Structure and distribution of inverted repeats (palindromes)

The size and distribution of renatured inverted repeats (palindromes) in D. melanogaster DNA were studied by electron microscopy (EM). The results of these studies differ from the previously published observations regarding the number, distribution and the size of inverted repeats (ir) present in DNA. -1. In contrast to the previous published observation almost all (96%) of the ir were found in crowded clusters. The DNA strands with clustered palindromes contained 2-21 palindromes (4-42 ir), with an average of 7.25 palindromes (14.5 ir) per strand. No correlation could be found between the length of the DNA strands and the number of ir per strand. -2, Also contrary to some previously published results, most (80%) of the ir formed on renaturation unlooped palindromes and these were always clustered. Looped palindromes (hairpins, formed by renaturation of ir separated by a non-homologous sequence long enough to be seen in EM as single-stranded loop) were found 1-2 per DNA strand, as part of clusters or as solitary palindromes in a DNA strand. The average spacing length (inside clusters) between centers of all palindromes was 2.349 kb, and between centers of looped palindromes 7.6 kb. - 3. The length of the ir was found to be smaller than documented in most of the previously published results. The majority, 80-90%, of the ir found in the unlooped and looped palindromes, respectively, belonged to one main-size class with a range of 30-210 bp and an average length of 100 bp, but longer ir were also observed. The average length of the ir in unlooped palindromes was 124 bp, in looped 244 bp, and the total average was 148 bp - 4. It was calculated that there are about 30,000 palindromes (60,000 ir) in the D, melanogaster genome, of which about 24,000 are unlooped and 6,000 looped, with the spacing between centers of all palindromes averaging about 4.4 kb in length.     

DNA sequence organization in the genome of Cycas revoluta

The pattern of DNA sequence organization in the genome of Cycas revoluta was analyzed by DNA/DNA reassociation. Reassociation of 400 base pair (bp) fragments to various C₀t values indicates the presence of at least four kinetic classes: the foldback plus very highly repetitive sequences (15%), the fast repeats (24%), the slow repeats (44%), and the single copy (17%). The latter component reassociates with a rate constant 1×10^–4 M^–1S^–1 corresponding to a complexity of 1.6× 10⁶ kb per haploid genome. A haploid C. revoluta nucleus contains approximately 10.3 pg DNA. The single-copy sequences account for about 28% of the DNA, but only 17% reassociate with single-copy kinetics because of interspersion with repetitive sequences. — The interspersion of repetitive and single-copy sequences was examined by reassociation of DNA fragments of varying length to C₀t values of 70 and 500. A major (65%) and homogeneous class of single-copy sequences averaging 1,100 bp in length is interspersed in a short period pattern with repeated sequences. A minor (35%) heterogeneous single-copy component is interspersed in a long-period pattern. The majority of repetitive sequences have a length distribution of 100–350 bp with subclasses averaging 150 and 300 bp in length. Repeat sequences with a wide range in sizes exceeding 2 kilobase pair (kb) are also present in this genome. — The size and distribution of inverted repeat (ir) sequences in the DNA of C. revoluta were studied by electron microscopy. It is estimated that there are approximately 4 × 10⁶ ir pairs (one per 2.33 kb) that form almost equal numbers of looped and unlooped palindromes. This high value is 2.5 times that found in wheat DNA. These palindromes are in general randomly distributed in the genome with an average interpalindrome distance of 1.6 kb. The majority (about 85%) of ir sequences of both types of palindromes belong to a main-size class, with an average length of 210 bp in the unlooped and and 163 bp in the looped type. These values are comparable to those reported for some other plant and animal genomes. Distribution of length of single stranded loops showed a main-size class (75%) with an average length of 220 bp.     

Characterization of inverted repeated sequences in wheat nuclear DNA.

The properties of inverted repeated sequences in wheat nuclear DNA have been studied by HAP(1) chromatography, nuclease S1 digestion and electron microscopy. Inverted repeated sequences comprise 1.7% of wheat genome. The HAP studies show that the amount of "foldback HAP bound DNA" depends on DNA length. Inverted repeats appear to be clustered with an average intercluster distance of 25 kb. It is estimated that there are approximately 3 x 10(6) inverted repeats per haploid wheat genome. The sequences around inverted repeats involve all families of repetition frequencies. Inverted repeats are observed as hairpins in electron microscopy. 20% of hairpins are terminated by a single-stranded spacer ranging from 0.3 to 1.5 kb in length. Duplex regions of the inverted repeats range from 0.1 to 0.45 kb with number average values of 0.24 kb and 0.18 kb for unlooped and looped hairpin respectively. Thermal denaturations and nuclease S1 digestions have revealed a length of about 100 bases for duplex regions. The methods used to study inverted repeated sequences are compared and discussed.     

