RNA Pol II promotes transcription of centromeric satellite DNA in beetles

Transcripts of centromeric satellite DNAs are known to play a role in heterochromatin formation as well as in establishment of the kinetochore. However, little is known about basic mechanisms of satellite DNA expression within constitutive heterochromatin and its regulation. Here we present comprehensive analysis of transcription of abundant centromeric satellite DNA, PRAT from beetle Palorus ratzeburgii (Coleoptera). This satellite is characterized by preservation and extreme sequence conservation among evolutionarily distant insect species. PRAT is expressed in all three developmental stages: larvae, pupae and adults at similar level. Transcripts are abundant comprising 0.033% of total RNA and are heterogeneous in size ranging from 0.5 kb up to more than 5 kb. Transcription proceeds from both strands but with 10 fold different expression intensity and transcripts are not processed into siRNAs. Most of the transcripts (80%) are not polyadenylated and remain in the nucleus while a small portion is exported to the cytoplasm. Multiple, irregularly distributed transcription initiation sites as well as termination sites have been mapped within the PRAT sequence using primer extension and RLM-RACE. The presence of cap structure as well as poly(A) tails in a portion of the transcripts indicate RNA polymerase II–dependent transcription and a putative polymerase II promoter site overlaps the most conserved part of the PRAT sequence. The treatment of larvae with alpha-amanitin decreases the level of PRAT transcripts at concentrations that selectively inhibit pol II activity. In conclusion, stable, RNA polymerase II dependant transcripts of abundant centromeric satellite DNA, not regulated by RNAi, have been identified and characterized. This study offers a basic understanding of expression of highly abundant heterochromatic DNA which in beetle species constitutes up to 50% of the genome.

Cloning and characterization of an extremely conserved satellite DNA family from the root-knot nematode Meloidogyne arenaria

A new satellite DNA family, named pMaE, has been cloned from the genome of the phytoparasitic nematode, Meloidogyne arenaria (Nematoda: Tylenchida). It is represented as tandemly repeated sequences with a monomeric unit of 172 bp. The monomers are present at approximately 15700 copies per haploid genome, and represent about 5.3% of the total genomic DNA. Twenty-seven independent monomers have been cloned and sequenced. The deduced consensus sequence is 70.9% A + T rich, with frequent stretches of A and (or) T. Several direct or inverted sub-repeats are present in the sequence, which may allow the formation of a dyad structure, suggesting some potential role of this repetitive sequence in heterochromatin condensation. The monomers are very homogeneous in sequence, showing on average 1.8% divergence from their consensus sequence. Moreover, Southern blot experiments and sequence analysis of homologous monomers from the genome of geographically distinct M. arenaria populations have shown that this satellite DNA is uniformly distributed and highly conserved within the species. Therefore, it is hypothesized that this unusually low level of variability, either within the genome of a given population or between populations, could be achieved as the result of some highly effective homogenization mechanism acting upon the nematode genome.

Differential diagnosis of Taenia saginata and Taenia solium infection by PCR

We have designed species-specific oligonucleotides which permit the differential detection of two species of cestodes, Taenia saginata and Taenia solium. The oligonucleotides contain sequences established for two previously reported, noncoding DNA fragments cloned from a genomic library of T. saginata. The first, which is T. saginata specific (fragment HDP1), is a repetitive sequence with a 53-bp monomeric unit repeated 24 times in direct tandem along the 1, 272-bp fragment. From this sequence the two oligonucleotides that were selected (oligonucleotides PTs4F1 and PTs4R1) specifically amplified genomic DNA (gDNA) from T. saginata but not T. solium or other related cestodes and had a sensitivity down to 10 pg of T. saginata gDNA. The second DNA fragment (fragment HDP2; 3,954 bp) hybridized to both T. saginata and T. solium DNAs and was not a repetitive sequence. Three oligonucleotides (oligonucleotides PTs7S35F1, PTs7S35F2, and PTs7S35R1) designed from the sequence of HDP2 allowed the differential amplification of gDNAs from T. saginata, T. solium, and Echinococcus granulosus in a multiplex PCR, which exhibits a sensitivity of 10 pg.

A species-specific satellite DNA from the entomopathogenic nematode Heterorhabditis indicus

An AluI satellite DNA family has been cloned from the entomopathogenic nematode Heterorhabditis indicus. This repeated sequence appears to be an unusually abundant satellite DNA, since it constitutes about 45% of the H. indicus genome. The consensus sequence is 174 nucleotides long and has an A + T content of 56%, with the presence of direct and inverted repeat clusters. DNA sequence data reveal that monomers are quite homogeneous. Such homogeneity suggests that some mechanism is acting to maintain the homogeneity of this satellite DNA, despite its abundance, or that this repeated sequence could have appeared recently in the genome of H. indicus. Hybridization analysis of genomic DNAs from different Heterorhabditis species shows that this satellite DNA sequence is specific to the H. indicus genome. Considering the species specificity and the high copy number of this AluI satellite DNA sequence, it could provide a rapid and powerful tool for identifying H. indicus strains.

