Phylogeny of <Emphasis Type="Italic">Banana Streak Virus</Emphasis> Reveals Recent and Repetitive Endogenization in the Genome of Its Banana Host (<Emphasis Type="Italic">Musa</Emphasis> sp.)

Banana streak virus (BSV) is a plant dsDNA pararetrovirus (family Caulimoviridae, genus badnavirus). Although integration is not an essential step in the BSV replication cycle, the nuclear genome of banana (Musa sp.) contains BSV endogenous pararetrovirus sequences (BSV EPRVs). Some BSV EPRVs are infectious by reconstituting a functional viral genome. Recent studies revealed a large molecular diversity of episomal BSV viruses (i.e., nonintegrated) while others focused on BSV EPRV sequences only. In this study, the evolutionary history of badnavirus integration in banana was inferred from phylogenetic relationships between BSV and BSV EPRVs. The relative evolution rates and selective pressures (d_N/d_S ratio) were also compared between endogenous and episomal viral sequences. At least 27 recent independent integration events occurred after the divergence of three banana species, indicating that viral integration is a recent and frequent phenomenon. Relaxation of selective pressure on badnaviral sequences that experienced neutral evolution after integration in the plant genome was recorded. Additionally, a significant decrease (35%) in the EPRV evolution rate was observed compared to BSV, reflecting the difference in the evolution rate between episomal dsDNA viruses and plant genome. The comparison of our results with the evolution rate of the Musa genome and other reverse-transcribing viruses suggests that EPRVs play an active role in episomal BSV diversity and evolution.     

How endogenous plant pararetroviruses shed light on Musa evolution

Background and Aims Banana genomes harbour numerous copies of viral sequences derived from banana streak viruses (BSVs) – dsDNA viruses belonging to the family Caulimoviridae. These viral integrants (eBSVs) are mostly defective, probably as a result of ‘pseudogenization’ driven by host genome evolution. However, some can give rise to infection by releasing a functional viral genome following abiotic stresses. These distinct infective eBSVs correspond to the three main widespread BSV species (BSOLV, BSGFV and BSIMV), fully described within the Musa balbisiana B genomes of the seedy diploid ‘Pisang Klutuk Wulung’ (PKW).Methods We characterize eBSV distribution among a Musa sampling including seedy BB diploids and interspecific hybrids with Musa acuminata exhibiting different levels of ploidy for the B genome (ABB, AAB, AB). We used representative samples of the two areas of sympatry between M. acuminata and M. balbisiana species representing the native area of the most widely cultivated AAB cultivars (in India and in East Asia, ranging from the Philippines to New Guinea). Seventy-seven accessions were characterized using eBSV-related PCR markers and Southern hybridization approaches. We coded both sets of results to create a common dissimilarity matrix with which to interpret eBSV distribution.Key Results We propose a Musa phylogeny driven by the M. balbisiana genome based on a dendrogram resulting from a joint neighbour-joining analysis of the three BSV species, showing for the first time lineages between BB and ABB/AAB hybrids. eBSVs appear to be relevant phylogenetic markers that can illustrate the M. balbisiana phylogeography story.Conclusion The theoretical implications of this study for further elucidation of the historical and geographical process of Musa domestication are numerous. Discovery of banana plants with B genome non-infective for eBSV opens the way to the introduction of new genitors in programmes of genetic banana improvement.     

Molecular and pathobiological characterization of 61 Potato mop‐top virus full‐length cDNAs reveals great variability of the virus in the centre of potato domestication,novel genotypes and evidence for recombination