Replication of chromosomal DNA in diploid Drosophila melanogaster cells cultured in vitro

Replication rate and replicon sizes in chromosomal DNA of in vitro cultured diploid D. melanogaster cells were determined using autoradiography of ³H-thymidine labeled DNA. Synthesis of DNA in euchromatic and heterochromatic regions of Drosophila diploid cells occurs at different periods of the S phase which lasts 10 h. During the first 4 h the synthesis is observed only in euchromatic regions. The heterochromatic synthesis starts shortly before the synthesis in euchromatic regions is completed and lasts for 6 h until the end of the S phase. The cells were synchronized by 5fluorodeoxyuridine which blocked the diploid cell DNA synthesis. Synthesis was found to start simultaneously in most euchromatic replicons. In the majority of the replicons the synthesis started at a single point and proceeded bidirectionally. The average rate of DNA synthesis per fork was 12.5 m/h (38 kb). The mean distance between the middle points of adjacent labeled regions was 70 m (210 kb). The size of most replicons ranged from 40 to 120 m. — These estimates do not apply to the heterochromatic portions of the D. melanogaster genome since the measurements have been carried out on DNA preparations obtained during the first 2 h of the S phase. — On the average, a replicon can consist of 7 chromomeres since the size of a replicon in diploid cell chromosomal DNA and DNA length of a polytene chromomere average 210 and 30 kb, respectively.     

Organization of the 5S RNA genes in macro- and micronuclei of Tetrahymena pyriformis

The organization of the 5S genes in macro- and micronuclei of Tetrahymena pyriformis was studied using restriction endonucleases. After complete digestion of macronuclear DNA with BamH-I or Hpa I, 5S RNA hybridized to a DNA fragment of approximately 280 base pairs (bp). When macronuclear DNA was only partially digested with these enzymes, hybridization with ³²P-5S RNA demonstrated an oligomeric series with a spacing of 280 bp. These results indicate that the 5S genes are tandemly repeated in macronuclei and that the repeating unit is 280 bp (or 180,000 daltons). Since 5S RNA is 120 nucleotides, we conclude that the 5S repeat units contain a 120 bp transcribed region and a 160 bp spacer region. When macronuclear DNA was digested with Eco RI, Bgl I, or Eco RI + Bgl I, 5S RNA hybridized to DNA of molecular weight 3–4×10⁶, suggesting that these enzymes do not cleave within a 5S repeat. These 3–4×10⁶ dalton fragments define the maximum size of an average cluster of 5S repeated units. Assuming the size of the 5S repeat to be 0.18×10⁶ daltons, there are about 15–20 5S repeats per average tandem cluster, and since there are 350 5S-genes per haploid genome, there must be approximately 15–20 tandem arrays. Results obtained using micronuclear DNA suggest that organization of the 5S-genes is very similar in macro- and micronuclei. Macronuclear rRNA genes are extracnromosomal palindromic dimers. In contrast, 5S genes in Tetrahymena were found to be integrated within the genomes of both macro- and micronuclei and not linked to the rRNA genes. Moreover, it is unlikely that they are palindromes; rather they appear to be tandemly repeated in head-to-tail linkages. Thus, the organization of the 5S genes in Tetrahymena is similar to that of higher eukaryotes.     

Isolation of an autonomously replicating sequence (ARS) from satellite DNA of Drosophila melanogaster

