Target sites for the transposition of rat long interspersed repeated DNA elements (LINEs) are not random

Suppressor of cytokine signalling (SOCS)-3 protects beta cells against IL-1beta-mediated toxicity through inhibition of multiple nuclear factor-kappaB-regulated proapoptotic pathways

AIMS/HYPOTHESIS

The proinflammatory cytokine IL-1beta induces apoptosis in pancreatic beta cells via pathways dependent on nuclear factor-kappaB (NF-kappaB), mitogen-activated protein kinase, and protein kinase C. We recently showed suppressor of cytokine signalling (SOCS)-3 to be a natural negative feedback regulator of IL-1beta- and IFN-gamma-mediated signalling in rat islets and beta cell lines, preventing their deleterious effects. However, the mechanisms underlying SOCS-3 inhibition of IL-1beta signalling and prevention against apoptosis remain unknown.

METHODS

The effect of SOCS-3 expression on the global gene-expression profile following IL-1beta exposure was microarray-analysed using a rat beta cell line (INS-1) with inducible SOCS-3 expression. Subsequently, functional analyses were performed.

RESULTS

Eighty-two known genes and several expressed sequence tags (ESTs) changed expression level 2.5-fold or more in response to IL-1beta alone. Following 6 h of IL-1beta exposure, 23 transcripts were up-regulated. Of these, several, including all eight transcripts relating to immune/inflammatory response pathways, were suppressed by SOCS-3. Following 24 h of IL-1beta exposure, secondary response genes were detected, affecting metabolism, energy generation, protein synthesis and degradation, growth arrest, and apoptosis. The majority of these changes were prevented by SOCS-3 expression. Multiple IL-1beta-induced NF-kappaB-dependent proapoptotic early response genes were inhibited by SOCS-3 expression, suggesting that SOCS-3 inhibits NF-kappaB-mediated signalling. These observations were experimentally confirmed in functional analyses.

CONCLUSIONS/INTERPRETATION

This study suggests that there is an unexpected cross-talk between the SOCS/IFN and the IL-1beta pathways of signalling in pancreatic beta cells, which could lead to a novel perspective of blocking two important proapoptotic pathways in pancreatic beta cells by influencing a single signalling molecule, namely SOCS-3.

An ancient retrovirus-like element contains hot spots for SINE insertion

Vertebrate retrotransposons have been used extensively for phylogenetic analyses and studies of molecular evolution. Information can be obtained from specific inserts either by comparing sequence differences that have accumulated over time in orthologous copies of that insert or by determining the presence or absence of that specific element at a particular site. The presence of specific copies has been deemed to be an essentially homoplasy-free phylogenetic character because the probability of multiple independent insertions into any one site has been believed to be nil. Mys elements are a type of LTR-containing retrotransposon present in Sigmodontine rodents. In this study we have shown that one particular insert, mys-9, is an extremely old insert present in multiple species of the genus Peromyscus. We have found that different copies of this insert show a surprising range of sizes, due primarily to a continuing series of SINE (short interspersed element) insertions into this locus. We have identified two hot spots for SINE insertion within mys-9 and at each hot spot have found that two independent SINE insertions have occurred at identical sites. These results have major repercussions for phylogenetic analyses based on SINE insertions, indicating the need for caution when one concludes that the existence of a SINE at a specific locus in multiple individuals is indicative of common ancestry. Although independent insertions at the same locus may be rare, SINE insertions are not homoplasy-free phylogenetic markers.

