Interspersion of repetitive and non-repetitive DNA sequences in the sea urchin genome

Comment on "Computational Improvements Reveal Great Bacterial Diversity and High Metal Toxicity in Soil"

Gans et al. (Reports, 26 August 2005, p. 1387) provided an estimate of soil bacterial species richness two orders of magnitude greater than previously reported values. Using a re-derived mathematical model, we reanalyzed the data and found that the statistical error exceeds the estimate by a factor of 26. We also note two potential sources of error in the experimental data collection and measurement procedures.

Response to Comment by Bunge et al . on "Computational Improvements Reveal Great Bacterial Diversity and High Metal Toxicity in Soil"

Bunge et al . claim that we underestimated the error in our analysis of bacterial diversity in noncontaminated soil. However, they used an unsatisfactory model that exhibited pathological behavior and consequently led to an exceptionally high calculated error. In contrast, the zipf distribution yielded an error estimate only 0.7 times the estimate of the total number of species ( S ), and it is more biologically relevant.

The genome ofOscheius tipulae: determination of size, complexity, and structure by DNA reassociation using fluorescent dye

This work describes the physicochemical characterization of the genome and telomere structure from the nematode Oscheius tipulae CEW1. Oscheius tipulae is a free-living nematode belonging to the family Rhabditidae and has been used as a model system for comparative genetic studies. A new protocol that combines fluorescent detection of double-stranded DNA and S1 nuclease was used to determine the genome size of O. tipulae as 100.8 Mb (approximately 0.1 pg DNA/haploid nucleus). The genome of this nematode is made up of 83.4% unique copy sequences, 9.4% intermediate repetitive sequences, and 7.2% highly repetitive sequences, suggesting that its structure is similar to those of other nematodes of the genus Caenorhabditis. We also showed that O. tipulae has the same telomere repeats already found in Caenorhabditis elegans at the ends and in internal regions of the chromosomes. Using a cassette-ligation-mediated PCR protocol we were able to obtain 5 different putative subtelomeric sequences of O. tipulae, which show no similarity to C. elegans or C. briggsae subtelomeric regions. DAPI staining of hermaphrodite gonad cells show that, as detected in C. elegans and other rhabditids, O. tipulae have a haploid complement of 6 chromosomes.Key words: Oscheius tipulae, Caenorhabditis elegans, DNA reassociation, telomere, genome size, karyotype.

Genome complexity and repetitive DNA in metazoans from extreme marine environments

As genomics converges with ecology and evolution to identify the fundamental linkages between genome structure and function, genome and transcriptome complexity will need to be measured in organisms from more diverse habitats, most often in the absence of complete sequence data. Here, we describe the complexity of ten genomes measured by a novel, high-throughput fluorescence-based kinetic hybridization assay. We applied the Shannon information index, H, and a related, fluorescence-adjusted index, H(f), as unique metrics of the hybridization kinetics to complement the conventional rate constant, k. A strong, positive relationship was present between H(f), and the repetitive DNA content of five eukaryotic genomes previously determined by Cot kinetic analyses (Onchorynchus keta, Ilyanassa obsoleta, Bos taurus, Limulus polyphemus, Saccharyomyces cerevisiae). This relationship was used to characterize the complexity of previously unstudied genomic samples in five metazoan taxa from three marine environments, including deep-sea hydrothermal vents (Alvinella pompejana), the temperate subtidal (Streblospio benedicti), and Antarctic coastal bays (Sterechinus neumayeri, Odontaster validus, Tritonia antarctica). Contrary to the predictions of nucleotypic theory, Antarctic invertebrates consistently had the lowest quantities of repetitive DNA in conjunction with low metabolic rates and highly protracted rates of cell division and larval development. Conversely, hydrothermal vent species with rapid cell division and growth do not have significantly different genome sizes or particularly low amounts of repetitive DNA as compared to non-vent, deep-sea taxa. Furthermore, there appears to be a positive correlation between the temperature at which the most abundant repetitive sequence classes anneal and habitat thermal stability. Thus, our study reveals a potential shift in repetitive sequence representation between these extreme environments that may be related to genome function in species living at these different thermal regimes.