Summary Autonomously replicating sequences (ARSs) were cloned from the 1.688 satellite DNA of D. melanogaster using YIp5, consisting of pBR322 and the yeast ura3 gene, as the cloning vector and YNN27, a Ura^– yeast strain as the recipient. Three out of six clones contained an ARS and the average frequncy of the occurrence of ARS was thus calculated to be approximately one per 14 kbp of the satellite DNA. A 500 bp ARS fragment (BgHS500) was obtained from one of the resultant clones (pYDS57). BgHS500 does not hybridize with the major repeating unit (370 bp) but it does with the minor unique sequence of the satellite. The sequence of BgHS500 was determined and found to be rich in AT and to contain the sequence, 5AAAACATAAAA3, a sequence common to yeast ARSs. However, a smaller fragment (150 bp) isolated from BgHS500 and containing the 11 bp sequence did not exhibit the characteristics of an ARS. The average copy number in the transformants of pBgHS500, a recombinant molecule of BgHS500 and YIp5, ranged from 0.05–0.5, while that of the parent plasmid, pYDS57, was about 2–10. On the basis of these results, it is postulated that the sequence 5AAAACATAAAA3 may possibly consiitute the core of ARSs and certain other sequences may also be necessary to insure that the ARS consistently undergoes at least one complete replication in each cell cycle. The role of ARSs in the genome of D. melanogaster is discussed.     

Characterization of inverted repeated sequences in Ascaris nuclear DNA

The inverted repeated sequences of the chromatin-eliminating nematode Ascaris lumbricoides var. suum have been examined by electron microscopy and by hydroxyapatite chromatography, both in the germ-line and in the somatic DNA. 38% of the inverted repeats of the germ-line DNA analysed in the electron microscope have a single-stranded loop, in comparison to about 50% of looped structures in the somatic DNA. The loops are on average 2.3 X 10(3) base pairs (bp) long. The rest of the foldback DNA consists of simple hairpins. The average length of looped and unlooped inverted repeats is of the order of 300-400 bp in the germ-line and in the somatic DNA. The content of S1-resistant foldback duplexes isolated by hydroxyapatite chromatography amounts to 1.3% in spermatids, with an average length of 350 bp, and to 1.1% in intestinal or larval cell nuclei, with a length of about 320 bp. We estimate by two different methods that there exist approximately 12500 inverted repeats per haploid germ-line genome and approximately 8000 in the haploid somatic genome. A statistical analysis of the data indicates that the great majority of the foldback sequences are randomly distributed in the Ascaris genome, with a spacing of about (40-80) X 10(3) bp, both in the germ-line and in the somatic DNA.     

Structural evolution of the Drosophila 5S ribosomal genes

We compare the 5S gene structure from nine Drosophila species. New sequence data (5S genes of D. melanogaster, D. mauritiana, D. sechellia, D. yakuba, D. erecta, D. orena, and D. takahashii) and already-published data (5S genes of D. melanogaster, D. simulans, and D. teissieri) are used in these comparisons. We show that four regions within the Drosophila 5S genes display distinct rates of evolution: the coding region (120 bp), the 5-flanking region (54–55 bp), the 3-flanking region (21–22 bp), and the internal spacer (149–206 bp). Intra- and interspecific heterogeneity is due mainly to insertions and deletions of 6–17-bp oligomers. These small rearrangements could be generated by fork slippages during replication and could produce rapid sequence divergence in a limited number of steps. Correspondence to: M. Wegnez     

Two type II keratin genes are localized on human chromosome 12

Summary Human genomic DNA containing two type II keratin genes, one coding for keratin 1 (K1, a 68-kD basic protein) and another closely linked type II gene 10–15 kb upstream (K?, gene product unknown), was isolated on a single cosmid clone. EcoRI restriction fragments of the cosmid were subcloned into pGEM-3Z, and specific probes comprising the C-terminal coding and 3 noncoding regions of the two genes were constructed. The type II keratin genes were localized by in situ hybridization of the subcloned probes to normal human lymphocyte chromosomes. In a total of 70 chromosome spreads hybridized with the K? probe (gHK?-3, PstI, 800 bp), 36 of the 105 grains observed were on chromosome 12, and 32 of these were clustered on the long arm near the centromere (12q11–13). In 100 labeled metaphases hybridized with the K1 probe (gHK1–3, BamHI-PstI, 2100 bp), 53 grains localized to chromosome 12 and 46 of these were found in the same region (q11–13). Therefore, both the gene for human keratin 1, a specific marker for terminal differentiation in mammalian epidermis, and another closely linked unknown type II keratin gene (K?, 10–15 kb upstream of K1) are on the long arm (q11–13) of human chromosome 12.     