The biological properties and evolutionary dynamics of mammalian LINE-1 retrotransposons

Mammalian LINE-1 (L1) elements belong to the superfamily of autonomously replicating retrotransposable elements that lack the long terminal repeated (LTR) sequences typical of retroviruses and retroviral-like retrotransposons. The non-LTR superfamily is very ancient and L1-like elements are ubiquitous in nature, having been found in plants, fungi, invertebrates, and various vertebrate classes from fish to mammals. L1 elements have been replicating and evolving in mammals for at least the past 100 million years and now constitute 20% or more of some mammalian genomes. Therefore, L1 elements presumably have had a profound, perhaps defining, effect on the evolution, structure, and function of mammalian genomes. L1 elements contain regulatory signals and encode two proteins: one is an RNA-binding protein and the second one presumably functions as an integrase-replicase, because it has both endonuclease and reverse transcriptase activities. This work reviews the structure and biological properties of L1 elements, including their regulation, replication, evolution, and interaction with their mammalian hosts. Although each of these processes is incompletely understood, what is known indicates that they represent challenging and fascinating biological phenomena, the resolution of which will be essential for fully understanding the biology of mammals.

The disabled 1 gene is disrupted by a replacement with L1 fragment in yotari mice

The yotari autosomal recessive mutant mouse has a phenotype that is almost identical to that of the reeler mouse. We reported in our previous study that the yotari mouse expresses a mutated form of disabled 1 (Dab1) mRNA resulting in no Dab1 protein. In this study, we demonstrate that the yotari mutation is caused by a replacement of gene sequence with a long interspersed nuclear element (L1) fragment. The nucleotides of two complete exons and part of an additional exon of Dab1 were eliminated as well as three introns by this substitution. The substituted L1 fragment contains 962 nucleotides and is highly homologous to the members of the T(F) subfamily of L1. It is truncated at both the 5' and 3' ends and contains two blocks in a head-to-head arrangement. Based on the DNA sequences around the replacement we developed a screening method that enables us to distinguish wild type, yotari, and heterozygous mice. This method should greatly contribute to analyses of the early anatomical and physiological consequences of the yotari mutation.

Sequence patterns indicate an enzymatic involvement in integration of mammalian retroposons

It is commonly accepted that the reverse-transcribed cellular RNA molecules, called retroposons, integrate at staggered breaks in mammalian chromosomes. However, unlike what was previously thought, most of the staggered breaks are not generated by random nicking. One of the two nicks involved is primarily associated with the 5'-TTAAAA hexanucleotide and its variants derived by a single base substitution, particularly A --> G and T --> C. It is probably generated in the antisense strand between the consensus bases 3'-AA and TTTT complementary to 5'-TTAAAA. The sense strand is nicked at variable distances from the TTAAAA consensus site toward the 3' end, preferably within 15-16 base pairs. The base composition near the second nicking site is also nonrandom at positions preceding the nick. On the basis of the observed sequence patterns it is proposed that integration of mammalian retroposons is mediated by an enzyme with endonucleolytic activity. The best candidate for such enzyme may be the reverse transcriptase encoded by the L1 non-long-terminal-repeat retrotransposon, which contains a freshly reported domain homologous to the apurinic/apyrimidinic (AP) endonuclease family [Martin, F., Olivares, M., Lopez, M. C. & Alonso, C. (1996) Trends Biochem. Sci. 21, 283-285; Feng, Q., Moran, J. V., Kazazian, H. H. & Boeke, J. D. (1996) Cell 87, 905-916] and shows nicking in vitro with preference for targets similar to 5'-TTAAAA/3'-AATTTT consensus sequence [Feng, Q., Moran, J. V., Kazazian, H. H. & Boeke, J. D. (1996) Cell 87, 905-916]. A model for integration of mammalian retroposons based on the presented data is discussed.

The evolution of an intron: analysis of a long, deletion-prone intron in the human dystrophin gene

The sequence of a 112-kb region of the human dystrophin (DMD/BMD) gene encompassing the deletion prone intron 7 (110 kb) and the much shorter intron 8 (1.1 kb) has been determined. Recognizable insertion sequences account for approximately 40% of intron 7. LINE-1 and THE-1/LTR sequences occur in intron 7 with significantly higher frequency than would be expected statistically while Alu sequences are underrepresented. Intron 7 also contains numerous mammalian-wide interspersed repeats, a diverse range of medium reiteration repeats of unknown origin, and a sequence derived from a mariner transposon. By contrast, the shorter intron 8 contains no detectable insertion sequences. Dating of the LI and Alu sequences suggests that intron 7 has approximately doubled in size within the past 130 million years, and comparison with the corresponding intron from the pufferfish (Fugu rubripes) suggests that the intron has expanded some 44-fold over a period of 400 million years. The possible contribution of the insertion elements to the instability of intron 7 is discussed.

