Nucleotide sequence of the BALB/c mouse beta-globin complex

The nucleotide sequence of 55,856 base-pairs containing all seven beta-globin homologous structures from chromosome 7 of the BALB/c mouse is reported. This sequence links together previously published sequences of the beta-globin genes, pseudogenes and repetitive elements. Using low stringency computer searches, we found no additional beta-globin homologous sequences, but did find many more long interspersed repetitive sequences (L1) than predicted by hybridization. L1 is a major component of the mouse beta-globin complex with at least 15 elements comprising about 22% of the reported sequence. Most open reading frames greater than 300 base-pairs in the cluster overlap with L1 repeats or globin genes. Polypurine, polypyrimidine and alternating purine/pyrimidine tracts are not evenly dispersed throughout the complex, but they do not appear to be excluded from or restricted to particular regions. Several regions of intergenic homology were detected in dot-plot comparisons of the mouse sequence with itself and with the human beta-globin sequence. The significance of these homologies is unclear, but these regions are candidates for further study in functional assays in erythroid cell lines or transgenic animals.     

Localization and characterization of members of a family of repetitive sequences in the goat beta globin locus.

We have characterized a family of repetitive DNA elements in the beta-globin locus of the goat. These sequences are structurally analogous to the Alu families of repeats of other mammals. Repetitive elements are located both in the intervening sequences and in the intergenic regions of the goat beta-globin locus. Nucleotide sequence analysis of five repetitive elements located within the large intervening sequence of the beta-like globin genes, and four repeats located 5' to the major developmentally regulated beta-globin genes has resulted in the definition of a consensus sequence for this family of repeats.     

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.     

Location of DNA sequences complementary to small nuclear repeat RNA (fr 3-RNA) in relation to DNA sequences coding for albumin and α-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 α-fetoprotein genomic clones, DNA sequences complementary to this RNA were detected on a 4.6 kbp EcoRI fragment located 600 bp downstream from the termination exon of the albumin gene and on a 2 kbp EcoRI-HindIII fragment located 10 kbp downstream from the restriction fragment containing the α-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 α-fetoprotein exon. We concluded that sequences complementary to fr 3-RNA are present at the 3′-end flanking regions of the rat albumin and α-fetoprotein gene complexes.     

Analysis of rat repetitive DNA sequences.

Parameters of repetitive sequence organization have been measured in the rat genome. Experiments using melting, hydroxylapatite binding, and single strand specific nuclease digestion have been used to measure the number, length, and arrangement of repeated DNA sequences. Renaturation and melting or S1 nuclease digestion of 1.0 kbp DNA fragment show about 20% of rat DNA sequences are 3000-fold repeated. Renatured duplexes from 4.0 kbp DNA fragments display two repetitive size fractions after nuclease digestion. About 60% of the repeated sequences are 0.2-0.4 kbp long while the remainder are longer than 1.5 kbp. The arrangement of the repeated sequences has been measured by hydroxylapatite fractionation of DNA fragments of varying lengths bearing a repeated sequence. Repeated DNA sequences are interspersed among 2.5 kbp long nonrepeated sequences throughout more than 70% of the rat genome. There are approximately 350 different 3000-fold short repeated sequences in the rat interspersed among 600,000 nonrepeated DNA sequences.     

Short interspersed repeats from Xenopus that contain multiple octamer motifs are related to known transposable elements.

We have identified in an intron of an X. laevis alpha-tubulin gene a member of a novel family of short (226-431 bp) interspersed repetitive elements. We have isolated other members of this family, which we term Ocr, from ovary cDNA and genome libraries and have identified another two in the published sequences of an H1B histone gene cluster and an actin gene intron. The termini of the Ocr elements are formed by a 19 bp inverted repeat that has clear sequence homologies to those of certain large transposable elements, such as 1723 (Xenopus) and Ac (maize). However, the Ocr elements do not appear to be deletion derivatives of larger transposons. The internal regions of the Ocr elements contain multiple copies of the octamer motif (ATTTGCAT) arranged as divergently-orientated dyads. We have shown by a gel mobility shift assay that these octamer dyads specifically bind what is presumably an OTF-type activator protein in oocyte nuclear extracts. We speculate that short interspersed repetitive families of this type may be generated by a mechanism of replicative transposition that uses a DNA intermediate and involves the interaction of DNA-binding proteins also utilised in other cellular processes.     