Nuclear tRNATyr genes are highly amplified at a single chromosomal site in the genome of Arabidopsis thaliana

Summary We have examined the organization of tRNA^Tyr genes in three ecotypes of Arabidopsis thaliana, a plant with an extremely small genome of 7 × 107 bp. Three tRNA^Tyr gene-containing EcoRI fragments of 1.5 kb and four fragments of 0.6, 1.7, 2.5 and 3.7 kb were cloned from A. thaliana cv. Columbia (Col-O) DNA and sequenced. All EcoRl fragments except those of 0.6 and 2.5 kb comprise an identical arrangement of two tRNA^Tyr genes flanked by a tRNA^Ser gene. The three tRNA genes have the same polarity and are separated by 250 and 370 bp, respectively. The tRNA^Tyr genes encode the known cytoplasmic tRNA_GA ^Tyr. Both genes contain a 12 by long intervening sequence. Densitometric evaluation of the genomic blot reveals the presence of at least 20 copies, including a few multimers, of the 1.5 kb fragment in Col-O DNA, indicating a multiple amplification of this unit. Southern blots of EcoRl-digested DNA from the other two ecotypes, cv. Landsberg (La-O) and cv. Niederzenz (Nd-O) also show 1.5 kb units as the major hybridizing bands. Several lines of evidence support the idea of a strict tandem arrangement of this 1.5 kb unit: (i) Sequence analysis of the EcoRI inserts of 2.5 and 0.6 kb reveals the loss of an EcoRI site between 1.5 kb units and the introduction of a new EcoRI site in a 1.5 kb dimer. (ii) Complete digestion of Col-O DNA with restriction enzymes which cleave only once within the 1.5 kb unit also produces predominantly 1.5 kb fragments. (iii) Partial digestion with EcoRI shows that the 1.5 kb fragments indeed arise from the regular spacing of the restriction sites. The high degree of sequence homology among the 1.5 kb units, ranging from 92% to 99%, suggests that the tRNA^Ser/tRNA^Tyr cluster evolved 1–5 million years ago, after the Brassicaceae diverged from the other flowering plants about 5–10 million years ago.     

Analysis of DNA–Protein Contacts in a Complex between Methyltransferase SsoII and a Promoter Region of the SsoII Restriction–Modification Genes

Heterocyclic bases and phosphate groups involved in the DNA–methyltransferase SsoII (M·SsoII) interaction were identified in the regulatory DNA region localized within the promoter region of the SsoII restriction–modification genes by footprinting with the use of formic acid, hydrazine, dimethyl sulfate, and N-ethyl-N-nitrosourea as modifying agents. It has been established that the enzyme interacts with three guanines, one adenine, two thymines, and three phosphate groups of each strand of the DNA duplex. These heterocyclic bases and phosphate groups are disposed symmetrically within the 15-mer inverted repeat of the regulatory DNA region. It has been demonstrated by footprinting with dimethyl sulfate that the C7 atoms of guanines interacting with the enzyme are exposed to the DNA major groove. Two theoretical models were built describing the contacts in a complex between M·SsoII and the regulatory DNA region.     

The pogo transposable element family of Drosophila melanogaster.

Summary A 190 by insertion is associated with the white-eosin mutation in Drosophila melanogaster. This insertion is a member of a family of transposable elements, pogo elements, which is of the same class as the P and hobo elements of D. melanogaster. Strains typically have many copies of a 190 by element, 10–15 elements 1.1–1.5 kb in size and several copies of a 2.1 kb element. The smaller elements all appear to be derived from the largest by single internal deletions so that all elements share terminal sequences. They either always insert at the dinucleotide TA and have perfect 21 bp terminal inverse repeats, or have 22 by inverse repeats and produce no duplication upon insertion. Analysis by DNA blotting of their distribution and occupancy of insertion sites in different strains suggests that they may be less mobile than P or hobo. The DNA sequence of the largest element has two long open reading frames on one strand which are joined by splicing as indicated by cDNA analysis. RNAs of this strand are made, whose sizes are similar to the major size classes of elements. A protein predicted by the DNA sequence has significant homology with a human centrosomal-associated protein, CENP-B. Homologous sequences were not detected in other Drosophila species, suggesting that this transposable element family may be restricted to D. melanogaster.     

