Genetic and molecular analysis of a three-component transposable-element system in maize

Summary Two different factors control the mutability of an unstable allele (c2-m8810581) of the C2 gene of maize. Both an autonomous En/Spm element and an unrelated independent factor, named Mediator, are coordinately required for the excision of the insert in c2-m881058Y. According to genetic analysis, Mediator does not have the suppressor (S) function or mutator (M) function of En/Spm. Mediator has no effect on the timing or frequency of excision of Enl, En-low, or various I/dSpm elements. Hence, Mediator only mediates a specific interaction between En and the insert at c2m881058Y. Molecular analysis of c2-m881058Y has revealed a 3.3 kb, complex, En-related receptor element inserted into the second exon of the C2 gene. The ends of this element are homologous to the ends of En/Spm, but an internal l.7 kb region shows no En/Spm homology. A great degree (11–14%) of nucleotide changes, relative to Enl, occur within and between the 12 bp TNPA binding motifs. Alterations of these critical cis-determinants may account for the need for a helper factor for excision. This element is named Irma, for Inhibitor that requires Mediator also, and represents a unique, low copy number class of receptor element.     

Distribution and conservation of the foldback transposable element inDrosophila

Summary Foldback elements are a family of transposable elements described inDrosophila melanogaster. The members of this dispersed repetitive family have terminal inverted repeats that sometimes flank a central region. The inverted repeats of all the family members are homologous.The study of the distribution and conservation of the foldback elements in differentDrosophila species shows that this distribution is different from that of the hybrid dysgenesis systems (PM and IR). Sequences homologous to foldback elements were observed by Southern blots and in situ hybridization in all species of themelanogaster subgroup and in some species of themontium andtakahashii subgroups. The element was probably already present before the radiation of these subgroups. No evidence of horizontal transmission of the foldback element could be observed.     

Survey of Mariner-Like Elements in the Housefly, Musca Domestica

The presence of mariner-like elements in four strains of the housefly, Musca domestica, was surveyed by PCR. Using the inverted terminal repeat (ITR) sequences of the Mos 1element as primers, DNAs were successfully amplified from all strains of the housefly. Southern blot analysis indicated that these amplified DNAs were repetitive sequences in the genome of M. domestica. Sequence analyses of cloned PCR products showed that they were 45% identical to the Mos 1element. These fragments appeared to be nonfunctional, because they contained no intact open reading frame (ORF) capable of encoding transposase. We conclude that these DNAs are degraded mariner-like elements (MLEs) in M. domestica. Because these endogenous MLEs in M. domesticado not encode any functional proteins, they probably would not affect the behavior of mariner-based vectors if such were introduced into this species as transformation vectors.     

Identification of Novel Non-autonomous CemaT Transposable Elements and Evidence of their Mobility within the C. elegans Genome

We describe here two new transposable elements, CemaT4 and CemaT5, that were identified within the sequenced genome of Caenorhabditis elegans using homology based searches. Five variants of CemaT4 were found, all non-autonomous and sharing 26 bp inverted terminal repeats (ITRs) and segments (152–367 bp) of sequence with similarity to the CemaT1 transposon of C. elegans. Sixteen copies of a short, 30 bp repetitive sequence, comprised entirely of an inverted repeat of the first 15 bp of CemaT4’s ITR, were also found, each flanked by TA dinucleotide duplications, which are hallmarks of target site duplications of mariner-Tc transposon transpositions. The CemaT5 transposable element had no similarity to maT elements, except for sharing identical ITR sequences with CemaT3. We provide evidence that CemaT5 and CemaT3 are capable of excising from the C. elegans genome, despite neither transposon being capable of encoding a functional transposase enzyme. Presumably, these two transposons are cross-mobilised by an autonomous transposon that recognises their shared ITRs. The excisions of these and other non-autonomous elements may provide opportunities for abortive gap repair to create internal deletions and/or insert novel sequence within these transposons. The influence of non-autonomous element mobility and structural diversity on genome variation is discussed.     

