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.     

Characterization of variant Neurospora crassa mitochondrial DNAs which contain tandem reiterations.

Two variant mtDNA types ((types IIa and HI-10) have been identified in individual subcultures of the extra-nuclear [poky] mutant of Neurospora crassa. Eco RI digests of type IIa mtDNA are characterized by an extra band, alpha, Mr = 1.4 Mdal, which arises from tandemly inserted reiterations of a 1.4 Mdal sequence. Restriction enzyme analysis and Southern hybridization experiments show: that the 1.4 Mdal repeats are located at the junction of Eco RI-4 and -6, that the repeats contain sequences ordinarily present in Eco RI-4 and -6, that the repeats are oriented head-to-tail and that the number of repeats per molecule (n) varies from n = 0 to n = 8, with about half of the molecules containing no repeats. The 1.4 Mdal repeats appear to be actively mained in type IIa mtDNA populations as a result of a specific alteration in mtDNA. Data are presented which suggest that this alteration may be located near small deletions and/or sequence changes in Eco RI-3 and -10, fragments almost exactly opposite the site of the repeats on the genome. The second variant, HI-10 mtDNA, arose in a heteroplasmic strain in which type IIa mtDNA was one component. The most striking feature of HI-10 mtDNA is the up to 5-fold amplification of an 18 Mdal segment extending from Eco RI-4 (the site of the 1.4 Mdal repeats) through the rRNA genes. Eco RI digests show that HI-10 possesses characteristic features of type IIa mtDNA, including the 1.4 Mdal repeats and the alteration in Eco RI-10. HI-10 mtDNA also shows a novel Eco RI fragment, beta, Mr = 2.9 Mdal. The variant Neurospora mtDNAs may be generated by mechanisms analogous to those which give rise to defective mtDNAs of yeast petite mutants. The possible consequences of defective mtDNAs in obligately aerobic organisms are discussed.     

Characterisation of the telomeres at opposite ends of a 3 Mb Theileria parva chromosome.

Bacteriophage lambda clones containing Theileria parva genomic DNA derived from two different telomeres were isolated and the nucleotide sequences of the telomeric repeats and adjacent telomere-associated (TAS) DNA were determined. The T.parva telomeric repeat sequences, a tandem array of TTTTAGGG or TTTAGGG interspersed with a few variant copies, showed a high degree of sequence identity to those of the photosynthetic algae Chlamydomonas reinhardtii (97% identity) and Chlorella vulgaris (87.7% identity) and the angiosperm Arabidopsis thaliana (84.4% identity). Unlike most organisms which have been studied, no significant repetitive sequences were found in the nucleotide sequences of TAS DNA located centromere-proximal to the telomeric repeats. Restriction mapping and hybridisation analysis of lambda EMBL3 clones containing 16 kilobases of TAS DNA derived from one telomere suggested that they did not contain long regions of repetitive DNA. The cloned TAS DNAs were mapped to T.parva Muguga genomic SfiI fragments 8 and 20, which are located at opposite ends of the largest T.parva chromosome. A 126 bp sequence located directly centromere-proximal to the telomeric repeats was 94% identical between the two cloned telomeres. The conserved 126 bp sequence was present on all T.parva Muguga telomeric SfiI fragments.     

Location of DNA sequences complementary to small nuclear repeat RNA (fr 3-RNA) in relation to DNA sequences coding for albumin and alpha-fetoprotein in rat liver cells

Rat liver nuclei contain a 29-nucleotides-long RNA (fr 3-RNA) which is transcribed from middle repetitive DNA sequences. By Southern analysis of restriction fragments of rat albumin and alpha-fetoprotein genomic clones, DNA sequences complementary to this RNA were detected on a 4.6 kbp Eco RI fragment located 600 bp downstream from the termination exon of the albumin gene and on a 2 kbp Eco RI-HindIII fragment located 10 kbp downstream from the restriction fragment containing the alpha-fetoprotein site. No sequence complementary to this RNA was found either in the introns of exons of both genes or in the regions extending 7 kbp upstream from the first albumin exon and 10 kbp upstream of the first alpha-fetoprotein exon. We concluded that sequences complementary to fr 3-RNA are present at the 3'-end flanking regions of the rat albumin and alpha-fetoprotein gene complexes.     

Occurrence of reiterated sequences in an untranslated region of Simian virus 40 DNA determined by nucleotide sequence analysis.