Evolution of thedec-1 eggshell locus inDrosophila. I. Restriction site mapping and limited sequence comparison in themelanogaster species subgroup

Summary We have analyzed 18 kb of DNA in and upstream of thedefective chorion-1 (dec-1) locus of the eight known species of themelanogaster species subgroup ofDrosophila. The restriction maps ofD. simulans, D. mauritiana, D. sechellia, D. erecta, andD. orena are shown to have basically the restriction map ofD. melanogaster, whereas the maps ofD. teissieri andD. yakuba were more difficult to align. However, the basic amount of DNA and sequence arrangement appear to have been conserved in these species. A small deletion of varying length (65–200 bp) is found in a repeated sequence of the central transcribed region ofD. melanogaster, D. simulans, andD. erecta. Restriction site mapping indicated that thedec-1 gene is highly conserved in themelanogaster species subgroup. However, sequence comparison revealed that the amount of nucleotide and amino acid substitution in the repeated region is much larger than in the 5 translated region. The 5 flanking region showed noticeable restriction site polymorphisms between species. Based on calculations from the restriction maps a dendrogram was derived that supports earlier published phylogenetic relationships within themelanogaster species subgroup except that theerecta-orena pair is placed closer to themelanogaster complex than toD. teissieri andD. yakuba.     

DNA binding domains in Tn3 transposase

Summary Various segments of Tn3 transposase were fused individually to -galactosidase, and the resulting fusion proteins were examined for their DNA binding ability by a nitrocellulose filter binding assay. Analyses of a series of the fusion proteins revealed that the N-terminal segment of the transposase (amino acid positions 1–242; the transposase gene encodes 1004 residues in all) had specific DNA binding ability for the 38 bp terminal inverted repeat (IR) sequence, and the central segment (amino acid positions 243–632) had non-specific DNA binding ability. Further analyses of each of the two regions revealed that the N-terminal segment could be divided into at least two subsegments (amino acid positions 1–86 and 87–242), neither of which had specific DNA binding ability, but which both possessed nonspecific DNA binding ability. The central segment included two subsegments (amino acid positions 243–289 and 439–505) with non-specific DNA binding ability. These results and other observations suggest that Tn3 transposase has several domains including those responsible for non-specific DNA binding, and a combination of two or more domains gives rise to specific DNA binding activity. The C-terminal segment of the transposase (amino acid positions 633-1004), which is very well conserved among transposases encoded by Tn3 family transposons, had no DNA binding ability. This segment may represent the main part of the catalytic domain responsible for the initiation step of transposition.     

Molecular Phylogeny of the <Emphasis Type="Italic">Drosophila melanogaster</Emphasis> Species Subgroup

Although molecular and phenotypic evolution have been studied extensively in Drosophila melanogaster and its close relatives, phylogenetic relationships within the D. melanogaster species subgroup remain unresolved. In particular, recent molecular studies have not converged on the branching orders of the D. yakuba–D. teissieri and D. erecta–D. orena species pairs relative to the D. melanogaster–D. simulans–D. mauritiana–D. sechellia species complex. Here, we reconstruct the phylogeny of the melanogaster species subgroup using DNA sequence data from four nuclear genes. We have employed vectorette PCR to obtain sequence data for orthologous regions of the Alcohol dehydrogenase (Adh), Alcohol dehydrogenase related (Adhr), Glucose dehydrogenase (Gld), and rosy (ry) genes (totaling 7164 bp) from six melanogaster subgroup species (D. melanogaster, D. simulans, D. teissieri, D. yakuba, D. erecta, and D. orena) and three species from subgroups outside the melanogaster species subgroup [D. eugracilis (eugracilis subgroup), D. mimetica (suzukii subgroup), and D. lutescens (takahashii subgroup)]. Relationships within the D. simulans complex are not addressed. Phylogenetic analyses employing maximum parsimony, neighbor-joining, and maximum likelihood methods strongly support a D. yakuba–D. teissieri and D. erecta–D. orena clade within the melanogaster species subgroup. D. eugracilis is grouped closer to the melanogaster subgroup than a D. mimetica–D. lutescens clade. This tree topology is supported by reconstructions employing simple (single parameter) and more complex (nonreversible) substitution models. Present address (Ryan M. David): University of Texas Health Science Center at San Antonio, 7703 Floyd Curl Drive, San Antonio, TX 78284, USA     

Heterochromatin and highly repeated DNA sequences in rye (Secale cereale)

