Single-strand and double-strand cleavage at half-modified and fully modified recognition sites for the restriction nucleases Sau3a and Taqi

The influence of cytosine methylation on the cleavage of DNA by the restriction nucleases Sau3A and TaqI has been investigated. Bovine satellite DNA fragments containing a GATCGA sequence, i.e. a Sau3A site overlapping with a TaqI site have been used in this study. The methylation of these fragments has been determined by sequence analysis. It has been found that a TaqI site (TCGA) methylated at cytosine in both DNA strands is still sensitive to double-strand cleavage. A Sau3A site (GATC), however, is rendered resistant to double-strand cleavage by methylation of a single cytosine. Fragments containing the "half-modified" Sau3A site are nicked in the unmethylated DNA strand. It has been shown by sequence analysis of nicked DNA that the single-strand break occurs at the same position which is cleaved in unmodified DNA.     

Cloning and nucleotide sequence of the genes coding for the Sau96I restriction and modification enzymes.

The genes coding for the GGNCC specific Sau96I restriction and modification enzymes were cloned and expressed in E. coli. The DNA sequence predicts a 430 amino acid protein (Mr: 49,252) for the methyltransferase and a 261 amino acid protein (Mr: 30,486) for the endonuclease. No protein sequence similarity was detected between the Sau96I methyltransferase and endonuclease. The methyltransferase contains the sequence elements characteristic for m5C-methyltransferases. In addition to this, M.Sau96I shows similarity, also in the variable region, with one m5C-methyltransferase (M.SinI) which has closely related recognition specificity (GGA/TCC). M.Sau96I methylates the internal cytosine within the GGNCC recognition sequence. The Sau96I endonuclease appears to act as a monomer.     

Nucleotide sequence of a highly repetitive component of rat DNA.

A highly repetitive component of rat DNA which could not yet be enriched by density gradient centrifugation was isolated with the help of the restriction nuclease Sau3AI. This nuclease converted the bulk of the DNA to small fragments and left a repetitive DNA component as large fragments which were subsequently purified by gel filtration and electrophoresis. This DNA component which was termed rat satellite DNA I is composed of tandemly repeated 370 bp blocks. According to sequence analysis the 370 bp repeats consist of alternating 92 and 93 bp units with homologous but not identical sequences. Methylation of CpG residues was correlated to the rate of cleavage by restriction nucleases. Significant homologies exist between the sequences of rat satellite DNA I and satellite DNAs of several other organisms. The divergence of the sequence of rat satellite DNA I was discussed with respect to evolutionary considerations.     

Microtubule-associated protein MAP2 preferentially binds to a dA/dT sequence present in mouse satellite DNA

Microtubule-associated protein MAP2 binds to the Sau96.1 restriction monomer fragment of mouse satellite DNA. This fragment is also present in a lower proportion in bulk DNA. The digestion of MAP2-Sau96.1 fragment complex by DNase results in the protection of certain nucleotide sequences. The sequence poly(dA)4/poly(dT)4 is mainly protected against DNase digestion.     

Sequence analysis of bovine satellite I DNA (1.715 gm/cm3).

The 1402 bp Eco RI repeating unit of bovine satellite I DNA (rho CsCl = 1.715 gm/cm3) has been cloned in pBR322. The sequence of this cloned repeat has been determined and is greater than 97% homologous to the sequence reported for another clone of satellite I (48) and for uncloned satellite I DNA (49). The internal sequence structure of the Eco RI repeat contains imperfect direct and inverted repeats of a variety of lengths and frequencies. The most outstanding repeat structures center on the hexanucleotide CTCGAG which, at a stringency of greater than 80% sequence homology, occurs at 26 locations within the RI repeat. Two of these 6 bp units are found within the 31 bp consensus sequence of a repeating structure which spans the entire length of the 1402 bp repeat (49). The 31 bp consensus sequence contains an internal dodecanucleotide repeat, as do the consensus sequences of the repeat units determined for 3 other bovine satellite DNAs (rho CsCl = 1.706, 1.711a, 1.720 gm/cm3). Based on this evidence, we present a model for the evolutionary relationship between satellite I and the other bovine satellites.     

