Zhao Y, Daggett LP, Hardies SC

A LINE-1 element, LIC105, was found in the Mus musculus domesticus inbred strain, C57BL/6J. Upon sequencing, this element was found to belong to a M. spretus LINE-1 subfamily originating within the last 0.2 million years. This is the second spretus-specific LINE-1 subfamily found to be represented in C57BL/6J. Although it is unclear how these M. spretus LINE-1s transferred from M. spretus to M. m. domesticus, it is now clear that at least two different spretus LINE-1 sequences have recently transferred. The limited divergence between the C57BL/6J spretus-like LINE-1s and their closest spretus ancestors suggests that the transfer did not involve an exceptionally long lineage of sequential transpositions.

PMID: 8852852, UI: 97005553

Rikke BA, Zhao Y, Daggett LP, Reyes R, Hardies SC

The inbred mouse strain, C57BL/6J, was derived from mice of the Mus musculus complex. C57BL/6J can be crossed in the laboratory with a closely related mouse species, M. spretus to produce fertile offspring; however there has been no previous evidence of gene flow between M. spretus and M. musculus in nature. Analysis of the repetitive sequence LINE-1, using both direct sequence analysis and genomic Southern blot hybridization to species-specific LINE-1 hybridization probes, demonstrates the presence of LINE-1 elements in C57BL/6J that were derived from the species M. spretus. These spretus-like LINE-1 elements in C57BL/6J reveal a cross to M. spretus somewhere in the history of C57BL/6J. It is unclear if the spretus-like LINE-1 elements are still embedded in flanking DNA derived from M. spretus or if they have transposed to new sites. The number of spretus-like elements detected suggests a maximum of 6.5% of the C57BL/6J genome may be derived from M. spretus.

PMID: 7713440, UI: 95229069

The dynamics of murine LINE-1 subfamily amplification.

Casavant NC, Hardies SC

We have examined the dynamics of replication of the mouse LINE-1 retrotransposon within a single large expanding LINE-1 family found in a particular population of Mus spretus. This family has reached thousands of copies per haploid genome within 0.1 to 0.2 Myr and accounts for most, if not all, LINE-1 replication since 0.4 Myr ago. The family shows only one split into two clades during this time. From these data we propose a model that links the evolution of LINE-1 to the dynamics of its migration among mouse populations. We hypothesize that selected LINE-1 elements, referred to as master sequences, each amplify a subfamily within a distinct mouse population before migrating into the global mouse population. When these master sequences come in contact with each other by migration, generally one continues to expand at the expense of the other. We further discuss potential tests of this model.

PMID: 8064855, UI: 94343523

Shared sequence variants of Mus spretus LINE-1 elements tracing dispersal to within the last 1 million years.

Casavant NC, Hardies SC

LINE-1 repetitive sequences contain a record of an evolving population of transposons within the mammalian genome. Of the 100,000 copies of LINE-1 sequences per genome there are many shared sequence variants representing changes occurring within the propagating LINE-1 elements themselves, rather than changes that occur during retrotransposition or after an element inserts in the genome. These shared sequence variants define families of LINE-1 elements which have spread within specific periods of time. We have been interested in studying events in LINE-1 evolution since the speciation of Mus spretus and Mus domesticus approximately 3 million years (Myr) ago. To do this, we have collected LINE-1 sequences that have shared sequence variants specific to M. spretus. The sampled LINE-1 elements were sequenced at their extreme 3' ends, where the density of sequence variants is highest. The new sequences define six new M. spretus-specific sequence variants. Of these, we have found one that could be used to screen for LINE-1 elements arising in the last 1 Myr, which we argue is a critical sample for understanding the dynamics of LINE-1 propagation.

PMID: 8070666, UI: 94350211

Rikke BA, Pinto LH, Gorin MB, Hardies SC

LINE-1 is the major family of long, interspersed, repetitive DNA sequences found in mammalian genomes. The mouse species Mus spretus contains large LINE-1 subfamilies that are distinguishable from the LINE-1 elements of laboratory Mus domesticus strains by their content of particular nucleotide differences. Oligonucleotides containing these differences act as M. spretus-specific LINE-1 hybridization probes. We have used these probes as a novel genetic tool in conjunction with an interspecific hybrid congenic mouse, in which the M. spretus allele of the pearl gene has been transferred onto a M. domesticus background. From a lambda library prepared from this congenic mouse, four clones were isolated by hybridization to the M. spretus-specific probes. After derivation of genetic markers from these clones, two of them were found to be linked to the pearl gene. These markers are the first two of up to 75 that could be isolated to support cloning the pearl gene. Considering the interspersed nature of LINE-1, we propose that species-specific LINE-1 probes could also be used to isolate markers for many other target genes.