De novo generation of simple sequence during gene amplification

Mammalian cells that have undergone gene amplification and/or gene rearrangement have been used as resources to gain insight into the questions of chromosome structure and dynamics. The multidrug resistant murine cell line J7.V2-1 has been shown previously to contain two distinct forms of the highly amplified mdr2 gene, a member of the mouse gene family responsible for the multidrug resistant (MDR) phenotype [Kirschner, L. S. (1995) DNA Cell Biol. 14, 47-59]. Characterization of both forms of the gene revealed that one form corresponded to the wild-type structure of the gene, whereas the other represented a rearrangement. Investigation of this altered gene demonstrated a deletion of 1.6 kb of the wild-type sequence, and replacement of this region with a poly(AT) tract that appears to have been generated de novo. Analysis of the native sequence in this region demonstrated the absence of repetitive elements, but was notable for the presence of two long stretches of polypurine: polypyrimidine strand asymmetry. Analysis of mdr2 transcripts in this cell line revealed that nearly all of the mRNA is transcribed from the rearranged form of the gene. This message is unable to code for a functional mdr2 gene product, owing to a deletion of the fourth exon during this event. Mechanisms of the rearrangement, as well as the significance of this curious effect on transcription, are discussed.

RNA template requirements for target DNA-primed reverse transcription by the R2 retrotransposable element

R2 is a non-long terminal repeat-retrotransposable element that inserts specifically in the 28S rRNA gene of most insects. The single protein encoded by R2 has been shown to contain both site-specific endonuclease and reverse transcriptase activities. Integration of the element involves cleavage of one strand of the 28S target DNA and the utilization of the exposed 3' hydroxyl group to prime the reverse transcription of the R2 RNA transcript. We have characterized the RNA requirement of this target DNA-primed reverse transcription reaction and found that the 250 nucleotides corresponding to the 3' untranslated region of the R2 transcript were necessary and sufficient for the reaction. To investigate the sequence requirements at the site of reverse transcription initiation, a series of RNA templates that contained substitutions and deletions at the extreme 3' end of the RNA were tested. The R2 templates used most efficiently had 3' ends which corresponded to the precise boundary of the R2 element with the 28S gene found in vivo. Transcripts containing short polyadenylated tails (8 nucleotides) were not utilized efficiently. R2 RNAs that were truncated at their 3' ends by 3 to 6 nucleotides were used less efficiently as templates and then only after the R2 reverse transcriptase had added extra, apparently nontemplated, nucleotides to the target DNA. The ability of the reverse transcriptase to add additional nucleotides to the target DNA before engaging the RNA template might be a mechanism for the generation of poly(A) or simple repeat sequences found at the 3' end of most non-long terminal repeat-retrotransposable elements.

Comparison of chromosomal distribution of a retroposon (LINE) and a retrovirus-like element mys in Peromyscus maniculatus and P. leucopus

Chromosomal distribution for two interspersed elements (LINEs and mys) that are thought to have established their chromosomal position primarily by transposition was compared between two species of deer mice (Peromyscus leucopus and P. maniculatus). Both LINEs and mys generally produced an autosomal banding pattern reflective of G-bands and both hybridized preferentially to the sex chromosomes. The pattern on the long arm of the X was unique for each, with mys reflecting the G-bands (four bands with the telomeric most prominent) and LINE producing five equally spaced bands of equal intensity. LINE also preferentially hybridized to the short arm of the longest autosomal pair. Some aspects of these patterns are explained adequately with proposed mechanisms that would produce a non-random pattern of chromosomal distribution (i.e. both reflect autosomal G-bands and both preferentially insert into AT-rich regions characteristic of G-bands). However, other aspects such as the differences observed on the long arm of the X do not appear to fit any predictions of proposed mechanisms.