Characterization of MboI satellites in Cirrhina mrigala and Clarias batrachus (Pisces)

We have cloned and characterized two highly reiterated, tandemly repeated, and A+T rich MboI DNA fragments, one in Cirrhina mrigala (Cyprinidae), with a monomer size of 266 bp, and one in Clarias batrachus (Clariidae), with a monomer size of 227 bp. The MboI fragment in C. mrigala is species-specific and absent in other carps, such as Catla catla and Labeo rohita. The MboI fragment in C. batrachus was also present in two other catfishes tested, namely Clarias gariepinus and Heteropneustes fossilis. In C, mrigala x C. catla and C. mrigala x L. rohita hybrids, the C. mrigala specific MboI fragment is inherited uniparentally. In the reciprocal hybrids of C. batrachus x H. fossilis, the satellite ladder contains the bands of both parental species. The MboI satellite of carp may be useful in genetic introgression analysis and that of catfish in distinguishing between gynogenetic progeny and true hybrids.

Molecular sequences of two minisatellites in blacklip abalone, Haliotis rubra

In the cloning and sequencing of growth-promoting genes of the blacklip abalone, Haliotis rubra (Leach, 1814), two DNA variable number of tandem repeats (VNTRs) were identified in abalone cDNA libraries. One contained a 33 bp repeat unit (5'-CCCAAGGTCCCCAAGGTCAGGGAGGCGAAGGCT-3') located in the 3' untranslated region of a putative growth hormone (GH) gene, and the repeat was designated as GHR. The other contained an 18 bp repeat unit (5'-ACCCGGCGCTTATTAGAG-3') located in the 3' untranslated region of a putative molluscan insulin-related peptides (MIP) gene, and was designated as MIPR. Primers flanking the two VNTR repeat regions were derived from sequence information. One hundred blacklip abalones were collected along the Victorian coastline and used in a preliminary population study. The range of GHR alleles containing the 33 bp basic unit repeat motif included 7 to 20 repeats, with allele GHR 8 not being identified. The most frequent alleles contained GHR 16 and 17 repeats (56.0% and 16.5%, respectively). Four types of alleles were identified in MIPR, viz 4, 5, 6 and 7 repeats. The alleles containing 6 and 5 repeats were the most frequent (50.0% and 41.5%, respectively). Overall, the results indicate that these two DNA minisatellites have use in abalone studies, including paternity resting, triploid testing, population genetic structure, and gene flow.

Polyploid-specific repetitive DNA sequences from triploid ginbuna (Japanese silver crucian carp, Carassius auratus langsdorfi)

Repetitive DNA sequences (Cal3nDr) in the genome of a triploid ginbuna (Carassius auratus langsdorfi) were isolated from the DraI digests of the genomic DNA. This AT-rich (61%) Cal3nDr monomer was 137 bp in length. The nucleotide similarity among the monomers from the same individual was considerably high (above 97%). Hybridization analyses revealed that the Cal3nDr sequences were organized into tandem arrays. These DNA sequences were present only in triploid and tetraploid ginbunas and were absent from diploid ginbuna, gengorobuna, goldfish, and other cyprinid fishes, and therefore appeared to be specific to polyploid ginbunas. In situ hybridization data showed their localization on one to four out of a total of 150 to 156 chromosomes, depending on the individuals or clonal lines, of the triploid ginbuna. The origin of the Cal3nDr sequences is also discussed on the basis of observation of the artificial triploid ginbuna produced by crossing a diploid female with a tetraploid male.

Molecular characterization of two species-specific tandemly repeated DNAs from entomopathogenic nematodes Steinernema and Heterorhabditis (Nematoda:Rhabditida)

Two AluI tandemly repeated DNAs were cloned from two entomopathogenic nematodes: the first one from Steinernema glaseri and the second one from Heterorhabditis bacteriophora. The monomeric units of these two satellite DNAs have a repeat length of 174 and 168 bp, respectively. These AluI repeated element families appear to constitute 5.5% of the S. glaseri genome and 5% of the H. bacteriophora genome. Their A + T contents were estimated at 55% and 57%. Moreover, the monomers of these two families are quite homogeneous in sequence, showing, on average, 3.9% and 2.7% divergence from their respective consensus sequence. These results suggest that some mechanism is acting to maintain the homogeneity of these repeated DNAs despite their abundance. We have also shown that these two DNA families are species-specific and therefore could be used for the identification of Steinernema and Heterorhabditis entomopathogenic nematode species.

A tandemly repetitive DNA sequence is present at diverse locations in the genome of Ostertagia circumcincta

A novel repetitive DNA sequence in the sheep parasitic nematode Ostertagia circumcincta was cloned and sequenced. This 1.2-kb sequence (Oc1B) was not found in the closely related cattle parasite Ostertagia ostertagi, nor in the more distantly related sheep parasites Haemonchus contortus or Trichostronylus colubriformis. Sequences similar to Oc1B were found at various genomic locations and contained a pair of 33-bp direct repeats. Oc1B also contained a single copy of a 218-bp sequence (designated OcREP) which was present in 100 to 200 copies in the O. circumcincta genome and mostly organized in distinctive tandem arrays. The dual organizational pattern of OcREP as both a satellite-like sequence as well as interspersed as single copies amongst dissimilar sequences adds to the growing evidence for the fluidity of the parasitic nematode genome, and of eukaryotic genomes in general.