Restriction endonuclease/nick translation of fixed mouse chromosomes: A study of factors affecting digestion of chromosomal DNA in situ

We used a restriction endonuclease/nick translation procedure to study the ability of certain enzymes, known to cleave mouse satellite DNA in solution, to attack satellite DNA in fixed mouse chromosomes. Although AvaII and Sau96I readily attack the mouse major satellite in fixed chromosomes, BstNI and EcoRII do not normally do so, although if the heterochromatin is uncondensed as a result of culture in the presence of 5-azacytidine, BstNI can attack it. No clear evidence was obtained for digestion in situ of the minor satellite of mouse chromosomes by MspI, the only enzyme reported to cleave this satellite. Our results show that the DNA of mouse heterochromatin is not merely not extracted by certain restriction enzymes, but is actually not cleaved by them. Chromatin conformation is therefore shown to be an important factor in determining patterns of digestion of chromosomes by restriction endonucleases.by D. Schweizer     

Genetic variability in a family of satellite DNAs from tilapia (Pisces: Cichlidae).

We have cloned and sequenced members of a family of satellite DNAs from three genera of the tilapiine tribe of fishes: Oreochromis, Sarotherodon, and Tilapia. The satellite DNAs, visualized as intensely staining bands following electrophoretic separation of EcoRI-digested genomic DNA, consist of three size variants differentially distributed in the various tilapiine species. The sizes of the monomers are approximately 237 bp (type I), 230 bp (type II), and 209 bp (type III). Several cloned monomers were sequenced from Oreochromis niloticus (type III), Oreochromis placidus (types I and II), Sarotherodon galilaeus (type I), Tilapia zillii (type I), and Tilapia rendalli (type I). Comparison of derived consensus sequences for the monomer units of the satellite DNAs revealed sequence identities within and between species that ranged from 89 to 96%. The type II and type III size variants appear to have arisen by deletions of 9 and 29 bp, respectively, within different regions of the type I satellite. Hybridization of a cloned monomer satellite from O. niloticus (type III) to PalI digests of genomic DNA from all three genera detected polymorphic, high molecular weight restriction fragments that produced fingerprint-like patterns. The complexity of these DNA fingerprints varied from one species to another, suggesting a markedly different genomic organization for these polymorphic satellite DNAs.     

Positioning of a Nucleosome on Mouse Satellite DNA Inserted into a Yeast Plasmid Is Determined by Its DNA Sequence and an Adjacent Nucleosome

It has earlier been shown that multiple positioning of nucleosomes on mouse satellite DNA is determined by its nucleotide sequence. To clarify whether other factors, such as boundary ones, can affect the positionings, we modified the environment of satellite DNA monomer by inserting it into a yeast plasmid between inducible GalCyc promoter and a structural region of the yeast FLP gene. We have revealed that the positions of nucleosomes on satellite DNA are identical to those detected upon reconstruction in vitro. The positioning signal (GAAAAA sequence) of satellite DNA governs nucleosome location at the adjacent nucleotide sequence as well. Upon promoter induction the nucleosome, translationally positioned on the GalCyc promoter, transfers to the satellite DNA and its location follows the positioning signal of the latter. Thus, the alternatives of positioning of a nucleosome on satellite DNA are controlled by its nucleotide sequence, though the choice of one of them is determined by the adjacent nucleosome.     

A second site-specific restriction endonuclease from Staphylococcus aureus.

A site-specific restriction endonuclease has been isolated from Staphylococcus aureus PS 96. This enzyme, Sau96 I, recognizes the DNA sequence 5'--G-G-N-C-C--3' and cleaves as indicated by the arrows. The enzyme 3'--C-C-N-G-G--5' cleaves adenovirus type 5 and lambda DNA many times, SV40 DNA 10 times and 0X174 RF DNA 2 times. Evidence is presented that the enzyme is involved in biological restriction-modification.     

Yeast thioredoxin genes

Based on the conserved protein sequence of thioredoxins from yeast and other organisms, two primers were synthesized for polymerase chain reaction of yeast genomic DNA. A 34-base pair (bp) sequence around the active site of yeast thioredoxin was obtained from the polymerase chain reaction product. This specific sequence was used as a probe in Southern blot analysis of total yeast genomic DNA digested with various restriction enzymes. Under conditions of high stringency, more than one DNA species hybridized with the probe, suggesting that more than one gene encodes yeast genomic library. Two Sau3A1 fragments, 825 and 2045 bp, respectively, from two different clones were cloned into pUC13. Sequence analysis of these fragments gave two different open reading frames without introns. The 825-bp Sau3A1 fragment encodes a 103-amino acid residue protein named thioredoxin I. The 2045-bp Sau3A1 fragment contains a sequence encoding thioredoxin II which has 102 amino acid residues. This is the first report of the cloning and sequencing of eukaryotic thioredoxin genes from any source. Both yeast thioredoxins contain a dithiol active site sequence, Cys-Gly-Pro-Cys. Thioredoxins I and II show 78% amino acid sequence identity. They display more amino acid sequence similarity with mammalian thioredoxin than with Escherichia coli and plant chloroplast thioredoxins.     

