Programmed cell death in the larval salivary glands of <Emphasis Type="Italic">Apis mellifera</Emphasis> (Hymenoptera,Apidae)

The morphological and histochemical features of degeneration in honeybee (Apis mellifera) salivary glands were investigated in 5th instar larvae and in the pre-pupal period. The distribution and activity patterns of acid phosphatase enzyme were also analysed. As a routine, the larval salivary glands were fixed and processed for light microscopy and transmission electron microscopy. Tissue sections were subsequently stained with haematoxylin-eosin, bromophenol blue, silver, or a variant of the critical electrolyte concentration (CEC) method. Ultrathin sections were contrasted with uranyl acetate and lead citrate. Glands were processed for the histochemical and cytochemical localization of acid phosphatase, as well as biochemical assay to detect its activity pattern. Acid phosphatase activity was histochemically detected in all the salivary glands analysed. The cytochemical results showed acid phosphatase in vesicles, Golgi apparatus and lysosomes during the secretory phase and, additionally, in autophagic structures and luminal secretion during the degenerative phase. These findings were in agreement with the biochemical assay. At the end of the 5th instar, the glandular cells had a vacuolated cytoplasm and pyknotic nuclei, and epithelial cells were shed into the glandular lumen. The transition phase from the 5th instar to the pre-pupal period was characterized by intense vacuolation of the basal cytoplasm and release of parts of the cytoplasm into the lumen by apical blebbing; these blebs contained cytoplasmic RNA, rough endoplasmic reticule and, occasionally, nuclear material. In the pre-pupal phase, the glandular epithelium showed progressive degeneration so that at the end of this phase only nuclei and remnants of the cytoplasm were observed. The nuclei were pyknotic, with peripheral chromatin and blebs. The gland remained in the haemolymph and was recycled during metamorphosis. The programmed cell death in this gland represented a morphological form intermediate between apoptosis and autophagy.     

THE ORIGIN AND FATE OF MICROBODIES IN THE FAT BODY OF AN INSECT

The structure and life history of insect microbodies are described during the development of the fat body from the 4th to 5th larval molt through the 5th to pupal molt. The mature microbodies are flattened spheres about 1.1 x 0.9 µ, with a depression on one side where a dense mass connects the limiting membrane to the core of coiled tubules. They contain catalase and urate oxidase. The precise synchrony of development of insect cells during the molt/intermolt cycle makes it easy to study the life history of particular organelles. Phases of growth are correlated with the hormonal milieu. Mature 4th stage microbodies decrease in size before ecdysis to the 5th stage when they atrophy at the same time as the new 5th stage generation arises. The 5th stage microbodies form as diverticula of the RER and, grow while confronted by RER cisternae. The mature microbodies decrease in size when the fat body engages in massive larval syntheses. At the end of the 5th larval stage, the microbodies are invested by isolation membranes and destroyed before pupation. There are thus two mechanisms for microbody destruction: atrophy of the 4th stage organelles and isolation with autophagy at the end of the 5th stage.     

Sequential protein-dependent steps in the cell cycle initiation and completion of division in vitamin B12 replenishedEuglena gracilis

Summary InEuglena gracilis Z, vitamin B₁₂ deficiency arrests cell divisions in S/G 2 phase. After the addition of vitamin B₁₂ to blocked cells, nuclear and cellular divisions begin to be induced between the 3rd and the 4th and between the 4th and the 5th hour respectively; the cell population is doubled after the 11th hour.Addition of cycloheximide either with vitamin B₁₂ or 2 to 6 hours later inhibits the resumption of divisions and blocks cell development in different stages between G 2, karyokinesis and cytokinesis. These results suggest that as a prerequisite protein-dependent steps are required at precise times during the reversibility of blocked cell divisions: at least sequential syntheses of protein concern a) formation of the mitotic spindle and replication of the pellicle; b) completion of the nuclear division; c) progression of the cleavage furrow.     

FINE STRUCTURAL CHANGES IN THE INTESTINAL EPITHELIUM OF THE BULLFROG DURING METAMORPHOSIS

The fine structural changes occurring in the columnar absorbing cells of the intestinal epithelium during metamorphosis of the bullfrog, Rana catesbeiana, have been examined by phase contrast and electron microscopy. Tissue samples taken just posterior to the entrance of the hepatopancreatic duct were fixed in veronal acetate-buffered osmium tetroxide and embedded in methacrylate. Under the action of the metamorphic stimulus (thyroid hormone), specific and characteristic responses were given by differentiated larval cells and undifferentiated basal cells within the same epithelium. The functional larval cells underwent degenerative changes and were retained for a time within the metamorphosing epithelium. Dense bodies appeared and increased in number in association with the loss of normal cell structure. Because of their morphology and time of formation, these bodies have been tentatively identified as lysosomes. Early in metamorphosis the basal cells did not change, but they subsequently proliferated to form a new cell layer beneath the remaining degenerating cells that lined the lumen. After the dying cells were sloughed into the gut, the new epithelium differentiated to form the adult tissue. The columnar epithelial cells of the mature animal differed in their fine structural organization from their larval precursors. Therefore, their adult configuration was molded by the action of the metamorphic stimulus.     