A new EcoRI family of satellite DNA in lampreys

Satellite DNA sequences have been studied in several groups of organisms. However, until now this type of sequence has not been characterized in cyclostomata, an evolutionarily important class of vertebrates. In the present work, we report the molecular characterization of a new family of satellite DNA in lampreys (Petromyzon marinus). Digestion of lamprey DNA with EcoRI identified a series of very abundant AT-rich (60% A+T) repeating units, with short stretches of AT, that are multimers of 370 bp. Southern blot analysis and comparison with the satellite DNA sequences deposited in the databases indicate that this new family of satellite DNA is exclusive to lampreys. The distribution of this EcoRI satellite DNA on lamprey chromosomes was analyzed by in situ hybridization. The evolutionary origin of this satellite is briefly discussed.

Characterization of a human alphoid satellite DNA sequence: potential use in assessing genetic diversity in Indian populations

Sequence analysis of a human repetitive DNA sequence (pTRF5.6) revealed considerable homology (76%) to the alphoid consensus sequence. Genomic blots of StuI-digested human DNA, hybridized to pTRF5.6, generated a ladder of bands with each band corresponding to oligodeoxyribonucleotide of an approx. 170-bp repeat, indicating a tandemly arrayed organization of this repeat element within the genome. Genomic hybridization analyses of unrelated individuals belonging to various geographical regions of India, using this alphoid satellite prove, revealed polymorphic bands ranging between 2 and 9 kb. Along with an individual-specific band pattern, several isomorphic bands below 2 kb were also evident. There was very little genetic variability between populations, suggestive of low polymorphism at the inter-population level. Our result suggest that alphoid satellite sequence probe can be used in assessing the genetic diversity of various ethnic groups/populations belonging to different geographical regions.

Characterization of a complex satellite DNA in the mollusc Donax trunculus: analysis of sequence variations and divergence

A highly repetitive sequence in the genomic DNA of the bivalve mollusc Donax trunculus (Dt) has been identified upon restriction with EcoRV. During the time-course of DNA digestion, genomic fragments resolved electrophoretically into a ladder-like banding pattern revealing a tandem arrangement of the repeated elements, thus representing satellite DNA sequences. Cloning and sequence analysis unraveled the presence of two groups of monomer units which can be considered distinctive satellite subfamilies. Each subclass is distinguishable by the presence of 17 evenly spread diagnostic nucleotides (nt). The respective consensus sequences are 155 bp in length and differ by 11%, while relevant internal substructures were not observed. The two satellite subfamilies constitute 0.23 and 0.09% of the Dt genome, corresponding to 20 000 and 7600 copies per haploid complement, respectively. Sequence mutations often appear to be shared between two or more monomer variants, indicating a high degree of homogenization as opposed to that of random mutational events. Shared mutations among variants appear either as single changes or in long stretches. This pattern may arise from gene conversion mechanisms acting at different levels, such as the spread of nt sequences of a similar length to the monomer repeat itself, and the diffusion of short tracts a few bp long. Subfamilies might have evolved from the occasional amplification and spreading of a monomer variant effected by gene conversion events.

Expression profiling of mRNA obtained from single identified crustacean motor neurons: determination of specificity of hybridization

The purpose of this study was to determine if the technique of expression profiling would allow us to determine the changes in the abundance of certain mRNAs in identifiable, single neurons as a result of heightened electrical activity. In doing so we developed an approach to test the specificity of hybridization in expression profiling. Messenger RNA from single identified crayfish motor neurons was amplified by ligation-mediated reverse transcription PCR and hybridized by dot-blotting to 45 target cDNAs from different species. As a test of specificity, the hybridization was repeated using unlabelled cDNAs, the dots were excised, and the hybridized nucleic acids were re-amplified, cloned, and sequenced to confirm their identity. By cloning and sequencing the re-amplified product for each cDNA examined, one can determine the degree of background hybridization as compared to homologous hybridization. False positive results were also observed when a species-specific cDNA and highly stringent hybridization conditions were used. Our results demonstrate that ligation-mediated PCR is a useful technique for checking the specificity of expression profiling. This approach can easily be adapted to any situation when confirmation of the specificity of nucleic acid hybridization is required. During this study, part of a novel crayfish neuronal actin cDNA was cloned and sequenced.

Cloning, characterization and chromosomal location of a satellite DNA from the Pacific oyster, Crassostrea gigas

We report the cloning and characterization of a high-copy-number, tandem-repeat satellite DNA sequence from the genome of the Pacific oyster, Crassostrea gigas (Cg). The monomeric unit was found to be 166 (+/- 2) bp in length with 79-94% homology between monomers of the array. The sequence is A+T-rich (60%) and lacks internal repetition and substructural features. The repeat was estimated to account for 1-4% of the Cg genome. Fluorescence in situ hybridization (FISH) studies mapped the repeat to two distinct heterochromatic regions of two pairs of homologous chromosomes on Cg embryonic metaphases. Also, the number of metaphase chromosomes containing this repeat varied with the ploidy of the cell.

Highly polymorphic repetitive sequences in Rhynchosciara americana genome

Rhynchosciara americana genomic DNA when digested with EcoR1 or BamH1 presents visible fragments suggestive of repetitive sequences after fractionation on EtBr stained agarose gels. The cloning and molecular analysis of some of these fragments showed a highly polymorphic family of repetitive sequences. These were mapped by in situ hybridization to telomeres and some heterochromatic regions on polytene chromosomes.