Evolution of Tribolium madens (Insecta,Coleoptera) Satellite DNA Through DNA Inversion and Insertion

Two different satellite DNAs from tenebrionid speciesTribolium madens (Insecta, Coleoptera) have been detected, cloned, and sequenced. Satellite I comprises 30% of the genome; it has a monomer size of 225 by and a high A + T content of 74%. Satellite 11, with a monomer size of 711 by and A + T content of 70%, is less abundant, making 4% of the total DNA. Sequence variability of the monomers relative to consensus sequence is 4.1% and 1.2% for satellite I and II, respectively. Both satellites are localized in the heterochromatic regions of all chromosomes. A search for internal motifs showed that both satellites contain a related subsequences, about 100 by long. The creation of satellite I monomer is explained by duplication of the basic subunit, followed by subsequent divergence by single point mutations, deletions, and gene conversion. Inversion of the subsequence in addition to its duplication has occurred in satellite II. The result of this inversion is possible formation of a long, stable dyad structure. The 408-bp sequence, inserted within satellite II monomer, shares no similarity with a basic subunit. Frequent direct repeats found within the inserted sequence point to its evolution by duplication of shorter motifs. It is proposed that both satellites have been derived from a common ancestral sequence whose duplication played a major role in the formation of satellite I monomer, while insertion of a new sequence together with inversion of an ancestral one induced the occurrence of satellite II. Correspondence to: D. Ugarković     

Direct visualization of the genomic distribution and organization of two cervid centromeric satellite DNA families

Several repetitive DNA fragments were generated from PCR amplifications of caribou DNA using primer sequences derived from the white-tailed deer satellite II DNA clone OvDII. Two fragments, designated Rt-0.5 and Rt-0.7, were sequenced and found to have 96% sequence similarity. These caribou clones also had 85% sequence similarity with OvDII. Multiple-colored fluorescence in situ hybridization (FISH) studies with satellite I and satellite II DNA probes to caribou metaphase chromosomes and extended chromatin fibers provided direct visualization of the genomic organization of these two satellite DNA families, with the following findings: (1) Cervid satellite I DNA is confined to the centromeric regions of the acrocentric autosomes, whereas satellite II DNA is found at the centromeric regions of all chromosomes except for the Y. (2) For most acrocentric chromosomes, the satellite I signal appeared to be medially located at the primary constriction, in contrast to that of satellite II, which appeared to be oriented toward the lateral sides as two separate fluorescent dots. (3) The satellite II clone Rt-0.7 appeared to be enriched in the centromeric region of the caribou X chromosome, a pair of biarmed autosomes, and a number of other acrocentric autosomes. (4) Fiber-FISH demonstrated that the satellite I and satellite II arrays were juxtaposed. On highly extended chromatin fibers, the total length of the hybridization signals for the two satellite DNA arrays often reached 300-400 microm. The length of a given satellite II array usually reached 200 microm, corresponding to 2 x 10(3) kb of DNA in a given centromere.     

Positioning of nucleosomes in satellite I-containing chromatin of rat liver

The location of nucleosomes on rat satellite I DNA has been investigated using a new approach. Nucleosome cores were prepared from rat liver nuclei with micrococcal nuclease, exonuclease III and nucleases S1. From the total population of core DNA fragments the satellite-containing fragments were isolated by molecular cloning and the complete sequence of 50 clones was determined. The location of nucleosomes along the satellite sequence was found to be non-random. Our results show that nucleosomes occupy a number of positions on satellite I DNA. About 35 to 50% of all nucleosomes are positioned in two corresponding major sites, the remainder in about 16 less preferred sites. The major nucleosome positions are apparently strictly defined with the precision of a single base-pair. These results were confirmed by other approaches, including restriction nuclease digestion experiments. There are good indications of a defined long-range organization of the satellite chromatin fiber in two or more oligonucleosomal arrays with distinct nucleosome configurations.     

Long range periodicities in mouse satellite DNA.