A simple and efficient method for constructing high resolution physical maps

This paper describes a simple and efficient walking method for constructing high resolution physical maps and discusses its applications to genome analysis. The method is an integration of three strategies: (1) use of a highly redundant library of 3Kb-long subclones; (2) construction of a multidimensional pool from the library; (3) direct application of a PCR (polymerase chain reaction)-based screening technique to the pooled library, with two PCR primers, one from the end of the subcloning vector and the other from the leading edge of the walk. This technique allows not only detection of each overlapping subclone but simultaneous determination of its orientation and the size of its overlap. The end of the subclone with the smallest overlap is sequenced and a primer is designed for the next step in the walk. Iteration of the screening procedure with minimum overlapping subclones results in completion of the high resolution map. Using this method, a 3Kb-resolution map was constructed from an 80Kb region of the bithorax complex of Drosophila melanogaster. The method is general enough to be applicable to DNA from other species, and simple enough to be automated.

Structural analysis of length mutations in a hot-spot region of wheat chloroplast DNAs

The hot-spot region related to length mutations in the chloroplast genome of the wheat group was precisely analyzed at the DNA sequence level. This region, located downstream from the rbcL gene, was highly enriched in A + T, and contained a number of direct and inverted repeats. Many deletions/insertions were observed in the region. In most deletions/insertions of multiple nucleotides, short repeated sequences were found at the mutation points. Furthermore, a pair of short repeated sequences was also observed at the border of the translocated gene. A sequence homologous with ORF512 of tobacco cpDNA was truncated in cpDNAs of the wheat group and found only in the mitochondrial DNA of Ae. crassa, suggesting the inter-organellar translocation of this sequence. Mechanisms that could generate structural alterations of the chloroplast genome in the wheat group are discussed.

A transposon-like element in the deletion-prone region of the dystrophin gene

The central portion of the dystrophin gene locus is a preferential site for deletions causing progressive muscular dystrophy of the Duchenne type (DMD). The nucleotide sequence of a deletion junction fragment from a DMD patient was determined, revealing that the proximal breakpoint of the deletion in intron 43 fell within the sequence of a transposon-like element. This segment, belonging to the THE-1 family of human transposable elements, is normally present in a complete form in intron 43 of the dystrophin gene. The deletion mutation was maternally transmitted and eliminated two-thirds of the THE-1 element. Analysis of DNA from additional DMD patients revealed a second deletion with the proximal breakpoint mapping within the same THE-1 element.

Transposable elements and the evolution of genome organization in mammals

All mammalian transposable elements characterized to date appear to be nonrandomly distributed in the mammalian genome. While no element has been found to be exclusively restricted in its chromosomal location, LINE elements and some retrovirus-like elements are preferentially accumulated in G-banding regions of the chromosomes, and in some cases in the sex chromosomes, while SINE elements occur preferentially in R-banding regions. Four mechanisms are presented which may explain the nonrandom genomic distribution of mammalian transposons: i) sequence-specific insertion, ii) S-phase insertion, iii) ectopic excision, and iv) recombinational editing. Some of the available data are consistent with each of these four models, but no single model is sufficient to explain all of the existing data.

Evidence that chicken CR1 elements represent a novel family of retroposons

We report the first precise delineation of a chicken CR1 element and show that it is flanked by a 6-base-pair target site duplication that occurred when this repetitive element transposed. The 3' end of this CR1 element is defined by an 8-base-pair imperfect direct repeat, and we infer that this sequence represents the 3' end of all intact CR1 elements. In contrast, the 5' ends are not unique, and we argue that this variation existed at the time each element transposed. We also provide evidence that CR1 elements transposed into preferred target sites. CR1 elements therefore appear to represent a novel class of passive retroposons.

