Nuclear DNA content and chromosome numbers in the myxomycete Physarum polycephalum

An improved method is described for making chromosome spreads of the plasmodium of the myxomycete, Physarum polycephalum. It consists of isolating metaphase nuclei, spreading the chromosomes with hot lactic acid, and staining with acetic-orcein.Most sublines derived from the Backus Wis 1 sclerotium had about 1 pg of DNA per nucleus, and had nuclei with 50 and 75 chromosomes in both the growing and sporulating plasmodium. Mature spores contained 0.6 pg of DNA, and hatching amoebae had 20–25 chromosomes and 0.6 pg of DNA. Plasmodia of the homothallic Colonia strain had a nuclear DNA content of about 1 pg, and had 35–40 chromosomes during growth and sporulation. Polyploid plasmodial sublines were found which had 1.5 and 3 times the normal DNA content and chromosome number. The polyploid sublines had the same plasmodial protein:DNA and RNA:DNA ratios as normal cultures. DNA content of nuclei varied directly with nuclear surface area. Ploidy was determined by the parent amoebae and therefore can serve as a genetic marker.A simple technique is given for completing the life cycle of P. polycephalum axenically. Germinating spores are plated without bacteria on one-tenth strength semidefined plasmodial growth medium, containing 2% agar. Plasmodia are visible in 2–4 days.     

Replication of polyoma DNA in isolated nuclei. V. Complementation of in vitro DNA replication.

Nuclei from polyoma-infected 3T6 fibroblasts elongate in vitro the progeny strands of the replicative intermediates of polyoma DNA. When high concentrations of such nuclei were incubated, short DNA fragments were formed and subsequently added onto growing progeny strands. When nuclei were repeatedly washed with buffer containing detergent and then incubated at low concentrations. DNA synthesis was decreased. In particular, the joining process was reduced, resulting in an accumulation of short DNA fragments. All aspects of the synthetic capacity of the nuclei were restored by addition of cytoplasmic extract. Additions of purified enzymes (polynucleotide ligase from calf thymus or Escherichia coli together with E. coli DNA polymerase I) increased the joining function of the nuclei. The system can be used for the identification of the enzymatic steps concerned with polyoma DNA replication.     

The Ascogenous Hyphae of Pyronema confluens

The ascogenous hyphae arise from the oogonium, opposite groupsof nuclei, as minute, enucleate papillae. Nuclei pass into themsingly, rarely two at a time, and a knob-like swelling is formed,containing several nuclei and later growing out into one ormore branches. The nuclei are in single file in the branchesand irregularly arranged in the bulbous base. There are frequentlytwo nuclei in a leading position at the tip of the young branch,but the nuclei may become more evenly spaced as the hypha elongates.The nuclei undergo a simultaneous mitosis. The spindles of thedividing nuclei in the branches are not parallel and this is,therefore, not a conjugate division. Walls are formed as ingrowingrings across the spindles so that the ascogenous hypha, whenseptate, has a uninucleate end cell followed by one, or usuallymore, binucleate cells and a basal bulb containing a variablenumber of nuclei. Croziers are formed as lateral, hooked outgrowths from the binucleatecells. After a simultaneous mitosis of the two nuclei a uninucleateend cell, a binucleate penultimate cell, and a uninucleate stalkcell are formed. Thus, the division in the crozier and thatin the ascogenous hypha are alike. The binucleate cell of the crozier may proliferate to form anothercrozier, or it may form an ascus after the fusion of its twonuclei. The stalk and terminal cell of the crozier may anastomoseand grow out to form a lateral crozier. The chromosome number in the mitosis in the ascogenous hyphais twelve and there are twelve bivalents at the first divisionof meiosis in the ascus. The effect of increasing the illumination of the cultures withan electric lamp in addition to diffuse daylight is to ensurethe further development of all early formed sexual organs, tomake the ascogenous hyphae develop rapidly, to make the lattershort and curved in form with few binucleate cells, and to increasethe tendency towards a period of erect proliferation beforethe formation of the asci and lateral proliferation begin. The bearing of the results on current theories of sexualityin the Ascomycetes is discussed.     