PMID: 8449493, UI: 93194174

Subfamily-specific LINE-1 PCR (SSL1-PCR) is the targeted amplification and cloning of defined subfamilies of LINE-1 elements and their flanking sequences. The targeting is accomplished by incorporating a subfamily-specific sequence difference at the 3' end of a LINE-1 PCR primer and pairing it with a primer to an anchor ligated within the flanking region. SSL1-PCR was demonstrated by targeting amplification of a Mus spretus-specific LINE-1 subfamily. The amplified fragments were cloned to make an SSL1-PCR library, which was found to be 100-fold enriched for the targeted elements. PCR primers were synthesized based on the sequence flanking the LINE-1 element of four different clones. Three of the clones were recovered from Mus spretus DNA. A fourth clone was recovered from a congenic mouse containing both Mus spretus and Mus domesticus DNA. Amplification between these flanking primers and LINE-1 PCR primers produced a product in Mus spretus and not in Mus domesticus. These dimorphisms were further verified to be due to insertion of Mus spretus-specific LINE-1 elements into Mus spretus DNA and not into Mus domesticus DNA.

PMID: 8499652, UI: 93271540

Publication Types:

Review
Review, tutorial

PMID: 1543914, UI: 92182539

Mus domesticus and Mus spretus mice are closely related subspecies. For genetic investigations involving hybrid mice, we have developed a set of species-specific oligonucleotide probes based on the detection of LINE-1 sequence differences. LINE-1 is a repetitive DNA family whose many members are interspersed among the genes. In this study, library screening experiments were used to fully characterize the species specificity of four M. domesticus LINE-1 probes and three M. spretus LINE-1 probes. It was found that the nucleotide differences detected by the probes define large, species-specific subfamilies. We show that collaborative use of such probes can be employed to selectively detect thousands of species-specific library clones. Consequently, these probes could be exploited to monitor and access almost any given species-specific region of interest within hybrid genomes.

PMID: 1783397, UI: 92147133

The complete nucleotide and encoded amino acid sequences were determined for the dihydrofolate reductase (DHFR) from the bacteria Enterobacter aerogenes and Citrobacter freundii. These were compared with the closely related Escherichia coli DHFR sequence. The ancestral DHFR sequence common to these three species was reconstructed. Since that ancestor there have been seven, nine, and one amino acid replacements in E. coli, E. aerogenes, and C. freundii, respectively. In E. coli, five of its seven replacements were located in the beta-sheet portion of the protein, and all seven were located in a single restricted region of the protein. In E. aerogenes, all nine of its replacements were located within surface residues, with five clustered in a region topologically distinct from the E. coli cluster. The replaced side chains are sometimes in direct contact but more often are separated by an intervening side chain. It is argued that the temporal clustering of replacements is typical for the evolution of most proteins and that the associated topological clustering gives a picture of how evolutionary change is accommodated by protein structure.

PMID: 1766362, UI: 92114753

LINE-1 is a family of repetitive DNA sequences interspersed among mammalian genes. In the mouse haploid genome there are about 100,000 LINE-1 copies. We asked if the subspecies Mus spretus and Mus domesticus have developed species-specific LINE-1 subfamilies. Sequences from 14 M. spretus LINE-1 elements were obtained and compared to M. domesticus LINE-1 sequences. Using a molecular phylogenetic tree we identified several differences shared among a subset of young repeats in one or the other species as candidates for species-specific LINE-1 variants. Species specificity was tested using oligonucleotide probes complementary to each putative species-specific variant. When hybridized to genomic DNAs, single-variant probes detected an expanded number of elements in the expected mouse. In the other species these probes detected a smaller number of matches consistent with the average rate of random divergence among LINE-1 elements. It was further found that the combination of two species-specific sequence differences in the same probe reduced the detection background in the wrong species below our detection limit.