Indirect gene diagnoses for complex (multifactorial) diseases--a review

The analysis of multifactorial diseases requires the efficient investigation of large numbers of (gene) loci and patient (family) samples. Since simple repetitive DNA markers are dispersed all over the chromosomes, molecular techniques employing these tools render most conventional screening procedures obsolete. Examples of tumors, autoimmune diseases and infections are presented to validate concepts of indirect gene diagnoses via simple, tandemly arranged, repetitive DNA sequences. The salient advantages of microsatellite technologies vs. those of multilocus DNA fingerprinting are weighed.

Characterization of a DNA sequence that detects repetitive DNA elements in the Asian rice gall midge (Orseolia oryzae) genome: potential use in DNA fingerprinting of biotypes

We have isolated based on reverse genome hybridization, and sequenced a DNA clone, pNZE25, from a partial genomic library of the Asian rice gall midge Orseolia oryzae (Wood-Mason) (O.o.). Clone pNZE25 is highly A+T rich (67%), lacks any open reading frame and does not display homology to sequences in GenBank. Clone pNZE25 detects a 120-bp repeat in the O.o. genome, as seen from the generation of a 120-bp ladder after Southern analysis of HinfI-digested genomic DNA. When used to probe O.o. genomic DNA digested with DraI, HaeIII or AluI, pNZE25 generates individual specific DNA fingerprints on target DNA isolated from gall midge biotypes collected from different parts of India.

Characterization of a species-specific satellite DNA from the entomopathogenic nematode Steinernema carpocapsae

An HaeIII satellite DNA family has been cloned from the entomopathogenic nematode Steinernema carpocapsae. This repeated sequence appears to be an unusually abundant satellite DNA, since it constitutes about 62% of the S. carpocapsae genome. The nucleotide sequences of 13 monomers have been determined. This satellite DNA family is represented by two sub-families: one with monomeric units of 170 bp and the other with monomeric units of 182 bp. These monomers are quite homogeneous in sequence, showing an average intermonomer variability of 6% from the consensus sequence. These results suggest that some homogenizing mechanism is acting to maintain the homogeneity of this satellite DNA. After hybridization with the genomic DNA of several other Steinernema species, this DNA sequence appears to be specific to the S. carpocapsae genome. Therefore, the species specificity and the high copy number of the HaeIII satellite DNA sequence should provide a rapid and powerful tool which could contribute to the identification of Steinernema species.

Cytoplasmic localization of transcripts of a complex G+C-rich crab satellite DNA

The primary sequence and higher order structures of a G+C-rich satellite DNA of the Bermuda land crab Gecarcinus lateralis have been described previously. The repeat unit of the satellite is approximately 2.1 kb. In exploring a possible function for this satellite, we asked whether it is transcribed. As a probe for transcripts, we used a segment of DNA amplified from a 368 bp EcoRI fragment from the very highly conserved 3' end of the satellite DNA. During polymerase chain reaction (PCR) amplification, the probe was simultaneously either radiolabeled or biotinylated. Tissue- and stage-specific transcripts were observed when blots of poly(A)+ mRNAs recovered from polysomes isolated from crab tissues [including midgut gland (hepatopancreas), limb bud, and claw muscle] were probed with the satellite DNA fragment. The presence of satellite transcripts in polysomal mRNAs is strong evidence that the transcripts had reached the cytoplasm. To corroborate the presence of transcripts in the cytoplasm, we investigated in situ hybridization of satellite probes with RNAs in tissue sections. Biotinylated satellite DNA probes were applied to sections of midgut gland, limb bud papilla, ovary, or testis of anecdysial crabs. Retention of RNAs in tissue sections was improved by UV-irradiation prior to hybridization. Transcripts were abundant in the cytoplasm of all tissues except testis. Sections of crab midgut gland treated with RNase A prior to hybridization and sections of mouse pancreatic tumor served as controls; neither showed any signals with the probe.

Cloning and characterization of two satellite DNAs in the low-C-value genome of the nematode Meloidogyne spp

Two highly reiterated StyI satellite DNAs have been cloned from two nematode species: one from Meloidogyne hapla and another from M. incognita. The monomeric units of these two satellites have a repeat length of 169 and 295 bp, respectively. These StyI repeated element families constitute 5% of the M. hapla and 2.5% of the M. incognita haploid genomes. The A + T content is elevated in both families (i.e., 68% and 77%, respectively). Nucleotide methylation and transcriptional activity are negative. No similarity was found between the two satellites, nor to other known highly repetitive elements. These StyI satellite DNAs are quite homogenous in sequence, showing on average 3% and 3.5% divergence from their respective calculated consensus sequence. An internal subrepeating unit of about 11 bp is observed in the StyI satellite monomer sequences of M. hapla, suggesting that it could have evolved from a shorter sequence. Because of the small size of the Meloidogyne genome (51 Mb) and the abundance of repeated sequences, this genus approaches a limit in terms of coding fraction.

