Characterization of the nuclear genome of pearl millet.

The nuclear genome of pearl millet has been characterized with respect to its size, buoyant density in CsCl equilibrium density gradients, melting temperature, reassociation kinetics and sequence organization. The genome size is 0.22 pg. The mol percent G + C of the DNA is calculated from the buoyant density and the melting temperature to be 44.9 and 49.7%, respectively. The reassociation kinetics of fragments of DNA 300 nucleotides long reveals three components: a rapidly renaturing fraction composed of highly repeated and/or foldback DNA, middle repetitive DNA and single copy DNA. The single copy DNA consists of 17% of the genome. 80% of the repetitive sequences are at least 5000 nucleotide pairs in length. Thermal denaturation profiles of the repetitive DNA sequences show high Tm values implying a high degree of sequence homogeneity. About half of the single copy DNA is short (750--1400 nucleotide paris) and interspersed with long repetitive DNA sequences. The remainder of the single copy sequences vary in size from 1400 to 8600 nucleotide pairs.     

Satellite DNA specific to knob heterochromatin inCucumis metuliferus (Cucurbitaceae)

Buoyant density gradient analysis of nuclear DNA of fourCucumis species showed asymmetric profiles indicating the presence of satellite DNA sequences in the nuclear genome. A highly repeated satellite DNA sequence was isolated from the nuclear genome ofC. metuliferus under neutral CsCl gradients. The satellite DNA constitutes about 4.96% of total nuclear DNA and has 48.06% guanine plus cytosine content. The kinetic complexity of satellite DNA is 150 times smaller than T₄ phage DNA and the base sequence divergence is low.³H-labeled cRNA transcribed from satellite DNA hybridized clearly to six heterochromatic knobs of pachytene chromosomes. The knob heterochromatin can be distinguished by Giemsa C-banding of pachytene chromosomes. Restriction enzyme analysis and Southern blot hybridization indicated that the satellite DNA has a tandem arrangement and predominantly formed two bands of size 210 and 151 base pairs. Absence of knob satellite DNA ofC. metuliferus in the nuclear genomes ofC. melo, C. anguria andC. sativus showed thatC. metuliferus remains isolated within the genusCucumis.     

Genome complexity of the maize rust fungus,Puccinia sorghi

The base composition and complexity of genomic DNA fromPuccinia sorghi have been estimated by thermal denaturation, analytical ultracentrifugation, and reassociation kinetics. The buoyant density of genomic DNA in CsCl was found to be 1.7021 g/ml, which corresponds to a GC content of 43%. From thermal denaturation curves the GC content was estimated to be 41%. The haploid genome size ofP. sorghi was estimated to be 4.7 × 10⁷ bp, half of which represented a moderately repetitive fraction. The size of theP. sorghi genome is similar to that of other basidiomycete fungi; however, the amount of repetitive DNA is greater than that reported for most other fungi.     

Replication process of the parvovirus H-1. VIII. Partial denaturation mapping and localization of the replication origin of H-1 replicative-form DNA with electron microscopy.

Partial denaturation mapping, restriction endonuclease digestion, and electron microscopy were used to determine which end of the linear duplex replicative-form (RF) DNA molecule contains the origin of RF replication for the parvovirus H-1. This origin was localized within approximately 300 base pairs of the arbitrarily designated right end of the RF DNA, in the EcoRI or HaeII-A fragment. Based on denaturation behavior in formamide, the right end was also found to have a relatively high guanine plus cytosine content, whereas the region adjacent to the left terminus of the RF DNA molecule was adenine plus thymine rich.     

Genome size and complexity of the obligate fungal pathogen,Bremia lactucae

The size and organization of the genome of Bremia lactucae, a highly specialized fungal pathogen of lettuce, has been characterized using dot blot genomic reconstructions, reverse genomic blots, and genomic DNA reassociation kinetics. The haploid genome contains 5 × 10⁷ bp of DNA and 65% of the nuclear DNA is repeated. Low copy sequences are interspersed with repeated sequences in a short-period interspersion pattern. This pattern of genome organization is different to that described for other fungi. Although most fungi have been shown to contain some form of repetitive DNA other than the ribosomal repeat, the high percentage of repetitive DNA and the interspersion of low copy and repeated sequences are atypical of fungi characterized previously.     

