Extrachromosomal rDNA and polarity of pro-oocytes during ovary development in Creophilus maxillosus (Coleoptera, Staphylinidae).

In telotrophic ovary of Creophilus maxillosus, the differentiation of the oocyte and nurse cells takes place within the linear clusters of sister oogonial cells. The amplification of rDNA occurs in the nuclei of pro-oocytes which are the most posterior cells of the clusters. During the consecutive oogonial divisions extrachromosomal rDNA segregates preferentially to the pro-oocyte of the next generation. We analyzed the ultrastructure of pro-oocytes and pro-nurse cells in the early and late phase of rDNA amplification in pupal ovary of Creophilus maxillosus. We found that pro-oocytes of the same generation contain variable amounts of extrachromosomal rDNA and that the presence of extra DNA is not limited to the nuclei of pro-oocytes; extra DNA is also present in the nuclei of some pro-nurse cells. Pro-oocytes can experience partial loss of extrachromosomal DNA during early oogonial divisions which is caused by the imprecise segregation of this material to the posterior pole. We believe that this imperfect segregation is a source of extrachromosomal DNA present in the nuclei of pro-nurse cells. Ultrastructural analysis showed that multiple nucleoli do not disperse in oogonial mitoses but remain associated with extrachromosomal chromatin and segregate with it to the posterior pole of the pro-oocyte. We also analyzed the ultrastructure of the germ plasm--a cytoplasmic structure present at the posterior pole of pro-oocytes. We have found that this structure contains spectrin and at the ultrastructural level is strikingly similar to the spectrosome which is present in germline cells of Drosophila. We also found spectrin in the intercellular bridges which connect oogonial cells and are known to contain fusomes.     

THE TIMING OF MEIOSIS AND DNA SYNTHESIS DURING EARLY OOGENESIS IN THE TOAD, XENOPUS LAEVIS

Recently metamorphosed female Xenopus laevis toads were injected with tritiated thymidine. Animals were kept at 20°C and were sacrificed 1–23 days after isotope injection. Radio-autographs of squash preparations of the ovaries were made. The progress of labeled germ cell nuclei was followed to obtain information on the time course of early meiosis and extra-chromosomal DNA synthesis. Premeiotic S was estimated to take not more than 7 days. Leptotene takes 4 days, zygotene takes 5 days, and pachytene was estimated to be completed in about 18 days. The major period of amplification of the extrachromosomal DNA occurs in pachytene and takes about 13 days. A low level of synthesis was observed before and after this period, in zygotene and late pachytene-early diplotene, extending the total time for extrachromosomal DNA synthesis during meiosis to about 18 days. These data allowed the calculation to be made that one round of replication of the amplified DNA takes between 1.2 and 3.0 days. It was also found that in both oogonial and premeiotic interphases, the nucleolus-associated DNA shows asynchronous (probably late) labeling with respect to the chromosomes.     

Metabolic DNA in Tipula oleracea

Summary In Tipula oleracea females 2n=6+XX (Diptera) a Feulgen positive body is present in the oogonia and oocyte nuclei. This body appears in the nucleus at the oogonial divisions that precede meiosis. It gets larger by leptotene, attaining a diameter of 6 microns, and at diplotene suddenly disintegrates. By metaphase I the body is not seen.Injection of tritiated thymidine into the larvae leads to a heavy labelling of the Feulgen positive body. The body is found to synthesize DNA at a different period of time from the chromosomes, and there is an intermediate period when the synthesis of the two nuclear structures overlaps.The tritium labelled thymidine is released from the body between the third and fourth day of pupal life. At this time the yolk granules in the cytoplasm become particularly conspicuous.When the body disintegrates the labelled material becomes easily diluted. The volume of the nucleus and of the cytoplasm are sufficiently large to dilute this material in such a way that it easily becomes indistinguishable from background radiation.Spectrophotometric measurements of the body reveal that it contains four times more DNA per unit area than the chromosomes. The area of the body is 28.3 square microns and that of the chromosomes 78.5 square microns. This means that the amount of DNA in the body is of a higher order of magnitude than that found in all the chromosomes.This large amount of DNA becomes suddenly available either to the chromosomes or other cellular components. DNA can carry its own genetic information to other cellular components.This work was supported by a grant from the Swedish Natural Science Research Council.     