Cloning and characterization of a highly conserved satellite DNA sequence specific for the phytoparasitic nematode Bursaphelenchus xylophilus

The phytoparasitic nematode, Bursaphelenchus xylophilus, contains an unusually abundant satellite DNA which constitutes up to 30% of its genome. It is represented as a tandemly repeated MspI-site-containing sequence with a monomeric unit of 160 bp. Thirteen monomers were cloned and sequenced. The consensus sequence is 62% A+T-rich, with the presence of direct and inverted repeat clusters. Monomers of the sequence are very similar, showing on average 3.9% divergence from the calculated consensus. The results suggest that some homogenizing mechanism is acting to maintain the homogeneity of this satellite DNA despite its abundance and that it is not transcribed.

Presence of highly repetitive DNA sequences in Tribolium flour-beetles

Digestion of genomic DNA from seven species of Tribolium (Coleoptera) with Sau3AI, TaqI and ClaI restriction enzymes shows the presence of remarkable amounts of highly repetitive DNA sequences in these species. In Tribolium freemani the sequences are tandemly repeated with a satellite monomer of 166 bp, A-T rich (70.5 per cent), representing 31 per cent of the total genome and located in centromeric chromosome areas as demonstrated by in situ hybridization. The sequence has the potential to form secondary structures such as stems or cruciforms due to the presence of frequent inverted repeats. Tribolium castaneum, T. anaphe and T. madens show homologous sequences to T. freemani satellite DNA but T. confusum, T. audax, T. brevicornis and other tenebrionid beetles, such as Tenebrio molitor and Misolampus goudoti, do not. A phylogenetic dendrogram, based on the homology and abundance of highly repetitive sequences deduced by dot-blot hybridization, chemotaxonomic and karyological characters, is proposed for the seven studied species of Tribolium.

Dissecting (CAC)5/(GTG)5 multilocus fingerprints from man into individual locus-specific, hypervariable components

Individual components of multilocus fingerprints from man produced by (CAC)5/(GTG)5 oligonucleotides have been scrutinized to characterize their peculiar properties. Successful cloning and changes occurring during the propagation of recombinant simple repetitive DNA in prokaryotic hosts are described. The isolated locus-specific probes were characterized with respect to their formal (and population genetic) properties and their usefulness for individualization and linkage studies. The localization was determined on chromosomes 8, 9, 11, and 22. Repeat flanking sequences were characterized and analyzed for their coding potential because of significant open reading frames and apparent evolutionary conservation among vertebrates. The organization of the repeats and their flanking regions in the human genome is discussed with respect to the sequence (fine) architecture that developed during evolution. Classical "minisatellite" sequences were not detected near hypervariable (cac)n/(gtg)n repeats. The single-copy probes described herein are a convenient complement to the oligonucleotides employed for multilocus fingerprinting. Many practical applications are apparent.

Identification of two families of satellite-like repetitive DNA sequences from the zebrafish (Brachydanio rerio)

To further our understanding of the structure and organization of the zebrafish genome, we have undertaken the analysis of highly and middle-repetitive DNA sequences. We have cloned and sequenced two families of tandemly repeated DNA fragments. The monomer units of the Type I satellite-like sequence are 186 bp long, A+T-rich (65%), and exhibit a high degree of sequence conservation. The Type I satellite-like sequence constitutes 8% of the zebrafish genome, or approximately 8 x 10(5) copies per haploid genome. Southern analysis of genomic DNA, digested with several restriction endonucleases, shows a ladder of hybridizing bands, consistent with a tandem array, and suggests longer range periodic variations in the sequence of the tandem repeats. The Type II satellite has a monomer length of 165 bp, is also A+T-rich (68%), and constitutes 0.2% of the zebrafish genome (22,000 copies per haploid genome). Southern analysis reveals a complex pattern rather than a ladder of regularly spaced hybridizing bands.

Cloning and characterization of a Beta vulgaris satellite DNA family

Three members of the BamHI-sequence family of sugar beet (Beta vulgaris) have been cloned in Escherichia coli and compared by sequence analysis. The sequence family shows the typical features of eukaryotic satellite DNA, e.g., organization in tandem arrays and sequence divergence. A typical ladder pattern of a monomer (327 bp) and multiple oligodeoxyribonucleotides have been observed. The BamHI monomer is A + T-rich (69%) and does not show any similarity to other known plant satellite DNAs.

Chromosomal organization of simple repeated DNA sequences used for DNA fingerprinting

Stretches of short, simple DNA sequences are widespread in all eukaryote genomes studied so far. Simple sequences are thought to undergo frequent expansion and deletion due to intrinsic genomic mechanisms. Some of the simple sequences were used successfully to detect hypervariable loci in various genomes. Hybridization experiments using synthetic probes not only revealed the informative simple repeats suitable for DNA fingerprinting in a particular species, but also reflected the wide range of distribution of the simple sequences among eukaryotes. The organization of these simple repetitive sequences at the chromosomal loci was investigated using in situ hybridization with chemically synthesized, pure oligonucleotide probes. Both biotin- and digoxigenin-attached probes detected specific chromosomal sites that are enriched in the respective simple-repeat blocks. Depending on the organism and probe used, accumulation of simple DNA sequences at individual or multiple sites on the chromosomes of different vertebrates could be demonstrated. The simple repetitive DNA sequences are located in different chromosomal regions (e.g., heterochromatin on the sex chromosomes, nucleolus organizer regions, and R-band sites), which are constrained considerably during evolution.