Contrasting patterns of DNA sequence arrangement in Apis mellifera (Honeybee) and Musca domestica (housefly)

We have examined the organization of the repeated and single copy DNA sequences in the genomes of two insects, the honeybee (Apis mellifera) and the housefly (Musca domestica). Analysis of the reassociation kinetics of honeybee DNA fragments 330 and 2,200 nucleotides long shows that approximately 90% of both size fragments is composed entirely of non-repeated sequences. Thus honeybee DNA contains few or no repeated sequences interspersed with nonrepeated sequences at a distance of less than a few thousand nucleotides. On the other hand, the reassociation kinetics of housefly DNA fragments 250 and 2,000 nucleotides long indicates that less than 15% of the longer fragments are composed entirely of single copy sequences. A large fraction of the housefly DNA therefore contains repeated sequences spaced less than a few thousand nucleotides apart. Reassociated repetitive DNA from the housefly was treated with S1 nuclease and sized on agarose A-50. The S1 resistant sequences have a bimodal distribution of lengths. Thirty-three percent is greater than 1,500 nucleotide pairs, and 67% has an average size about 300 nucleotide pairs. The genome of the housefly appears to have at least 70% of its DNA arranged as short repeats interspersed with single copy sequences in a pattern qualitatively similar to that of most eukaryotic genomes.     

Kinetic Complexity, Homogeneity, and Copy Number of Chloroplast DNA from the Marine Alga Olisthodiscus luteus

The kinetic complexity of chloroplast DNA isolated from the chromophytic alga Olisthodiscus luteus has been determined. Using optical reassociation techniques, it was shown that the plastid DNA of this alga reacted as a single component with a second order rate constant of 4.1 molar⁻¹ and second⁻¹ (Cot_½ 0.24 molar second) under conditions equivalent to 180 millimolar Na⁺ and 60°C. Given the 92 × 10⁵ dalton complexity calculated for this chloroplast genome, an Olisthodiscus cell contains 650 plastome copies. Although this complement remains constant throughout the growth cycle of the organism, the ploidy level of an individual chloroplast shows significant plasticity and is dependent upon the number of chloroplasts present per cell. Experiments with the DNA fluorochrome Hoechst dye 33258 (bisbenzimide) demonstrate that plastids isolated from all phases of cell growth each possess a ring-shaped nucleoid containing detectable DNA. Olisthodiscus chloroplast DNA showed no sequence mismatch when thermal denaturation profiles of reassociated chloroplast DNA were examined, thus all plastome copies are essentially identical. Finally, reassociation studies demonstrated that no foldback (short inverted repeat) sequences were present in the plastid genome although significant hairpin loop structures were observed in control nuclear DNA samples.     

Chromosomal DNA denaturation and reassociation in situ.

The degree of chromosomal DNA (cDNA) denaturation and renaturation on polytene chromosomes has been measured by UV microspectrophotometry. Also DNA losses occurring upon denaturation have been quantified by Feulgen, gallocyanin-chromalum and UV. It has been observed that denaturation in alkali (0.07 N NaOH at room temperature) and formamide (90% formamide; 0.1 SSC, pH 7.2) at 65 °C removes about 30% of the DNA. Low DNA loss occurs upon denaturation in HCl (0.24 M) at room temperature and 60% formamide: 2 × 10^?4 M EDTA (pH 8) at 55 °C. The presence of 4% formaldehyde in the denaturation buffer prevents DNA loss. After denaturation of chromosomes in 0.1 × SSC containing 4% formaldehyde at 100 °C for 30 sec, an hyperchromicity of 39 °C is observed. The denaturation efficiency varies with the denaturation treatment. The percentage reassociation was measured from the difference in the UV absorption of renatured chromosomes and that of denatured chromosomes from the same set. It seems that in our conditions DNA:DNA reassociation does not occur. The efficiency of hybridization is proportional to the denaturation extent of the DNA. However, the entire fraction of DNA which has been denatured is not available for hybridization.     

