Changes in the polyadenylated messenger RNA population during development of Dictyostelium discoideum

The program of gene expression during the life cycle of Dictyostelium discoideum has been assessed by molecular hybridization of cDNA probes with polysomal RNA extracted at the following different stages of development: vegetative growth, interphase (2.5 hr), aggregation (8 hr), postaggregation (12 hr), and preculmination (18 hr). Several different cDNA probes were used. Two probes were prepared from vegetative stage poly(A⁺) RNA, one representing all species present and the other enriched for abundant species. A third cDNA probe was prepared from preculmination stage polysomal RNA and a fourth probe consisted of the preculmination stage cDNA depleted in those species also present at the vegetative stage. Hybridization of the various probes with the different polysomal RNA preparations has revealed developmental changes in the mRNA populations. These changes were not detected in an aggregation less mutant under similar conditions of starvation. Abundant RNA species of vegetative cells were found to drop to low levels, especially during the aggregation period. Fifty percent by mass of the RNA present in polysomes at 18 hr is not present during vegetative growth. Some of the new RNA species appeared during interphase and the remaining during the postaggregation period. A gradual increase in the number of copies per cell of certain RNA species comprising both new species as well as some shared with vegetative cells was observed throughout development. Other results indicated that the composition of polysomal and cytoplasmic RNA is similar during vegetative growth but differs markedly at 18 hr of development. Also, cytoplasmic RNA at 18 hr contained, in addition to polysomal RNA, a large proportion by mass of nonpolysomal RNA similar to vegetative RNA. The number of polysomal RNA species detected by this analysis during vegetative growth and during the preculmination stage were estimated to be 3000 and 3700, respectively. The number of copies of these RNA species ranged between 30 and 2000 per cell during vegetative growth and 3 to 300 per cell in polysomes at 18 hr. Developmentally induced RNAs which were preferentially distributed among abundant and intermediate classes were estimated to number 700–900 species.     

Adenovirus transcription. V. Quantitation of viral RNA sequences in adenovirus 2-infected and transformed cells.

The concentrations, in copies per cell, of viral RNA sequences complementary to different regions of the genome were determined at 8, 18 and 32 hours after infection of human cells with adenovirus type 2: separated strands of fragments of ³²P-labelled adenovirus 2 DNA, generated by cleavage with restriction endonucleases EcoR1, Hpa1 and BamH1, were added to reaction mixtures at sufficient concentrations to drive hybridizations with infected or transformed cell RNA. Under these conditions, the fraction of ³²P-labelled DNA entering hybrid is directly proportional to the absolute amount of complementary RNA in the reaction.At 8 hours after infection in the presence of cytosine arabinoside, “early” viral messenger RNA sequences are present at a frequency of 300 to 1000 copies per cell. The abundance of early mRNA sequences in different lines of adenovirus 2-transformed rat cells is markedly lower than their concentration in lytically infected cells. Moreover, the abundance of early mRNA in a given transformed rat cell line reflects the number of copies of its template DNA sequences per diploid quantity of cell DNA. After the onset of the late phase of the lytic cycle, the abundance of one early mRNA species, that coding for a single-stranded DNA binding protein required for viral DNA replication, is amplified. Viral RNA sequences complementary to regions of the genome coding for other early mRNA sequences remain at the level observed at 8 hours after infection.Exclusively “late” viral mRNA sequences are present over a range of concentrations, 500 to 10,000 copies per cell, depending on the region of the genome. By 18 hours after infection, the nucleus contains approximately three times as much total, viral RNA as the cytoplasm. The abundant nuclear, viral RNA sequences at 18 hours are transcribed from a contiguous region, 65% of the genome in length. In some cases, viral RNA sequences complementary to mRNA sequences are very abundant in the nucleus. When cytoplasmic and nuclear fractions are mixed and incubated under annealing conditions, some mRNA sequences will anneal with more abundant, anti-messenger nuclear RNA sequences to form double-stranded RNA. Such annealing of nuclear, viral RNA to early, cytoplasmic mRNA sequences probably accounts for the inability to detect, by filter hybridization, certain classes of early mRNA sequences during the late stage of infection.     

Synethesis and integration of viral DNA in chicken cells at different time after infection with various multiplicities of avian oncornavirus.