Synthesis and characterization of amplified DNA in oocytes of the house cricket,Acheta domesticus (Orthoptera: Gryllidae)

At a time in the life cycle when a large proportion of the oocytes of Acheta incorporate ³H-thymidine into an extrachromosomal DNA body, synthesis of a satellite or minor band DNA, the density of which is greater than main band DNA, is readily detected. Synthesis of the satellite DNA is not detectable in tissues, the cells of which do not have a DNA body, or in ovaries in which synthesis of extrachromosomal DNA by the oocytes is completed. The DNA body contains the amplified genes which code for ribosomal RNA. However, less than 1 percent of the satellite DNA, all of which appears to be amplified in the oocyte, is complementary to ribosomal 18S and 28S RNA. In situ hybridization demonstrates that non-ribosomal elements, like the ribosomal elements of the satellite DNA, are localized in the DNA body.Abbreviations used rRNA ribosomal RNA, includes 18S and 28S RNA - rDNA gene sequences complementary to rRNA - cRNA complementary RNA synthesized in vitro     

Nucleolar organization in oocytes of gryllid crickets: subfamilies Gryllinae and Nemobiinae

A cytological and cytochemical survey was made of nucleolar changes during oocyte development in several different species of crickets (Gryllidae) representing the subfamilies Gryllinae and Nemobiinae. A large mass of extrachromosomal DNA is characteristic of the pachytene stage nuclei of all species examined. Nucleolar material accumulates at the periphery of the DNA body as the cells proceed into the diplotene stage of development. As the oocytes proceed through diplotene, the nucleoli reorganize into many small masses which eventually disperse in the nucleoplasm. These changes reflect both an increase in number and in size of the nucleolar material during the diplotene stage and the mode by which dispersal of nucleolar material is accomplished. These differences probably reflect differences in the organization of extrachromosomal nucleolar DNA.     

Characterization of extrachromosomal DNA in the flesh fly Sarcophaga bullata

The polytene pupal foot pad cells of the flesh fly Sarcophaga bullata contain numerous extrachromosomal DNA containing granules. We have determined both the origin and the nature of the DNA sequences present in these granules. Studies done with quinacrine staining of seven day old pupal foot-pad polytene nuclei showed that the granules fluoresced very brightly while the chromosomal bands to which the granules were attached did not. The only other highly fluroescent regions of the polytene karyotype were the centromeric heterochromatin of chromosomes C and E and several bands associated with the nucleolus of Chromosome A. When polytene nuclei were hybridized in situ with cRNA made from highly repetitive DNA, many of the granules positively labeled. Most of the label on these slides was concentrated on the centromeric heterochromatin of chromosomes C and E. Quinacrine staining of the foot-pad cells at very early stages of pupal development showed that when granules were present, they were always closely associated with the same two centromeric regions, those of chromosomes C and E. Since the highly repetitive DNA located in these centromeric regions is underreplicated, we conclude that the granules result from an extrusion process which takes place early during the polytenization of these cells. The chromosomal integrity of the centromeric heterochromatin of chromosomes C and E is apparently disrupted and repetitive sequences are dissociated from the chromosomes as DNA granules which then secondarily become associated with chromosomal bands throughout the nucleus.     

Ultrastructure of trophocyte nuclei in polytrophic ovarioles of Chrysopa perla (Neuroptera)]

The light and electron microscope and autoradiographic studies (H3-uridin incorporation) were carried out on the trophocyte nuclei of imago polytrophic ovarioles of Chrysopa perla (Neuroptera), from the trophocyte differentiation up to their degeneration. Like the oocytes, one of the seven nurse cells o every ovariole chamber contains extrachromosomal DNA bodies. This nurse cell is formed during differential mitoses in the germarium as one of two prooocytes. In contrast to extrachromosomal DNA of oocytes the trophocyte DNA bodies are less active structures. Several (2--4) complex nucleoli develop in the trophocytes of Chrysopa in the early stages of oogenesis. They consist of three main components: the chromatin mass, fibrillar bodies and granular strands. Such nucleoli grow, through increasing in number of fibrillar bodies and granular strands. They are most developed by the start of the vitellogenesis. At the middle vitellogenesis the general nucleolar structure modify due to the beginning of trophocyte degeneration. The consecutive stages of nuclear degeneration are described. The trophocyte nucleoli synthesize RNA still in germarium. The most intensive RNA synthesis is observed at the beginning of the vitellogenesis to decrease by the beginning of trophocyte degeneration.     