Differentiation of metaxylem cell line in the root ofAllium cepa

Summary The first step of differentiation in the root segments ofAllium cepa containing metaxylem cells in different stages of differentiation were studied by DNA reassociation curves and compared to meristem cell extracted DNA. Upon sonication of DNA samples to about 400 base pairs, the reassociation profiles of the heat denatured DNA, were spectrophotometrically followed at two different concentrations. The kinetic complexities,i.e., the number of base pairs per haploid genome of a given sequence and its redundancy were calculated. Differences were found at the level of highly and medium repetitive sequences, thus demonstrating that some DNA reassociation classes may undergo amplification during root development.     

An analysis of repeated sequence heterogeneity

High-resolution thermal denaturation was used to measure the heterogeneity within repeated DNA sequences. An analysis of combined denaturation/redenaturation experiments on mouse satellite DNA suggests the existence of two minor components, one of which does not appear in the prepared EcoRII monomer. The resolving power of the denaturation/redenaturation experiment is estimated and contrasted with that of the reassociation experiment, often used to estimate repeated sequence heterogeneity. A mathematical model of the redenaturation experiment was developed and applied to mouse satellite data; the results suggest that only one-fourth of the mismatched base pairs are energetically significant in the reduction of heteroduplex stability.     

A tandemly reiterated DNA sequence in the long repeat region of herpes simplex virus type 1 found in close proximity to immediate-early mRNA 1.

The 3' end of immediate-early mRNA 1 was mapped precisely within the IRL/TRL genome regions, and the DNA sequences around the 3' end were determined. An AATAAA polyadenylation signal was present 17 base pairs upstream of the 3' end, and eight tandemly repeated copies of a 16-base-pair sequence (GGGGGTGCGTGGGAGT) plus one further closely related copy were located 20 base pairs downstream. Other tandem reiterations present in the herpes simplex virus genome are described and their properties are considered.     

Characterization of cytoplasmic and nuclear genomes in the colorless alga Polytoma

DNA isolated from purified nuclei of Polytoma obtusum has a buoyant density of 1.711 g/ml in CsCl, a Tm of 91.3° C in SSC, and a G + C content of 52.5% as determined by base composition analysis. Thermal dissociation and reassociation studies indicated that this nuclear DNA contains a considerable amount of heterogeneity. Under appropriate reannealing conditions for denatured DNA, about 15% of the DNA reannealed to form a satellite peak at a density of 1.711 g/ml within one hour. Native DNA fractions of different average buoyant densities, ranging from 1.723 to 1.708 g/ml were also obtained in a preparative CsCl gradient, indicating the presence of intermolecular heterogeneity at a molecular size of 8.5×10⁶ daltons. The nuclear DNA reassociated as three distinct classes. The very fast species constituted about 20 % of the total hyperchromicity, the class of intermediate rate comprised roughly 10% of the nuclear DNA, while the remaining 70% consisted of unique sequences. The haploid genome set was estimated by renaturation kinetics studies to contain 5.0×10¹⁰ daltons of DNA or 7.5×10⁷ nucleotide pairs. The analytical complexity of the total nuclear genome was found to be 9.35×10¹⁰ daltons, thus indicating that vegetative cells of P. obtusum are diploid.     

Genome organization in Xiphophorus (Poeciliidae; Telostei)

Summary Xiphophorus represents a valuable model for studying genomic contributions to neoplasia. For analyzing these contributions at the molecular level, basic information about the genome organization is a prerequisite. This study presents data on the organization and complexity of the genomes of three species of Xiphophorus, maculatus, variatus and helleri, representative of the problem. Their diploid nuclei, as measured in the erythrocyte, contain 1.19 pg, 1.23 pg, and 1.27 pg DNA, these values representing approximately 50% of that of birds, 20% of that of mammals. The melting curves of native, high molecular weight DNA are homogeneous, the T_m was determined for maculatus as 85.0° C (corresponding to a mean GC-content of 38.3%) for variatus as 86.0° C (GC=40.7%), for helleri as 85.0° C (GC=39.3%). Reassociation of sheared denatured DNA indicated approximately 90% single copy sequences, the remaining 10% are predominantly multiple copy sequences. The complexity of single copy DNA was determined from reassociation kinetics for maculatus as 3.97×10⁸ base pairs, for variatus as 4.31×10⁸ base pairs, and for helleri as 4.49×10⁸ base pairs. The DNA of the three species upon isopycnic density gradient centrifugation in the presence of the fluorescence dye Hoechst 33258 shows in addition to the main band, two heavy (GC-rich) satellites, denoted in the order of increasing density, components I and II. Analytical centrifugation reveals for the main band DNA a buoyant density of 1.6980 gcm^-3 (GC=38.7%), for component I 1.7080 gcm^-3 (GC=48.9%), for component II 1.7150 gcm^-3 (GC=56.1%). Each of the components comprises approximately 0.38% of the total DNA. Complete digestion of components I and II with restriction enzymes EcoRI and BamHI yields a complex banding pattern upon agarose gel-electrophoresis. A 2.4 kb fragment of component I and a 5.3 kb fragment of component II of helleri, cloned and amplified in the pBR322/E. coli RR1 system, hybridize efficiently to purified nuclei of liver. Furthermore, restriction fragments of component II DNA, transferred to nitrocellulose by Southern-blotting, hybridize with 18S and 28S ribosomal DNA.     