Escherichia coli restriction enzyme II breaks mouse satellite DNA into fragments which form a series of bands on gel electrophoresis. The DNA in the strongest band has a length of 220 to 260 nucleotide pairs and the other bands are multiples of this length. It is shown that these fragments are linked together in long arrays in the satellite sequence. The reassociation register of the DNA is about half the length of the 220 to 260 nucleotide pair fragment. In the electrophoresis pattern of the Eco RII² fragments other weaker bands can be seen. The stronger bands of the minor patterns fall half-way between the bands of the main pattern and the smallest is 120 to 130 nucleotide pairs long. The properties of the minor fragments suggest short spacings of the restriction site which have been produced by unequal crossing-over. The extents of divergence and unequal crossing-over are estimated. From this analysis and the sequence analysis described in the accompanying paper (Biro et al., 1975) it is proposed that mouse satellite DNA consists of an hierarchy of four periodicities which reflect stages in the evolution of the sequence.Digestion of mouse satellite DNA with Hae III produces fragments with the same sizes as those produced by Eco RII, but the yields are much lower. It is suggested that Hae III sites have been introduced by divergence and subsequently spread by unequal crossing-over.     

A novel repetitive DNA sequence in lemon [Citrus limon (L.) Burm.] and related species Bruna

Repetitive DNA sequences constitute a significant component of most eukaryotic genomes, and the isolation and characterization of such sequences provide an insight into the organization of the genome of interest. Here, we report the isolation and molecular characterization of a novel repetitive DNA sequence from the genome of Citrus limon. Digestion of C. limon DNA with MboI produced a prominent fragment of approximately 600 bp. Southern blotting revealed a ladder composed of DNA fragments that are multimers of the 600 bp Mbo I band. This suggests that MboI isolated a novel satellite, named C. limon satellite DNA 600 (CL600). Methylation analyses using Sau3AI-MboI isoschizomers demonstrated that most cytosine residues in the GATC sites of this element were methylated in C. limon. This sequence was also found in related citrus plants, like grapefruit and orange, and the hardiest close relatives of Citrus, such as kumquat and trifoliate orange.     

The DNA sequences of cloned complex satellite DNAs from Hawaiian Drosophila and their bearing on satellite DNA sequence conservation

A class of restriction endonuclease fragments near 185 bp in length and comprising approximately 20% of the genomes of 3 species of Hawaiian Drosophila has been cloned using bacteriophage M13. The nucleotide sequences of 14 clones have been determined and the variation between clones has been found to be due to deletions and base changes. Analyses of uncloned material show that the cloning system itself does not introduce the variation. The variation of the basic repeat within and between species is high; 15% due to deletions and 10% due to base changes. The Drosophila data are similar in many respects to both the 23 bp calf satellite results (Pech et al., 1979b) and those from sequence analyses of the 170 bp primate restriction fragments (Rubin et al, 1979; Donehower et al., 1980, Wu and Manuelidis, 1980). The intraspecies level of base changes and deletions in the calf satellite approaches 25% as does that in the human/African green monkey/baboon comparisons. The between species variation in the primate group is near 35%. Direct sequencing methods thus reveal a widespread sequence heterogeneity in both invertebrate and mammalian satellite systems of long or short repeat length. This heterogeneity does not support the strict sequence conservation implied by the library hypothesis, which claims a functional role in speciation for the rigid conservation of satellite DNA sequences (Fry and Salser, 1977). Furthermore the Drosophila and primate data reveal that satellite DNAs can change rapidly, though nonrandomly, at the nucleotide sequence level in a relatively closely knit group such as the Hawaiian species, as well as in more distantly related species from amongst the primates. We draw two major conclusions. There is no universal attribute of satellite DNA sequence per se, the only biological variable to date being the amount of satellite DNA and its effects in the germ line. Many aspects of satellite DNA evolution conform to Kimura's (1979) concepts of neutrality.     

The spread of sequence variants in Rattus satellite DNAs

The genus Rattus has two related families of satellite DNA: Satellite I consists of tandem arrays of a 370 base pair repeat unit which is a dimer of two 185 base pair portions (a, b) which are about 60% homologous. Satellite I' consists of tandem arrays of a 185 base pair repeat unit (a') which is about 85% homologous to a and 60% homologous to b. R. norvegicus contains only satellite I but R. rattus contains both satellites I and I'. We examined certain aspects of satellite DNA evolution by comparing the spacing at which variant repeat units of each satellite have spread among non-variant repeat units in these two species. With but one exception, in R. rattus, 15 different variant repeat units have spread among non-variant repeat units of satellite I, with a spacing equal to the length of the (a,b) dimer. Similarly, fourteen different variant repeat units of the monomeric satellite I' have mixed among non-variant repeat units with a spacing equal to the length of the (a') monomer. These results suggest that a mechanism involving homologous interaction among satellite sequences could account for the spread of variant family members. We also found that a sequence variant present in certain portions of the dimeric repeat unit of satellite I is more efficiently amplified (or less efficiently corrected) than variants occurring in other regions. This was not true for the monomeric repeat unit of satellite I'.