Synchrony of Nuclear Replication in Individual Hyphae of Aspergillus nidulans

The synchrony of nuclear replication in individual, multinucleate hyphae of Aspergillus nidulans has been investigated. Samples were taken from cultures of germinating conidiospores, and the relative frequency of hyphae containing two to eight nuclei was determined. Because the conidiospores are mononucleate, complete synchrony will yield populations of hyphae containing only 2ⁿ nuclei, n being the number of doublings after germination. The appearance of hyphae with total numbers of nuclei other than 2ⁿ will indicate lack of synchrony. The relative frequency of hyphae not having 2ⁿ nuclei will depend on the degree of synchrony in the individual hyphae; numerical aspects of this relation are discussed. In two different strains, replication of the nuclei in any one hypha was highly synchronized when the dry weight doubling time was 1.4 to 1.8 hr. As the doubling time was made longer by changing the nitrogen or carbon source, synchrony was progressively lost. At the slowest growth rate tested, the interval between the division of the fastest and the slowest nucleus equaled 48% of the dry weight doubling time. The active replication of some nuclei in a hypha where other nuclei were resting suggested that nuclear duplication in this eukaryotic organism may be controlled by specific initiators.     

Amplification of the Y chromosome in three murine tumor cell lines transformed in vivo by different human prostate cancers

Summary Conventional and molecular cytogenetic analyses of three murine cancer cell lines that had been induced in male athymic mice by the injection of three different human prostate cancer cell lines revealed selective amplification of the Y chromosome. In particular, analysis of metaphase and interphase nuclei by fluorescence in situ hybridization (FISH) with the mouse Y chromosome-specific DNA painting probe revealed the presence of various numbers of Y chromosomes, ranging from one to eight, with a large majority of nuclei showing two copies (46.5–60.1%). In Interphase nuclei, the Y chromosomes showed distinct morphology, allowing identification irrespective of whether the preparations were treated for 15 min or for 5 h with Colcemid, a chemical known to cause chromosome condensation. However, FISH performed on human lymphocyte cultures with chromosome-specific DNA painting probes other than the Y chromosome did not reveal condensed chromosome morphology in interphase nuclei even after 12 h of Colcemid treatment. Our FISH results indicate that (1) the Y chromosome is selectively amplified in all three cell lines; (2) the mouse Y chromosome number is comparable in both interphase and metaphase cells; (3) the Y chromosome number varies between one and eight, with a large majority of cells showing two or three copies in most interphase nuclei; (4) the condensation of the Y chromosome is not affected by the duration of Colcemid treatment but by its inherent DNA constitution; and (5) the number of copies of the Y chromosome is increased and retained not only in human prostate tumor cell lines but also in murine tumors induced by these prostate tumor cell lines.     

Parental DNA strands segregate randomly during embryonic development of Caenorhabditis elegans

The fate of gamete DNA was followed in the next generation embryos of the nematode C. elegans. Either male worms or spermless hermaphrodites were grown on bromodeoxyuridine-containing E. coli in order to label germ-line DNA. Matings then produced embryos in which only the DNA strands provided by the gametes contained label. This original gamete DNA could be detected during embryonic development by using a fluorescently labeled monoclonal antibody specific to bromodeoxyuridine. Both the number and position of fluorescent spots in the embryo indicate that gamete DNA strands segregate randomly during development. Random segregation of parental DNA strands rules out models of development that invoke chromosome imprinting or immortal DNA strands.     

Mycelial differentiation and spore formation by Streptomyces brasiliensis in submerged culture.