Morphofunctional changes in the midgut of tick nymphs of the genus Ixodes (Acarina: Ixodidae) during and after feeding

The midgut epithelium of feeding nymph is represented by the digestive cells of larval phase. Digestion of the main part of feed is performed by the one generation of digestive cells of nymphal phase after detachment, during moult. This period precedes the apolysis. The generation of secretory cells is absent on the nymphal phase. Secretory vacuoles are formed in the digestive cells of larval phase. All functioning cells form a peritrophic matrix on their apical surface. The replacement of the digestive cells of larval phase by the digestive cells of nymphal phase proceeds gradually, during the first 5-10 days after detachment. The beginning of the accumulation of digestive inclusions in the young digestive cells of nymphal phase takes place in the 10-15 days after detachment.     

Control of the developmental timer forDrosophila pupariation

Summary In the insectDrosophila, formation of the puparium marks the onset of metamorphosis and serves as a useful marker for developmental progress. The cells of the adult remain diploid and divide during the larval stage while the larval cells become polytene and do not divide. We use a high dose of gamma-irradiation (10 krad) to selectively delete the imaginal lineage from the developing larvae ofDrosophila melanogaster. We find that animals depleted of imaginal cells including those of the imaginal brain pupariate only if the larval cells are allowed to mature, demonstrating that the larval cells harbor the primary developmental timer for this process. However, proliferating imaginal cells can exert a negative influence on the timing of pupariation.     

Attachment of origins of replication to the nuclear matrix and the chromosomal scaffold

We have investigated the attachment of DNA to the nuclear matrix and chromosomal scaffold in synchronized bovine liver cells. Label incorporated at the onset of the S phase remained preferentially associated with the matrix during the subsequent G1 phase and with a residual protein structure from dehistonized chromosomes during mitosis. On the other hand label incorporated during mid or late S phase was about equally distributed over the DNA molecule after a chase into the G1 phase. These results suggest that DNA is attached to the nuclear matrix and chromosome scaffolds by the origins of replication.     

DNA replication events during larval silk gland development in the silkworm, Bombyx mori

The silk gland is an important organ in silkworm as it synthesizes silk proteins and is critical to spinning. The genomic DNA content of silk gland cells dramatically increases 200-400 thousand times for the larval life span through the process of endomitosis. Using in vitro culture, DNA synthesis was measured using BrdU labeling during the larval molt and intermolt periods. We found that the cell cycle of endomitosis was activated during the intermolt and was inhibited during the molt phase. The anterior silk gland, middle silk gland, and posterior silk gland cells asynchronously exit the endomitotic cycle after day 6 in 5th instar larvae, which correlated with the reduced expression of the cell cycle-related cdt1, pcna, cyclin E, cdk2 and cdk1 mRNAs in the wandering phase. Additional starvation had no effect on the initiation of silk gland DNA synthesis of the freshly ecdysed larvae.     

Light and Electron Microscopic Observation on the Developing Pattern of Cotyledons of Nelumbo nucifera

The whole growing period (from the formation of cotyledon primordia till ripe) of cotyledons of Nelumbo nucifera takes about 30 days, but can be varied in 3–5 days according to the varieties, temperature, light duration and its intensity during the blooming season. The observations by light and electron microscopy show that the feature and structure of mesophyllous cell are changed greatly during its development. The developing pattern of the cotyledons is similar to that of dicotyledonous plants. For comparitive analysis the authors divide the whole developing process into four developing phases: Ⅰ, the phase of cell division and organ formation; Ⅱ, the phase of cell vacuolation, elongation and swelling; Ⅲ, the phase of main physiological function in which the materials are largely synthesized and accumulated and Ⅳ, the phase of dehydration, contraction, maturation and dormancy. The development of mesophyllous cells in different part of cotyledons is not simultaneous and the duration of each phase is also different. In general, the developing order is from the base to the top and first the outlayer then the centre. On the 25–26th days after fertilization almost all mesophyllous cells are developing into maturation and dormancy by order. This is the first report about the developing pattern of cotyledons and the ultrastructural changes in mesophyllous cells of Netumbo nucifera.     

Recovery of Pisum root meristems after mitotic-inhibitory treatments with 3H-thymidine. Inhibition of cell-cycle progression by unincorporated 3H-thymidine.