A sea urchin genome project: sequence scan, virtual map, and additional resources

Results of a first-stage Sea Urchin Genome Project are summarized here. The species chosen was Strongylocentrotus purpuratus, a research model of major importance in developmental and molecular biology. A virtual map of the genome was constructed by sequencing the ends of 76,020 bacterial artificial chromosome (BAC) recombinants (average length, 125 kb). The BAC-end sequence tag connectors (STCs) occur an average of 10 kb apart, and, together with restriction digest patterns recorded for the same BAC clones, they provide immediate access to contigs of several hundred kilobases surrounding any gene of interest. The STCs survey >5% of the genome and provide the estimate that this genome contains approximately 27,350 protein-coding genes. The frequency distribution and canonical sequences of all middle and highly repetitive sequence families in the genome were obtained from the STCs as well. The 500-kb Hox gene complex of this species is being sequenced in its entirety. In addition, arrayed cDNA libraries of >10(5) clones each were constructed from every major stage of embryogenesis, several individual cell types, and adult tissues and are available to the community. The accumulated STC data and an expanding expressed sequence tag database (at present including >12, 000 sequences) have been reported to GenBank and are accessible on public web sites.

Microsatellite loci in wild-type and inbred Strongylocentrotus purpuratus

Strongylocentrotus purpuratus, a major research model in developmental molecular biology, has been inbred through six generations of sibling matings. Though viability initially decreased, as described earlier, the inbred line now consists of healthy, fertile animals. These are intended to serve as a genomic resource in which the level of polymorphism is decreased with respect to wild S. purpuratus. To genotype the inbred animals eight simple sequence genomic repeats were isolated, in context, and PCR primers were generated against the flanking single-copy sequences. Distribution and polymorphism of these regions of the genome were studied in the genomes of 27 wild individuals and in a sample of the inbred animals at F2 and F3 generations. All eight regions were polymorphic, though to different extents, and their homozygosity was increased by inbreeding as expected. The eight markers suffice to identify unambiguously the cellular DNA of any wild or F3 S. purpuratus individual.

Organization of an echinoderm Hox gene cluster

The Strongylocentrotus purpuratus genome contains a single ten-gene Hox complex >0.5 megabase in length. This complex was isolated on overlapping bacterial artificial chromosome and P1 artificial chromosome genomic recombinants by using probes for individual genes and by genomic walking. Echinoderm Hox genes of Paralog Groups (PG) 1 and 2 are reported. The cluster includes genes representing all paralog groups of vertebrate Hox clusters, except that there is a single gene of the PG4-5 types and only three genes of the PG9-12 types. The echinoderm Hox gene cluster is essentially similar to those of the bilaterally organized chordates, despite the radically altered pentameral body plans of these animals.

Analysis of Two Cosmid Clones from Chromosome 4 of Drosophila melanogaster Reveals Two New Genes Amid an Unusual Arrangement of Repeated Sequences

Chromosome 4 from Drosophila melanogaster has several unusual features that distinguish it from the other chromosomes. These include a diffuse appearance in salivary gland polytene chromosomes, an absence of recombination, and the variegated expression of P-element transgenes. As part of a larger project to understand these properties, we are assembling a physical map of this chromosome. Here we report the sequence of two cosmids representing ∼5% of the polytenized region. Both cosmid clones contain numerous repeated DNA sequences, as identified by cross hybridization with labeled genomic DNA, BLAST searches, and dot matrix analysis, which are positioned between and within the transcribed sequences. The repetitive sequences include three copies of the mobile element Hoppel, one copy of the mobile element HB, and 18 DINE repeats. DINE is a novel, short repeated sequence dispersed throughout both cosmid sequences. One cosmid includes the previously described cubitus interruptus(ci) gene and two new genes: that a gene with a predicted amino acid sequence similar to ribosomal protein S3a which is consistent with the Minute(4)101 locus thought to be in the region, and a novel member of the protein family that includes plexin and met–hepatocyte growth factor receptor. The other cosmid contains only the two short 5′-most exons from thezinc-finger-homolog-2 (zfh-2) gene. This is the first extensive sequence analysis of noncoding DNA from chromosome 4. The distribution of the various repeats suggests its organization is similar to the β-heterochromatic regions near the base of the major chromosome arms. Such a pattern may account for the diffuse banding of the polytene chromosome 4 and the variegation of many P-element transgenes on the chromosome.