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.     

Essential role of duplications of short motif sequences in the genomic evolution of Bombyx mori

Summary The Bombyx fibroin gene has a discrete mosaic structure of various repetitive sequences, which may have evolved through various repeating arrangements. Detailed sequence analysis of the fibroin gene containing coding and noncoding regions revealed that the whole sequence could be arranged as an array of short repetitive sequences. A portion of the intron of the fibroin gene is one of interspersed repetitive elements. We cloned a 1.5-kb DNA fragment of the Bombyx genome that contains interspersed elements homologous to the intron sequence. Sequence comparison between the intron and the 1.5-kb fragment shows that partial duplication has frequently occurred in evolutionary progress, and the resultant repetitive blocks of short motif sequences are abundant in the genome. These facts suggest that tandem duplication of the short motif sequence is an important rearrangement in genomic evolution of the fibroin gene. Offprint requests to: S. Ichimura     

Sequence organization of the rat genome by electron microscopy.

The size and arrangement of repetitive and inverted repeat (foldback) sequences in rat DNA were studied by visualization of hybrid and heteroduplex structures in the electron microscope. The self-reassociation of repetitive sequence-bearing DNA strands often results in the formation of four-ended "H" structures, whose duplex regions equal the repetitive sequence length and can be measured in the electron microscope. In this way, it was determined that the average size of the class of numerous short repetitive sequences is 0.40 +/- 0.15 kbp. Heteroduplex structures were prepared between long whole DNA single strands and short repeat-sequence-bearing strands. The analysis of these structures confirms that the size of the repetitive sequences in 0.4 kbp on average. Length measurements between adjacent duplexes show that the average spacing between two interspersed repeats is at least 1.5-1.8 kbp. By examining 29.4-kbp single strands after brief renaturation, the size and distribution of foldback sequences were determined. There are 1.9 X 10(5) foldback apirs per rat genome, spaced an average of 9.7 kbp apart according to our measurement. Repetitive, inverted repeat and unique sequences are interspersed with each other in at least half the genome.     

The organization of repetitive sequences in the albumin and alpha-fetoprotein gene loci in the rat

Summary The distribution of middle repetitive sequences in the genic and extragenic regions of the rat albumin and -fetoprotein genes was analyzed. Their presence was determined by probing Southern blots of restriction fragments of albumin and -fetoprotein genomic subclones with ³²P-labeled total rat DNA. Repetitive sequences were detected in both genes. They were classified as weak, moderate and intense hybridizing elements according to the intensity of hybridization. Weak repetitive sequences were characterized as dG·dT repeats by using ³²P-labeled poly-(dG·dT)(dC·dA) oligomer probe. They occurred in 5 and 3 extragenic regions of the two genes and in introns 4 and 5 of the albumin gene. The moderate repetitive sequence present in intron 6 of the albumin gene was identified as the rat SINES element, 4D12. The intense repetitive sequence, localized in the 3 non-coding region of the albumin gene, corresponded to the terminal segment of a rat high repeat long interspersed DNA family, L1Rn. 4D12 and L1Rn sequences were also scattered throughout the -fetoprotein locus as moderate and intense repetitive elements, respectively, but their distribution was different from that of the albumin genomic region. These results indicate that repetitive sequences invaded the two loci in a non-conservative manner.     

The DNA sequence of the 5' flanking region of the human beta-globin gene: evolutionary conservation and polymorphic differences.