PMID: 2056531, UI: 91278091

LINES ONE (L1) is a family of movable DNA sequences found in mammals. To measure the rate of their movement, we have compared the positions of L1 elements within homologous genetic loci that are separated by known divergence times. Two models that predict different outcomes of this analysis have been proposed for the behavior of L1 sequences. (i) Previous theoretical studies of concerted evolution in L1 have indicated that the majority of the 100,000 extant L1 elements may have inserted as recently as within the last 3 million years. (ii) Gene conversion has been proposed as an alternative to a history of prolific recent insertions. To distinguish between these two models, we cloned and characterized two embryonic beta-globin haplotypes from Mus caroli and compared them with those of M. domesticus. In 9 of 10 instances, we observed an L1 element to be present in one chromosome and absent at the same site in a homologous chromosome. This frequency is quantitatively consistent with the known rate of concerted evolution. Therefore, we conclude that gene conversion is not required for concerted evolution of the L1 family in the mouse. Furthermore, we show that the extensive movement of L1 sequences contributes to restriction fragment length polymorphism. L1 insertions may be the predominant cause of restriction fragment length polymorphisms in closely related haplotypes.

PMID: 2905421, UI: 89096836

L1 is a family of long interspersed repetitive sequences in mammals that includes the BamHI family in rodents and the KpnI family in primates. Previous studies have shown that L1 repeats contain a long open reading frame and that the family evolves in concert. Working with 32 rodent elements for which DNA sequence is available, we used the distribution of replacement and synonymous changes to determine which L1 lineages had been expressing their reading frame. The evidence obtained is consistent with there having been a small number of L1 genes that have been expressing a functional protein. Much of the concerted evolution in L1 is accounted for by the tendency of these functioning L1 genes to continually create nonfunctional pseudogenes by reinsertion into the genome of sequences derived from their transcripts. The gain of new pseudogenes is balanced by the loss of old pseudogenes with a half-life of 2 Myr. Therefore, most of the observed L1 repeats are at a dead end with respect to either the expression of the L1 protein or the potential to elaborate further copies of themselves. However, the turnover of L1 pseudogenes is sufficient to constitute a vast flux of sequences into and then out of the flanking regions of all cellular genes. If the presence of flanking L1 pseudogenes affects the expression of other genes in even a subtle fashion, this process should represent a major source of genetic variation. A second level of concerted evolution occurs within the functional L1 sequences in a pattern that did not meet our expectations for selfish DNA. Also, in spite of the marked suppression of replacement relative to synonymous changes in functioning L1 genes, they evolve at an overall rate accelerated to the level of their own pseudogenes.

PMID: 3444397, UI: 88174336

The complete nucleotide sequence of a 6,851-base pair (bp) member of the L1Md repetitive family from a selected random isolate of the BALB/c mouse genome is reported here. Five kilobases of the element contains two overlapping reading frames of 1,137 and 3,900 bp. The entire 3,900-bp frame and the 3' 600 bp of the 1,137-bp frame, when compared with a composite consensus primate L1 sequence, show a ratio of replacement to silent site differences characteristic of protein coding sequences. This more closely defines the protein coding capacity of this repetitive family, which was previously shown to possess a large open reading frame of undetermined extent. The relative organization of the 1,137- and 3,900-bp reading frames, which overlap by 14 bp, bears resemblance to protein-coding, mobile genetic elements. Homology can be found between the amino acid sequence of the 3,900-bp frame and selected domains of several reverse transcriptases. The 5' ends of the two L1Md elements described in this report have multiple copies, 4 2/3 copies and 1 2/3 copy, of a 208-bp direct tandem repeat. The sequence of this 208-bp element differs from the sequence of a previously defined 5' end for an L1Md element, indicating that there are at least two different 5' end motifs for L1Md.

PMID: 3023821, UI: 87064284

A 300-bp DNA sequence has been determined for 30 (10 from each of three species of mice) random isolates of a subset of the long interspersed repeat family L1. From these data we conclude that members of the L1 family are evolving in concert at the DNA sequence level in Mus domesticus, Mus caroli, and Mus platythrix. The mechanism responsible for this phenomenon may be either duplicative transposition, gene conversion, or a combination of the two. The amount of intraspecies divergence averages 4.4%, although between species base substitutions accumulate at the rate of approximately 0.85%/Myr to a maximum divergence of 9.1% between M. platythrix and both M. domesticus and M. caroli. Parsimony analysis reveals that the M. platythrix L1 family has evolved into a distinct clade in the 10-12 Myr since M. platythrix last shared a common ancestor with M. domesticus and M. caroli. The parsimony tree also provides a means to derive the average half-life of L1 sequences in the genome. The rates of gain and loss of individual copies of L1 were estimated to be approximately equal, such that approximately one-half of them turn over every 3.3 Myr.

PMID: 3870857, UI: 88216107