Interruption of an alpha-satellite array by a short member of the KpnI family of interspersed, highly repeated monkey DNA sequences.

We describe here the interruption of a cloned African green monkey alpha-satellite array by an 829-base-pair-long nonsatellite DNA segment. Hybridization experiments indicate that the sequences within the interruption are homologous to segments frequently found in the 6-kilobase-pair-long members of the KpnI family of long, interspersed repeats. These data confirm and extend earlier results suggesting that sequences common to the KpnI family can occur independently of one another and in segments of variable lengths. The 829-base-pair-long segment, which is termed KpnI-RET, contains a terminal stretch of adenosine residues preceded by two typical but overlapping polyadenylation sites. KpnI-RET is flanked by direct repeats of a 14-base-pair-long segment of alpha-satellite that occurs only once in the satellite consensus sequence. These structural features suggest that KpnI-RET was inserted into the satellite array as a movable element.

A transcriptionally active monkey genomic segment homologous to the regulatory region of simian virus 40 is associated with DNase I-hypersensitive sites.

Segments of monkey genomic DNA that are homologous to the control region around the origin of replication of simian virus 40 were previously cloned and characterized (Queen et al., Mol. Cell Biol. 1:1061-1068, 1981). We describe here two DNase I-hypersensitive sites that map in the region of monkey chromatin around one such ori-like segment. One of these sites lies within the simian virus 40 homologous segment which is also a site from which transcription initiates bidirectionally (J. Saffer and M. Singer, submitted for publication).

Unit-length line-1 transcripts in human teratocarcinoma cells.

We have characterized the approximately 6.5-kilobase cytoplasmic poly(A)+ Line-1 (L1) RNA present in a human teratocarcinoma cell line, NTera2D1, by primer extension and by analysis of cloned cDNAs. The bulk of the RNA begins (5' end) at the residue previously identified as the 5' terminus of the longest known primate genomic L1 elements, presumed to represent "unit" length. Several of the cDNA clones are close to 6 kilobase pairs, that is, close to full length. The partial sequences of 18 cDNA clones and full sequence of one (5,975 base pairs) indicate that many different genomic L1 elements contribute transcripts to the 6.5-kilobase cytoplasmic poly(A)+ RNA in NTera2D1 cells because no 2 of the 19 cDNAs analyzed had identical sequences. The transcribed elements appear to represent a subset of the total genomic L1s, a subset that has a characteristic consensus sequence in the 3' noncoding region and a high degree of sequence conservation throughout. Two open reading frames (ORFs) of 1,122 (ORF1) and 3,852 (ORF2) bases, flanked by about 800 and 200 bases of sequence at the 5' and 3' ends, respectively, can be identified in the cDNAs. Both ORFs are in the same frame, and they are separated by 33 bases bracketed by two conserved in-frame stop codons. ORF 2 is interrupted by at least one randomly positioned stop codon in the majority of the cDNAs. The data support proposals suggesting that the human L1 family includes one or more functional genes as well as an extraordinarily large number of pseudogenes whose ORFs are broken by stop codons. The cDNA structures suggest that both genes and pseudogenes are transcribed. At least one of the cDNAs (cD11), which was sequenced in its entirety, could, in principle, represent an mRNA for production of the ORF1 polypeptide. The similarity of mammalian L1s to several recently described invertebrate movable elements defines a new widely distributed class of elements which we term class II retrotransposons.

Three segments from the monkey genome that hybridize to simian virus 40 have common structural elements.

Three cloned segments that hybridize to a region of simian virus 40 (SV40) deoxyribonucleic acid including the origin of replication have been isolated from a monkey genomic library. The primary structure of one segment was previously reported (T. McCutchan and M. Singer, Proc. Natl. Acad. Sci. U.S.A. 78:95-99, 1981). We report here the sequences of the other two segments and a comparison of all three. The SV 40-hybridizing region in each segment is limited to several hundred base pairs. All of the segments contain multiple and disconnected sequences homologous to the region of SV40 directly surrounding the viral replication origin. The number and arrangement of the homologous sequences is different in the three segments. However, the segments have the following features in common: (i) each contains multiple copies of the sequence GGGCGGPuPu, which also appears six times near the origin of SV40; (ii) each contains several strong homologies to the central dyad symmetry of SV40; (iii) each contains a long internal repeat, as does the origin region of SV40. The three SV40-hybridizing segments are members of a larger family of genomic sequences that hybridize well to each other, but not necessarily to SV40.

Ribonuclease and high salt sensitivity of the ribonucleoprotein complex formed by the human LINE-1 retrotransposon.

P40 is encoded by the first open reading frame of the human LINE-1 retrotransposon and is found in a large cytoplasmic ribonucleoprotein (RNP) complex, the p40 RNP-complex, in association with LINE-1 RNA(s) in human teratocarcinoma cell lines. We report here investigations on the stability of the p40 RNP-complex against various nucleases and high salt (0.5 M NaCl) treatment. The results indicate that (1) the p40 RNP-complex is dissociated after ribonuclease or high salt treatment, (2) DNase I does not disrupt the complex, (3) after dissociation of the complex, p40 maintain protein-protein interactions but in smaller complexes, and (4) p40 is not associated with the LINE-1 RNA(s) after high salt treatment. These observations suggest that the RNA molecule(s) is(are) essential for the stability of the large p40 complex and that the complex has a structure which allows various nucleases to reach the RNA. These features are distinct from those of typical virus and virus-like particles of retroviruses and other retrotransposons, respectively. Together with the fact that no significant sequence homology exists between p40 and the gag and gag-like proteins, it is likely that the p40 RNP-complex is structurally different from the typical virus and virus-like particles.

