小地老虎变态期间马氏管超微结构与酯酶活性的变化

本实验用光镜和电镜观察了小地老虎Agrotis ypsilon Rottemberg幼虫在变态期间马氏管超微结构的变化及成虫马氏管的重组过程,同时还研究了变态期马氏管酯酶的活性.结果表明:(1)变态期间马氏管外形完整,除至预蛹期隐肾复合体解体外,其余无明显变化.(2)变态期间管壁细胞变化显著.幼虫6龄末期马氏管细胞结构开始变化,主要特点为:细胞质电子密度高,充满了核糖体颗粒,微绒毛萎缩,线粒体从萎缩的微绒毛中退出进入细胞质,基膜内褶破坏.进入预蛹期幼虫马氏管细胞解体:基膜内褶、顶端微绒毛、线粒体及细胞质内的其它细胞器消失,并形成自体吞噬泡,细胞质内仅存细胞核及各种类型的液泡.但是在变态期间因底膜始终存在,故马氏管外形不变;至蛹后期,成虫马氏管细胞在原位重组,基膜内褶由浅变深,微绒毛由短变长,线粒体内嵴从无到有.(3)变态过程中羧酸酯酶和酸性磷酸酯酶的活性变化趋势基本相同,以六龄幼虫最强,预蛹期次之,蛹期最低.     

白蜡虫马氏管的超微结构

白蜡虫Ericerus Pela的马氏管由两条黄色膨泡串状的端管和一条公共管构成,通过公共管与消化道相连。端管和公共管细胞结构相似,都具有非胶原质的基膜,高度发达的基褶, 长而致密的微绒毛,微绒毛无线粒体插入,细胞质中线粒体少,且随机分布。细胞质的绝大部分为两种矿质-尿酸颗粒结晶所占据,一种为不规则结晶,另一种为轮纹状结晶。白蜡虫马氏管可能发生了合胞化,其排泄方式可能是一种以滞留排泄为主,离子梯度排泄方式为辅的特有的排泄方式。     

Ultrastructural effects of lethal freezing on brain,muscle and Malpighian tubules from freeze-tolerant larvae of the gall fly,Eurosta solidaginis

In preparation for winter low temperatures, larvae of the gall fly, Eurosta solidaginis, accumulate the cryoprotectants glycerol, sorbitol, and trehalose. The fat body cells of these freeze-tolerant larvae can survive intracellular freezing to -80 degrees C for 48 h even though no whole larvae survive this treatment. We hypothesized that some other tissue was more susceptible to freezing and therefore may be responsible for larval death. This paper compares the ultrastructure of brain, muscle, and Malpighian tubules between non-lethally frozen and lethally frozen freeze-tolerant larvae. The nuclei of cortical brain cells from lethally frozen larvae exhibited clumped chromatin and nuclear membranes with occasional expansions or 'blebs' of the intermembranous space, while the cytoplasm contained swollen spheres of endoplasmic reticulum. In contrast, non-lethally frozen brain contained nuclei with evenly dispersed chromatin, smooth nuclear membranes and a cytoplasm free of swollen endoplasmic reticulum. Muscle tissue of lethally frozen larvae contained disrupted myofilaments surrounding the Z-line in comparison to non-lethally frozen muscle which had myofilaments extending all the way to the Z-line. Alterations of Malpighian tubule cells from lethally frozen larvae included an extracted cytoplasm with swollen and rounded mitochondria. In contrast, Malpighian tubule cells from non-lethally frozen larvae had a more concentrated cytoplasm with many rod-shaped mitochondria. Results show alterations to all three tissue types due to lethal freezing. The brain tissue contained the most observable alterations and therefore may be the most susceptible to lethal freeze damage.     

Ultrafine structure of the malpighian tubules of hematophagous Diptera

The ultrastructure of Malpighian tubes of 5 species of bloodsucking Diptera was studied: Culicoides pulicaris, Tabanus bromius, Hybomitra schineri, Haematopota pluvialis and Stomoxys calcitrans. The Malpighian tubes of the above species include the cells of two types. The most abundant cells of the 1st type contain many spherical inclusions which represent deposits of mineral compounds. The microvilli of the 1st type cells always contain mitochondria. Cells of the 2nd type are characterized by a smaller size, their microvilli lack mitochondria and no sphere crystals are observed in cytoplasm. Differences in the ultrastructure of epithelial cells of Malpighian tubes were found out.     