Regulatory potential of nonautonomous mariner elements and subfamily crosstalk

Two naturally occurring nonautonomous mariner elements were tested in vivo for their ability to down-regulate excision of a target element in the presence of functional mariner transposase. The tested elements were the peach element isolated from Drosophila mauritiana which encodes a transposase that differs from the autonomous element Mos1 in four amino acid replacements, and the DTBZ1 element isolated from D. teissieri which encodes a truncated protein consisting of the first 132 residues at the amino end of the normally 345-residue transposase. We provide evidence that the protein from the peach element does interact to down-regulate wildtype transposase, indicating that at least some nonautonomous elements in natural populations that retain their open reading frame may play a regulatory role. In contrast, our tests reveal at most a weak interaction between transposase from the autonomous Mos1 element and the truncated protein from DTBZ1 and none between Mos1 transposase and that from the distantly related mariner-like element Himar1 identified in the horn fly Haematobia irritans. Hence, the extent of regulatory crosstalk between mariner-like elements may be limited to closely related ones. The evolutionary implications of these results are discussed. This revised version was published online in July 2006 with corrections to the Cover Date.     

Drosophila melanogaster P Transposable Elements: Mechanisms of Transposition and Regulation

The molecular mechanisms that control P element transposition and determine its tissue specificity remain incompletely understood, although much information has been compiled about this element in the last decade. This review summarizes the currently available information about P element transposition, P-M hybrid dysgenesis and P cytotype features, P element-encoded repressors, and regulation of transposition.     

Prevalence of full-size <Emphasis Type="Italic">P</Emphasis> and <Emphasis Type="Italic">KP</Emphasis> elements in North American populations of <Emphasis Type="Italic">Drosophila melanogaster</Emphasis>

The P transposable element invaded the Drosophila melanogaster genome in the middle of the twentieth century, probably from D. willistoni in the Caribbean or southeastern North America. P elements then spread rapidly and became ubiquitous worldwide in wild populations of D. melanogaster by 1980. To study the dynamics and long-term fate of transposable genetic elements, we examined the molecular profile of genomic P elements and the phenotype in the P-M system of the current North American natural populations collected in 2001-2003. We found that full-size P and KP elements were the two major size classes of P elements present in the genomes of all populations ("FP + KP predominance") and that the P-related phenotypes had largely not changed since the 1980s. Both FP + KP predominance and phenotypic stability were also seen in other populations from other continents. As North American populations did not show many KP elements in earlier samples, we hypothesize that KP elements have spread and multiplied in the last 20 years in North America. We suggest that this may be due to a transpositional advantage of KP elements, rather than to a role in P-element regulation.     

Telomeric transgenes and trans-silencing in Drosophila

Autonomous P elements, inserted in heterochromatic telomeric associated sequences (TAS) at the X chromosome telomere (site 1A) have strong P element regulatory properties that include repression of P-induced hybrid-dysgenesis and of P-lacZ expression in the germline. P-lacZ insertions or defective P elements at 1A in TAS can also repress in trans a euchromatic P-lacZ in the germline. This property has been called a trans-silencing effect (TSE). It requires some sequence-homology between the telomeric insertion and the euchromatic transgene. When repression is partial, variegating lacZ expression is observed, suggesting a chromatin-based component. TSE is observed only when the silencer transgenes are maternally inherited and occurs only in the female germline. We have evidence that this silencing also works in the presence of homologous non-P element sequences suggesting that homology-dependent silencing could be a general phenomenon in the female germline; such a system might have been subsequently adopted by the P element family, allowing its own repression.     

Distribution of Bs1 retrotransposons in Zea and related genera

Summary Thirty-eight accessions from Zea and 20 accessions from related genera were probed for the presence of Bs1, a retrotransposon originally found in maize. All maize and teosinte plants tested show the presence of Bs1 in one to five densely hybridizing bands. The mean copy numbers of Bs1 elements among the maize and teosinte accessions were similar: 2.92 and 3.25, respectively, with no large differences between any subgroups. Most exotic maize samples exhibited two common bands of 7.8 kb and 4.7 kb. Section Zea teosintes (but not teosintes of section Luxuriantes) also show the presence of a common band of the same size as the smaller common band in maize. At reduced stringency, Tripsacum dactyloides exhibited a single hybridizing band at 6.9 kb. Results argue for the evolution of maize from a mexicana or parviglumis teosinte, and the evolution of the Bs1 element within the tribe Andropogoneae. Additionally, recombinant inbred lines were probed for the presence of Bs1, in order to map the chromosomal locations of Bs1 elements in four different maize lines. Two of the recombinant inbred parental lines had an element (Bs1-F) on chromosome 5, while the other two lines had an element (Bs1-S) on chromosome 8. Restriction site polymorphisms have apparently arisen in the vicinity of Bs1-S since its insertion. Segregation analysis of other lines was also performed; the data indicate that Bs1 has the distribution expected of a transposable element, different locations in different lines, and not that of a fixed gene locus. However, the common bands in the Zea mays lines and the recombinant inbred data imply that Bs1 is not highly mobile.     