Streptomyces brasiliensis ATCC 23727 showed extensive sporulation when cultured in a liquid medium containing galactose and glutamic acid as carbon and nitrogen sources. Sporogenic hyphae formed under these conditions were morphologically similar and developmentally equivalent to aerial hyphae and metamorphosed into chains of spores by following a sequence of ultrastructural changes similar to that observed during growth on solid media. In addition, our electron microscopy study revealed two previously unrecognized aspects of hyphal development in streptomycetes: the formation of sporogenic hyphae was always preceded by changes in the structure of the nucleoid, and the sheath that characteristically covered these hyphae was not deposited coincidently with wall formation in the apical growing portion of the hypha.     

Ligation and synthesis of chromatin deoxyribonucleic acid in vitro in neuronal, glial and liver nuclei isolated from adult guinea pig

Neuron-rich and glial nuclear preparations and liver nuclei were isolated from adult guinea pigs. These nuclei were incubated to carry out DNA-ligation and -synthesis reactions. Before and after incubation, the sizes of single-standed DNA and DNA-synthesis patterns in single strands were analysed by using alkaline sucrose-density-gradient centrifugation. Isolation of nuclei by cell-fractionation technique shortened chromatin DNA and decreased markedly the number-average molecular weight of DNA strands. Chromatin DNA in neuronal and glial nuclei was ligated at the nicks during incubation in a reaction mixture containing ATP, Mg(2+), dithiothreitol and four deoxyribonucleotides. The number-average molecular weights were estimated to increase 1.1-and 2.1-fold in neuronal and glial nuclei respectively. DNA strands in liver nuclei were shortened during incubation, but elongated under conditions that inhibit deoxyribonuclease. Since the endogenous deoxyribounuclease activity was conspicuously higher in liver nuclei than in neuronal and glial nuclei, the shortening and elongation were thought to depend on the balance between DNA ligase and deoxyribonuclease reactions. DNA synthesis occurred at the gaps in chromatin DNA and about 50% of the total synthesized DNA was found in the shorter strands having 6 to 297 bases in all species of nuclei. Based on these results, it was concluded that in nuclei isolated from non-dividing cells (neurons) and slowly dividing cells (glial and liver cells) DNA-ligation and -synthesis reactions proceeded in parallel at the breaks in single-stranded DNA, which was produced mainly by endogenous deoxyribonuclease during isolation and incubation processes.     

Chromosomal Evidence on the Sporogony of Amblyospora californica (Microspora: Amblyosporidae) in Culex tarsalis (Diptera: Culicidae)

ABSTRACT. Amblyospora californica is a polymorphic, eukaryotic microsporidian. Three types of sporogony producing three types of spores occur in male larvae and female adults of its mosquito host, Culex tarsalis , and an alternate copepod host, Acanthocyclops vernalis. Development of A. californica in male larvae includes merogony and sporogony. Karyogamy and meiosis was observed in sporogony in male larvae but not in the female adult or in the copepod. Chromosomal evidence showed that sporogony included two consecutive meiotic divisions and a subsequent mitosis forming an octosporont, ultimately containing eight haploid, uninucleate mature spores. In this species, the haploid number of chromosomes is nine. Macrosporoblasts and macrospores, containing 1, 2 or more nuclei, can be seen in infected male larvae. The stage of sporogony in which cytokinesis was arrested seems to determine the number of nuclei. Those with only one nucleus, we believe are due to failed nuclear division at meiosis. Although A. californica displayed a process of karyogamy and meiosis similar to that of the species from Cx. salinarius , they may not be the same species because of the difference in their chromosome numbers.     

Deoxyribonuclease I produces staggered cuts in the DNA of chromatin

The relationship of cuts made by deoxyribonuclease I (DNase I, EC. 3.1.4.5) on the two strands of DNA of chromatin has been investigated. DNA was extracted from a DNase I digest of rat liver nuclei and incubated with the large fragment of DNA polyrnerase I. Analysis of the products of this incubation indicates the cuts made by DNase I on opposite strands are staggered with respect to one another. A cut on one strand is about two bases in the 3′ direction or eight bases in the 5′ direction from the position on its own strand which is directly across from the cut on the other strand. A different result is obtained when a DNase I digest of native DNA is analyzed. Current models for the organization of DNA in the nucleosome are discussed with respect to these results.     