Two highly reiterated nucleotide sequences in the low C-value genome of Panagrellus redivivus

Two families of highly reiterated satellite nucleotide (nt) sequences have been found in the genome of the sexually separated nematode Panagrellus redivivus. The repeats are arranged in tandem arrays but the different satellites are not intermingled. Monomeric lengths are of 155 bp for one kind and 167 bp for the other; they were named E155 and E167. The A + T content is elevated in both families (i.e., 59.5%, and 65.3%, respectively). No similarity was found between the two satellites nor to other known highly repetitive elements. Furthermore, nt methylation as well as transcriptional activity were negative. An internal subrepeating unit, about 30 bp long, was observed in E167, implying that it could have evolved from a shorter sequence. Reiteration frequencies are approx. 30,000 and 40,000 copies per haploid genome, for E155 and E167, respectively, constituting together about 17% of the total DNA. This figure is astonishingly high, considering a C-value of 70,000 kb in P. redivivus, which is thought to be the lower limit for metazoans. Hence, the genome complexity is approx. 58,000 kb. In contrast to the nematodes Ascaris lumbricoides and Parascaris equorum, however, P. redivivus does not seem to eliminate large blocks of satellite DNA in the presomatic cells during early development.

Intragenomic movement, sequence amplification and concerted evolution in satellite DNA in harvest mice, Reithrodontomys: evidence from in situ hybridization

Three DNA probes isolated from three species of Reithrodontomys (R. montanus, R. megalotis, R. fulvescens) were used to examine within and among species variation in the chromosomal location of satellite DNA and constitutive heterochromatin. These probes hybridized to the centromeric regions on all chromosomes in six species of the subgenus Reithrodontomys. Additionally, nearly all extra-centromeric C-band positive regions (with the exception of some heterochromatic material on the X and Y) hybridized to these probes. Within the subgenus Reithrodontomys both the chromosomal distribution and organization of satellite DNA has changed throughout evolution. The evolutionary transition has been from a totally centromeric position in R. fulvescens to centromeric and non-centromeric regions in other species that have undergone extensive chromosomal rearrangements from the primitive karyotype for peromyscine rodents. In addition, the monomer repeat of the satellite sequence differs between R. fulvescens (monomer defined by PstI) and the remaining species in the subgenus Reithrodontomys (monomer defined by EcoRI). These results suggest at least two amplification events for this satellite DNA sequence. Models and mechanisms concerned with the homogenization and spread of satellite sequences in complex genomes are evaluated in light of the Reithrodontomys data. From a phylogenetic standpoint, the satellite sequences composing heterochromatic regions were restricted to the subgenus Reithrodontomys, which supports morphological differences used to recognize two subgenera, Reithrodontomys and Aporodon. Probes failed to hybridize to any part of the karyotype of R. mexicanus (subgenus Aporodon) or to seven species from other closely related genera (Baiomys, Neotoma, Nyctomys, Ochrotomys, Onychomys, Peromyscus, Xenomys), some of which are considered as potential sister taxa for Reithrodontomys.

A satellite DNA family from pollock (Pollachius virens)

We have cloned and sequenced a highly reiterated EcoRI fragment of DNA from pollock (Pollachus virens). The EcoRI repeat is 200 (+/- 5) bp long, A + T-rich (65%) and exhibits a high degree of sequence conservation among representative members. It comprises 13% of the pollock nuclear DNA with a copy number of 5 x 10(5) per haploid genome. Partial digestion of pollock DNA with EcoRI or Hinf1, which cleaves within the repeat, followed by blot hybridization to a cloned repeat sequence, produced a ladder of hybridising bands indicating a tandemly arrayed organisation for the EcoRI repeat. Longer range periodicities, revealed by restriction endonuclease digestion, are superimposed on the tandem array.

Molecular evolution of centromere-associated nucleotide sequences in two species of canids

The major centromeric satellite nt sequences present in the domestic dog (Canis familiaris) and in the grey fox (Urocyon cineroargenteus) have been examined. The dog satellite monomer is 737 bp long and contains 51% G + C; the grey fox satellite monomer is 880 b long and contains 54% G + C. The two satellites share three regions of 78, 92 and 314 bp with 70-80% sequence similarity. Sequence data from 16 monomers of dog satellite and 19 monomers of grey fox satellite demonstrate that the substitution spectra are different in the two canid species. For example, substitutions involving G or C residues are much more common in the grey fox satellite than in the domestic dog satellite despite their similar G + C contents.

Detection and molecular cloning of highly repeated DNA in the sea cucumber sperm

A highly reiterated sequence in the sperm DNA of the echinoderm Holothuria tubulosa has been isolated by digestion with EcoRI, and cloned in the phagemid Bluescript. The monomeric unit has a repeat length of 391 bp and is arranged in tandem. The uncloned genomic monomer as well as two independent cloned fragments have been sequenced. The repeated element constitutes about 1.8% of total Holothuria DNA which corresponds to a repetition frequency of about 1.4 x 10(5) copies per haploid complement. The repetitive sequence has a high A + T content (66.8%) characterized by scattered tracts of A and T residues with no apparent internal sub-repeats, although several inverted and direct repeats are present. Heterogeneity between monomers derived from individual clones is low, whereas sequence similarity to known repetitive elements appears to be negligible.