The evolutionary divergence of Potato mop‐top virus (PMTV), a tri‐partite, single‐stranded RNA virus, is exceptionally low, based on the analysis of sequences obtained from isolates from Europe, Asia and North America. In general, RNA viruses exist as dynamic populations of closely related and recombinant genomes that are subjected to continuous genetic variation. The reason behind the low genetic variation of PMTV remains unclear. The question remains as to whether the low variability is a shared property of all PMTV isolates or is a result of the limited number of isolates characterized so far. We hypothesized that higher divergence of the virus might exist in the Andean regions of South America, the centre of potato domestication. Here, we report high variability of PMTV isolates collected from 12 fields in three locations in the Andean region of Peru. To evaluate PMTV genetic variation in Peru, we generated full‐length cDNA clones, which allowed reliable comparative molecular and pathobiological characterization of individual isolates. We found significant divergence of the CP‐RT and 8K sequences. The 8K cistron, which encodes a viral suppressor of RNA silencing, was found to be under diversifying selection. Phylogenetic analysis determined that, based on the CP‐RT sequence, all PMTV isolates could be categorized into three separate lineages (clades). Moreover, we found evidence for recombination between two clades. Using infectious cDNA clones of the representatives of these two clades, as well as reassortants for the RNA‐CP genomic component, we determined the pathobiological differences between the lineages, which we coined as S (for severe) and M (for mild) types. Interestingly, all isolates characterized previously (from Europe, Asia and North America) fall into the S‐type clade, whereas most of the Peruvian isolates belong to the M‐type. Taken together, our results support the notion of the single introduction of PMTV from the centre of potato origin to Europe, and subsequent spread of the S‐type into Asia and USA. This is also supported by the suggested novel classification of isolates based on genetic constellations.     

Three Infectious Viral Species Lying in Wait in the Banana Genome

Plant pararetroviruses integrate serendipitously into their host genomes. The banana genome harbors integrated copies of banana streak virus (BSV) named endogenous BSV (eBSV) that are able to release infectious pararetrovirus. In this investigation, we characterized integrants of three BSV species—Goldfinger (eBSGFV), Imove (eBSImV), and Obino l''Ewai (eBSOLV)—in the seedy Musa balbisiana Pisang klutuk wulung (PKW) by studying their molecular structure, genomic organization, genomic landscape, and infectious capacity. All eBSVs exhibit extensive viral genome duplications and rearrangements. eBSV segregation analysis on an F1 population of PKW combined with fluorescent in situ hybridization analysis showed that eBSImV, eBSOLV, and eBSGFV are each present at a single locus. eBSOLV and eBSGFV contain two distinct alleles, whereas eBSImV has two structurally identical alleles. Genotyping of both eBSV and viral particles expressed in the progeny demonstrated that only one allele for each species is infectious. The infectious allele of eBSImV could not be identified since the two alleles are identical. Finally, we demonstrate that eBSGFV and eBSOLV are located on chromosome 1 and eBSImV is located on chromosome 2 of the reference Musa genome published recently. The structure and evolution of eBSVs suggest sequential integration into the plant genome, and haplotype divergence analysis confirms that the three loci display differential evolution. Based on our data, we propose a model for BSV integration and eBSV evolution in the Musa balbisiana genome. The mutual benefits of this unique host-pathogen association are also discussed.     

Analysis of the distribution and structure of integrated Banana streak virus DNA in a range of Musa cultivars

Banana streak virus strain OL (BSV-OL) commonly infects new Musa hybrids, and this infection is thought to arise de novo from integrated virus sequences present in the nuclear genome of the plant. Integrated DNA (Musa6+8 sequence) containing the whole genome of the virus has previously been cloned from cv. Obino l’Ewai (Musa AAB group), a parent of many of the hybrids. Using a Southern blot hybridization assay, we have examined the distribution and structure of integrated BSV-OL sequences in a range of Musa cultivars. For cv. Obino l’Ewai, almost every restriction fragment hybridizing to BSV-OL was predicted from the Musa6+8 sequence, suggesting that this is the predominant type of BSV-OL integrant in the genome. Furthermore, since only two junction fragments of Musa/BSV sequence were detected, and the Musa6+8 sequence is believed to be integrated as multiple copies in a tandem array, then the internal Musa spacer sequences must be highly conserved. Similarly sized restriction fragments were detected in four BB group cultivars, but not in six AA or AAA group cultivars, suggesting that the BSV-OL sequences are linked to the B-genome of Musa. We also provide evidence that cv. Williams (Musa AAA group) contains a distinct badnavirus integrant that is closely related to the ‘dead’ virus integrant previously characterized from Calcutta 4 (Musa acuminata ssp. burmannicoides). Our results suggest that the virus integrant from cv. Williams is linked to the A-genome, and the complexity of the hybridization patterns suggest multiple sites of integration and/or variation in sequence and structure of the integrants.     

