The human LINE-1 reverse transcriptase:effect of deletions outside the common reverse transcriptase domain.

Heterologous expression of human LINE-1 ORF2 in yeast yielded a single polypeptide (Mr145 000) which reacted with specific antibodies and co-purified with a reverse transcriptase activity not present in the host cells. Various deletion derivatives of the ORF2 polypeptide were also synthesized. Reverse transcriptase assays using synthetic polynucleotides as template and primer revealed that ORF2 protein missing a significant portion of the N-terminal endonuclease domain still retains some activity. Deletion of the C-terminal cysteine-rich motif reduces activity only a small amount. Three non-overlapping deletions spanning 144 amino acids just N-terminal to the common polymerase domain of the ORF2 protein were analyzed for their effect on reverse transcriptase activity; this region contains the previously-noted conserved Z motif. The two deletions most proximal to the polymerase domain eliminate activity while the third, most-distal deletion had no effect. An inactive enzyme was also produced by substitution of two different amino acids in a highly-conserved octapeptide sequence, Z8, located within the region removed to make the deletion most proximal to the polymerase domain; substitution of a third had no effect. We conclude that the octapeptide sequence and neighboring amino acids in the Z region are essential for reverse transcriptase activity, while the endonuclease and cysteine-rich domains are not absolutely required.

Sequence-specific single-strand RNA binding protein encoded by the human LINE-1 retrotransposon.

Previous experiments using human teratocarcinoma cells indicated that p40, the protein encoded by the first open reading frame (ORF) of the human LINE-1 (L1Hs) retrotransposon, occurs in a large cytoplasmic ribonucleoprotein complex in direct association with L1Hs RNA(s), the p40 RNP complex. We have now investigated the interaction between partially purified p40 and L1Hs RNA in vitro using an RNA binding assay dependent on co-immunoprecipitation of p40 and bound RNA. These experiments identified two p40 binding sites on the full-length sense strand L1Hs RNA. Both sites are in the second ORF of the 6000 nt RNA: site A between residues 1999 and 2039 and site B between residues 4839 and 4875. The two RNA segments share homologous regions. Experiments involving UV cross-linking followed by immunoprecipitation indicate that p40 in the in vitro complex is directly associated with L1Hs RNA, as it is in the p40 RNP complex found in teratocarcinoma cells. Binding and competition experiments demonstrate that p40 binds to single-stranded RNA containing a p40 binding site, but not to single-stranded or double-stranded DNA, double-stranded RNA or a DNA-RNA hybrid containing a binding site sequence. Thus, p40 appears to be a sequence-specific, single-strand RNA binding protein.

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.

Cytoplasmic ribonucleoprotein complexes containing human LINE-1 protein and RNA.

P40 is the protein encoded by the first open reading frame (ORF1) of the human LINE-1 (L1Hs) retrotransposon; it is 338 amino acids long, has a leucine zipper motif and has been found in human teratocarcinoma cell lines and some tumor cells. In this report, we describe properties of p40 in the human teratocarcinoma cell lines NTera2D1 and 2102Ep. The results indicate that: (i) most of p40 occurs in large multimeric cytoplasmic complexes, (ii) L1Hs RNA is associated with the p40 complexes, (iii) the complexes are dissociated by ribonuclease and (iv) p40 is a novel RNA-binding protein. Cross-linking experiments with full-length and truncated p40 produced in Escherichia coli also showed that: (i) p40 itself can form a multimeric complex larger than 250 kDa, (ii) the leucine zipper motif and the region conserved among the predicted ORF1 polypeptides of mammalian LINE-1s participate in complex formation and (iii) the amino terminal region is important for the stability of complex formation. Analysis of the amino acid sequence of p40 suggests that long segments of the molecule can assume an alpha-helical configuration including the leucine zipper and the conserved region. The evidence presented here suggests that the p40 complex is a ribonucleoprotein complex containing L1Hs RNA(s) and that protein-protein interactions in which alpha-helix structures participate, for example coiled-coils, may occur in the complex.

Translation of the human LINE-1 element, L1Hs.