An earlier report (Subramanian, Dhar, and Weissman, 1977c) presented the nucleotide sequence of Eco RII-G fragment of SV40 DNA, which contains the origin of DNA replication. The nucleotide sequence of Eco RII-N fragment located next to Eco RII-G on the physical map of SV40 DNA is presented in this report. Eco RII-N is found to be a tandem duplication of the last 55 nucleotides of Eco RII-G. This tandem repeat is immediately preceded by two other reiterated sequences occurring within Eco RII-G, one of them being a tandem repeat of 21 nucleotides and the other a nontandem repeat of 10 nucleotides. These repetitive sequences occur in close proximity to the origin of DNA replication which is known to contain other specialized sequences such as a few palindromes (one of which is 27 long and possesses a perfect 2-fold axis of symmetry), one "true" palindrome, and a long A/T-rich cluster. The repeats (and the replication origin) occur within an untranslated region of SV40 DNA flanked by (the few) structural genes coding for the "late" proteins on the one side and that (those) coding for the "early" protein(s) on the other side. The reiterated sequences are comparable in some respects to repetitive sequences occurring in eucaryotic DNAs. Possible biological functions of the repeats are discussed.     

The ovalbumin gene: alleles created by mutations in the intervening sequences of the natural gene.

Two allelic forms of the natural chicken ovalbumin gene have been independently cloned. These alleles differ from each other by an Eco RI restriction cleavage site in one of the seven intervening sequences within the natural ovalbumin gene. Restriction endonuclease mapping and sequence analyses of these cloned genotypic alleles have shown identical sequence organization and molecular structures of the interspersed structural and intervening sequences except for the particular Eco RI cleavage site. Sequencing data of the cloned DNA suggest that this Eco RI site may be created or eliminated by a single base mutation in the intervening sequence of the ovalbumin gene. The occurrence of apparent homozygous and heterozygous allelic forms of the ovalbumin gene in individual hens and roosters within the same breed has been observed. 10 and 40% of the chickens examined are homozygous for the ovalbumin gene with and without the extra Eco RI site, respectively, while 50% of them are heterozygous. Further analysis of individual chicken DNA cleaved by restriction endonuclease Hae III has revealed that there may be a series of such mutational variations within the ovalbumin gene. We have identified two Hae III cleavage sites that do not occur in all of the chickens, thus giving rise to several additional allelic variations of the ovalbumin gene. At least one of these Hae III sites is situated in the intervening sequence of the ovalbumin gene, and its lcoation has been mapped. Such allelic variations must be taken into consideration when determining eucaryotic gene structure by restriction mapping of the genomic DNA. Furthermore, this type of mutation within the intervening sequences of an eucaryotic gene has no known phenotypic manifestation. It represents an extrastructural silent mutation that must be taken account of in studies to estimate the rates of eucaryotic gene sequence divergence during evolution.     

Genetic Mapping of a Possible New Alcohol Dehydrogenase Sequence to Mouse Chromosome 3 at the Adh-1/Adh-3 Complex

Southern blot analysis of mouse genomic DNA reveals two Eco RI fragments which faintly hybridize to mouse Adh-1 cDNA and are not part of the Adh-1 gene. These fragments were isolated from agarose gels, cloned, and characterized. Sequence analysis of the 2.1-kb Eco RI fragment suggests that it is likely a pseudogene since it does not contain a long open reading frame. However, the 2.0-kb Eco RI fragment contains a coding sequence with a long open reading frame which corresponds to exon 6 of the mouse Adh-1 gene. Comparison of the coding sequence with other known ADHs suggests that the sequence has diverged sufficiently from any currently known class of ADH to be a possible distinct class. Further confirmation awaits analysis of currently available genomic clones. Using these sequences as probe, restriction fragment length polymorphisms were identified for each sequence between C57Bl/6J and DBA/2J inbred mouse strains. The strain distribution pattern for these allelic differences was determined among the B × D recombinant inbred strains. This analysis revealed that the 2.1-kb Eco RI sequence is located on chromosome 3 but at a distance from the Adh-1/Adh-3 complex as previously reported. However, the new polymorphism identified in the 2.0-kb Eco RI fragment enabled this sequence to be mapped at the Adh-1/Adh-3 complex.     

A chicken middle-repetitive DNA sequence which shares homology with mammalian ubiquitous repeats.