Formation,transport, and storage of ribonucleic acid containing structures in oocytes of Acheta domesticus (Orthoptera)

Summary Oocyte development of Acheta domesticus was investigated morphologically and cytochemically. The studies demonstrated a size decrease and final disappearance of a large extrachromosomal DNA body in the nuclei as the cells proceeded through the diplotene stage of meiosis. The body was surrounded by fascicles of RNA containing material. This material remained within the nuclei in individual packets after the DNA body was no longer detectable. An active nucleo-cytoplasmic migration of RNA was seen prior to the disappearance of the DNA body. After the disappearance of the body very little migration was detected. Evidence was presented to demonstrate the ribosomal nature of this migratory RNA. The RNA packets remaining in nuclei of cells arrested in the diplotene stage of oogenesis functioned as storage depots for ribosomal RNA.The authors acknowledge the technical assistance of Miss Agnes Cralley. Dr. D. Ammermann, Zoologisches Institut, Tübingen, W. Germany, provided the animals used in this study. — This work was supported in part by a Health Research Services Foundation Grant No. J-1 and in part by U.S.P.H.S. Grant No. 7-FZCA-23,971-O1A1.     

Single extrachromosomal ribosomal rna gene copies are synthesized during amplification of the rDNA in tetrahymena

A novel form of extrachromosomal rDNA has been identified in conjugating Tetrahymena cells. This rDNA consists of 11 kb linear double-stranded DNA molecules, each containing a single rRNA gene copy. The DNA sequence, tandemly repeated CCCCAA (Blackburn and Gall 1978) found at the termini of extrachromosomal palindromic rDNA (the macronuclear form found in vegetatively growing cells), is also present at the corresponding terminus of the 11 kb rDNA. The other end of this molecule has an extra 0.3 kb segment of DNA covalently attached to the DNA region corresponding to the center of the palindromic rDNA. The kinetics of appearance and synthesis of the 11 kb rDNA early in macronuclear development are consistent with its being an intermediate in rDNA amplification.     

The cell cycle of epidermal cells during reprogramming in the pupa of Galleria

The epidermal cell cycle of the pupal mesonotum of Galleria was investigated by the determination of mitotic indices, [³H]thymidine incorporation and flow-cytophotometric analysis during the first 48 h after pupation.Immediately after the pupal ecdysis nearly all epidermal cells are arrested in G2. Thereafter only a few mitoses occur, leading to a slow increase in the number of G1 nuclei. With the onset of a mitotic wave at a pupal age of 21 h this increase becomes more rapid. On day 2, the cell population reaches a plateau in the number of G1 (resp. G2) cells, reflecting a steady state between mitotic activity and DNA synthesis.A comparison of these cell cycle changes with known data of the time course of reprogramming and ecdysteroid titre leads to the conclusion that there is no causal relationship between DNA synthesis and cellular determination in the sense of a quantal cell cycle, and that DNA synthesis can precede the definite rise in ecdysteroid titre.     

Haemolymph ecdysteroid levels and cellular events in the intermoult/moult sequence of Calpodes ethlius

The haemolymph ecdysteroid titre of the last larval and pupal stadia of Calpodes ethlius was determined by radioimmunoassay. During the last larval stadium, four significant ecdysteroid peaks are present, two of which have been reported for other Lepidoptera. The first peak occurs 12 hr after ecdysis and correlates temporally with nucleolar activity, RNA synthesis and organelle formation in the fat body and epidermis. It correlates also with fat body DNA synthesis, polyploidy and the initiation of a low rate of lipid synthesis. Another peak, at 78 hr, starts its increase when the prothoracic glands no longer require the influence of the brain to produce ecdysone for pupation, and marks the first critical period. It correlates with the initiation of epidermal DNA synthesis and mitosis, and with the progressive determination of pupal characteristics (change in commitment, reprogramming). This ecdysteroid peak may also be involved in the massive intermoult syntheses in the epidermis (lamellate cuticle, wax) and the fat body (lipid, protein). The largest ecdysteroid peak is seen at 162 hr, 6 hr after the tissues no longer require the prothoracic glands for pupation (second critical period). It correlates temporally with the cessation of massive synthetic activity in both epidermis and fat body and initiates preparation for pupal synthesis in both tissues. At this time the ratio of ecdysone: 20-hydroxyecdysone is ～ 1 : 6.6.In common with other Lepidoptera, a single large ecdysteroid peak occurs during the first half of the pupal stadium. Comparisons between these events and the ecdysteroid titre are made between Calpodes and other insects.     

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.     