Full-length RNA transcribed from the human LINE-1 (L1) element L1 Homo sapiens (L1Hs) has a 900-nt, G+C-rich, 5'-untranslated region (UTR). The 5' UTR is followed by two long open reading frames, ORF1 and ORF2, which are separated from each other by an inter-ORF region of 33 nt that includes two or three in-frame stop codons. We examine here the mechanism(s) by which the translation of L1Hs ORF1 and ORF2 is initiated. A stable hairpin structure (delta G = -74.8 kcal/mol), inserted at nt 661 of the 5' UTR, caused a 3- to 8-fold decrease in the in vitro and in vivo translation of either a lacZ reporter gene for ORF1 or the ORF1 polypeptide product, p40, but translation of a lacZ reporter gene in ORF2 was increased. The results are compatible with a model for ORF1 translation initiation in which the majority of ribosomes scan from a point 5' of nt 661 but suggest that ORF2 is not translated by attached ribosomes that reinitiate after the termination of ORF1 translation. Our data are compatible with a model whereby the translation of L1Hs ORF2 is initiated internally.

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.

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.

Studies on p40, the leucine zipper motif-containing protein encoded by the first open reading frame of an active human LINE-1 transposable element.

Full-length human LINE-1 retrotransposons encode p40 proteins with varying electrophoretic mobilities under denaturing conditions. The p40 expressed from the first open reading frame in the LINE-1 copy designated L1.2A co-electrophoreses with the endogenous p40 in human teratocarcinoma cells. This finding is consistent with previous data indicating that L1.2A is an active element. The amino acid sequence in the central region of the L1.2A p40 accounts, at least in part, for its characteristic mobility. This region includes sequences which can, in principle, form a leucine zipper.

Translation of LINE-1 DNA elements in vitro and in human cells.

The LINE-1 (L1) family of interspersed DNA sequences found throughout the human genome (L1 Homo sapiens, L1Hs) includes active transposable elements. Current models for the mechanism of transposition involve reverse transcription of an RNA intermediate and utilization of element-encoded proteins. We report that an antiserum against the polypeptide encoded by the L1Hs 5' open reading frame (ORF1) detects, in human cells, an endogenous ORF1 protein as well as the ORF1 product of an appropriate transfecting recombinant vector. The endogenous polypeptide is most abundant in teratocarcinoma and choriocarcinoma cells, among those cell lines tested; it appears to be a single species of approximately 38 kDa. In contrast, RNAs synthesized in vitro from cDNAs representing full-length, polyadenylylated cytoplasmic L1Hs RNA yield, upon in vitro translation, ORF1 products of slightly different sizes. This is consistent with the fact that the various cDNAs are different and represent transcription of different genomic L1Hs elements. In vitro studies additionally suggest that translation of ORF1 is initiated at the first AUG codon. Finally, in no case was an ORF1-ORF2 fusion protein detected.

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.

Genomic organization of low copy number sequences that are associated with deca-satellite DNA in the monkey genome.

A previously described segment of African green monkey DNA (cloned in phage lambda MkA) contains deca-satellite linked to DNA sequences that are estimated to occur once per genome. Sequences homologous to the low copy number sequences in lambda MkA are also associated with species-specific satellite DNAs in the human and mouse genomes. A second clone, lambda Mk8, contains a monkey DNA region that is colinear and homologous to a portion of the low copy number sequences in lambda MkA, but no satellite sequences. The two cloned segments are markedly different starting at a point proximal to the satellite DNA region in lambda MkA. DNA-blotting experiments indicate that lambda Mk8 but not lambda MkA represents the typical genomic organization and that the low copy number segments occur only once per haploid genome. The data suggest that rearrangements such as deletions or inversions occurring in monkey cells account in part for the structure of lambda MkA. Additional rearrangements may have occurred during cloning in E. coli. This unique chromosomal region may be particularly susceptible to recombination.

Localization of a unique DNA sequence to band p16 of human chromosome 4.

Southern blot analysis of DNA from human-rodent cell hybrids and in situ hybridization to metaphase chromosomes allowed the assignment of a unique human DNA sequence associated with satellite DNA to band p16 of human chromosome 4.