We have identified and sequenced two members of a chicken middle repetitive DNA sequence family. By reassociation kinetics, members of this family (termed CRl) are estimated to be present in 1500-7000 copies per chicken haploid genome. The first family member sequenced (CRlUla) is located approximately 2 kb upstream from the previously cloned chicken Ul RNA gene. The second CRl sequence (CRl)Va) is located approximately 12 kb downstream from the 3' end of the chicken ovalbumin gene. The region of homology between these two sequences extends over a region of approximately 160 base pairs. In each case, the 160 base pair region is flanked by imperfect, but homologous, short direct repeats 10-15 base pairs in length. When the CRl sequences are compared with mammalian ubiquitous interspersed repetitive DNA sequences (human Alu and Mouse Bl families), several regions of extensive homology are evident. In addition, the short nucleotide sequence CAGCCTGG which is completely conserved in ubiquitous repetitive sequence families from several mammalian species is also conserved at a homologous position in the chicken sequences. These data imply that at least certain aspects of the sequence and structure of these interspersed repeats must predate the avian-mammalian divergence. It seems that the CRl family may possibly represent an avian counterpart of the mammalian ubiquitous repeats.     

Base sequence studies of 300 nucleotide renatured repeated human DNA clones

A band of 300 nucleotide long duplex DNA is released by treating renatured repeated human DNA with the single strand-specific endonuclease S₁. Since many of the interspersed repeated sequences in human DNA are 300 nucleotides long, this band should be enriched in such repeats. We have determined the nucleotide sequences of 15 clones constructed from these 300 nucleotide S₁-resistant repeats. Ten of these cloned sequences are members of the Alu family of interspersed repeats. These ten sequences share a recognizable consensus sequence from which individual clones have an average divergence of 12.8%. The 300 nucleotide Alu family consensus sequence has a dimeric structure and was evidently formed from a head to tail duplication of an ancestral monomeric sequence. Three of the remaining clones are variations on a simple pentanucleotide sequence previously reported for human satellite III DNA. Two of the 15 clones have distinct and complex sequences and may represent other families of interspersed repeated sequences.     

Deoxyribonucleic acid sequence organization in the genome of the dinoflagellate Crypthecodinium cohnii

Details of the general DNA sequence organization in the dinoflagellate Crypthecodinium cohnii have been obtained by using hydroxylapatite binding experiments, S1 nuclease digestion .and electron microscopy of reassociated DNA. It has been found that roughly half of the genome is made up of unique sequences interspersed with repeated sequence elements with a period of approximately 600 nucleotides. This class represents roughly 95% of the total number of interspersed unique elements in the genome. The remaining 5% are uninterrupted by repeated sequences for at least 4000 nucleotide pairs. The interspersed repeated elements are narrowly distributed in length with 80% under 300 nucleotide pairs in length. About half of the repeated DNA (20-30% of the genome) is not interspersed among unique sequences. The close spacing of the short repeats interspersed throughout much of the genome is consistent with the occurrence of the huge network structures observed in the electron microscope for low Cot reassociation of moderately long fragments. An unusual class of heteroduplexes was detected in the electron microscope which is believed to derive from the reassociation of repeated sequences from different families which are frequently found adjacent to one another in different locations in the genome. The occurrence of this novel arrangement of repeated sequences may reflect the unusual organization of the dinoflagellate nucleus. However, in most respects the sequence arrangement in this unicellular alga is very typical of higher plants and animals.     

Evidence that populations of Dictyostelium single-copy mRNA transcripts carry common repeat sequences.

Two recombinant plasmids, M4 and KH10, carrying Dictyostelium DNA inserted into the Eco RI restriction endonuclease site of pMB9 by poly(dA)-poly(dT) tailing, were selected for study because they are complementary to abundant mRNA populations from Dictyostelium. Both plasmids have been shown to hybridize a heterogeneous size class of mRNAs which, in the case of KH10, comprise 5-10% of the pulse-labeled poly(A)+ RNA from vegetative cells. Analysis of the sequence organization of the two pieces of Dictyostelium DNA shows that they consist mostly of single-copy sequences with a short DNA sequence which is repeated in the genome and interspersed with single-copy DNA. These and other results suggest that the majority of the hybridization of pulse-labeled mRNA to M4 and KH10 is to the short "repeated" DNA sequences. In the genome, members of these repeat families appear to be transcribed onto a population of different single-copy mRNAs. Additional results show that M4 DNA contains a sequence which is entirely complementary to a discrete mRNA.     

Sequence organization of the human genome

The organization of three sequence classes—single copy, repetitive, and inverted repeated sequences—within the human genome has been studied by renaturation techniques, hydroxylapatite binding methods, and DNA hyperchromism. Repetitive sequence classes are distributed throughout 80% or more of the genome. Slightly more than half of the genome consists of short single copy sequences, with a length of about 2 kb interspersed with repetitive sequences. The average length of the repetitive sequences is also small and approximates the length of these sequences found in other organisms. The sequence organization of the human genome therefore resembles the sequence organization found in Xenopus and sea urchin. The inverted repeats are essentially randomly positioned with respect to both sequence class and sequence arrangement, so that all three sequence classes are found to be mutually interspersed in a portion of the genome.     