SINEs and LINEs cluster in distinct DNA fragments of Giemsa band size

By in situ hybridization, short interspersed repeated DNA elements (SINEs), exemplified by Alu repeats, are located principally in Giemsa-light human metaphase chromosome bands. In contrast, the L1 family of long interspersed repeats (LINEs) preferentially cluster in Giemsa-dark bands. These SINE/LINE patterns also generally correspond to early and later replication band patterns. In order to provide a molecular link between structurally visible chromosome bands and a framework of interspersed repeats, we investigated patterns of SINE and LINE hybridization using pulse-field gel electrophoresis (PFGE). Interspersed SINEs and LINEs hybridize with high intensity to specific size fragments of 0.2-3 megabase pairs (Mb). Using appropriate restriction enzymes and pulse-field conditions, a number of fragments were delineated that were either SINE or LINE rich, and were mutually exclusive. Control studies with a human endogenous retroviral repeat that is related in sequence to the major LINE family, delineated a subset of fragments of 0.07-0.4 Mb with unequal intensity. Thus these less numerous repeats also appear to cluster selectively in DNA domains that are larger than a chromosome loop (60-120 kb). In summary, PFGE studies independently confirm the clustering of interspersed repeats on contiguous DNA loops. Selective clustering of repeat motifs may contribute to special structural or functional properties of large chromosome domains, such as chromatin extension/condensation or replication characteristics. In some cases the DNA fragments defined by these repeats approach the size of tandem satellite arrays.

A LINE 1 sequence interrupts the rat alpha 2u globulin gene

The rat alpha 2u globulin gene family is composed of about 25 members with closely related structure. Several of these genes are transcriptionally active in the liver of adult males. We isolated about 50 independent genomic clones from the library and determined complete nucleotide sequences of two. Although they were alike and revealed structural features prerequisite for active genes, one cloned gene was interrupted in the 6th intron with about 900 bp 5' truncated and 3'-terminal triplicated form of LINE 1 sequence flanked by 16 bp complete direct repeat originating from the 6th intron. Within the inserted LINE 1 an excellent splicing acceptor homologue with a precedent lariat junction motif and multiple polyadenylation signals was identified. Thus, the possible production of a chimeric RNA, the last exon of which would be replaced by a part of LINE 1, has to be considered.

Evidence that chicken CR1 elements represent a novel family of retroposons

We report the first precise delineation of a chicken CR1 element and show that it is flanked by a 6-base-pair target site duplication that occurred when this repetitive element transposed. The 3' end of this CR1 element is defined by an 8-base-pair imperfect direct repeat, and we infer that this sequence represents the 3' end of all intact CR1 elements. In contrast, the 5' ends are not unique, and we argue that this variation existed at the time each element transposed. We also provide evidence that CR1 elements transposed into preferred target sites. CR1 elements therefore appear to represent a novel class of passive retroposons.

Evolution of chromosome bands: molecular ecology of noncoding DNA

Giemsa dark bands, G-bands, are a derived chromatin character that evolved along the chromosomes of early chordates. They are facultative heterochromatin reflecting acquisition of a late replication mechanism to repress tissue-specific genes. Subsequently, R-bands, the primitive chromatin state, became directionally GC rich as evidenced by Q-banding of mammalian and avian chromosomes. Contrary to predictions from the neutral mutation theory, noncoding DNA is positionally constrained along the banding pattern with short interspersed repeats in R-bands and long interspersed repeats in G-bands. Chromosomes seem dynamically stable: the banding pattern and gene arrangement along several human and murine autosomes has remained constant for 100 million years, whereas much of the noncoding DNA, especially retroposons, has changed. Several coding sequence attributes and probably mutation rates are determined more by where a gene lives than by what it does. R-band exons in homeotherms but not G-band exons have directionally acquired GC-rich wobble bases and the corresponding codon usage: CpG islands in mammals are specific to R-band exons, exons not facultatively heterochromatinized, and are independent of the tissue expression pattern of the gene. The dynamic organization of noncoding DNA suggests a feedback loop that could influence codon usage and stabilize the chromosome's chromatin pattern: DNA sequences determine affinities of----proteins that together form----a chromatin that modulates----rate constants for DNA modification that determine----DNA sequences. Theories of hierarchical selection and molecular ecology show how selection can act on Darwinian units of noncoding DNA at the genome level thus creating positionally constrained DNA and contributing minimal genetic load at the individual level.