Xenopus interspersed RNA families, Ocr and XR, bind DNA-binding proteins

Interspersed RNA makes up two-thirds of cytoplasmic polyadenylated RNA in Xenopus and sea urchin eggs. Although it has no known function, previous work has suggested that at least one family of interspersed RNA, XR, binds Xenopus oocyte proteins, and can influence the rate of translation. We have used two Xenopus repeat families, Ocr and XR, to explore their protein binding abilities. Ocr RNA binds the same pattern of highly abundant oocyte proteins that XR RNA binds, which are believed to be messenger ribonucleoprotein (mRNP) particle proteins. In addition, we show that Ocr RNA binds the Oct-60 protein, a member of the POU-domain family of transcription factors found in Xenopus oocytes. Using a 32 base pair sequence from the XR repeat in a DNA affinity column two proteins were isolated, 66 kDa and 92 kDa, that together form a complex with XR DNA. One of these proteins (92 kDa) also binds XR RNA. We suggest that the role of at least a subset of interspersed RNAs in development may be to bind, and sequester in the cytoplasm, DNA-binding proteins until the end of oogenesis.

Organization of repetitive DNA sequences in the genome of the echinoderm Holothuria tubulosa

The abundance of repetitive DNA in the haploid sea cucumber genome has been determined by screening a Holothuria genomic DNA library for clones containing repeated sequences using reverse genome hybridization. Analysis by in situ plaque hybridization of a set of 1132 clones has revealed the presence of repetitive DNA sequences in about 38.1% of the clones screened. The distribution of the reiterated DNA has been further analyzed by restriction endonuclease digestion of seven randomly selected repetitive clones. The repeated sequences have a fairly uniform distribution of lengths with an average length value of 7.3 kb. Analysis of the measurements suggests that the repetitive sequences are interspersed among longer single copy sequences with an average spacing interval of about 47.3 kb indicating that the repetitive and single copy DNA in the Holothuria genome are arranged in a long-period interspersion pattern.

Modulation of sea urchin actin mRNA prevalence during embryogenesis: nuclear synthesis and decay rate measurements of transcripts from five different genes

The parameters determining the prevalence of the five actin gene transcripts that are differentially expressed during embryogenesis in the sea urchin Strongylocentrotus purpuratus were measured in vivo. These results and previous studies show that the developmental appearance of the cytoskeletal actin mRNA, CyI, CyIIa, CyIIb, and CyIIIa, and the muscle-specific actin message M, is transcriptionally regulated. The cytoskeletal actin genes are activated at the 64-cell stage or shortly thereafter. At this stage the specification of the early embryonic lineages has just completed. M gene transcription was detected only after muscle cells appear in the late embryo. The CyI, CyIIa, and CyIIb genes are transcribed at a moderate rate that does not vary significantly during development. In contrast, during late cleavage CyIIIa transcripts are produced at the maximum rate observed for structural genes in this embryo. In later stages, CyIIIa transcription is reduced at least 30-fold. The rate at which new actin transcripts enter the cytoplasm was also measured. The data show that essentially all primary actin gene transcripts are processed into mature messages. Actin message stability does not change during development. The mRNA half-life of the various messages was found to range from 4 hr to greater than 14 hr.