The ovalbumin split gene: molecular cloning of Eco RI fragments "c" and "d".

The Eco RI fragments "c" and "d" of the ovalbumin gene (1, 2) have been isolated by molecular cloning. Restriction enzyme mapping and electron microscopy have confirmed that the two fragments contain the same ovalbumin mRNA coding sequences. These sequences are split into two regions which have been mapped in fragments "c" and "d". There is no evidence that the ovalbumin mRNA sequences contained in these fragments could be further interrupted. Our results confirm that the presence of Eco RI fragment "d" in some chickens is due to the existence of an allelic variant of the ovalbumin gene which contains an additional Eco RI site within the region corresponding to Eco RI fragment "c". This additional Eco RI site appears to be the main difference between the two alleles. Finally, our results provide a direct demonstration that most of the ovalbumin mRNA sequences are encoded for by Eco RI fragments "a", "b" and "c".     

DNA fragments associated with chromosome scaffolds

Following extensive digestion of HeLa metaphase chromosomes with either Hae III endonuclease or micrococcal nuclease, nonhistone protein scaffolds may be isolated. Scaffolds isolated after Hae III digestion have about 1.5% of the chromosomal DNA attached to them. This DNA is heterogeneous in size, ranging from about 0.2 to 20 kbp. It can be cleaved with either Eco RI or Hae III - Eco RI, producing a series of repeated fragments, of which the most abundant is 1.7 kbp in length. The 1.7-kdp fragment is tandemly repeated and is enriched (about 50-fold) in the scaffold-associated DNA. It is located primarily on human chromosome 1 and is probably a component of human satellites II and III. Scaffolds isolated after micrococcal nuclease digestion have about 0.1% of chromosomal DNA attached. This DNA is present in two size classes - fragments larger than 10 kbp and fragments approximately 0.2 kbp long. Restriction enzyme digestion of this DNA gives no prominent repeated fragments. Its reassociation kinetics are similar to those of total DNA, indicating that it is not enriched in either highly repetitive or middle repetitive sequences.     

Heteroduplexes of phiX174 and G4 DNAs: orientation to genetic map and comparison with predictions from nucleotide sequences.

Heteroduplexes between the viral DNA of phiX174 and DNA from the replicative form (RF) of phage G4 were examined by electron microscopy. The single Eco RI site of G4-RF was utilized as a physical marker by preparing the heteroduplexes from the denatured, linear DNA obtained by restricting G4-RF with Eco RI endonuclease. Restriction fragments of phiX were used in a separate series of heteroduplexes to align the heteroduplex map and the G4 Eco RI site with the similar genetic maps of the two phages. The positions of the branch migrating junctions of recombinant phiX-G4 figure-8s, previously located only with respect to the G4-Eco RI site, have now been located with high proability within the gene A region of the two genomes. The degree of mismatch between the known nucleotide sequences of phi X and G4 accounts for positions of all of the regions of single-strandedness in the observed heteroduplexes, but unexplained discrepancies were also found.     

Isolation and characterization of cloned human fetal globin genes.

Three clones containing both the human G gamma and A gamma globlin genes have been isolated and characterized from a library of DNA fragments generated by partial Eco RI digestion of cellular DNA using charon 4A phage as vector. Two of the clones (NY 2 and 3) are identical and have an insert of 14.0 kb. The third clone (NY 1) has a 15.4 kb insert by virtue of an extra 1.4 kb Eco RI fragment at its 5' most end. This clone also has a Kpn I site not present in the other two suggesting it is the product of the gamma gene on the opposite chromosome. Restriction analysis of the three clones indicates that the G gamma and A gamma genes are linked on a single continuous piece of DNA and are separated by 3.5 kb and each contains at least one large intervening sequence of 0.85 kg between the Bam HI and Eco RI sites. These findings in cloned DNA provide direct evidence for linkage and organization of the gamma genes in man.     

Characterization of the primate-specific repetitive DNA element MER1.

Computer analyses of the 3'-flanking DNA sequence of the human elastase I gene revealed a significant degree of similarity with seven human gene sequences in the GenBank and EMBL databases. Genomic Southern analysis indicates that the shared nucleotide sequences are a primate-specific family of short interspersed elements. These elements are members of MER1 sequences (medium reiteration frequency sequences). The consensus sequence of MER1 repeats spans 543 nucleotides and contains several inverted repeats. Since the copy number of MER1 elements seems to be much smaller than that of Alu and L1 repeats, MER1 elements may provide useful landmarks marks for human genome mapping.