Molecular characterization of <Emphasis Type="Italic">Banana streak virus</Emphasis> isolate from <Emphasis Type="Italic">Musa Acuminata</Emphasis> in China

Banana streak virus (BSV), a member of genus Badnavirus, is a causal agent of banana streak disease throughout the world. The genetic diversity of BSVs from different regions of banana plantations has previously been investigated, but there are relatively few reports of the genetic characteristic of episomal (non-integrated) BSV genomes isolated from China. Here, the complete genome, a total of 7722bp (GenBank accession number DQ092436), of an isolate of Banana streak virus (BSV) on cultivar Cavendish (BSAcYNV) in Yunnan, China was determined. The genome organises in the typical manner of badnaviruses. The intergenic region of genomic DNA contains a large stem-loop, which may contribute to the ribosome shift into the following open reading frames (ORFs). The coding region of BSAcYNV consists of three overlapping ORFs, ORF1 with a non-AUG start codon and ORF2 encoding two small proteins are individually involved in viral movement and ORF3 encodes a polyprotein. Besides the complete genome, a defective genome lacking the whole RNA leader region and a majority of ORF1 and which encompasses 6525bp was also isolated and sequenced from this BSV DNA reservoir in infected banana plants. Sequence analyses showed that BSAcYNV has closest similarity in terms of genome organization and the coding assignments with an BSV isolate from Vietnam (BSAcVNV). The corresponding coding regions shared identities of 88% and ∼95% at nucleotide and amino acid levels, respectively. Phylogenetic analysis also indicated BSAcYNV shared the closest geographical evolutionary relationship to BSAcVNV among sequenced banana streak badnaviruses.     

MITOCHONDRIAL DNA PHYLOGENY OF THE SYMBIOTIC DINOFLAGELLATES (SYMBIODINIUM,DINOPHYTA)1

Symbiotic dinoflagellates belonging to the genus Symbiodinium (Freudenthal) are found worldwide in association with shallow‐water tropical and subtropical marine invertebrates. Most phylogenetic studies of Symbiodinium have used nuclear rRNA (nrDNA) genes to infer relationships among members of the genus. In this report, we present the first phylogeny of Symbiodinium based on DNA sequences from a mitochondrial protein‐coding gene (cytochrome oxidase subunit I [cox1]). Two principal groups, one comprised of Symbiodinium clade A and the second encompassing Symbiodinium clades B/C/D/E/F, are strongly supported in the cox1 phylogeny. Relationships within Symbiodinium clades B/C/D/E/F, however, are less well resolved compared with phylogenies inferred from nrDNA and chloroplast large subunit (cp23S)‐rDNA genes. Statistical tests between alternative tree topologies verified, with an exception being the position of one controversial member of Symbiodinium clade D, that relationships inferred from cox1 are congruent with those inferred from nrDNA and cp23S‐rDNA. Taken together, the relationships between the major Symbiodinium clades are robust, and there appears to be no evidence of hybridization or differential introgression of nuclear and plastid genomes between clades.     

Centrifugation Assisted Agrobacterium tumefaciens-mediated Transformation (CAAT) of embryogenic cell suspensions of banana (Musa spp. Cavendish AAA and Lady finger AAB)

Centrifugation-assisted Agrobacterium-mediated transformation (CAAT) protocol, developed using banana cultivars from two economically important genomic groups (AAA and AAB) of cultivated Musa, is described. This protocol resulted in 25-65 plants/50mg of settled cell volume of embryogenic suspension cells, depending upon the Agrobacterium strain used, and gave rise to hundreds of morphologically normal, transgenic plants in two banana cultivars from the two genomic groups. Development of a highly efficient Agrobacterium-mediated transformation protocol for a recalcitrant species like banana, especially the Cavendish group (AAA) cultivars, required the identification and optimisation of the factors affecting T-DNA delivery and subsequent plant regeneration. We used male-flower-derived embryogenic cell suspensions of two banana cultivars (Cavendish and Lady Finger) and Agrobacterium strains AGL1 and LBA4404, harbouring binary vectors carrying hpt (hygromycin phosphotransferase) and gusA (-glucuronidase) or nptII (neomycin phosphotransferase) and a modified gfp (green fluorescent protein) gene in the T-DNA, to investigate and optimise T-DNA delivery and tissue culture variables. Factors evaluated included pre-induction of Agrobacterium, conditions and media used for inoculation and co-cultivation, and the presence of acetosyringone and Pluronic F68 in the co-cultivation media. One factor that led to a significant enhancement in transformation frequency was the introduction of a centrifugation step during co-cultivation. Post co-cultivation liquid-media wash and recovery step helped avoid Agrobacterium overgrowth on filters supporting suspension culture cells. Marker-gene expression and molecular analysis demonstrated that transgenes integrated stably into the banana genome. T-DNA:banana DNA boundary sequences were amplified and sequenced in order to study the integration profile.     