Ultrastructure of the Malpighian Tubule Cells in the Mosquito Larvae, Anopheles sinesis

Ultrastructure of epithelial cells constituting the Malpighian tubule of Anopheles sinesis last instar larvae was observed with electron microscope. Malpighian tubule consists of four long and narrow tubule structures with principal cells in typical absorptive cells and regenerative cells forming the simple epithelium. Apical plasma membrane of the principal cell is differentiated into microvilli with one mitochondrion in each microvilli. Basal plasma membrane had extreme infolding to form a canaliculi and a well developed mitochondria was attached in the infoldings. And, rER, ribosomes, and vacuoles were well developed inside the cells. However, there were two main cell types depending on the differentiation of cell organelles. Type 1 cell was cubic, forming the distal portion of Malpighian tubule. The length of microvilli was approximately 4 μm and the basal infoldings were introjected to the depth of 2 μm inside the cell. On the other hand, Type II cell that formed the main proxinal portion was a low squamous type cells with shorter 2 μm of microvilli and the basal infoldings were introjected to the depths of 4 μm inside the cell. As for vacuoles scattered inside the cells, they were regularly observed in both Type I and II and the Type II cells had better developed cellular organelles. Although regenerative cells were extremely small, their cellular organelles were developed and their overall electron density was high that they appeared darker than the principal cells.     

Carbonic anhydrase supports electrolyte transport in Drosophila Malpighian tubules. Evidence by X-ray microanalysis of cryosections

Electron probe X-ray microanalytical studies on the role of carbonic anhydrase in electrolyte transport in the cells of Drosophila Malpighian tubules indicate that carbonic anhydrase delivers protons and bicarbonate ions to ion transport systems in the cell membrane. After injection and after feeding acetazolamide or hydrochlorothiazide, known inhibitors of carbonic anhydrase, the contents of potassium, magnesium and chloride in the apical cytoplasm and in the cytoplasm close to the basal plasma membrane decreased. We explain our measurements by the hypothesis of a basal Mg-H-antiport system in parallel with Cl-HCO(3)-antiport, inhibitable by DIDS. Zinc is supposed to enters cells and intracellular Zn storage vacuoles by a negatively charged Zn-anion-complex in exchange for HCO(3)(-) ions. This antiport is inhibitable by SITS. The content of the Zn storage vacuoles is acid, as shown by red fluorescence after incubation of Malpighian tubules with acridine orange. Red fluorescence is absent after preincubation in a medium containing an inhibitor of carbonic anhydrase. Carbonic anhydrase was demonstrated cytochemically in the Golgi-ER complex, Golgi vesicles and intercellular space. We suppose that carbonic anhydrase is synthesized and stored in the Golgi-ER-complex from where it is released into the tubule lumen.     

Early cellular responses in the Malpighian tubules of the mosquito Aedes taeniorhynchus to infection with Dirofilaria immitis (Nematoda)

Early ultrastructural changes in the Malpighian tubules of the mosquito, Aedes taeniorhynchus, were examined following infection with the nematode, Dirofilaria immitis. After ingestion by the mosquito, the microfilariae enter the cells of the Malpighian tubules, becoming intracellular. During early development, the filarial prelarvae reside in the cell cytoplasm surrounded by a clear zone without a delimiting membrane. Cells infected with prelarvae differed from uninfected cells and from cells in uninfected mosquitoes in that the volume of the apical microvilli was reduced and mitochondria were retracted from these microvilli. Morphometric analysis was used to quantify the ultrastructural consequences of infection. In infected cells, microvillar volume, the percent of microvillar volume occupied by mitochondria, and volume of mitochondria within the microvilli were significantly reduced.     