To see if integration of the provirus resulting from RNA tumor virus infection is limited to specific sites in the cell DNA, the variation in the number of copies of virus-specific DNA produced and integrated in chicken embryo fibroblasts after RAV-2 infection with different multiplicities has been determined at short times, long times, and several transfers after infection. The number of copies of viral DNA in cells was determined by initial hybridization kinetics of single-stranded viral complementary DNA with a moderate excess of cell DNA. The approach took into account the different sizes of cell DNA and complementary DNA in the hybridization mixture. It was found that uninfected chicken embryo fibroblasts have approximately seven copies, part haploid genome of DNA sequences homologous to part of the Rous-association virus 2 (RAV-2) genome. Infection with RAV-2 adds additional copies, and different sequences, of RAV -2- specific DNA. By 13 h postinfection, there are 3 to 10 additional copies per haploid genome. This number can not be increased by increasing the multiplicity of infection, and stays relatively constant up to 20 h postinfection, when some of the additional viral DNA is integrated. Between 20 and 40 h postinfection, the cells accumulated up to 100 copies per haploid genome of viral DNA. Most of these are unintegrated. This number decreases with cell transfer, until cells are left with one to three copies of additional viral DNA sequences per haploid genome, of which most are integrated. The finding that viral infection causes the permanent addition of one to three copies of integrated viral DNA, despite the cells being confronted with up to 100 copies per haploid genome after infection, is consistent with a hypothesis that chicken cells contain a limited number of specific integration sites for the oncornavirus genome.     

Variability of DNA Content in Individual Cells of <Emphasis Type="Italic">Bacillus</Emphasis>

THE average content of DNA in Bacillus spores is unaffected by the growth medium and is constant for each species¹. Within the Bacillus group, however, the average amount of DNA per spore varies from species to species¹. A cell of B. cereus contains on average twice as much DNA as the spore and during sporulation this DNA is divided equally between the spore and the sporangium². Estimates^3–5 of genome size vary from 1.3 × 10⁹ to 10 × 10⁹ daltons and the number of genomes per cell from 2 to 4^4–8. Some of these variations may be associated with differences within the cells rather than differences of methodolqgy; spores within a population vary not only in size and shape, but also in their content of stainable chromatin⁹. Moreover, in ‘Renografm’ density gradients¹⁰, spores band within a range of densities. If spores are taken from a narrow part of this range, regrown and rebanded, the original pattern of dispersal occurs, suggesting that spores in the same population normally show variation in density as well as in size (A. I. Aronson, personal communication).     

Identification of capsule-forming Bacillus anthracis spores with the PCR and a novel dual-probe hybridization format.

Anthrax is a fatal infection of humans and livestock that is caused by the gram-positive bacterium Bacillus anthracis. The virulent strains of B. anthracis are encapsulated and toxigenic. In this paper we describe the development of a PCR technique for identifying spores of B. anthracis. Two 20-mer oligonucleotide primers specific for the capB region of 60-MDa plasmid pXO2 were used for amplification. The amplification products were detected by using biotin- and fluorescein-labeled probes in a novel dual-probe hybridization format. Using the combination of PCR amplification and dual-probe hybridization, we detected two copies of the bacterial genome. Because the PCR assay could detect a minimum of 100 unprocessed spores per PCR mixture, we attempted to facilitate the release of DNA by comparing the effect of limited spore germination with the effect of mechanical spore disruption prior to PCR amplification. The two methods were equally effective and allowed us to identify single spores of B. anthracis in PCR mixtures.     

Systematics of the genus Ceratopteris Brongn. (Parkeriaceae) II. Taxonomy

A revision of the genusCeratopteris is presented based on comparative morphology and geographical distribution. Four species are recognized:C. thalictroides, C. cornuta, C. pteridoides, andC. richardii. Characteristics of taxonomic importance include frond length, shape, and dissection; stipe width; insertion of basal pinnae; bud development; habit; annulus cell number; spore number per sporangium; spore size; and spore surface features. Evolution within species and putative hybridization between species are discussed.     

Parasitism of Helicotylenchus lobus by Pasteuria penetrans in Naturally Infested Soil

The population density of Helicotylenchus lobus and the percentage of the population with spores of Pasteuria penetrans were determined for 10 monthly intervals in naturally infested turf grass soil at Riverside, California. The percentage of nematodes with attached spores ranged from 40% to 67%. No relationship was found between nematode density and the percentage of nematodes with spores. The mean and maximum numbers of spores adhering per nematode with at least one spore ranged from 2 to 8 and 7 to 66, respectively. The mean number of spores per nematode (based on total number of H. lobus) was correlated with the percentage of nematodes with spores. Spores adhered to both adult and juvenile H. lobus. Between 9% and 32% of the nematodes with spores had been penetrated and infected by the bacterium. Many infected nematodes were dead, but mature spores were also observed within living adult and juvenile H. lobus that exhibited no apparent reduction in viability and motility. Spore and central endospore diameters of this P. penetrans isolate were larger than those reported for the type isolate from Meloidogyne incognita, but transmission and scanning electron microscopy did not reveal significant morphological differences between the two isolates. Spores of the isolate associated with H. lobus did not adhere to juveniles of M. incognita.     