A rapid method to identify cosmids containing rare restriction sites.

A procedure for identifying specific cosmid clones containing recognition sites for "rare cutting" restriction enzymes has been developed. Cosmid clones containing human inserts were selected by hybridisation to human repetitive DNA. An oligonucleotide corresponding to the NotI recognition site, eight bases long, was labelled and used to probe DNA samples from one hundred cosmids. By optimising the difference in melting characteristics between eight-base perfect match and six-base match/two base mismatch hybrids, we were able to detect the cosmids containing either NotI (8 bp match) or XmaIII/EagI (6 bp match) sites. The generation of a map for rare cutter sites along a human chromosome, or a chromosome region, should be simplified using this approach, which will enable the identification of a set of "milestones" at intervals of several hundred kilobases (kb) along the DNA sequence.     

Differential DNase I sensitivity of the two complementary nucleosomal DNA strands in cycloheximide-treated Ehrlich ascites tumor cells

The accessibility of the two complementary DNA strands in newly replicated chromatin of Ehrlich ascites tumor (EAT) cells grown under conditions of cycloheximide-inhibited protein synthesis was studied by analysis of the DNase I digestion of isolated nuclei. Bulk DNA was labeled with 14C-thymidine and the newly synthesized strands - with bromodeoxyuridine and 3H-thymidine. The DNase I digests were fractionated in two successive CsCl density gradient centrifugations to obtain a dense fraction containing 15-20% newly replicated DNA. Analysis of the distribution of 14C-labeled parental DNA fragments complementary to the 3H-nascent strand has shown that the 14C-labeled fragments prevail in the region of 30-50 nucleotides. Simulation experiments using the rate constants for DNase I attack show that this result may be explained by an enhanced accessibility at the nucleosomal 5'-end region of the parental strands, where the H2a-H2b dimer interacts with DNA. This asymmetry seems to be induced by interactions in the chromatin.     

Metakaryotic stem cell nuclei use pangenomic dsRNA/DNA intermediates in genome replication and segregation

Bell shaped nuclei of metakaryotic cells double their DNA content during and after symmetric and asymmetric amitotic fissions rather than in the separate, pre-mitotic S-phase of eukaryotic cells. A parsimonious hypothesis was tested that the two anti-parallel strands of each chromatid DNA helix were first segregated as ssDNA-containing complexes into sister nuclei then copied to recreate a dsDNA genome. Metakaryotic nuclei that were treated during amitosis with RNase A and stained with acridine orange or fluorescent antibody to ssDNA revealed large amounts of ssDNA. Without RNase treatment metakaryotic nuclei in amitosis stained strongly with an antibody complex specific to dsRNA/DNA. Images of amitotic figures co-stained with dsRNA/DNA antibody and DAPI indicated that the entire interphase dsDNA genome (B-form helices) was transformed into two dsRNA/DNA genomes (A-form helices) that were segregated in the daughter cell nuclei then retransformed into dsDNA. As this process segregates DNA strands of opposite polarity in sister cells it hypothetically offers a sequential switching mechanism within the diverging stem cell lineages of development.     

Metakaryotic stem cell nuclei use pangenomic dsRNA/DNA intermediates in genome replication and segregation

Bell shaped nuclei of metakaryotic cells double their DNA content during and after symmetric and asymmetric amitotic fissions rather than in the separate, pre-mitotic S-phase of eukaryotic cells. A parsimonious hypothesis was tested that the two anti-parallel strands of each chromatid DNA helix were first segregated as ssDNA-containing complexes into sister nuclei then copied to recreate a dsDNA genome. Metakaryotic nuclei that were treated during amitosis with RNase A and stained with acridine orange or fluorescent antibody to ssDNA revealed large amounts of ssDNA. Without RNase treatment metakaryotic nuclei in amitosis stained strongly with an antibody complex specific to dsRNA/DNA. Images of amitotic figures co-stained with dsRNA/DNA antibody and DAPI indicated that the entire interphase dsDNA genome (B-form helices) was transformed into two dsRNA/DNA genomes (A-form helices) that were segregated in the daughter cell nuclei then retransformed into dsDNA. As this process segregates DNA strands of opposite polarity in sister cells it hypothetically offers a sequential switching mechanism within the diverging stem cell lineages of development.     