Full length L1 retroposons contain tRNA-like sequences near the 5' termini--hypothesis on the replication mechanism of retroposons

Retrotransposons replicate via a complex mechanism which depends on, among other things, the presence of long terminal repeats (LTRs) and a tRNA binding site just 3' of the 5' LTR. The LINES 1 (L1) family of sequences, which similar to retrotransposons in many other properties, represents a new class of retroposon which does not possess LTRs. However, we show here that the repetitive 5' motif associated with murine L1 elements contains a tRNA-like sequence in a location analogous to the position of the retro-transposon tRNA binding site. Although the repetition of such a 5' motif has only been found associated with murine L1 elements, we have found an analogous tRNA-like sequence near the 5' ends of the L1 elements from each of the other analyzed species for which the L1 family has been characterized, that is rat (L1Rr), human (L1Hs), drosophila (I element) and trypanosome (INGI). The conservation of this tRNA-like sequence near the 5' terminus of L1 elements from such diverse species suggests that it plays a functional role in the life of the L1 class of retroposon.

The structure of the regulatory region of the rat L1 (L1Rn, long interspersed repeated) DNA family of transposable elements

Here we report the DNA structure of the left 1.5 kb of two newly isolated full length members of the rat L1 DNA family (L1Rn, long interspersed repeated DNA). In contrast to earlier isolated rat L1 members, both of these contain promoter-like regions that are most likely full length. In addition, the promoter-like region of both members has undergone a partial tandem duplication. A second internal region of the left end of one of the reported members is also tandemly duplicated. The propensity of the left end of rat L1 elements to undergo this form of genetic rearrangement, as well as other structural features revealed by the present work, is discussed in light of the fact that during evolution the otherwise conserved mammalian L1 DNA families have each acquired completely different promoter-like regions. In an accompanying paper [Nur, I., Pascale, E., and Furano, A. V. (1988) Nucleic Acids Res. 16, submitted], we report that one of the rat promoter-like regions can function as a promoter in rat cells when fused to the Escherichia coli chloramphenicol acyltransferase gene.

Rat L (long interspersed repeated DNA) elements contain guanine-rich homopurine sequences that induce unpairing of contiguous duplex DNA

The L family (long interspersed repeated DNA) of mobile genetic elements is a persistent feature of the mammalian genome. In rats, this family contains approximately equal to 40,000 members and accounts for approximately equal to 10% of the haploid genome. We demonstrate here that the guanine-rich homopurine stretches located at the right end of L-DNA induce oligonucleotide uptake by contiguous duplex DNA. The uptake is dependent on negative supercoiling and the length of the homopurine stretch and occurs even when the L-DNA homopurine stretches are introduced into a different DNA environment. The bound oligomer primes DNA synthesis when DNA polymerase and deoxyribonucleoside triphosphates are added, resulting in a faithful copy of the template to which the oligonucleotide had bound. The implications of this property of the L-DNA guanine-rich homopurine stretches in the amplification, recombination, and dispersal of L elements is discussed.

Human transposon-like elements insert at a preferred target site: evidence for a retrovirally mediated process

Members of the human transposon-like family of repetitive sequences (called THE 1 repeats) like many other repetitive DNA sequences are flanked by short direct repeats. Comparison of the base sequences of twelve examples of these flanking direct repeats indicates that THE 1 repeats insert into a preferred genomic target site. In one case, we have identified the sequence of an empty site into which a THE 1 element inserted. The sequence of this empty site and sequences of truncated THE 1 LTRs are consistent with a retroviral mechanism for the insertion of THE 1 elements. Truncated transposon structures illustrate for the first time that intermediate structures of retrotransposition may also be integrated into the genome.