Quantitative in situ hybridization using initial velocity measurements

In situ hybridization can be used to quantitate viral RNA at the single cell level by measuring levels of hybridization after saturation hybridization with an excess of cDNA probe has been achieved (1,2). In this paper we describe an alternative approach which consists in measuring the initial hybridization rate using a low concentration of cDNA probe and a short hybridization time. Under these conditions, we obtained a linear relationship between the number of autoradiographic grains and the number of viral genomes per cell in the range of 600 to 60,000 copies per cell of a 7-kb RNA genome. This approach allows an accurate measurement of copy number in a range for which saturation in situ hybridization is very difficult to achieve.     

Inter- and intrasporal nuclear ribosomal gene sequence variation within one isolate of arbuscular mycorrhizal fungus, Diversispora sp.

Most molecular ecological studies of arbuscular mycorrhizal fungi (AMF) have been based on the rRNA gene sequences. However, information about intraspecific nucleotide variation is still limited in these fungi. In this study, we calculated the inter- and intrasporal nucleotide variation of Diversispora sp. EE1 using 78 cloned sequences from four spores within a ca 4960 bp fragment of the nuclear ribosomal operon spanning the near full length small ribosomal subunit (SSU) rRNA gene, the full internal transcribed spacer (ITS: ITS1-5.8S-ITS2) and ca 2740 bp of the large ribosomal subunit (LSU) rRNA gene. Data for each marker region (SSU, ITS and LSU) originated from the very same spores. Sequence variation resulting from point mutations and small indels was recorded in all regions. Highest sequence variation was observed in the ITS region at both the inter- and intrasporal levels. The ITS1 component was more variable than ITS2, whilst the 5.8S gene was the least variable component of the ITS region. Evolutionary divergence of gene copies between spores was intermediate for the LSU and lowest for the SSU. The SSU and the LSU genes had relatively similar evolutionary divergence per spore. Sequence variant richness was not exhaustive for any of the marker regions, indicating that multiple sequences per spore from multiple spores are needed when characterizing a species. This study provides reference sequences for ecological studies, permitting identification of AMF using any of the ribosomal regions or primer systems.     

The in vivo production of Bacillus popilliae var. rhopaea spores

The effect of various factors on the yield of Bacillus popilliae var. rhopaea spores formed in Rhopaea verreauxi larvae have been studied. Lack of adequate food, temperatures above and below 23°C, and infecting doses above 10⁶ spore larva, all significantly lowered spore yield per larva. Larval age had a pronounced effect; second-instar and young third-instar larvae produ ed about 1 × 10¹⁰ spores while old third-instar larvae produced about 4 × 10¹⁰ spores. Incubation of larvae for longer than 4 weeks did not increase spore yield per larva. Yields were similar whether larvae were infected by injection or per os. Three other host species could be used to mass-produce B. popilliae var. rhopaea spores but all were less efficient than R. verreauxi. Milky third-instar R. verreauxi larvae, which were field collected, yielded 1.57 × 10¹⁰ spores per larva.     