Die Entstehung multipler Oocytennukleolen aus akzessorischen DNS-Körpern bei Gryllus domesticus

The early stages of female and male germ cells have been investigated in Feulgen squash preparations, in unfixed state with phase contrast optics and in the electron microscope. The DNA axes of the ring-shaped multiple nucleoli in the growing oocytes of Gryllus arise from compact DNA bodies which are found in oogonia of young larvae and in oocytes prior to the growth period. The nuclei of the early oogonia contain several little DNA bodies whereas young oocytes at leptotene, zygotene and pachytene have only one body which is bigger than at earlier stages (Pig. 3). At metaphase and anaphase during oogonial mitosis the DNA body has a filamentous shape distinguishable from the compact chromosomes (Fig. 5). In oogonia as well as at leptotene and zygotene stages, nucleoli are produced in the peripheral, uncoiled parts of each DNA body whereas the compact interior is completely free of nucleolar material (Figs. 4, 12). At pachytene, the whole DNA body begins to despiralize, and single DNA strands are released into the nucleoplasm. These strands form hundreds of multiple nucleoli which finally are dispersed in the germinal vesicle (Fig. 11). — Incorporation studies with radio-active thymidine have shown that DNA synthesis in the DNA body is not synchronous with the S-phase of the chromosomes (Fig. 7). — The DNA body is an own formation distinct from the sex chromosomes (in contrast to the opinion of Sotelo and Wettstein, 1964). Although the positive heteropycnotic X-chromosome in the germ cells of the male cricket is very similar to the DNA body of the female (Fig. 8), there is no regular contact between sex chromosome and nucleolus neither in spermatogonia nor in spermatocytes (Figs. 9, 14). In all probability, the site of the nucleolar organizer is autosomal. — It is suggested that the amplification of the nucleolar genes in Gryllus oocytes results in an accumulation of ribosomal RNA for use during the early cleavage stages of the embryo     

PROTEIN AND NUCLEIC ACID METABOLISM IN INSECT FAT BODY

1. The appearance of larval fat body as seen under the light or electron microscope depends on the nutritional state of the larva and on the stage of larval development at which the fat body is observed. 2. Early in the last larval instar the cells usually possess a well-developed endo-plasmic reticulum rich in ribosomes, numerous mitochondria, glycogen granules, a Golgi complex and fat droplets, while later in the instar the endoplasmic reticulum is much reduced and mitochondria are few, but glycogen and fat droplets are present in greater amount together with the appearance of large numbers of proteinaceous spheres. 3. Early in the last instar the fat body synthesizes proteins and exports them into the blood, while later in the instar proteins are sequestered from the blood into the fat body. 4. The rate of protein synthesis by the fat body is high in the early to mid part of the last instar, but then falls off rapidly to a low level, at which it remains until the larva pupates. In diapausing pupae, protein synthesis remains at this low level. 5. The similarity between the electrophoretic patterns of proteins from the fat body and those from the blood provides strong evidence that the fat body is the site of synthesis of many of the blood proteins. 6. Some of the blood proteins have been shown to possess enzymic properties, while others are thought to play a role in the transportation of various types of compounds. 7. Ecdysone and juvenile hormone both stimulate the rate of protein synthesis by larval fat body. Protein synthesis in fat body from diapausing pupae is stimulated after injury to the pupae. 8. The appearance of adult fat body and the amount of protein it contains is often closely linked with the nutritional and reproductive states of the insect. 9. An important role of the fat body in the adult female insect is the synthesis of yolk proteins, which are released into the blood and then taken up by the developing oocytes. This synthesis and uptake are under the control of hormones secreted by the corpora allata and by the median neurosecretory cells of the pars intercerebralis. 10. The RNA content of fat body in final-instar larvae is not constant throughout the instar. In some larvae it is at its highest level early in the instar, falling to a low level as the instar progresses, while in other larvae (e.g. Calliphora) the level of RNA in fat body does not decrease as the instar progresses. 11. In some dipterous insects the base composition of total RNA is DNA-like in that the guanine + cytosine content is low, accounting for 40 % of the bases. A similar composition is seen in rapidly labelled RNA isolated from insects of other orders (Coleoptera and Lepidoptera), but the base content of total RNA from these latter insects resembles ribosomal RNA from vertebrate tissues in that it has a high (ca. 60 %) guanine + cytosine content. 12. The RNA/DNA ratios in blowfly larval tissues are high compared with those found in any vertebrate tissue. 13. In larval fat body, RNA synthesis is low at the time of a moult, increases during the early and mid-instar period and subsequently falls during the latter part of the instar. During the pupal period, especially during pupal diapause, the rate of RNA synthesis is very low and then increases during the subsequent development of the pharate adult. Injury to diapausing pupae results in an increased rate of RNA synthesis in most of their tissues. 14. Ecdysone and juvenile hormone both stimulate RNA and DNA synthesis in larval and adult fat body and in other tissues, although there is evidence that in some tissues these two hormones may act antagonistically to each other. The insecticide DDT also has been shown to stimulate RNA synthesis in tissues of adult insects.     