Phylogeny of the families Pyuridae and Styelidae (Stolidobranchiata, Ascidiacea) inferred from mitochondrial and nuclear DNA sequences

The Order Stolidobranchiata comprises the families Pyuridae, Styelidae and Molgulidae. Early molecular data was consistent with monophyly of the Stolidobranchiata and also the Molgulidae. Internal phylogeny and relationships between Styelidae and Pyuridae were inconclusive however. In order to clarify these points we used mitochondrial and nuclear sequences from 31 species of Styelidae and 25 of Pyuridae. Phylogenetic trees recovered the Pyuridae as a monophyletic clade, and their genera appeared as monophyletic with the exception of Pyura. The Styelidae, on the other hand, appeared as a paraphyletic group split into several clades. One of them was formed by solitary oviparous species, of which the Pyuridae were a sister group. A second clade included the colonial genera Botryllus, Botrylloides and Symplegma. The remaining colonial and solitary genera formed several poorly resolved clades. One of the more species genus, Polycarpa, was shown to be polyphyletic, and the species Styela plicata grouped into two genetically distant clades suggesting the existence of two cryptic species. The internal phylogeny of Styelidae has bearings on the origin of coloniality in this family. We suggest to abandon the traditional division of colonial forms into social and compound species and use instead the categories of aggregated colonies that do not have common vascular systems, and integrated colonies, that do possess such systems. Our molecular results indicate that there have been several independent acquisitions of coloniality in the Styelidae, and that viviparity may be a pre-adaptation for a colonial life-style.     

Natural variation, functional divergence, and local adaptation of nucleotide binding site sequences in Rhododendron (Ericaceae)

To further understand natural variation and local adaptation in the evolution of plant defense, we analyzed polymorphism data of nucleotide-binding site (NBS) sequences of Rhododendron at both the species and population levels. Multiple duplication events were found in NBS sequence evolution in Rhododendron genomes, which resulted in six clades: A–F. Our results of several NBS clade pair comparisons showed significant evolutionary rate changes based on differences in substitution rates between NBS-encoding protein clades (type I functional divergence). Pairwise comparisons of NBS clades further revealed that many amino acids displayed radical biochemical property changes causing a shift in amino acid preferences between NBS-encoding protein clades (type II functional divergence). Such divergent evolution of NBSs is likely a consequence of positive selection related to differentiation of recognition signals in response to different pathogens. Primers specific to clades B and C, which differed in the number of radical amino acid changes causing type II functional divergence and levels of nucleotide diversities, were further used to amplify population clades B and C NBS sequences of Rhododendron formosanum populations. Higher levels of net nucleotide divergences (measured by D _a) between R. formosanum populations were found based on NBS sequences of population clade B compared to population clade C, suggesting local adaptation of population clade B NBS sequences. Local adaptation can be further inferred for R. formosanum population clade B NBS sequences because of significant Φ _ST based on variation in nonsynonymous substitutions. Furthermore, local adaptation was also suggested by no significant correlation of population pairwise F _ST between population clades B and C in R. formosanum.     

Metagenomic recovery of two distinct comammox Nitrospira from the terrestrial subsurface

The recently discovered comammox process encompasses both nitrification steps, the aerobic oxidation of ammonia and nitrite, in a single organism. All known comammox bacteria are affiliated with Nitrospira sublineage II and can be grouped into two distinct clades, referred to as A and B, based on ammonia monooxygenase phylogeny. In this study, we report high-quality draft genomes of two novel comammox Nitrospira from the terrestrial subsurface, representing one clade A and one clade B comammox organism. The two metagenome-assembled genomes were compared with other representatives of Nitrospira sublineage II, including both canonical and comammox Nitrospira. Phylogenomic analyses confirmed the affiliation of the two novel Nitrospira with comammox clades A and B respectively. Based on phylogenetic distance and pairwise average nucleotide identity values, both comammox Nitrospira were classified as novel species. Genomic comparison revealed high conservation of key metabolic features in sublineage II Nitrospira, including respiratory complexes I–V and the machineries for nitrite oxidation and carbon fixation via the reductive tricarboxylic acid cycle. In addition, the presence of the enzymatic repertoire for formate and hydrogen oxidation in the Rifle clades A and B comammox genomes, respectively, suggest a broader distribution of these metabolic features than previously anticipated.     

