Nuclear genome characterization of the carrageenophyteAgardhiella subulata (Rhodophyta)

DNA reassociation kinetics were used to determine nuclear genome organization and complexity inAgardhiella subulata (Gigartinales, Rhodophyta). Results indicate the presence of three second-order components corresponding to fast (22%), intermediate (68%) and slow (10%) fractions. Thus, the genome consists of 90% repetitive sequences. Microspectrophotoometry with the DNA-localizing fluorochrome DAPI was used to confirm ploidy level differences in the gametophytic and tetrasporophytic phases. Results indicate that meiosis occurs during tetrasporogenesis. Comparison of mean nuclear DNA (I_f) values to chicken erythrocytes (RBC) resulted in an estimate of 0.9 pg/2C genome forAgardhiella. Karyological studies using aceto-orcein revealed a chromosome complement of 2N = 44 in carposporangia and the presence of 22 bivalents during diakinesis of tetraspore mother cells.     

Nuclear DNA content and separation of Nicotiana sylvestris vegetative and generative nuclei at various stages of male gametogenesis

At all stages of male gametogenesis, generative and vegetative pollen nuclei of Nicotiana sylvestris can be distinguished without ambiguity after Feulgen or ethidium bromide staining. They differ by their morphology and their apparent DNA content, always lower in vegetative nuclei. These differences provide a basis for their separation by sedimentation and fluorometry. After elimination of the another somatic cells and after crushing the pollen, vegetative and generative nuclei are separated by two successive Percoll gradients (purity 80–90%). Analysis of the gradient fractions and final purification can be done with a cell sorter. DNAs of both types are isolated by a cetyltrimethylammonium method, followed by a RNase treatment. Yields are lower for vegetative than for generative nuclei, and decrease with the age of pollen. Molecular weights and digestibility by restriction enzymes are compatible with molecular analyses.     

Evidence for Chromosomal Macronuclear Substructures in Tetrahymena*†

SYNOPSIS.
Under the growth conditions employed, the G₁ macronucleus of Tetrahymena pyriformis HSM contains 7.4 × 10^-12 g DNA, the G₂ micronucleus 0.42 × 10^-12 g. DNA content from the Tetrahymena thermophila macronucleus did not significantly differ from that of HSM, but the micronucleus contained about twice as much DNA as the micronucleus of the HSM cells. The T. thermophila macronucleus contained on average enough DNA for ˜ 35 haploid micronuclear copies. A new spreading technic allowed separation of macronuclear substructures from cells of late G₂ to early G₁. Photometric determination of DNA content of 345 individual structures suggested the existence of 5 different-sized macronuclear structures with a DNA content corresponding to 2, 4, 8, and 16 × the basic values. Comparison of the DNA content of these structures with (a) mitotic micronuclear chromosomes and (b) meiotic micronuclear chromosomes of T. thermophila cells suggests that the 5 basic values of macronuclear structures derive from structures of micronuclear chromosomes. The micronuclear chromosomes of T. pyriformis may be oligotenic. It is suggested that these results further our understanding of macronuclear organization.     

Endopolyploidy inHelianthus annuus (Asteraceae), A scanning cytophotometric study

Endopolyploidy has been detected in some varieties ofHelianthus annuus L. (Asteraceae/Compositae) by means of scanning photometry of Feulgen-stained nuclei and analysis of nuclear structure. In the hypocotyl cells of seedlings, ploidy levels reach respectively 8 C and 16 C in different varieties, in the root cells 8 C and 16 C; in the cotyledons of ripening seeds 4 C to 8 C values have been found, while all nuclei of the inflorescence axis of one variety exhibit a DNA content of 4 C.—This is the first report of endopolyploidy in a non-succulentAsteraceae species. The characteristic distribution of the endopolyploidy levels in different varieties suggests a strong genetic and/or hormonal control of the final nuclear DNA content in differentiated cells.     