Cloning and characterization of a highly repetitive fish nucleotide sequence

We have cloned and sequenced a highly repetitive HindIII fragment of DNA from the common carp Cyprinus carpio. It represents a tandemly repeated sequence with a monomeric unit of 245 bp and comprises 8% of the fish genome. Higher units of this monomer appear as a ladder in Southern blots. The monomeric unit has been sequenced; it is A + T-rich with some direct and some inverse-repeat nucleotide clusters.

The expression of the evolutionarily conserved GATA/GACA repeats in mouse tissues

Simple repeated GATA and GACA sequences were initially identified in sex-specific snake satellite DNA. The organization of these sequences in the mouse genome is described in Schäfer et al. 1986. The expression of these simple repeats was studied here in several mouse tissues using a variety of different probes: oligonucleotides and "single-stranded" as well as nick-translated DNA. The transcription of discrete RNA species was found to be differentially regulated in several organs but sex differences in transcription were not observed. GATA- and GACA-containing cDNA clones were isolated and sequenced and a genomic clone was characterized with respect to the transcription of GATA flanking sequences. Functional aspects of GATCA simple DNA repeats are discussed in terms of internally repetitive, hydrophobic translation products.

Satellite DNA in the crustacean Artemia

We have isolated a satellite fraction from the Artemia genome by both restriction endonuclease digestion and equilibrium density centrifugation in CsCl gradients containing ligand dye Hoechst 33258. Satellite DNA was arranged in long stretches (approx. 23 kb) of tandem repeats of a basic unit of 113 bp. The basic unit has been sequenced, showing a G + C content very close to that of total DNA. Different amounts of satellite were present in several populations of Artemia, whereas it was absent from others.

Centromeric satellite DNA in the newt Triturus cristatus karelinii and related species: its distribution and transcription on lampbrush chromosomes

Two abundant satellite DNA sequences have been identified in and cloned from the DNA of Triturus cristatus karelinii. The smaller of these with a repeat unit of 33 base pairs (bp) is designated TkS1, the larger with 68 bp is designated TkS2. These satellites are also present in DNA from T.c. cristatus, T.c. carnifex and T. marmoratus but in substantially lower copy number. In situ hybridisations to lampbrush chromosomes of T.c. karelinii and T.c. cristatus have shown that the satellites are concentrated in the heterochromatic centromere bars of T.c. karelinii and in a region around the centromere granule in T.c. cristatus. The satellites also bind specifically to the centromere regions of mitotic metaphase chromosomes. They do not bind to the heteromorphic arms of chromosome 1, which have previously been shown to be rich in highly repeated DNA. DNA/RNA-transcript in situ hybrids to lampbrush chromosomes with TkS1 suggest that this sequence is occasionally transcribed on lampbrush loops near the centromeres.

Preferential reaction of the carcinogen N-acetoxy-2-acetylaminofluorene with satellite DNA

The carcinogens N-acetoxy-2-acetylaminofluorene (N-acetoxy-AAF) and N-hydroxy-2-aminofluorene (N-hydroxy-AF) were incubated with calf thymus DNA to determine if reaction occurred preferentially with discrete regions within the DNA. Derivative melting profiles indicated that both compounds decreased satellite transitions and that N-acetoxy-AAF depressed the melting of higher temperature regions. These data suggest that N-acetoxy-AAF reacted to a greater extent with G + C-rich regions and, because the resulting adduct disrupted the helix, the cooperativity of melting decreased. Reaction of N-acetoxy-AAF with purified satellite III DNA confirmed the preferential interaction of this carcinogen with G + C-rich regions as compared to main component DNA. The derivative melting profile of lambda DNA in the presence of actinomycin D further demonstrated that this type of analysis can detect preferential interactions with specific DNA sequences.

Complex organization of a cryptic satellite DNA in the genome of the marine invertebrate Rapana thomasiana Grosse (Gastropoda)

Isopicnic centrifugation in Cs2SO4-Ag+ gradients at pH 7.0 reveals that the genome of the marine snail Rapana thomasiana Grosse (Gastropoda) contains an AT-rich satellite fraction comprising 5% of the DNA. Restriction enzyme analysis shows that the satellite DNA is composed of a number of related subsets arranged in tandem arrays. They have evolved from the segmental amplification of an 1460 bp long monomer unit with a complex inner organization. Most probably, the present basic repeat originates from an ancestral 400-500 bp long sequence in which some insertions and/or deletions have occurred.

Comparison of sequence repetitiveness of human cDNA and genomic DNA using the miniplasmid vector, piVX

We studied the sequence repetitiveness of human cDNA and genomic DNA fragments inserted in the miniplasmid piVX. Sequence repetitiveness was assayed by the frequency with which a given insert mediated recombination between the chimeric miniplasmid and a recombinant bacteriophage library constructed from large random human genomic fragments. The methodology allows rapid analysis and isolation of sequences of a given copy number in the genome: few (1 to 10 copies), low order-repeated (10 to 100 copies) and a more highly repeated (over 100 copies). In a model application of the method, the distribution of these classes of sequences was compared in cDNA and genomic DNA libraries constructed in piVX. The major difference observed between cDNA and genomic DNA repeat structure was the paucity of highly repeated elements in cDNA copies from high-molecular-weight cytoplasmic poly(A) + RNA.