Development, Ultrastructure and Secretion of Gum Ducts in Lannea coromandelica (Houtt.) Merrill (Anacardiaceae)

In Lannea coromandelica (Houtt.) Merrill, the gum ducts in theprimary phloem of the stem initiate and develop schizogenously.Formation of an intercellular space amongst a group of denselystained phloem procambial cells signals the initiation of aduct. Initiation of a duct starts by dissolution of the middlelamella of the walls. It widens by separation of cells alongthe radial walls by swelling and dissolution of the middle lamella.During separation of radial walls dictyosomes and paramuralbodies are observed in the peripheral cytoplasm at the siteof dissolution. Plasmodesmata occur in the radial and innertangential walls of epithelial cells of developing gum ducts.The epithelial cells have a dense cytoplasm and contain roughendoplasmic reticulum, ribosomes, polysomes, mitochondria withswollen cristae, plastids with poorly developed membranes, dictyosomesand vesicles. Dictyosomes and rough endoplasmic reticulum seemto be involved in the secretion of the gum. The polysaccharidegum constituents apparently originate from the outer wall layersof the epithelial cells. Following gum secretion, the epithelialcells degenerate. Lannea coromandelica (Houtt.) Merrill, Anacardiaceae, gum ducts, ultrastructure, gum secretion     

The fine structure of the light organ of the New Zealand glow-worm Arachnocampa luminosa (Diptera: Mycetophilidae).

The swollen distal tips of the Malpighian tubules of the glow-worm Arachnocampa luminosa constitute the light organ. The ventral and lateral surfaces are covered by a tracheal ‘reflector’ and the nervous supply to the light organ comes from the ganglion in the penultimate segment. Fine nerve terminals, axons, and glial cells can be seen in close proximity to the basal surface of the cells of the light organ. The epithelial cells of the light organ are large, the cytoplasm dense, homogeneous and acidophilic. The cytoplasm gives a strong positive reaction for protein. The cytoplasm contains a high density of free ribosomes, patches of dense material, smooth endoplasmic reticulum, glycogen and scattered microtubules. Mitochondria are numerous; they are large, randomly distributed and packed with fine cristae. These cells lack the features characteristic of Malpighian tubule epithelial cells; infolding of the apical and basal cell surfaces is reduced and the cytoplasm contains few organelles. These cells do not contain secretory or photocyte granules and the grainy cell matrix is thought to be the luciferin substrate. Oxygen is supplied via the tracheal layer (which may have secondary reflecting properties) and light production controlled by neurosecretory excitation either directly via synapses, or by hormones. There are no other reports of Malpighian tubules of insects producing light and the fine structure of these cells is distinct. Thus, the swollen distal tips of the Malpighian tubules of the glow-worm undoubtedly constitute a unique luminescent organ.     

Anatomy and fine structure of the alimentary canal of the spittlebug Lepyronia coleopterata (L.) (Hemiptera: Cercopoidea)

The alimentary canal of the spittlebug Lepyronia coleopterata (L.) differentiates into esophagus, filter chamber, midgut (conical segment, tubular midgut), and hindgut (ileum, rectum). The filter chamber is composed of the anterior extremity of the midgut, posterior extremity of the midgut, proximal Malpighian tubules, and proximal ileum; it is externally enveloped by a thin cellular sheath and thick muscle layers. The sac-like anterior extremity of the midgut is coiled around by the posterior extremity of the midgut and proximal Malpighian tubules. The tubular midgut is subdivided into an anterior tubular midgut, mid-midgut, posterior tubular midgut, and distal tubular midgut. Four Malpighian tubules run alongside the ileum, and each terminates in a rod closely attached to the rectum. Ultrastructurally, the esophagus is lined with a cuticle and enveloped by circular muscles; its cytoplasm contains virus-like fine granules of high electron-density. The anterior extremity of the midgut consists of two cellular types: (1) thin epithelia with well-developed and regularly arranged microvilli, and (2) large cuboidal cells with short and sparse microvilli. Cells of the posterior extremity of the midgut have regularly arranged microvilli and shallow basal infoldings devoid of mitochondria. Cells of the proximal Malpighian tubule possess concentric granules of different electron-density. The internal proximal ileum lined with a cuticle facing the lumen and contains secretory vesicles in its cytoplasm. Dense and long microvilli at the apical border of the conical segment cells are coated with abundant electron-dense fine granules. Cells of the anterior tubular midgut contain spherical secretory granules, oval secretory vesicles of different size, and autophagic vacuoles. Ferritin-like granules exist in the mid-midgut cells. The posterior tubular midgut consists of two cellular types: 1) cells with shallow and bulb-shaped basal infoldings containing numerous mitochondria, homocentric secretory granules, and fine electron-dense granules, and 2) cells with well-developed basal infoldings and regularly-arranged apical microvilli containing vesicles filled with fine granular materials. Cells of the distal tubular midgut are similar to those of the conical segment, but lack electron-dense fine granules coating the microvilli apex. Filamentous materials coat the microvilli of the conical segment, anterior and posterior extremities of the midgut, which are possibly the perimicrovillar membrane closely related to the nutrient absorption. The lumen of the hindgut is lined with a cuticle, beneath which are cells with poorly-developed infoldings possessing numerous mitochondria. Single-membraned or double-membraned microorganisms exist in the anterior and posterior extremities of the midgut, proximal Malpighian tubule and ileum; these are probably symbiotic.     