Primary root meristems of Pisum sativum recover form a 3H-thymidine-induced reduction in mitotic activity once the roots are no longer exposed to exogenous 3H-thymidine. Cells arrested in G2 during 3H-thymidine treatment apparently do not divide for at least 16 hours after treatment, whereas cells remaining in G1 and S do divide and thereby account for recovery. Recovery occurs only when meristems are no longer exposed to exogenous (i.e. unincorporated) 3H-thymidine, suggesting that cytoplasmic irradiation from unincorporated 3H-thymidine prevents cellular recovery from 3H-thymidine-induced inhibition of cell progression through the mitotic cycle. Concentrations of 14C-thymidine which result in cytoplasmic irradiation nearly equivalent to that achieved with 3H-thymidine, but much lower levels of nuclear irradiation, also prevent recovery from 3H-thymidine-induced inhibition of mitotic activity, but do not alone produced such inhibition. These results support the contention that cytoplasmic irradiation prevents recovery from the effects of nuclear irradiation. Unincorporated 3H-thymidine also prevents recovery from sucrose deprivation in stationary phase G2 cells which have not incorporated 3H-thymidine into nuclear DNA.     

Ecdysterone and an analogue of juvenile hormone on the autophagy in the cells of fat body of mamestra brassicae.

The effect of ecdysterone and a juvenile hormone analogue (JHa) on autophagy and heterophagy was investigated in the fat body cells of the last larval instar of Mamestra brassicae. In the course of normal development autophagic vacuoles and protein granules of heterophagic origin begin to accumulate in these cells, on the 4th and 5th day of the last larval stage respectively. When ecdysterone (10 mug/g body weight) was administered to the larvae for 24 h either on the 1st or on the 2nd day of the last larval stage, autophagic and heterophagic vacuoles appeared in the cells as early as on the 2nd or 3rd days. Autophagy was also observed in the cells of one-or two-day-old last larval fat body after a 5 h incubation in a medium containing 10 mug/ml ecdysterone, in vitro. Ligation of the last thoracic segment resulted in inhibition of metamorphic changes in the fat body lobules of the isolated abdomen. Injection of 10 mug ecdysterone into the isolated abdomen resulted in an appearence of autophagic vacuoles in these cells, too. JHa treatment, when started on the 2nd or 3rd day of the last larval stage, inhibited both auto- and heterophagy and the fat bodies maintained their larval character. Treatment started on the 4th or 5th day proved either ineffective or lethal. It is concluded that the auto- and heterophagy taking place in the larval fat body cells are stimulated by ecdysterone and inhibited by JHa. Experiments performed in vitro or on ligated animals in vivo provided evidence for a direct action of ecdysterone at the cellular level.     

daughterless-abo-like, a Drosophila maternal-effect mutation that exhibits abnormal centrosome separation during the late blastoderm divisions

daughterless-abo-like (dal) is a maternal-effect semilethal mutation in Drosophila. The nuclear divisions of embryos derived from homozygous dal females are normal through nuclear cycle 10. However, during nuclear cycles 11, 12 and 13, a total of about half of the nuclei in each embryo either fail to divide or fuse with a neighboring nucleus during telophase. These abnormal nuclei eventually sink into the interior of the embryo, leaving their centrosomes behind on the surface. The loss of about one-half of the peripheral nuclei into the interior of the embryo results in these embryos cellularizing during nuclear cycle 14 with about one-half the normal number of cells. Surprisingly, many of these embryos develop a nearly normal larval cuticle and 8% develop to adulthood. Observations of live embryos doubly injected with tubulin and histones that have been fluorescently labeled allows nuclear and centrosomal behavior to be directly followed as the embryo develops. We find that the abnormal nuclei arise from nuclei whose centrosomes have failed to separate normally in the previous interphase. These incompletely separated centrosomes can cause a non-functional spindle to form, leading to a nuclear division failure. Alternatively, they can form an abnormal spindle with a centrosome from a neighboring nucleus, causing two nuclei to share a common spindle pole. Such nuclei with a shared centrosome will undergo telophase fusions, unequal divisions, or division failures later in mitosis. These findings have helped us to understand the function of the centrosome in the Drosophila embryo.     