Secale cereale DNA, of mean fragment length 500 bp, was fractionated by hydroxylapatite chromatography to allow recovery of a very rapidly renaturing fraction (C₀t 0–0.02). This DNA fraction was shown to contain several families of highly repeated sequence DNA. Two highly repeated families were purified; (1) a fraction which renatured to a density of 1.701 g/ cc and comprised 2–4% of the total genome, and (2) polypyrimidine tract DNA which comprised 0.1% of the total genome. The 1.701 g/cc DNA consisted of short sequence repeat units (5–50 bp long) tandemly repeated in blocks 30 kb long, while a portion of the polypyrimidine tract DNA behaved as part of a much larger block of tandemly repeated sequences. The chromosomal location of these sequences was determined by the in situ hybridisation of radioactive, complementary RNA to root tip mitotic chromosomes and showed the 1.701 g/cc sequences to be largely limited to the telomeric blocks of heterochromatin, accounting for 25–50% of the DNA present in these parts of the chromosomes. The polypyrimidine tracts were distributed at interstitial locations with 20–30% of the sequences at three well defined sites. The combined distributions of the 1.701 g/cc DNA sequences and polypyrimidine tracts effectively individualised each rye chromosome thus providing a sensitive means of identifying these chromosomes. The B chromosomes present in Secale cereale cv. Unevita, did not show defined locations for the sequences analysed. — The data are discussed in terms of the structure of the rye genome and the generality of the observed genomic arrangement of highly repeated sequence DNA.     

A novel minisatellite at a cloned hamster telomere

The ends of eukaryotic chromosomes have special properties and roles in chromosome behavior. Selection for telomere function in yeast, using a Chinese hamster hybrid cell line as the source DNA, generated a stable yeast artificial chromosome clone containing 23 kb of DNA adjacent to (TTAGGG)n, the vertebrate telomeric repeat. The common repetitive element d(GT)n appeared to be responsible for most of the other stable clones. Circular derivatives of the TTAGGG-positive clone that could be propagated in E. coli were constructed. These derivatives identify a single pair of hamster telomeres by fluorescence in situ hybridization. The telomeric repeat tract consists of (TTAGGG)n repeats with minor variations, some of which can be cleaved with the restriction enzyme MnlI. Blot hybridization with genomic hamster DNA under stringent conditions confirms that the TTAGGG tracts are cleaved into small fragments due to the presence of this restriction enzyme site, in contrast to mouse telomeres. Additional blocks of (TTAGGG)n repeats are found 4–5 kb internally on the clone. The terminal region of the clone is dominated by a novel A-T rich 78 bp tandemly repeating sequence; the repeat monomer can be subdivided into halves distinguished by more or less adherence to the consensus sequence. The sequence in genomic DNA has the same tandem organization in probably a single primary locus of >20–30 kb and is thus termed a minisatellite.     

DNA-replication of spi - mutants of bacteriophage lambda in recombination-deficient bacteria

Summary Phage imm ²¹ c spi ^– infecting recA ^– cells gives a burst of 6 progeny phages compared to 120 in rec ⁺ cells. Parental spi ^– DNA is not degraded in recA ^– cells. The synthesis of early replication products is enhanced by a factor of 2 yielding 30 closed circular progeny DNA molecules per cell compared to 15 in the control. These DNA supercoils include 9% of dimer molecules under red ^– recA ^– and red ^– rec ⁺ conditions. On the other hand, the formation of linear phage DNA molecules in recA ^– cells is reduced by a factor of 5 to 6, if compared to spi ^– DNA in rec ⁺ and spi ⁺ DNA in recA ^– cells, respectively. The specific biological activity of these linear molecules in the helper phage assay system is unimpaired. Intermediates of late spi ^– replication under recA ^– conditions are supposed to be the unprotected targets of the action of the recB ⁺ recC ⁺ nuclease.     

Chromosome size and DNA content of species of anemone L. and related genera (Ranunculaceae)

Relative amounts of DNA were determined by Feulgen cytophotometry in 22 diploid species of Ranunculaceae (n=7, 8, 9) representing six genera, and exhibiting large differences in chromosome size, but no marked differences in karyotype pattern. Chemical determination of absolute amounts of DNA for six of these species, allowed conversion of all the photometric data into absolute units of DNA. The mean DNA content per nucleus varied from.13×10^–11gm in Aquilegia to 5.25×10^–11gm in species of Anemone in the section Homalocarpus. The DNA values obtained appeared to be quantized, and data for the majority of species fitted a non-geometrical series with the observed relative terms: 1—8—12—16—20—24—40. The magnitude of these variations in DNA content, the preservation of the karyotype and the tendency towards a simple numerical progression in DNA values, lead us to prefer an interpretation of the evolution of DNA content in terms of differential polynemy to one postulating changes in size of genetic units in an unchanging number of strands per chromosome.