Fine structure of the Malpighian tubules in the housefly, Musca domestica

The epithelium of the Malpighian tubules in the housefly is comprised of four distinct cellular types. Type I cells are characterized by the presence of intimate associations between infoldings of basal plasma membrane and mitochondria. On the luminal surface, cytoplasm is extended into microvilli which contain mitochondria. Membrane-bound vacuoles in the cytoplasm seem to progressively accumulate granular material. Type II cells have dilated canaliculi. Microvilli lack mitochondria. The Type III cell has not been reported previously in Malpighian tubules. It has very well-developed granular endoplasmic reticulum which contains intracisternal bundles of tubules. Cytoplasm contains numerous electron dense bodies. Type IV cells occur in the common duct region of the Malpighian tubules. Mitochondria do not extend into the microvilli.     

Ultrathin structure of normally growing and regenerating cells of Acetabularia mediterranea]

The ultrastructure of nucleus and cytoplasm in regenerating cells of Acetabularia mediterranea differs from that in normally growing ones: the nucleus of regenerating cells form numerous outgrowths; the cortical layer of nucleolus disintegrates markedly; the emission of nucleolar material in the nucleoplasm is observed. In the cytoplasm the portion of active chloroplasts increases and a great number of tubular fibrils appears. In the cytoplasm of regenerating cells the Golgi dictyosomes occur more frequently and the vesicles at their ends are larger than in that of normally growing cells. The changes of macromolecular organization of the nucleus and cytoplasm in question observed at the earlier stages of regeneration (2--12 hrs) suggest the increase of metabolic activity of cells.     

Cytopathological observations on renal tubule epithelium cells in common carp Cyprinus carpio under Trypanoplasma borreli (Protozoa: Kinetoplastida) infection

Cytological alterations in renal tubule epithelium cells of carp Cyprinus carpio infected with the blood flagellate Trypanoplasma borreli Laveran & Mesnil, 1901 were investigated during the course of a laboratory infection of a highly susceptible carp line. With the development of the parasitaemia, a hyperplasia of the interstitial renal tissue was induced, which resulted in a tubulus necrosis. Cytological changes were already seen in tubulus epithelium cells on Day 7 post injection (PI) of the parasite. The basilar invaginations of the cells fragmented and a swelling of mitochondria was noted. With increasing parasitaemia, on Days 14 and 21 PI, these changes progressed up to the loss of the basilar invagination and high amplitude swellings of mitochondria and deterioration of their internal membrane structures. Cells of the distal tubule segment reacted earlier and more rapidly than cells of the proximal tubule. The cytological alterations suggested a loss of function of the epithelum cells, which most likely resulted in impaired ionic and osmotic regulation of T. borreli-infected fishes. Our findings indicate that in response to the proliferation of the interstitial renal tissue cell structures of the renal tubule cells are altered quickly and in a progressive manner.     