Hormonal regulation of macromolecular synthesis in testes and accessory reproductive glands of Spodoptera litura during post-embryonic and adult development

In S. litura testicular growth during the last larval instar and early pupal stage is associated with significant increase in DNA, RNA and protein contents. DNA synthesis is stimulated by 20-hydroxyecdysone (20-HE) in the penultimate instar testes. 20-HE injection in ligated late last instars increases the testicular weight and protein content. Accessory reproductive gland (ARG) development takes place during the mid and late pupal stages. Protein synthesis in the pharate adult ARG is stimulated by 20-HE. Juvenile hormone has no effect on ARG protein synthesis.     

Nuclear structures in the ovarioles of the butterfly Laspeyresia pomonella. Sex chromatin in trophocytes

The nuclear structures in the ovarioles have been studied in Laspeyresia pomonella by means of light and electron microscopy, autoradiography (RNA and DNA synthesis) and molecular hybridization in situ. The karyosphere was shown to form in oocyte nuclei at the beginning of oocyte growth. Numerous protein granules appeared in close contact with the karyosphere chromosomes; the true nucleolus was absent and the whole nucleus was inactive in RNA synthesis. A special attention was paid to studying nuclear structures in trophocytes. Numerous complex nucleoli actively synthesizing RNA formed in highly endopolyploid nuclei of trophocytes. Besides, each trophocyte had a spheroid vacuolized body of DNA which developed from one of meiotic bivalents soon after trophocyte differentiation and increased in diameter up to 10-15 mu. The DNA body in trophocytes and follicle cells was in close contact with the nucleolar material. Ribosomal DNA was present in these bodies as was shown by molecular hybridization in situ. A suggestion is put forward to the effect that the DNA bodies take part in the formation of complex nucleolar apparatus of trophocytes. On the basis of both the author's and literary data, a conclusion is drawn that DNA spheres in trophocytes and follicle cells are sex chromatin bodies formed, however, by both the X- and Y-chromosomes, rather than by one Y-chromosome.     

Cytochemical and ultrastructural studies of ribonucleoprotein containing structures in oocytes of Acheta domesticus

Summary Two distinct types of ribonucleoprotein containing structures are found in oocytes of the house cricket, Acheta domesticus, a large secondary or accessory nucleolus and many small primary nucleoli. The secondary nucleolus increases in size during oocyte development and is similar in appearance to the nucleolus of somatic cells. The primary nucleoli are intimately associated with a large, extrachromosomal DNA containing body. The DNA body is no longer visible in nuclei of late diplotene stage cells when the primary nucleoli are dispersed within the nucleoplasm. Both types of nucleoli contain cytochemically detectable RNA and acid protein, little or no DNA and basic protein, and particulate structures similar to but smaller than cytoplasmic ribosomes.The authors acknowledge the technical assistance of Miss Celeste Malinoski and Mrs. Marcia Andrews. This work was supported by a U.S.P.H.S. grant, number GM-16440-01 and grants number L-16 and J-1 from the Health Research Services Foundation.     

Oogenesis in hydra. II. Cytophotometric determination of DNA concentration in the nuclei of somatic and sex cells

During sexual reproduction in Hydra, interstitial cells in the female sex zone of the body (i-cells) undergo mitotic division and form a thickening in the epiderm. The proliferation of i-cells is accompanied by the increase of cytoplasm volume and by the appearance in the cytoplasm of a great number of membranous structures (rough endoplasmic reticulum, Golgi apparatus and mitochondria), enzymatic granules, lipid inclusions and glycogen. All cells of the epidermal thickening soon (in approximately twenty four hours) acquire the characteristics of typical phagocytes. However it is the cell situated inside the group of syncytially connected ones and adjacent to mesogloea that begins to grow rapidly and phagocytize surrounding cells. The cells of the epidermal thickening, though they are often given the name of oogonia, were found to have a tetraploid DNA content in their nuclei. The presence of four unseparated centrioles of equal size suggests that all preparatory processes for division were completed. A conclusion was drawn that cells of the epidermal thickening undergo premeiotic DNA synthesis prior to their phagocytizing by the growing oocyte and, thus, are oocytes themselves. The oogonial stage in Hydra coincides with the early period of mitotic reproduction of i-cells. The data obtained are discussed from the viewpoint of the formation of the accessory gonad apparatus.