Metakaryotic stem cell lineages in organogenesis of humans and other metazoans

A non-eukaryotic, metakaryotic cell with large, open mouthed, bell shaped nuclei represents an important stem cell lineage in fetal/juvenile organogenesis in humans and rodents. each human bell shaped nucleus contains the diploid human DNA genome as tested by quantitative Feulgen DNA cytometry and fluorescent in situ hybridization with human pan-telomeric, pan-centromeric and chromosome specific probes. From weeks ∼5–12 of human gestation the bell shaped nuclei are found in organ anlagen enclosed in sarcomeric tubular syncytia. Within syncytia bell shaped nuclear number increases binomially up to 16 or 32 nuclei; clusters of syncytia are regularly dispersed in organ anlagen. Syncytial bell shaped nuclei demonstrate two forms of symmetrical amitoses, facing or “kissing” bells and “stacking” bells resembling separation of two paper cups. Remarkably, DNA increase and nuclear fission occur coordinately. Importantly, syncytial bell shaped nuclei undergo asymmetrical amitoses creating organ specific ensembles of up to eight distinct closed nuclear forms, a characteristic required of a stem cell lineage. Closed nuclei emerging from bell shaped nuclei are eukaryotic as demonstrated by their subsequent increases by extra-syncytial mitoses populating the parenchyma of growing anlagen. From 9–14 weeks syncytia fragment forming single cells with bell shaped nuclei that continue to display both symmetrical and asymmetrical amitoses. These forms persist in the juvenile period and are specifically observed in bases of colonic crypts. Metakaryotic forms are found in organogenesis of humans, rats, mice and the plant Arabidopsis indicating an evolutionary origin prior to the divergence of plants and animals.     

Cleavage of DNA in nuclei and chromatin with staphylococcal nuclease.

Treatment of either rat liver chromatin or intact nuclei with the enzyme staphylococcal nuclease results in the conversion of about half of the DNA to acid-soluble oligonucleotides. As previously described, mild digestion of nuclei results in the liberation of a series of nucleoprotein particles containing DNA fragments which are all integral multiples of a unit length DNA 185 base pairs in length. Analysis of the kinetics of appearance of these fragments suggests that at least 85% of the nuclear DNA is involved in the formation of the repeating subunit profile. More extensive digestion of nuclei however results in the generation of a series of eight unique DNA fragments containing 160 to 50 base pairs. The series of smaller molecular weight DNA is virtually identical with the profile obtained upon limit digestion of isolated chromatin. By velocity centrifugation we have obtained highly purified preparations of the monomeric nucleoprotein particle. Digestion of this monomeric subunit results in the solubilization of 46% of the DNA and analysis of the resistant DNA again reveals the set of eight lower molecular weight fragments. These data suggest that the initial site of nuclease cleavage in chromatin resides within the DNA bridging the repeating monomeric subunits. Further attack results in cleavage at a set of sites within the monomer liberating a pattern of smaller DNA fragments which probably represents the points of intimate contact between the histones and DNA.     