Chromosome numbers, karyotypes and nuclear DNA contents from perennial polyploid groups ofCerastium (Caryophyllaceae)

Somatic chromosome numbers have been determined for the followingCerastium taxa:C. eriophorum (2n = 36),C. alpinum (2n = 72),C. transsylvanicum (2n = 108),C. arcticum (2n = 108),C. latifolium (2n = 36),C. carinthiacum (2n = 36),C. banaticum (2n = 36),C. arvense subsp.glandulosum (2n = 36),C. arvense subsp.arvense (2n = 72) andC. fontanum (2n = 144). Karyotypes of three diploid species (C. eriophorum, C. banaticum andC. latifolium), belonging to three different taxonomic groups, were analysed and found to be similar. The relative nuclear DNA contents of all taxa were determined by flow cytometry and, for five species, also by Feulgen cytophotometry. The values obtained by the two methods are similar. A comparison of nuclear DNA contents among diploids shows that values differ significantly between different taxonomic groups, and are correlated with average chromosome size. Within closely related polyploid groups nuclear DNA amounts increase from 2x- to 4x- and 6x taxa as 1 : 1.4 : 2.4 in theC. alpinum complex, whereas DNA amounts are doubled comparing 2x- and 4x-subspecies in theC. arvense complex.     

Patterns of genome size in the copepoda

Adult somatic nuclear DNA contents are reported for eleven cyclopoid species (Megacyclops latipes, Mesocyclops edax, M. longisetus, M. ruttneri, M. leuckarti, M. woutersi, Macrocyclops albidus, Cyclops strenuus, Acanthocyclops robustus, Diothona oculata, Thermocyclops crassus) and for the harpacticoid Tigriopus californicus and range from 0.50 to 4.1 pg DNA per nucleus. These diploid genome sizes are consistent with previously published values for four Cyclops species (0.28–1.8 pg DNA per nucleus), but are strikingly smaller than those reported for marine calanoids (4.32–24.92 pg DNA per nucleus). We discuss three explanations, none of them exclusive of another, to account for the smaller size and range of cyclopoid genome sizes relative to calanoid genome sizes: (1) higher prevalence of chromatin diminution in the Cyclopoida, (2) phylogenetic structure or older age of the Calanoida relative to Cyclopoida and (3) nucleotypic selection that may influence life history variation and fitness. Measurements of genome size were made on Feulgen stained, somatic cell nuclei, using scanning microdensitometry which is well suited to the sparse and heterogeneous populations of copepod nuclei. The importance of measuring large numbers of nuclei per specimen, possible sources of variation associated with cytophotometric measurements, and appropriate use of internal reference standards and stoichiometry of the Feulgen stained nuclei are discussed.     

Items from the Literature

LIPP, WALTHER. Histochemische Methoden. Twenty-four pages per issue; 3 issues (No. 12, 13 and 14) during 1957. R. Oldenbourg, Miinchen 1, Germany. DM 30-for 6 issues; DM 6—per single copy. (In German)

STACH, E. Auflicht-Mikroslcopie mit Immersions-Kappen. Mikroskopie, 12, 232-42. 1957.

JOHNSON, C. Time savers in the paraffin technique. Turtox News, 36, 126-7. 1958.

JONSSON, N., and LAGERSTEDT, S. Losses of nucleic acid derivatives from fixed tissues during flattening of paraffin sections on water. Experientia, 14, 157-9. 1958.

SCHAUMKELL, K. W., STANGE, H. H., and DÖRFFLER, P. Methodische Untersuchungen über die pH-abhängige Aufname saurer und basischer Hellfeld-Diachrome in der Nebennierenrinde. Mikroskopie, 12, 227-32. 1957.

SCHEFTHALER, MARIA, and MAYET, A. Eine Modification der Bielschowsky Methode für periphere Nervenfasern. Mikroskopie, 12, 298-801. 1958.

LANGENBUCH, R. Beitrag zur Färbung von Einschluszkörpern (Polyedern) in Blut- und Gewebeausstrichen viruskranker Insecten. Mikroskopie, 12, 267-8. 1957.

SHUGAR, D., and BARANOWSKA, J. Quantitative Gram staining with labelled iodine. Nature, 181, 357-8. 1958.