Deca-satellite: a highly polymorphic satellite that joins alpha-satellite in the African green monkey genome.

Three different cloned segments of African green monkey DNA that contain alpha-satellite sequences linked to a previously undescribed, distinct monkey satellite (called deca-satellite) are described here. The cloned segments were derived from a monkey DNA library in lambda Charon 4A that was constructed to select for junctions between alpha-satellite and other DNA sequences. The structure of the deca-satellite and of a junction between deca-satellite and alpha-satellite were studied by subcloning appropriate fragments of the original cloned segments and by sequence analysis. Deca-satellite has a ten base-pair repeat unit; the consensus sequence of the repeat units is 5' A-A-A-C-C-G-G-N-T-C. Sequences homologous to the deca-satellite are in the middle repeated class of genomic DNA. Analysis of the organization of deca-satellite sequences by digestion of total DNA with various restriction endonucleases and hybridization with a cloned deca-satellite probe revealed extensive polymorphism in the genomes of different individual monkeys but not among the tissues of one organism. These observations indicate that the arrangement of deca-satellite sequences is continually changing. An unusual alpha-satellite repeat unit occurs at a junction between the alpha-satellite and deca-satellite. It resembles the major baboon alpha-satellite more closely than it does monkey alpha-satellite and thereby provides evidence in favor of the "library" hypothesis for satellite evolution.

Continuous reorganization leads to extensive polymorphism in a monkey centromeric satellite.

Previously we reported the existence of a highly polymorphic satellite, deca-satellite, in the African green monkey genome; deca-satellite probe anneals to complex sets of repeated restriction endonuclease fragments that differ from individual to individual in the monkey population. Here we present experiments aimed at clarifying the structure and organization of deca-satellite sequences and investigating the mechanisms that generate the polymorphisms. Deca-satellite represents less than 1% of the monkey genome but the percentage varies from one monkey to another. The core sequence 5'-C-C-G-G within the ten base-pair deca-satellite repeat unit is well conserved and the central 5'-C-G is sometimes but not always methylated. Restriction endonuclease analysis with BamHI and EcoRI defines separate satellite domains that have evolved in an independent manner. In situ hybridization shows deca-satellite to be located at the centromeric regions of some but not all monkey chromosomes. This location is independently confirmed by a high frequency, in monkey libraries, of segments containing junctions between deca-satellite and alpha-satellite, the main monkey centromeric satellite. The total number of metaphase chromosomes that show centromeric grains after in situ hybridization with a deca-satellite probe varies from one monkey to another. Moreover, in situ hybridization to endoreduplicated diplochromosomes showed that deca-satellite is occasionally distributed asymmetrically on one or the other of the two pairs of sister chromatids in one diplochromosome. This indicates that major reorganization of the satellite can occur frequently in somatic cells. We discuss several possible mechanisms by which deca-satellite sequences could be either amplified or deleted during a single replicative cycle. Also, on the basis of the marked fluidity of deca-satellite abundance and organization and other well-known attributes of centromeric satellites, we suggest that the existence and maintenance of centromeric satellite rests on the role of the tandem repeats themselves and not on any particular nucleotide sequence, repeat length or organization.

Isolation of low-copy-number sequences that neighbor satellite DNA in mammals.

To investigate the role of satellite DNA in eukaryotic genomes, we isolated from an African green monkey (Cercopithecus aethiops) genomic library cloned segments containing the previously described deca-satellite linked to low-copy-number genomic sequences. Three such clones were obtained. The low-copy-number sequences in the three clones do not cross-hybridize suggesting that they derive from different genomic loci. The structure of one of the clones, lambda MkA, is described in detail. Subcloned segments containing the low-copy-number sequences from lambda MkA anneal to monkey, human and mouse genomic DNA. The subcloned probes were used to select clones containing homologous sequences from a second, independent monkey library as well as from human and mouse genomic libraries. Several of the newly isolated monkey clones hybridized to probes containing the species-specific deca- and alpha-satellites, confirming the genomic association of the low-copy-number sequence in lambda MkA with satellite DNA. Moreover, several of the human and mouse clones hybridized to species-specific human and mouse satellite DNAs, respectively. These experiments indicate that the low-copy-number sequence in lambda MkA and its association with satellite DNA is conserved in primates and rodents.

Undermethylation of specific LINE-1 sequences in human cells producing a LINE-1-encoded protein.

Nucleotide sequences near the 5' ends of some long interspersed elements-1 (LINE-1) from Homo sapiens (L1Hs) are undermethylated in cell lines which produce a L1Hs-encoded protein. In contrast, these sequences are methylated in cell lines with little or no detectable L1Hs expression. The fact that the 5' end of L1Hs is differentially methylated in cells exhibiting different levels of L1Hs expression suggests that the methylation state of this region plays a role in L1Hs expression.

LINE-1: a human transposable element.

Among the 10(5) LINE-1 sequences (L1Hs) in the human genome are one or more 6-kb segments that are active retrotransposons. Expression of these retrotransposons appears to be favored in cells of germ line origin, as well as in some other tumor cells of epithelial origin. In such cells, the product of the first L1Hs open reading frame (ORF), a protein called p40, is detectable; p40 has no apparent similarity to gag proteins, but contains a leucine zipper region which may be responsible for the occurrence of p40 multimers. Transcription of L1Hs initiates at residue 1 although the transcriptional regulatory regions are downstream in the first 670 bp of the 5' untranslated region; deletion of a YY1-binding site in the first 20 bp reduces transcription by fivefold. Translation of the second ORF, which encodes reverse transcriptase, is independent of the translation of the frame encoding p40.