An investigation into the effects of stimulators of fluid production on Locusta Malpighian tubule intracellular elemental composition

The intracellular elemental concentrations of Na, K, P, S, Cl and Mg in the type 1 cells of Malpighian tubules of Locusta migratoria L. have been measured using electron probe X-ray microanalysis. The effects of in vitro stimulation with 1 mM cAMP and corpora cardiaca extract (CC-extract) on the elemental concentrations have been quantified. The distribution of elements, particularly Na, K and Cl is not homogeneous in control cells, and concentration gradients exist within the cytoplasm. Dibutyryl-cAMP (DB-cAMP) caused a decrease in [K]_i without disrupting the gradient which increased from the basal to the apical surface, the apical [Na]_i was increased as was the [Cl]_i. In contrast, in vitro application of CC-extract did not cause changes to the intracellular elemental composition as compared with control cells These data are consistent with the interpretation that exogenous cAMP only partially activated the full stimulatory response of Malpighian tubule cells observed with CC-extract. The changes observed in the density and elemental composition of the `dark bodies' in response to DB-cAMP and CC-extract stimulation suggest that these structures have a role in the ionic economy of Malpighian tubule cells. Accepted: 6 April 1999     

Fine structure of larval malpighian tubules and rectal sac in the tick Ornithodoros (Pavlovskyella) erraticus (Ixodoidea: Argasidae)

The fine structure of the Malpighian tubules (Mts) and rectal sac (rs) is described in the larval tick Ornithodoros (Pavlovskyella) erraticus before and after feeding up to molting. Mts consist of structurally different pyramidal and cuboidal cells along the entire length of the tubule. In unfed ticks, the two types of cell are characterized by apical microvilli and a few basal membrane infoldings. The abundant pyramidal cells contain glycogen particles, lipid droplets, lysosomelike structures, and rickettsialike microorganisms. After feeding but before molting, pyramidal cells loose glycogen particles and become very dense and dramatically reduced in size. These cells are possibly involved in the formation of guanine crystalloids as an excretory product. In contrast, cuboidal cells, filled with glycogen particles, free ribosomes, and mitochondria in unfed larvae, grow steadily after feeding; their cytoplasm becomes rich in lipid droplets in addition to showing an increase in glycogen particles. Lipid and glycogen could be the source of energy required for water and ion reabsorption in which cuboidal cells are probably involved. The paired-lobe rs consists of one type of cuboidal cells with basal membrane infoldings and a brush-border microvilli covered by a fuzzy coat of glycocalyx. These cells grow rapidly after feeding; they have functional features indicating extensive, selective reabsorption of essential components from excretory products.     

An ultrastructural study of Dirofilaria immitis infection in the Malpighian tubules of Anopheles quadrimaculatus

An ultrastructural study was conducted of the Malpighian tubules of Anopheles quadrimaculatus, both uninfected and following infection with Dirofilaria immitis. The Malpighian tubules in Anopheles are composed of primary and stellate cells. The primary cells are the predominant cell type and are characterized by the presence of membrane-bound, intracellular, mineralized concretions and large apical microvilli containing mitochondria. Following the infective blood meal, the microfilariae enter the primary cells of the Malpighian tubules and reside in the cytoplasm in a clear zone without a delimiting membrane. Cells in infected tubules differ from those in uninfected tubules in that the membranes of the vacuoles surrounding the concretions are disrupted in many specimens. The apical and basal cell membranes and the mitochondria associated with these are not disrupted during the first 6-8 days of infection. These observations differ sharply from those previously described in Aedes taeniorhynchus infected with D. immitis. The observations are consistent with the hypothesis that the extended transport capacity observed in previous physiological studies of An. quadrimaculatus infected with D. immitis are dependent on the prolonged normal ultrastructure of the apical microvilli, mitochondria, and basal membranes.     

不同波段电磁辐射致大鼠睾丸支持细胞的损伤效应

为探讨不同波段电磁辐射对大鼠睾丸支持细胞(Sertoli细胞)损伤效应的异同.将原代培养的Sertoli细胞经场强6×104V/m的电磁脉冲(electromagnetic pulse,EMP)、平均功率密度为100mW/cm2的S-波段高功率微波(S-band high power microwave,S-HPM)和...     