Evolutionary Relationships Among Old World Fruitbats (Megachiroptera: Pteropodidae) Based on 12S rRNA, tRNA Valine, and 16S rRNA Gene Sequences

Old World fruitbats were divided into the cynopterine, epomophorine, rousettine, eonycterine, and notopterine sections by Knud Andersen (1912). Among these, the eonycterine and notopterine sections together comprise the subfamily Macroglossinae, which includes forms with specializations for nectarivory. Single-copy DNA hybridization data argue against the monophyly of four of Andersen's sections and further suggest paraphyly or polyphyly of the Macroglossinae. DNA hybridization data provide support for an endemic African clade that includes Megaloglossus (an eonycterine), Epomophorus (an epomophorine), and Lissonycteris (a rousettine). Analyses of mitochondrial 12S rRNA-tRNA valine gene sequences corroborate the African clade but provide less resolution than hybridization data for most branches on the pteropodid tree. Here, we report 11 new 16S rRNA sequences and analyze a mitochondrial data set that includes 12S rRNA, tRNA valine, and 16S rRNA for 18 pteropodid genera. Parsimony, minimum evolution, and maximum likelihood were all employed in phylogenetic analyses. The addition of 16S rRNA sequences to the mitochondrial data set resulted in increased support for several clades, including Macroglossus + Syconycteris, Cynopterus + Thoopterus, Rousettus + the endemic African clade, and Eonycteris + Rousettus + the endemic African clade. Statistical tests suggest that another endemic African genus, Eidolon, is dissociated from the African clade and represents an independent invasion into Africa. We constructed a molecular phylogenetic framework that incorporated clades that were strongly supported by both single-copy DNA hybridization and 12S rRNA-tRNA valine-16S rRNA sequences. Using this framework as a backbone phylogenetic constraint, we then analyzed a morphological data matrix for 34 pteropodid genera with parsimony. Results of this analysis suggest that other epomophorines and Myonycteris (a cynopterine) are also part of the endemic African clade.     

MITOCHONDRIAL DNA IN THE OOGAMOCHLAMYS CLADE (CHLOROPHYCEAE): HIGH GC CONTENT AND UNIQUE GENOME ARCHITECTURE FOR GREEN ALGAE1

Most mitochondrial genomes in the green algal phylum Chlorophyta are AT‐rich, circular‐mapping DNA molecules. However, mitochondrial genomes from the Reinhardtii clade of the Chlorophyceae lineage are linear and sometimes fragmented into subgenomic forms. Moreover, Polytomella capuana, from the Reinhardtii clade, has an elevated GC content (57.2%). In the present study, we examined mitochondrial genome conformation and GC bias in the Oogamochlamys clade of the Chlorophyceae, which phylogenetic data suggest is closely related to the Reinhardtii clade. Total DNA from selected Oogamochlamys taxa, including four Lobochlamys culleus (H. Ettl) Pröschold, B. Marin, U. G. Schlöss. et Melkonian strains, Lobochlamys segnis (H. Ettl) Pröschold, B. Marin, U. G. Schlöss. et Melkonian, and Oogamochlamys gigantea (O. Dill) Pröschold, B. Marin, U. G. Schlöss. et Melkonian, was subjected to Southern blot analyses with cob and cox1 probes, and the results suggest that the mitochondrial genome of these taxa is represented by multiple‐sized linear DNA fragments with overlapping homologies. On the basis of these data, we propose that linear mitochondrial DNA with a propensity to become fragmented arose in an ancestor common to the Reinhardtii and Oogamochlamys clades or even earlier in the evolutionary history of the Chlorophyceae. Analyses of partial cob and cox1 sequences from these Oogamochlamys taxa revealed an unusually high GC content (49.9%–65.1%) and provided evidence for the accumulation of cob and cox1 pseudogenes and truncated sequences in the mitochondrial genome of all L. culleus strains examined.     

Population structure of the Indonesian giant tiger shrimp Penaeus monodon: a window into evolutionary similarities between paralogous mitochondrial DNA sequences and their genomes

Here we used both microsatellites and mtCR (mitochondrial DNA control region) sequences as genetic markers to examine the genetic diversity and population structure of Penaeus monodon shrimp from six Indonesian regions. The microsatellite data showed that shrimp from the Indian and the Pacific Ocean were genetically distinct from each other. It has been reported previously that P. monodon mtCR sequences from the Indo‐Pacific group into two major paralogous clades of unclear origin. Here we show that the population structure inferred from mtCR sequences matches the microsatellite‐based population structure for one of these clades. This is consistent with the notion that this mtCR clade shares evolutionary history with nuclear DNA and may thus represent nuclear mitochondrial pseudogenes (Numts).     