Genome evolution in mosquitoes: intraspecific and interspecific variation in repetitive DNA amounts and organization

DNA reassociation kinetics were used to determine the amounts and organization of repetitive and unique DNA in four mosquito species:Anopheles quadrimaculatus(Say),Culex pipiens(L.),Aedes albopictus(Skuse) andAe. triseriatus(Say). Intraspecific variation in repetitive DNA amounts was examined in two geographic strains ofAe. albopictusfom Calcutta, India and the island of Mauritius. Repetitive and unique sequences inAn. quadrimaculatuswere distributed in a pattern of long period interspersion. Repetitive DNA in all other mosquito species exhibited a pattern of short period interspersion. The amounts of fold-back, middle repetitive, and highly repetitive sequences increased with genome size. The amount of foldback DNA increased at a much slower rate than the middle and highly repetitive sequences. Intraspecific variation in genome size inAe. albopictuswas due primarily to the amounts of highly repetitive DNA. S1 nuclease digestion of repetitive DNA in all species revealed a positive correlation between genome size and the proportion of the repetitive DNA consisting of short repeats. The amounts of long and short repeats increased with genome size but short repeats increased at a higher rate. The repetitive DNA of the Mauritius strain contained approximately 15% more short repeats than the Calcutta strain. These findings suggest that genome evolution in mosquitoes has resulted from changes in both the amounts and organization of repetitive elements.

Sea urchin actin gene linkages determined by genetic segregation

Genetic linkage between the actin genes of Strongylocentrotus purpuratus was investigated by observing the segregation of restriction fragment length polymorphisms (RFLPs). Specific RFLPs of actin gene pairs CyI/CyIIa and CyIIIa/CyIIIb always cosegregated, confirming the linkage groups CyI-CyIIa-CyIIb previously previously determined by molecular cloning. In contrast, RFLPs of actin genes CyI/CyIIa, CyIIIa/CyIIIb, and M all segregated at random with respect to one another. This demonstrates that the known actin gene clusters CyI-CyIIa-CyIIb, CyIIIa-CyIIIb, and the M actin gene are not closely linked.

Structure and evolution of a family of interspersed repetitive DNA sequences in Caenorhabditis elegans

The structure of three members of a repetitive DNA family from the genome of the nematode Caenorhabditis elegans has been studied. The three repetitive elements have a similar unitary structure consisting of two 451-bp sequences in inverted orientation separated by 491 bp, 1.5 kb, and 2.5 kb, respectively. The 491-bp sequence separating the inverted 451-bp sequences of the shortest element is found adjacent to one of the repeats in the other two elements as well. The combination of the three sequences we define as the basic repetitive unit. Comparison of the nucleotide sequences of the three elements has allowed the identification of the one most closely resembling the primordial repetitive element. Additionally, a process of co-evolution is evident that results in the introduction of identical sequence changes into both copies of the inverted sequence within a single unit. Possible mechanisms are discussed for the homogenization of these sequences. A direct test of one possible homogenization mechanism, namely homologous recombination between the inverted sequences accompanied by gene conversion, shows that recombination between the inverted repeats does not occur at high frequency.

DNA sequence organization in the genomes of three related millet plant species

A major portion of the genomes of three millet species, namely, barn yard millet, fox tail millet and little millet has been shown to consist of interspersed repeat and single copy DNA sequences. The interspersed repetitive DNA sequences are both short (0.15-1.0 kilo base pairs, 62-64% and long (>1.5 kilo base pairs, 36-38%) in barn yard millet and little millet while in fox tail millet, only long interspersed repeats (>1.5 kilo base pairs) are present. The length of the interspersed single copy DNA sequences varies in the range of 1.6-2.6 kilo base pairs in all the three species. The repetitive duplexes isolated after renaturation of 1.5 kilo base pairs and 20 kilo base pairs long DNA fragments exhibit a high thermal stability with Tms either equal to or greater than the corresponding native DNAs. The S1 nuclease resistant repetitive DNA duplexes also are thermally stable and reveal the presence of only 1-2% sequence divergence.The present data on the modes of sequence arrangement in millets substantiates the proposed trend in plants, namely, plants with 1C nuclear DNA content of less than 5 picograms have diverse patterns of sequence organization while those with 1C nuclear DNA content greater than 5 picograms have predominantly a short period interspersion pattern.