Metakaryotic stem cell lineages in organogenesis of humans and other metazoans

A non-eukaryotic, metakaryotic cell with large, open mouthed, bell shaped nuclei represents an important stem cell lineage in fetal/juvenile organogenesis in humans and rodents. Each human bell shaped nucleus contains the diploid human DNA genome as tested by quantitative Feulgen DNA cytometry and fluorescent in situ hybridization with human pan-telomeric, pan-centromeric and chromosome specific probes. From weeks ~5-12 of human gestation the bell shaped nuclei are found in organ anlagen enclosed in sarcomeric tubular syncytia. Within syncytia bell shaped nuclear number increases binomially up to 16 or 32 nuclei; clusters of syncytia are regularly dispersed in organ anlagen. Syncytial bell shaped nuclei demonstrate two forms of symmetrical amitoses, facing or “kissing“ bells and "stacking" bells resembling separation of two paper cups. Remarkably, DNA increase and nuclear fission occur coordinately. Importantly, syncytial bell shaped nuclei undergo asymmetrical amitoses creating organ specific ensembles of up to eight distinct closed nuclear forms, a characteristic required of a stem cell lineage. Closed nuclei emerging from bell shaped nuclei are eukaryotic as demonstrated by their subsequent increases by extra-syncytial mitoses populating the parenchyma of growing anlagen. From 9–14 weeks syncytia fragment forming single cells with bell shaped nuclei that continue to display both symmetrical and asymmetrical amitoses. These forms persist in the juvenile period and are specifically observed in bases of colonic crypts. Metakaryotic forms are found in organogenesis of humans, rats, mice and the plant Arabidopsis indicating an evolutionary origin prior to the divergence of plants and animals.     

Coordinated leading and lagging strand synthesis during SV40 DNA replication in vitro requires PCNA

Proliferating cell nuclear antigen (PCNA) is a cell cycle and growth regulated protein required for replication of SV40 DNA in vitro. Its function was investigated by comparison of the replication products synthesized in its presence or absence. In the completely reconstituted replication system that contains PCNA, DNA synthesis initiates at the origin and proceeds bidirectionally on both leading and lagging strands around the template DNA to yield duplex, circular daughter molecules. In contrast, in the absence of PCNA, early replicative intermediates containing short nascent strands accumulate. Replication forks continue bidirectionally from the origin, but surprisingly, only lagging strand products are synthesized. Thus two stages of DNA synthesis have been defined, with the second stage requiring PCNA for coordinated leading and lagging strand synthesis at the replication fork. We suggest that during eukaryotic chromosome replication there is a switch to a PCNA-dependent elongation stage that requires two distinct DNA polymerases.     

Nuclear structures in the telotrophic ovarioles of nocturnal ground beetles (Tenebrionidae, Polyphaga). III. The oocyte nucleus. Electron microscopic data]

The fine structural organization of nuclei was studied in the growing oocytes of Blaps lethifera, B. mortisaga and Gnaptor spinimanus. In the beginning of diplotene the nuclei contain primary fibrillar nucleoli and numerous electron dense globules dispersed all over the nucleus; the loose chromosome material (lampbrush chromosomes) is distributed all over the nucleus. With the oocyte growth the chromosomes are spiralized and join into the karyosphere. A capsule of fibrous material forms around the karyosphere. The karyosphere nucleoli appear on the chromosomes and, then, move to the capsule region and outside its limits, to the nuclear envelope. They are fibrillar and non-active with respect to RNA synthesis. The fibrous material of the capsule is represented by strands which consist of bundles of cross-striated filaments. These latter contact directly with the chromosomes in the karyosphere and with the surface of the karyosphere nucleoli. The fibrillar-granular bodies are distributed along the strands in the capsule; they contain both RNA and DNA. The nature of extrachromosomal DNA in the karyosphere capsule and its participation in the formation of the capsule material are discussed. A suggestion is put forward on the similarity of the capsule strands with the modified central elements of synaptinemal complex.     

Corn Smut Dikaryon in Culture

A TYPICAL smut life cycle has three phases—diploid, haploid and dikaryon¹. Diploid spores (teliospores) formed in the host tissue are a resting phase. They undergo meiosis at germination to form haploid vegetative cells which are usually yeast-like. The dikaryon is the pathogenic phase and is made up of cells with two haploid nuclei. It is initiated by the fusion of two compatible non-pathogenic haploid cells and the formation of an infection hypha by the fusion product.