Formation of the Dictyostelium spore coat

The spore coat forms as a rigid extracellular wall around each spore cell during culmination. Coats purified from germinated spores contain multiple protein species and an approximately equal mass of polysaccharide, consisting mostly of cellulose and a galactose/N-acetylgalactosamine polysaccharide (GPS). All but the cellulose are prepackaged during prespore cell differentiation in a regulated secretory compartment, the prespore vesicle. The morphology of this compartment resembles an anastomosing, tubular network rather than a spherical vesicle. The molecules of the prespore vesicles are not uniformly mixed but are segregated into partially overlapping domains. Although lysosomal enzymes have been found in the prespore vesicle, this compartment does not function as a lysosome because it is not acidic, and a common antigen associated with acid hydrolases is found in another, acidic vesicle population. All the prespore vesicle profiles disappear at the time of appearance of their contents outside of the cell; this constitutes an early stage in spore coat formation, which can be detected both by microscopy and flow cytometry. As an electron-dense layer, the future outer layer of the coat, condenses, cellulose can be found and is located immediately beneath this outer layer. Certain proteins and the GPS become associated with either the outer or inner layers surrounding this middle cellulose layer. Assembly of the inner and outer layers occurs in part from a pool of glycoproteins that is shared between spores, and unincorporated molecules loosely reside in the interspore matrix, a location from which they can be easily washed away. When the glycosylation of several major protein species is disrupted by mutation, the coat is assembled, but differences are found in its porosity and the extractibility of certain proteins. In addition, the retention or loss of proteolytic fragments in the mutants indicates regions of spore coat proteins that are required for association with the coat. Comparative examination of the macrocyst demonstrates that patterns of molecular distributions are not conserved between the macrocyst and spore coats. Thus spore coat assembly is characterized by highly specific intermolecular interactions, leading to saturable associations of individual glycoproteins with specific layers and the exclusion of excess copies to the interspore space.     

Transcription of Simian Virus 40 II. Hybridization of RNA Extracted from Different Lines of Transformed Cells to the Separated Strands of Simian Virus 40 DNA

The amount of simian virus 40 (SV40) DNA present in various SV40-transformed mouse cell lines and “revertants” isolated from them was determined. The number of viral DNA copies in the different cell lines ranged from 1.35 to 8.75 copies per diploid quantity of mouse cell DNA and from 2.2 to 14 copies per cell. The revertants had the same number of viral DNA copies per diploid quantity of mouse cell DNA as their parental cell lines. (However, they showed an increased number of viral DNA copies per cell due to their increased amount of DNA.) By using separated strands of SV40 DNA, the extent of each DNA strand transcribed into stable RNA species was determined for the transformed and “revertant” cell lines. From 30 to 80% of the “early” strand and from 0 to 20% of the “late” strand was present as stable RNA species in the cell lines tested. There was no alteration in the pattern of the stable viral RNA species present in three concanavalin A-selected revertants, whereas in a fluorodeoxyuridine-selected revertant there appeared to be less viral-specific RNA present in the cells.     

The rate of development of a microsporidan in moth cell culture.

A microsporidan parasite of the forest tent caterpillar Malacosoma disstria infected cells and replicated in vitro in a line from the moth Heliothis zea. After spore germination, the incidence of infected cells increased with time until leveling off with sporulation. During the first 24 hr, there was a static number of parasites, followed by a 2-day logarithmic growth phase during which the population doubled five to six times. The growth rate was 9 to 11 hr per population doubling. Sporulation commenced on day 3, and 40 to 50 spores were recovered from each infected cell. The life cycle was completed within 6 days, culminating in spores that were infectious for cultured cells. The antibiotic fumagillin at a dose of 1 ppm in the culture medium was microsporida-static.     

Size matters for violent discharge height and settling speed of Sphagnum spores: important attributes for dispersal potential

Background and Aims

Initial release height and settling speed of diaspores are biologically controlled components which are key to modelling wind dispersal. Most Sphagnum (peat moss) species have explosive spore liberation. In this study, how capsule and spore sizes affect the height to which spores are propelled were measured, and how spore size and spore number of discharged particles relate to settling speed in the aspherical Sphagnum spores.

Methods

Spore discharge and spore cloud development were filmed in a closed chamber (nine species). Measurements were taken from snapshots at three stages of cloud development. Settling speed of spores (14 species) and clusters were timed in a glass tube.

Key Results

The maximum discharge speed measured was 3·6 m s⁻¹. Spores reached a maximum height of 20 cm (average: 15 cm) above the capsule. The cloud dimensions at all stages were related positively to capsule size (R² = 0·58–0·65). Thus species with large shoots (because they have large capsules) have a dispersal advantage. Half of the spores were released as singles and the rest as clusters (usually two to four spores). Single spores settled at 0·84–1·86 cm s⁻¹, about 52 % slower than expected for spherical spores with the same diameters. Settling speed displayed a positive curvilinear relationship with spore size, close to predictions by Stokes'' law for spherical spores with 68 % of the actual diameters. Light-coloured spores settled slower than dark spores. Settling speed of spore clusters agrees with earlier studies. Effective spore discharge and small, slowly settling spores appear particularly important for species in forested habitats.

Conclusions

The spore discharge heights in Sphagnum are among the greatest for small, wind-dispersed propagules. The discharge heights and the slow settling of spores affect dispersal distances positively and may help to explain the wide distribution of most boreal Sphagnum species.