We have determined the DNA sequence of a 1464 bp segment immediately flanking the 5' side of the human beta-globin gene. The sequence shows little similarity to the corresponding regions of the epsilon- or gamma-globin genes. There is about 75% homology, however, between the 5' extragenic regions of the beta-globin genes of man, goat and rabbit respectively. The mouse beta minor globin gene, but not the mouse beta major globin gene, also shares this extensive homology. A short segment of simple sequence DNA is found from about 1418 to 1388 bp upstream from the human beta-globin gene which consists of repeats of the sequence (TTTTA). Similar DNA sequences are also found at several sites in the large intron of the beta-globin gene. We have compared the DNA sequence of the 5' extragenic region of the normal beta-globin gene with the same segment of the beta-globin gene of a patient with beta thalassaemia. Of the two nucleotide differences observed, one generates a polymorphic HinfI site present 990 bp upstream from the beta-globin gene in the thalassaemic beta-globin and absent in the normal gene. A second beta thalassemic beta-globin gene which has the same molecular defect as the above mentioned case, however, lacks this HinfI site. It is therefore not yet clear whether this HinfI site will have any value in prenatal diagnosis of beta thalassaemia.     

Sequence organization of variant mouse 4.5 S RNA genes and pseudogenes.

The rodent 4.5 S RNA is an RNA polymerase III product with a sequence related to the Alu family of interspersed repeated DNA. A previous study identified a tandem array of 4.2-kb repeating units that contain the 4.5 S RNA coding sequence as well as many short repetitive sequences. To understand the genomic organization of this gene family, we have isolated and characterized 4.5 S RNA sequences that are part of the tandem array as well as identified members that are not part of the array. One variant 4.5 S RNA gene family member exhibits length polymorphisms in its minisatellite sites relative to the single previously reported gene. The 4.5 S RNA sequences that are not part of the tandem array possess many of the features of processed pseudogenes and are found adjacent to other interspersed repeated elements. These findings suggest that the mouse 4.5 S RNA can behave as a retroposon, resulting in the accumulation of 4.5 S RNA-like elements at many sites in the genome.     

Members of the KpnI family of long interspersed repeated sequences join and interrupt alpha-satellite in the monkey genome.

Three different members of a family (KpnI-family) of interspersed repeated DNA sequences were found linked to alpha-satellite sequences in cloned segments of the African green monkey genome. In two of these segments the KpnI-family member is over 6 kbp in length and one of them is flanked by alpha-satellite on both sides indicating that it was inserted into a satellite array. Hybridization of subcloned portions of the family members to restriction endonuclease digests of monkey and human DNA and to a genomic library of African green monkey DNA indicate that 1) family members are interspersed in both the monkey and human genomes, 2) some family members may include sequences in addition to those in the three characterized here, 3) some family members may contain only parts of the sequences characterized here and 4) while the overall organization of the family is similar in the human and monkey genome the majority of the family members in each of the two genomes are distinctly identified by the variant position of certain restriction endonuclease sites. This last observation suggests that within each genome there is a tendency to maintain particular versions of the sequence. Observations 2) and 3) suggest that the KpnI family is complex and includes a variety of subfamilies.     

Long interspersed repeated sequences of the mouse genome

Long interspersed repeated sequences of the mouse genome can be prepared by digesting reassociated DNA with single-strand nuclease. Length resolution reveals many discrete bands that can be assigned to 15 kbp and 6 kbp groups. The reassociated 6 kbp group (which we identify with the MIF-1 family) possesses significant sequence heterogeneity, evidenced by the production of several smaller fragments upon single-strand nuclease digestion of heteroduplexes. The sites of sequence heterogeneity are relatively few and can be mapped using additional restriction endonuclease cuts. We have mapped additional restriction sites into this group, particularly within a cloned HindIII 400 bp fragment, and have also clearly mapped one end of this relatively homogeneous long interspersed repeated sequence.