A high amount of satellite DNA in the genome of Lupinus angustifolius L

Embryo DNA, isolated from ungerminated seeds of Lupinus angustifolius L., contains an exceptionally high amount of guanine-cytosine-rich satellite DNA. The thermal denaturation curve of total embryo DNA is biphasic with an inflexion point at 62% denaturation, indicating the presence of satellite DNA. The satellite fraction could be separated from the mainband DNA by three successive preparative CsCl-gradient centrifugations. The densities of the DNA fractions are 1.7045 g cm(-3) and 1.6925 g cm(-3), respectively. The percentages of guanine-cytosine calculated from these densities are comparable to the percentages of GC calculated from the melting temperatures. Finally, ressociation studies prove that foldback DNA and highly repeated sequences are much more frequent in the satellite DNA fraction than in the mainband DNA.

Restriction enzyme analysis of the germ line limited DNA of Ascaris suum

The germ line limited DNA of Ascaris suum was isolated from sperm and testis as a satellite DNA component in Hoechst 33 258 -- CsCl gradients. Employing restriction enzyme analysis, we show that the germ line limited DNA is composed entirely of two families of tandemly repeated sequences, one repeat unit is 125 bp, and the other 131 bp long. The total appr. 5 x 10(5) copies of the two families are physically separated from each other (segmental arrangement). Several repeat unit variants within both families could be detected. The copies of sequence variants are arranged in tandem (subsegmental arrangement). Reassociation and hybridization experiments revealed similar sequences of the two repeat units. The archaeotypic core sequence of both repeat units is probably a tetranucleotide which shows a 'theme and variation' pattern. During chromatin diminution in the presoma cells the satellite DNA is eliminated from the chromosomes. However, a limited number of tandemly repeated copies of both kinds of repeat units could be detected in the soma genome using radioactive probes of both repeat units in Southern blots of muscle and intestine of adult animals. The tandem arrangement and the hierarchical pattern of restriction sites throughout different subfamilies supports the model of successive segmental amplification events during the evolution of the germ line limited DNA. Since the germ line limited satellite DNA is exclusively located at the ends of the chromosomes, a fold back structure for the telomeric DNA sequences is proposed which might have generated this DNA.

Toward a molecular paleontology of primate genomes. I. The HindIII and EcoRI dimer families of alphoid DNAs

Families of related, but nonidentical repetitive DNA sequences, termed the alphoid DNAs, have been identified and characterized in representative species from seven major primate Families. The sequences appear as old as the primate Order itself: they are found in a prosimian (lemur), in a New World monkey, and in all Old World primates examined, including man. The alphoid DNAs are uniquely primate sequences and they may represent the most abundant repetitive DNAs in the primate genome. - A classification scheme for two major families of alphoid DNAs is proposed that is based upon restriction enzyme analysis and Southern blotting with radioactive probes prepared from component alpha DNA (Maio, 1971) and from the human EcoRI dimer sequences (Manuelidis, 1976). The family of alphoid DNAs that hybridizes readily with component alpha is termed the HindIII family of alphoid DNAs. This family shows an almost universal distribution among present-day primates. The family of DNA sequences that hybridizes readily with the human EcoRI dimer probe is termed the EcoRI dimer family of alphoid DNAs. This family may be restricted to the great apes and man. The two probes permitted the discrimination of different, but related alphoid families in present-day primates. Multiple alphoid sequence families are found within the genomes of individual primates and the major primate taxa can be characterized by the representations of the various alphoid DNAs within their genomes. - An Appendix is presented (Brown et al., 1981) indicating that competition hybridization effects may influence the autoradiographic banding patterns, and hence, the interpretations of Southern filter-transfer hybridizations when dealing with related repetitive sequences such as the alphoid DNAs that are present in abundance in eukaryotic genomes.

Repetitive DNA sequences in methotrexate- and methasquin-sensitive and -resistant Chinese hamster cell lines

DNA purified from a Chinese hamster cell line of lung fibroblast origin (DC83F) was analyzed by density gradient centrifugation and by gel electrophoresis after restriction endonuclease digestion in order to fractionate discrete repetitive fractions within the total DNA. No obvious satellite DNAs were resolved using the CsCl or Ag-Cs2SO4 density gradient conditions described herein. However, analysis of the digestion products of a battery of restriction endonucleases indicated that three of these enzymes, EcoR1, HaeIII, and XhoI, yielded discrete fragments which could be visualized with EtBr staining or identified by scintillation counting of [3H]DNA. DNAs from several highly (greater than or equal to hundredfold increased resistance) antifolate-resistant sublines of DC-3F, characterized by a large homogeneously staining region (HSR) in the chromosome complement, were examined with both techniques and compared to the parental, antifolate-sensitive cell line DNA. The density gradient profiles and electrophoretic patterns of restriction endonuclease digests were identical among all the cell lines examined and were indistinguishable from those of the parental DC-3F DNA.