Characterization of the genome of Arabidopsis thaliana

The small crucifer Arabidopsis thaliana has many useful features as an experimental organism for the study of plant molecular biology. It has a four-week life-cycle, only five chromosomes and a genome size less than half that of Drosophila. To characterize the DNA sequence organization of this plant, we have randomly selected 50 recombinant lambda clones containing inserts with an average length of 12,800 base-pairs and analyzed their content of repetitive and unique DNA by various genome blot, restriction digestion and RNA blot procedures. The following conclusions can be drawn. The DNA represented in this random sample is composed predominantly of single-copy sequences. This presumably reflects the organization of the Arabidopsis genome as a whole and supports prior conclusions reached on the basis of kinetics of DNA reassociation. The DNA that encodes the ribosomal RNAs constitutes the only major class of cloned nuclear repetitive DNA. It consists of approximately 570 tandem copies of a heterogeneous 9900-base-pair repeat unit. There is an average of approximately 660 copies of the chloroplast genome per cell. Therefore, the chloroplast genome constitutes the major component of the repetitive sequences found in A. thaliana DNA made from whole plants. The inner cytosine residue in the sequence C-C-G-G is methylated more often than the outer in the tandem ribosomal DNA units, whereas very few differences in the methylation state of these two cytosine residues are detected in unique sequences.

Persistence and integration of cloned DNA in postembryonic sea urchins

Cloned DNA was injected into the cytoplasm of unfertilized sea urchin eggs which were then fertilized and cultured in the laboratory through metamorphosis. The exogenous DNA replicated manyfold and persisted for weeks in a majority of growing larvae, as shown by hydridizing "dot blots" of the DNA of single individuals with appropriate labeled probes. After metamorphosis 5-15% of the juvenile sea urchins retained the exogenous sequences. Genomic integration of the exogenous sequence was observed in the DNA of a postmetamorphosis juvenile.

Informational content of the echinoderm egg

The sea urchin egg contains a store of mRNA synthesized during oogenesis but translated only after fertilization, which accounts for a large, rapid increase in the rate of synthesis of largely the same set of proteins synthesized by eggs. Starfish oocytes contain a population of stored maternal mRNA that becomes actively translated upon GVBD and codes for a set of proteins distinct from that synthesized by oocytes. The sequence complexity of RNA in echinoderm eggs is about 3.5 x 10(8) nucleotides, enough to code for about 12,000 different mRNAs averaging 3 kb in length. About 2-4% of the egg RNA functions as mRNA during early embryonic development; most of the sequences are rare, represented in a few thousand copies per egg, but some are considerably more abundant. Many of the stored RNA sequences accumulate during the period of vitellogenesis, which lasts a few weeks. The mechanisms of storage and translational activation of maternal mRNA are not well understood. Histone mRNAs are sequested in the egg pronucleus until first cleavage, but other mRNAs are widely distributed in the cytoplasm. The population of maternal RNA includes many very large molecules having interspersed repetitive sequence transcripts colinear with single-copy sequences. The structural features of much of the cytoplasmic maternal RNA is thus reminiscent of incompletely processed nuclear precursors of mRNA. The functional role of these strange molecules is not understood, but many interesting possibilities have been considered. For instance, they may be segregated into different cell lineages during cleavage and/or they may become translationally activated by selective processing during development. Maternal mRNA appears to be underloaded with ribosomes when translated, possibly because the coding sequences are short relative to the size of the mRNA. Most abundant and many rare mRNA sequences persist during embryonic development. The rare sequence molecules are replaced by newly synthesized RNA, but some abundant maternal transcripts appear to persist throughout embryonic development. Most of the proteins present in the egg do not change significantly in mass during development, but a few decline or accumulate substantially. Together, these observations indicate that much of the information for embryogenesis is stored in the egg, although substantial changes in gene expression occur during development.