Mouse mammary tumor proviruses from a T-cell lymphoma are associated with the retroposon L1Md

Four Charon 4A clones containing mouse mammary tumor virus (MMTV) proviruses and their cellular flanking sequences were obtained from partial EcoRI libraries of a C57BL/6 T-cell lymphoma with both endogenous and newly acquired MMTV proviruses. The cellular flanking sequences of three of four MMTV proviruses contained DNA homologous to the 3' end of the long interspersed retroposon L1Md. Two of the three proviruses were newly acquired in the lymphoma DNA, and these MMTV proviruses appeared to be 5 kilobases downstream and in the same transcriptional orientation as the L1 sequence. The third provirus was endogenous Mtv-9 and was located less than 500 base pairs from the 3' end of L1. Seven additional clones containing MMTV proviruses were isolated from partial MboI libraries of a B6 T-cell lymphoma. Five of the seven clones contained L1 elements in the cellular DNA flanking MMTV DNA. At least two clones (including one with the Mtv-8 provirus) had multiple L1 copies flanking the MMTV provirus, and one clone contained a single MMTV long terminal repeat directly integrated into a truncated L1 sequence. Although the frequencies of B1 and L1 in random library clones were similar, only one MMTV-containing clone hybridized to the abundant repetitive element B1. These data suggest a nonrandom association between MMTV and L1Md.

Suicidal death of rat chloroleukaemia cells by activation of the long interspersed repetitive DNA element (L1Rn)

Rat chloroleukaemia cells, maintained in suspension culture in different media, show rapid exponential growth without cell loss. At about half of the maximal population density the long interspersed repetitive DNA element (L1Rn) is suddenly transcriptionally activated without any obvious exogenous reason. Population growth is then inhibited and, within about 24 h after reaching the maximal density, the population undergoes programmed death (apoptosis). Suicidal cell death is caused by sudden incorporation, apparently by retroposition via an RNA intermediate, of about 300,000 copies of the L1Rn element into random locations in the cell genome, thus creating lethal mutations. The preceding growth inhibition is associated with repression, to an undetectable level, of c-Ki-ras expression. Up to the point of massive L1Rn incorporation and cell death, all phenomena are quickly reversible by subculturing; medium change alone is not sufficient. Biological implications of these surprising findings are discussed.

Unrelated sequences at the 5' end of mouse LINE-1 repeated elements define two distinct subfamilies

Some full length members of the mouse long interspersed repeated DNA family L1Md have been shown to be associated at their 5' end with a variable number of tandem repetitions, the A repeats, that have been suggested to be transcription controlling elements. We report that the other type of repeat, named F, found at the 5' end of a few L1 elements is also an integral part of full length L1 copies. Sequencing shows that the F repeats are GC rich, and organized in tandem. The L1 copies associated with either A or F repeats can be correlated with two different subsets of L1 sequences distinguished by a series of variant nucleotides specific to each and by unassociated but frequent restriction sites. These findings suggest that sequence replacement has occurred at least once in 5' of L1Md, and is related to the generation of specific subfamilies.

Characterization of the L1NH repeat family of Novikoff hepatoma

Long interspersed repeated sequences of the Novikoff hepatoma rat tumour cell genome were cloned and studied. No basic differences were found when the genomic organization of the Novikoff hepatoma was compared with that of other mammalian L1 families. The nucleotide sequence of the central approximately 4 kb (1 kb = 10(3) bases) part of the Novikoff hepatoma LINE (L1NH) appeared to be more highly conserved than the sequences found at the 5' and 3' ends. Moreover, the central approximately 4 kb core fragments were not always associated with the same end sequences. Thus, the occurrence of the more-conserved and more-abundant central portion in L1NH suggest that: (1) besides reverse transcription, other DNA- and/or RNA-mediated mechanisms might be involved in the dispersal of LINE families; and that (2) L1 sequences can sometimes consist of a compound unit made up of members of different L1 subunits and sequences with different genomic copy numbers.

