammary gland undergoes a physiologic process of tissue remodeling called involution in which glandular structures are lost, leaving an adipose tissue compartment that takes up a much larger proportion of the tissue. A quantitative morphometric analysis was undertaken to determine the mechanisms for clearance of the epithelial cells during this process. The involution process was set in motion by removal of pups from 14-day lactating C57BL/6 mice. Within hours, milk-secreting epithelial cells were shed into the glandular lumen. These cells became apoptotic, exhibiting exposure of phosphatidylserine residues on their surfaces, activation of effector caspase-3, staining for caspase-cleaved keratin 18, loss of internal organellar structure, and nuclear breakdown, but minimal blebbing or generation of apoptotic bodies. Clearance of residual milk and the shed epithelial cells was rapid, with most of the removal occurring in the first 72 h. Intact apoptotic epithelial cells were engulfed in large numbers by residual viable epithelial cells into spacious efferosomes. This process led to essentially complete involution within 4 days, at which point estrous cycling recommenced. Macrophages and other inflammatory cells did not contribute to the clearance of either residual milk or apoptotic cells, which appeared to be due entirely to the epithelium itself.     

蓖麻蚕个体发育中蜕皮甾类滴度的变化

用放射免疫分析法(RIA)测定了蓖麻蚕(Philosamia cynthia rieini)从卵期到成虫个体发育整个过程的蜕皮甾类(MH)水平.卵期在6天时有一个MH峰.一龄到四龄各龄均有一个MH峰,出现在停食前一天,导致幼虫蜕皮.五龄期有两个MF峰.第一个小峰出现在第三天,使进食的幼虫向预蛹转化;第二个高峰在上簇两天后,导致蛹表皮的形成.与其它鳞翅目昆虫一样,蛹期只有一个MH峰,发生在蛹期的前半段.成虫期血淋巴内MH含量很低.     

DNA-RNA bodies in midgut cells of the stick insect, Bacillus rossius.

In the anterior part of the midgut and in the Malpighian tubules of the stick insect Bacillus rossius, about 10% of the epithelial cells develop endonuclear bodies which appear as DNA-RNA masses; in these cells the usual nucleoli are no longer evident. The DNA-RNA bodies are first formed in third instar larvae, become numerous in the fourth instar and persist in adults. In all larval instars and adults a different kind of DNA-body has been noticed in the epithelial cells of the posterior midgut. The DNA-RNA bodies of the anterior midgut and of the Malpighian tubules have been interpreted as the result of somatic gene amplification, whereas the DNA masses of the posterior midgut are likely due to a virus infection.