A study of chromosomal organization of repetitive DNA sequences by in situ hybridization

Chromosomal DNA restriction fragments from Triturus cristatus carnifex, were cloned in pBR322. Five clones containing repetitive DNA sequences were analysed in terms of size, repetition frequencies, GC contents and interspersion patterns. All the data suggest that the cloned sequences are typical for the major repetitive classes found in carnifex and represent members of individual repetitive families. All five cloned sequences hybridize in situ to nascent RNA transcripts on lampbrush loops present in the heteromorphic region of chromosome 1. One of the cloned sequences is interesting in that it shows individual variation. The least repeated sequences are transcribed at many more loci than the more highly repeated sequences and are better represented in the total ovarian RNA.

Interspersed sequence organization and developmental representation of cloned poly(A) RNAs from sea urchin eggs

A random primed complementary DNA (cDNA) clone library constructed from total maternal poly(A) RNA of sea urchin eggs was screened with two cloned genomic repetitive sequence probes. Sets of cDNA clones reacting with each of these repetitive sequences were recovered. Most of the cloned transcripts included both single copy and repeat sequence elements. Except for the shared repeat sequence element, both the repetitive and single copy regions of the members of each set of clones failed to crossreact. Single copy probes linked to the repeats on the cloned maternal RNAs are represented in an asymmetric manner. It follows that many different genomic members of a given dispersed repeat sequence family are represented in the maternal RNA. RNA gel blots carried out with several repeat probes display about 10 to 20 prominent maternal poly(A) RNAs containing transcripts of each repetitive sequence family. The interspersed maternal transcripts are 3000 to 15,000 bases in length. Maternal transcripts reacting with single copy probes derived from the cloned cDNAs persist during embryonic development, and in some cases appear to be augmented by similar, newly synthesized embryo transcripts. Two examples were found in which additional transcripts of different length appear at specific developmental stages. The transcribed single copy regions are highly polymorphic in the genomes of different individual sea urchins, and comparisons of closely related sea urchin species showed that both the prevalence and length of specific maternal transcripts change rapidly during evolution. Nucleotide sequences of two homologous repeat elements occurring on different cloned transcripts displayed translation stop codons in every possible reading frame. These repeat sequences display structural features suggesting that there has been evolutionary transposition into transcription units active during oogenesis. The repeat elements and their flanking single copy regions reside either in very long 3' or 5'-terminal sequences, or in unprocessed intervening sequences in the maternal poly(A) RNA. These findings lead us to the proposal that the majority of the cytoplasmic poly(A) RNA in echinoderm eggs and early embryos is similar in form to RNAs that occur in the nucleus rather than to the messenger RNA of later cells.

Structural analysis of repetitive sequence elements transcribed in early development of Xenopus laevis

A cDNA library prepared from mRNA of Xenopus laevis embryos was screened with a genomic DNA fragment containing various transcribed repetitive sequence elements. Comparison of the nucleotide sequence of two isolated cDNAs and their genomic relatives allows one to define two transcribed repetitive sequence elements. One of them belongs to a highly reiterated family and consists of a tandem array of homologous subunits of 77-80 bp. The other is reiterated approximately 2200 times, has a size of 260 bp and displays a conserved region of 135 bp. The data are consistent with the presence of repetitive sequence transcripts in the 3' part of mRNA molecules.

Clustered genes require extragenic territorial DNA sequences

This paper is concerned with the basic question as to whether there exists a complex interaction between DNA sequences which have little specific function and functional genes regarding the spatial arrangement of the gene. Since gene clusters are a characteristic and basic feature of gene structure in higher eukaryotes, the size of extragenic DNA sequences surrounding the individual genes of various clustered gene families were compared. The size of the intergenic region, which is composed of the extragenic DNA sequences flanking the 3'-end of one gene and those flanking the 5'-end of the other gene, of the paired genes increases as the genes becomes larger. However, such a gene size-dependent increase is not seen if the total gene size of the paired genes is less than 0.3 kb or greater than 4 kb. The results suggests that a higher eukaryote gene requires extragenic territorial DNA sequences surrounding it, which presumably are necessary to maintain the gene's active functions.