Characteristics of nuclear DNA in the genus Oryza

Summary DNAs have been isolated from various Oryza species and studied using physical techniques. The percent of guanine plus cytosine has been determined by thermal denaturation. While the base composition varied between the species, no heterogeneity in the base pair distribution was observed. Renaturation kinetics data of DNAs from different species show that the proportion of repeated DNA sequences vary considerably depending on the DNA content per cell, whereas the nonrepetitive DNA component remains relatively constant. These results suggest that in addition to a small range of DNA variation between the species, changes in the base composition and proportion of repeated sequences have accompanied divergence of the species within the genus.     

Two families of repeated DNA sequences in Thiobacillus ferrooxidans.

The genome of Thiobacillus ferrooxidans ATCC 19859 is about 2.8 X 10(6) base pairs as determined by analysis of reassociation kinetics of sheared DNA. This is 70% of the size of the genome of Escherichia coli. About 6% of the genome of T. ferrooxidans consists of moderately repetitive DNA sequences that are repeated an average of 20 times per genome. Two distinct repeated sequences, designated family 1 and family 2, have been analyzed in more detail. Both families are approximately 1 kilobase in length and are repeated 20 to 30 times per genome. Preliminary evidence from restriction enzyme analysis, Southern blotting experiments, and thermal melting analysis indicates that members of both families are conserved and are interspersed with single-copy DNA. Six copies of one family are present on the 45-kilobase-pair plasmid of strain ATCC 19859.     

Classification of the Legionnaires' disease bacterium: An interim report

Deoxyribonucleic acid (DNA) from strains of the Legionnaires' disease bacterium (LDB) was characterized in order to aid in the proper classification of this organism. The genome size of LDB DNA was estimated at 2.5×10⁹ daltons by reassociation kinetics; a guanine-plus-cytosine content of LDB of 39% was established by optical thermal denaturation and buoyant density ultracentrifugation measurements. DNA relatedness studies on 12 strains of the LDB indicated that they were all members of the same species. DNA relatedness studies have thus far failed to show that the LDB is significantly related to any other organism, including all members of Enterobacteriaceae,Pasteurella multocida, Francisella tularensis, Rochalimaea quintana, Vibrio species,Staphylococcus epidermidis, andFlavobacterium meningosepticum.     

Satellite DNA properties of the germ line limited DNA and the organization of the somatic genomes in the nematodesAscaris suum andParascaris equorum

During the early cleavage divisions in some Ascarids, parts of the chromosomes are eliminated from the somatic blastomeres (chromatin diminution, Boveri, 1887) while the chromosomes in the germ line cells maintain their integrity. To characterize the germ line and soma genome, DNA was isolated from gametes and embryonic somatic cells of two Ascarid species,Parascaris equorum var. univalens andAscaris suum. It was shown that the germ line limited DNAs of these species have the same density and almost identical reassociation kinetics: in CsCl the predominant component of the germ line limited DNA ofP. equorum andA. suum has the buoyant density of 1.697g/cm³, while soma DNA of both species bands at 1.700 g/cm³. InP. equorum there is a small additional germ line limited satellite DNA component with the density of 1.690 g/cm³, identical to that of mitochondrial DNA of both organisms. Comparison of the reassociation kinetics of germ line and soma DNA demonstrates for both species that the eliminated DNA sequences are highly repetitive. In contrast to these similarities between the germ line limited DNAs ofP. equorum andA. suum the analysis of their base composition revealed differences (40% guanine plus cytosine inP. equorum and 36% inA. suum). The only very fast reassociating DNA sequences which we could isolate from soma DNA was demonstrated to be foldback DNA. The reassociation kinetics of totalA. suum soma DNA was investigated by hydroxylapatite chromatography. Least squares analysis of the data revealed about 10% of intermediate repetitive DNA sequences. Their interspersion between single copy DNA sequences was analyzed by comparing the reassociation kinetics of DNA fragments 0.35 and 7.2 kilobases long. Thus the DNA sequence arrangement ofAscaris does not follow the short period interspersion pattern observed in most organism.     