Evolutionary History of Endogenous Human Herpesvirus 6 Reflects Human Migration out of Africa

Human herpesvirus 6A and 6B (HHV-6) can integrate into the germline, and as a result, ∼70 million people harbor the genome of one of these viruses in every cell of their body. Until now, it has been largely unknown if 1) these integrations are ancient, 2) if they still occur, and 3) whether circulating virus strains differ from integrated ones. Here, we used next-generation sequencing and mining of public human genome data sets to generate the largest and most diverse collection of circulating and integrated HHV-6 genomes studied to date. In genomes of geographically dispersed, only distantly related people, we identified clades of integrated viruses that originated from a single ancestral event, confirming this with fluorescent in situ hybridization to directly observe the integration locus. In contrast to HHV-6B, circulating and integrated HHV-6A sequences form distinct clades, arguing against ongoing integration of circulating HHV-6A or “reactivation” of integrated HHV-6A. Taken together, our study provides the first comprehensive picture of the evolution of HHV-6, and reveals that integration of heritable HHV-6 has occurred since the time of, if not before, human migrations out of Africa.     

57 Systematics of hydropuntia montagne (gracilariaceae,gracilariales, rhodophyta) based on comparative morphology and rbcL sequence analysis

The taxonomic validity of the genus Hydropuntia Montagne (1843) (including Polycavernosa) within the Gracilariaceae (Gracilariales, Rhodophyta) is controversial. Morphological characters that define species of Hydropuntia are said to be variable and to overlap with those of Gracilaria. Here we present a global phylogenetic study of the family based on a Bayesian analysis of a large rbcL DNA sequence dataset indicating that the genus Hydropuntia forms a well supported monophyletic clade within the family, and recognize Hydropuntia as a genus distinct from Gracilaria. We also conducted smaller phylogenetic analyses in which thirty four Hydropuntia rbcL sequences resulted in two major clades within the genus, comprising a Caribbean clade and an Indo‐Pacific clade. Diagnostic reproductive stages that separate these two clades will be illustrated.     

Isolation and characterization of microsatellite markers from Musa balbisiana

This is the first report of targeted development of B genome microsatellite markers in Musa. A total of 44 sequences with microsatellites were isolated from an enriched library of Musa balbisiana cv. ‘Tani’ (BB genome). Of these, 25 were polymorphic when screened on 14 diverse diploid and triploid Musa accessions. The number of alleles detected by each marker ranged between one and seven. All 25 microsatellite markers generated amplification products in all species and genome complements. These new microsatellite markers fill an important gap for diversity assessment and linkage mapping studies in plantain (AAB) and cooking banana (ABB).     

Rapid evolution of a young L1 (LINE-1) clade in recently speciated rattus taxa

L1 elements are retrotransposons that have been replicating and evolving in mammalian genomes since before the mammalian radiation. Rattus norvegicus shares the young L1_mlvi2 clade only with its sister taxon, Rattus cf moluccarius. Here we compared the L1_mlvi2 clade in these recently diverged species and found that it evolved rapidly into closely related but distinct clades: the L1_mlvi2-rm clade (or subfamily), characterized here from R. cf moluccarius, and the L1_mlvi2-rn clade, originally described in R. norvegicus. In addition to other differences, these clades are distinguished by a cluster of amino acid replacement substitutions in ORF I. Both rat species contain the L1_mlvi2-rm clade, but the L1_mlvi2-rn clade is restricted to R. norvegicus. Therefore, the L1_mlvi2-rm clade arose prior to the divergence of R. norvegicus and R. cf moluccarius, and the L1_mlvi2-rn clade amplified after their divergence. The total number of L1_mlvi2-rm elements in R. cf moluccarius is about the same as the sum of the L1_mlvi2-rm and L1_mlvi2-rn elements in R. norvegicus. The possibility that L1 amplification is in some way limited so that the two clades compete for replicative supremacy as well as the implications of the other distinguishing characteristic of the L1_mlvi2-rn and L1_mlvi2-rm clades are discussed. Received: 6 November 1996 / Accepted: 12 April 1997