The L1 family (KpnI family) sequence near the 3' end of human beta-globin gene may have been derived from an active L1 sequence

We previously reported that some L1 family (KpnI family) members are closely associated with the Alu family sequence. To understand the details of the L1-Alu association, the structure of a L1-Alu unit downstream from the beta-globin gene was compared between human and primates. The results revealed that the L1-Alu-associated sequence was formed by the insertion of the L1 sequence, T beta G41, into the 3' poly A tract of the preexisting Alu family sequence. It was estimated that the T beta G41 sequence was inserted after the divergence of Old World monkeys and hominoids and before the divergence of orang-utan and common ancestor of other higher hominoids. From the calculation of the mutation rates of L1 sequences, it was suggested that the T beta G41 was derived from an active L1 sequence which was able to encode reverse transcriptase-related protein.

DNA synthesis arrest sites at the right terminus of rat long interspersed repeated (LINE or L1Rn) DNA family members

An approximately equal to 150-bp GC-rich (approximately equal to 60%) region is at the right end of rat long interspersed repeated DNA (LINE or L1Rn) family members. We report here that one of the DNA strands from this region contains several non-palindromic sites that strongly arrest DNA synthesis in vitro by the prokaryotic Klenow and T4 DNA polymerases, the eukaryotic alpha polymerase, and AMV reverse transcriptase. The strongest arrest sites are G-rich (approximately equal to 70%) homopurine stretches of 18 or more residues. Shorter homopurine stretches (12 residues or fewer) did not arrest DNA synthesis even if the stretch contains 11/12 G residues. Arrest of the prokaryotic polymerases was not affected by their respective single strand binding proteins or polymerase accessory proteins. The region of duplex DNA which contains DNA synthesis arrest sites reacts with bromoacetaldehyde when present in negatively supercoiled molecules. By contrast, homopurine stretches that do not arrest DNA synthesis do not react with bromoacetaldehyde. The presence of bromoacetaldehyde-reactive bases in a G-rich homopurine-containing duplex under torsional stress is thought to be caused by base stacking in the homopurine strand. Therefore, we suggest that base-stacked regions of the template arrest DNA synthesis.

Discrete high molecular weight RNA transcribed from the long interspersed repetitive element L1Md

The repetitive element LINE (L1) previously has been shown to contain two long open reading frames which are overlapping and out-of-frame similar to those found in retroviruses (1). In rodents and in human cells, these repeats appear to be transcribed into a heterogeneous population of RNAs in most cell types (2,3,4). No discrete transcript has been reported which is likely to be a mRNA for the open reading frames in rodent cells. In this paper, a discrete RNA species of approximately 8 kb has been identified in most murine lymphoid cells examined. This RNA is cytoplasmic and binds to oligo (dT) cellulose columns. Hybridization with labeled probes indicates that the transcript is of the same strandedness as the open reading frames. These results are consistent with proposals that L1Md is a retroposon with protein-encoding function.

Characterization of a human 'midisatellite' sequence

We have examined the structure and DNA sequence of a human genomic locus that consists of a large hypervariable region made up of repeats of a simple sequence. With several restriction enzymes, the locus shows many restriction fragments that vary quantitatively as well as qualitatively. Other restriction enzymes produce only a single, high-molecular-weight fragment at this locus. Almost all of the fragments are revealed with a simple sequence probe. Southern transfers of the high-molecular-weight restriction fragments produced by the restriction enzymes NotI and SfiI, resolved by pulsed-field gel electrophoresis, gave at most two fragments, demonstrated to be allelic, showing that the majority of the restriction fragments seen in the complex patterns are at a single locus. The estimated size of the region homologous to the probe varied from 250 to 500 kilobases. DNA sequencing indicated that the region consists of tandem repeats of a 40-base-pair sequence. Some homology was detected to the tandem repeating units of the insulin gene and the zetaglobin pseudogene hypervariable regions, and to the "minisatellite" DNA at the myoglobin locus.