Agar Analysis,nuclear genome quantification and characterization of four agarophytes (Gracilaria) from the Mexican Gulf Coast

DNA reassociation kinetics were used to determine nuclear genome organization and complexity in four species of Gracilaria (Gracilariales, Rhodophyta). In Gracilaria tikvahiae, G. caudata, G. cervicornis and G. divaricata, results indicate the presence of three second order components corresponding to fast, intermediate and slow fractions. Repetitive sequences varied from 13–46% and unique DNA ranged from 45–78%, Thermal denaturation (T _m) indicated guanine + cytosine (G + C) levels of 41.9–46.0 mol % G + C. Microspectrophotometry with the DNA-localizing fluorochrome DAPI was used to quantify nuclear DNA content. Comparisons of mean nuclear DNA (I _f) values to chicken erythrocytes (RBC) resulted in an estimate of 0.37–0.40 pg/2C genomes for the four Gracilaria species. Total agar content following alkaline pretreatment ranged from 7–15% dry weight. Gel strengths were generally below commercial levels, ranging from 40–260 g cm⁻² Nuclear genome profiles developed from information for genome size, organization and complexity are compared with data for agar quantity and quality. Gel quality and quantity do not appear to be correlated with either large repetitive fraction DNA or a high degree of genome complexity as previously speculated.     

Deoxyribonucleic acid base composition of the yeastlike and mycelial phases of Histoplasma capsulatum and Blastomyces dermatitidis

The base composition in moles percent guanine plus cytosine (%GC) of both nuclear and mitochondrial deoxyribonucleic acid (DNA) isolated from the yeastlike and mycelial phases of the dimorphic fungal pathogens Histoplasma capsulatum and Blastomyces dermatitidis was determined by techniques of thermal denaturation and CsCl buoyant density gradient equilibrium centrifugation. The mean observed values for GC content of nuclear DNA from H. capsulatum and B. dermatitidis were 47.3 and 48.2%, respectively. What is speculated to be mitochondrial DNA was found to be 34.0% for H. capsulatum and 34.3% for B. dermatitidis. Thermal denaturation curves for Blastomyces DNA indicated a bimodality in thermal denaturation profiles, thereby suggesting a significant mitochondrial DNA contamination. Mitochondrial DNA appeared to represent a smaller percentage of the total DNA prepared from Histoplasma, and was not observed consistently to affect%GC values as determined by thermal denaturation profiles. On the basis of the now known perfect stage of B. dermatitidis (Ajellomyces dermatitidis) as a member of the family Gymnoascaceae, the close approximation of%GC content of nuclear DNA of this fungal organism with that of H. capsulatum suggests possible phylogenetic relationship. It is suggested that the just reported, but as yet unclassified, perfect stage of H. capsulatum may be found to be phylogenetically a primitive form of the Gymnoascaceae.     

Isolation and characterization ofAnaplasma marginale DNA

Two procedures were used to isolateAnaplasma marginale bodies from bovine erythrocytes. DNA extracted from bodies prepared by the second method was free of any detectable bovine DNA contamination.Anaplasma marginale DNA was analyzed by agarose gel electrophoresis of endonuclease restriction fragments and by reassociation kinetics. Genome size was estimated to be 340 kb. Base composition of the DNA was 33 mol% guanine+ cytosine (G+C), determined from its thermal denaturation temperature.Anaplasma marginale has a very small genome compared with that of other bacteria and has a low G+C content. It is proposed thatA. marginale may be a close, but degenerate, relative of the rickettsiae.