ARVY, L., and GABE, M. Comparison des activitiés aliestérasique mises en évidence par les techniques au tween et a l'acétate de naphthyle. Ann. d'Histochimie, 2, 141-8. 1957.

VERNE, J., and WEGMANN, R. Problèmes actuels de la cytochimie des estérases (carboxyl estérases and cholinestérases). Ann. d'Histochimie, 2, 75-107. 1957.

WEGMANN, R. Les carbonyles lipidiques. III. Les facteurs associés au prétraitement. Ann. d'Histochimie, 2, 197-214. 1957.     

Nuclear DNA changes within Helianthus annuus L.: origin and control mechanism

Summary Previous results suggested that the amount of nuclear DNA varies in one and the same progeny of Helianthus annuus, depending on the head portion in which seeds have developed. Accordingly, cytophotometric determinations were carried out in a selfed line, after Feulgen-staining, to obtain information on the developmental stages at which DNA changes are produced and on the mechanism controlling the variation. It was found that the Feulgen absorption values of mitotic prophases in immature anthers and pistils and of meiotic prophases I are the same in any flower of the head. In contrast, the Feulgen/DNA contents of early prophases in heart-shaped embryos differ significantly, increasing from those developing at the centre of the head to those developing at its periphery, and remaining unchanged in each embryo during further development and seed germination. Variations in the number of chromosomes do not account for the differences observed in nuclear DNA contents in which sequences comprised in heterochromatic nuclear regions are involved. The Feulgen absorption values of seedlings obtained from seeds developed in different portions of single heads increase or diminish starting from those found in the mother plant. This depends on whether these latter are relatively low or high and on the gradient of seed location in the head. The variation occurring within each single progeny covers the whole range existing within the line.     

Periodicity of cambial activity in Abies balsamea. II. Effects of temperature and photoperiod on the size of the nuclear genome in fusiform cambial cells

Previously, we showed that the size of the nuclear genome, measured cytophotometrically in Feulgen-stained fusiform cambial cells of Abies balsamea (L.) Mill., oscillates annually between a maximum in spring and a minimum in late summer, the labile, extra DNA being synthesized during the fall. To determine it the oscillation is induced by the concomitant seasonal changes in temperature and photoperiod, genome size was measured in cambial cells obtained from one-year-old branches of 6-year-old potted trees at the beginning and end of 9 weeks of exposure during the fall, spring and summer to either the natural environment or one of 4 controlled environments, viz. (1) WS, warm temperature (24/20°C in day/night) and short photoperiod (8 h). (2) WL, warm temperature (24/20°C) and long photoperiod (8 h + 1 h night break), (3) CS, cold temperature (9/5°C) and short photoperiod (8 h). and (4) CL, cold temperature (9/5°C) and long photoperiod (8 h + 1 h night break). Overall, genome size (2C) varied between 20 and 34 pg. In the fall, when the cambium was initially dormant, the genome size increased in the natural environment, did not change under short days (WS and CS), and decreased under long days (WL and CL). The cambium reactivated in both WS and WL conditions. In the spring, while the cambium reactivated, the size of the genome decreased in the natural, WS and WL conditions, but not in the CS environment. In the CL conditions, the genome size started to decrease at the end of the 9-week exposure period. The decrease apparently occurred between prophase and telophase, which suggests that the extra DNA is extrachromosomal. In the summer, while the cambium ceased activity, the genome size did not change in the WS, WL and natural environments, whereas it decreased in the CS and CL conditions. The results indicate that increasing temperature and lengthening photoperiod in the spring induce the loss of the extra DNA. However, the environmental conditions that promote DNA synthesis in the fall remain unknown. Genome size varied independently of cambial growth potential and frost hardiness measured previously in the same experimental trees, indicating that the regulation of these processes does not directly involve the extra DNA. However, the finding that cambial cells cycled in the CS and CL environments only in the spring, when their genome size was large, suggests that the extra DNA is important for cambial growth at low temperatures.     

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.