Division of cell nuclei, mitochondria, plastids, and microbodies mediated by mitotic spindle poles in the primitive red alga Cyanidioschyzon merolae

To understand the cell cycle, we must understand not only mitotic division but also organelle division cycles. Plant and animal cells contain many organelles which divide randomly; therefore, it has been difficult to elucidate these organelle division cycles. We used the primitive red alga Cyanidioschyzon merolae, as it contains a single mitochondrion and plastid per cell, and organelle division can be highly synchronized by a light/dark cycle. We demonstrated that mitochondria and plastids multiplied by independent division cycles (organelle G1, S, G2 and M phases) and organelle division occurred before cell–nuclear division. Additionally, organelle division was found to be dependent on microtubules as well as cell–nuclear division. We have observed five stages of microtubule dynamics: (1) the microtubule disappears during the G1 phase; (2) α-tubulin is dispersed within the cytoplasm without forming microtubules during the S phase; (3) α-tubulin is assembled into spindle poles during the G2 phase; (4) polar microtubules are organized along the mitochondrion during prophase; and (5) mitotic spindles in cell nuclei are organized during the M phase. Microfluorometry demonstrated that the intensity peak of localization of α-tubulin changed in the order to spindle poles, mitochondria, spindle poles, and central spindle area, but total fluorescent intensity did not change remarkably throughout mitotic phases suggesting that division and separation of the cell nucleus and mitochondrion is mediated by spindle pole bodies. Inhibition of microtubule organization induced cell–nuclear division, mitochondria separation, and division of a single membrane-bound microbody, suggesting that similar to cell–nuclear division, mitochondrion separation and microbody division are dependent on microtubules.     

Cell cycle changes during growth and differentiation of imaginal leg discs in Drosophila melanogaster

The relative DNA content of Drosophila melanogaster imaginal leg disc nuclei during larval growth and pupal and adult differentiation was measured by microspectrophotometry. During the larval proliferative phase there were twice as many nuclei in the 4C class as nuclei in the 2C class. At the end of the third larval instar, the proportion of nuclei with a 4C DNA value increased. By 3 hr after pupariation, during pupal cuticle secretion, 90% of the nuclei were in this class. After pupal apolysis which occurs at 12 hr after pupariation, the 4C to 2C ratio was reversed. The increase in the proportion of nuclei with a 2C value was observed until 24 hr after pupariation when 90% of the nuclei were in this class. We propose that most cells divide at least once between pupal and adult differentiation. All of these changes in the cell cycle were correlated temporally with changes in the ecdysteroid titers that occur during these periods.     

Larval antigen molecules recognized by adult immune cells of inbred Xenopus laevis: partial characterization and implication in metamorphosis

It has been shown that larval skin (LS) grafts are rejected by an inbred strain of adult Xenopus, which suggests a mechanism of metamorphosis by which larval cells are recognized and attacked by the newly differentiating immune system, including T lymphocytes. In an attempt to define the larval antigenic molecules that are targeted by the adult immune system, anti-LS antibodies (IgY) were produced by immunizing adult frogs with syngeneic LS grafts. The antigen molecules that reacted specifically with this anti-LS antiserum were localized only in the larval epidermal cells. Of 53 and 59-60 kDa acidic proteins that were reactive with anti-LS antibodies, a protein of 59 kDa and with an isoelectric point of 4.5 was selected for determination of a 19 amino acid sequence (larval peptide). The rat antiserum raised against this peptide was specifically reactive with the 59 kDa molecules of LS lysates. Immunofluorescence studies using these antisera revealed that the larval-specific molecules were localized in both the tail and trunk epidermis of premetamorphic larvae, but were reduced in the trunk regions during metamorphosis, and at the climax stage of metamorphosis were detected only in the regressing tail epidermis. Culture of splenocytes from LS-immunized adult frogs in the presence of larval peptide induced augmented proliferative responses. Cultures of larval tail pieces in T cell-enriched splenocytes from normal frogs or in natural killer (NK)-cell-enriched splenocytes from early thymectomized frogs both resulted in significant destruction of tail pieces. Tissue destruction in the latter was enhanced when anti-LS antiserum was added to the culture. These results indicate that degeneration of tail tissues during metamorphosis is induced by a mechanism such that the larval-specific antigen molecules expressed in the tail epidermis are recognized as foreign by the newly developing adult immune system, and destroyed by cytotoxic T lymphocytes and/or NK cells.     

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.     

Autophagic and apoptotic features during programmed cell death in the fat body of the tobacco hornworm (Manduca sexta)

Two major pathways of programmed cell death (PCD)--the apoptotic and the autophagic cell death--were investigated in the decomposition process of the larval fat body during the 5th larval stage of Manduca sexta. Several basic aspects of apoptotic and autophagic cell death were analyzed by morphological and biochemical methods in order to disclose whether these mechanisms do have shared common regulatory steps. Morphological examination revealed the definite autophagic wave started on day 4 followed by DNA fragmentation as demonstrated by agarose gel electrophoresis and TUNEL assay. By the end of the wandering period the cells were filled with autophagic vacuoles and protein granules of heterophagic origin and the vast majority of the nuclei were TUNEL-positive. No evidence was found of other aspects of apoptosis, e.g. activation of executioner caspases. Close correlation was disclosed between the onset of autophagy and the nuclear accumulation of the ubiquitin-proteasome system.