Effects of Treatment with Sodium Dodecyl Sulfate on the Ultrastructure of Escherichia coli

An electron microscopy study has been made of the effects of dissolution of the plasma membrane of Escherichia coli with sodium dodecyl sulfate (SDS) on the organization of the nucleoplasm and the cytoplasm. The alterations observed in time course experiments were related to absorbance changes and to release of macromolecules from the cells. As the cells became plasmolyzed, under the conditions used, the first visible effect of SDS was a collapse of the plasmolysis spaces. This was accompanied by a displacement of the nuclear material which then appeared in broad contact with the redeployed plasma membrane. This initial displacement of nuclear material to the cell border may indicate an association between the nucleoplasm and the plasma membrane. Upon further dissolution of the plasma membrane, the nuclear material receded from the cell margin and contracted into an axial filament. Meanwhile, the cytoplasm dissociated into an amorphous, Pronase-sensitive component and an electron-opaque, granular one sensitive to ribonuclease. The latter represented one continuous area of ribosomal structures surrounding the nucleoplasm, an organization which did not occur when the cells were inhibited with rifamycin before SDS treatment. During prolonged SDS interaction, approximately 65% of the cellular protein, 25% of the ribonucleic acid and 40% of the deoxyribonucleic acid were released from the cells concomitant with the disappearance of the amorphous cytoplasmic part, expansion of the ribosomal aggregate, and rearrangement of the nuclear material at the cell periphery. The observations support the contention that all ribosomal structures bear a direct relationship with the nucleoplasm.     

Ultrastructural changes in the Malpighian tubules of the house cricket, Acheta domesticus, at the onset of diuresis: A time study

The Malpighian tubules (Mt) of insects are responsible for maintaining osmotic homeostasis and eliminating waste from the hemolymph. When stimulated by diuretic factors the tubule cells are able to transport extraordinary volumes of fluid over short periods of time. We have been studying the changes that occur within the cells that accompany and facilitate this phenomenon. We present the ultrastructural changes that occur in the mid-tubule of the house cricket, Acheta domesticus, following exposure to the second messenger analog, dibutyryl cAMP, over the period from 15-420 sec. Vacuolation of the cytoplasm begins as early as 30 sec poststimulation with a significant increase in vacuolation occurring after 120 sec. As expected, there is an increase in the surface area of the basolateral membrane to facilitate the rapid movement of fluid into the cells. Other ultrastructural changes noted to accompany the onset of diuresis include the movement of mitochondria into areas adjacent to transport membranes, the vesiculation of Golgi, mobilization of CaPO(4) spherites, and a direct interaction of these spherites with active mitochondria. We discuss several possible roles for these changes in terms of rapid fluid transport.     

Developmental changes in Malpighian tubule cell structure.

Structural changes which occur in the Malpighian tubule yellow region primary cells during larval-pupal-adult development of the skipper butterfly Calpodes ethlius are described. The developmental changes in cell structure are correlated with functional changes in fluid transport (Ryerse, 1978a) in a way which supports osmotic gradient models of fluid secretion. Larval tubules are specialized for fluid secretion with deep basal infolds and elongate mitochondria-containing apical microvilli which provide channels in which osmotic gradients could be set up. The Malpighian tubule cells are extensively remodelled at pupation when fluid transport is switched off, but they persist intact through metamorphosis. At this time, the basement membrane doubles in thickness, the mitochondria are retracted from the microvilli and are isolated for degradation in autophagic vacuoles, and both apical and basal plasma membranes are internalized via coated vesicles for degradation in multivesicular bodies, which results in the shortening of the microville and the disappearance of the basal infolds. Mitochondria are re-inserted into the microvilli, and the basal infolds re-form in pharate adult stage Malpighian tubules when fluid secretion resumes. Adult tubules are similar in general structure to larval tubules and contain mitochondria in the microvilli and basal infolds. However, they differ from larval tubules in that they are capable of very rapid fluid transport, have a reduced tubule diameter and tubule wall thickness, a much thicker basement membrane and peripherally associated tracheoles. Mineral concretions of calcium phosphate accumulate in larval tubules, persist through metamorphosis and decline in number in adults, suggesting they serve some anabolic role.