Nuclear deoxyribonucleic acid characterization of the marine chromophyte Olisthodiscus luteus

Nuclear DNA of the marine chromophytic alga Olisthodiscus luteus was analyzed in this study. Reassociation kinetics analysis has shown that 440-nucleotide DNA fragments from the genome of this alga contain 4% foldback, 58% repetitive, and 34% single-copy sequences. Precise analysis using isolated single-copy DNA revealed that Olisthodiscus has a large haploid DNA content of 1.66 x 10(-12) g/cell. For determination of the organization of single-copy and repetitive sequences within this genome, DNA fragments 3000 nucleotides in length were reassociated to C0t= 100 M . s. At this low C0t value 89% of the DNA bound to hydroxylapatite, suggesting that single-copy and repetitive elements are interspersed. The lengths of the duplexed repetitive DNA on these 3000-nucleotide fragments were measured by electron microscopy after digestion with S1 nuclease which removed the unreassociated single-copy DNA regions. Of these repetitive sequences, 68% were shorter than 1200 nucleotide pairs in length and had a modal length of 350 nucleotide pairs. A minor class of longer (to 4000 nucleotide pairs) repetitive sequences was also observed.

Long and short repeats of sea urchin DNA and their evolution

Repeated sequences cloned from the DNA of the sea urchin S. purpuratus were used as probes to measure the lengths of individual families of repeats. Some probes reassociated much more rapidly with preparations of long repeats than with short repeats while others reassociated more rapidly with short repeats than with long repeats. In this way two of five cloned repeats were shown to represent families with a great majority of sequences in the long class. One represented a family with similar number of long and short class members. Two were members of predominantly short class families - The cloned repeats representing long class families, formed more precise duplexes than those representing short class families. Thermal stability measurements using S. purpuratus or S. franciscanus driver DNA showed that precise repetitive sequences have as great an interspecies sequence difference as the less precise repeats. Thus the precision of many families may result from recent multiplication rather than from selective pressure on the DNA sequences. Measurements of evolutionary frequency change show a clear correlation between the frequency change and the size of families of repeats in S. purpuratus. Comparison with S. franciscanus indicates that many of the large size families in S. purpuratus are those that have grown in size since these two species diverged.

Repeated deoxyribonucleic acid clusters in the chicken genome contain homologous sequence elements in scrambled order

Part of the repeated deoxyribonucleic acid (DNA) in the chicken genome had a clustered organization. The following description of clustered repeated sequences is derived both from analysis of DNA segments cloned in lambda and from hybridization of individual cloned sequences to Southern blots of restricted total DNA. A cluster usually exceeds 20 kbp in length and consists principally, if not entirely, or repetitive DNA. Each cluster contains one cope of several different repeated sequences. The individual sequences occur several hundred times in the genome, but only once per cluster. Many of the clusters contain the same assortment of sequences but in scrambled order. In the genome, those repeated sequences that are elements of clusters occur mainly within the clustered context and are seldom, if ever, found as isolated elements flanked by nonrepeated DNA. These aspects of cluster organization suggest that the clustered sequences undergo limited rearrangement, maintaining the associations within clusters but allowing variability of sequence arrangement from cluster to cluster. The clusters that occupy the cloned DNA segments together represent at least 10% of the repetitive DNA of the chicken.

DNA sequence organization in the flax genome

The complexity of the flax genome has been determined by reassociation kinetics. The total complexity of one constituent genome was 3.5 . 10(8) nucleotide pairs. The single copy sequences comprised 44% of the genome and showed a long period interspersion pattern with the repetitive sequences. The repetitive sequences occurred in clusters which stretched for at least 10 000 base pairs. Within these clusters the individual repetitive elements were about 650 base pairs. These elements themselves showed little interspersion of different frequency classes in lengths less than 3000 base pairs. The repetitive sequence duplexes formed on reassociation, except for the satellite DNA, showed a high thermal stability. The fold-back DNA comprised 1% of the total genome, and was itself clustered in a small fraction of the genome.