荔枝、龙眼与其属间杂种的茎、叶解剖结构比较

为比较荔枝(Litchi)和龙眼(Dimocarpus)与其属间杂种的茎、叶解剖结构,采用徒手切片法、组织离析法和石蜡切片法对茎、叶片结构进行观察比较。结果表明,‘杂种A’和‘杂种B’的髓率、树皮率均居于父母本之间,而木质部率、导管总面积/木质部面积的比值、导管分子内径则表现出显著的超亲优势;‘杂种C’和‘杂种D’的树皮率和射线宽度均小于父母本。‘杂种A’和‘杂种B’导管分子无尾和两端水平的频率居于父母本之间,‘杂种C’和‘杂种D’的导管分子形态特征较接近其母本‘石峡’,‘杂种D’的导管分子长度显著大于父母本。4个杂种的叶主脉厚均居于父母本之间,‘杂种D’的叶脉突起度和‘紫娘喜’的栅栏组织/海绵组织厚度比值均显著大于其他试材。4个属间杂种叶片表皮细胞的大小、垂周壁的形态均居于父母本之间;荔枝和龙眼叶片表皮特征差异明显,可以作为两属的鉴别特征。4个属间杂种的解剖结构总体上呈现出较明显的偏母遗传效应。     

Actinomycete integrative and conjugative pMEA-like elements of Amycolatopsis and Saccharopolyspora decoded

Actinomycete integrative and conjugative elements (AICEs) are present in diverse genera of the actinomycetes, the most important bacterial producers of bioactive secondary metabolites. Comparison of pMEA100 of Amycolatopsis mediterranei, pMEA300 of Amycolatopsis methanolica and pSE211 of Saccharopolyspora erythraea, and other AICEs, revealed a highly conserved structural organisation, consisting of four functional modules (replication, excision/integration, regulation, and conjugative transfer). Features conserved in all elements, or specific for a single element, are discussed and analysed. This study also revealed two novel putative AICEs (named pSE222 and pSE102) in the Sac. erythraea genome, related to the previously described pSE211 and pSE101 elements. Interestingly, pSE102 encodes a putative aminoglycoside phosphotransferase which may confer antibiotic resistance to the host. Furthermore, two of the six pSAM2-like insertions in the Streptomyces coelicolor genome described by Bentley et al. [Bentley, S.D., Chater, K.F., Cerdeno-Tarraga, A.M., et al., 2002. Complete genome sequence of the model actinomycete Streptomyces coelicolor A3(2). Nature 417, 141-147] could be functional AICEs. Homologues of various AICE proteins were found in other actinomycetes, in Frankia species and in the obligate marine genus Salinispora and may be part of novel AICEs as well. The data presented provide a better understanding of the origin and evolution of these elements, and their functional properties. Several AICEs are able to mobilise chromosomal markers, suggesting that they play an important role in horizontal gene transfer and spread of antibiotic resistance, but also in evolution of genome plasticity.     

Retrotransposon Mys was active during evolution of the Peromyscus leucopus-maniculatus complex

Mys is a retrovirus-like transposable element found throughout the genus Peromyscus. Several mys subfamilies identified on the basis of restriction site variation occur in more than one species. The distribution of these subfamilies is consistent with the accepted species phylogeny, suggesting that mys was present in the ancestor of Peromyscus and has been active through much of the evolution of this genus. Quantitative Southern blot analysis was used to examine the variability of subfamilies in P. leucopus and maniculatus. We found that subfamilies with phylogenetically narrow distributions were more variable in copy number both within and between species than subfamilies with a broader distribution. Taken together, our data suggest that mys has undergone multiple rounds of transposition since the peromyscine radiation, and that five subfamilies have been amplified during the evolution of the leucopus-maniculatus species complex. Correspondence to: H.A. Wichman     

黄柳与小红柳导管分子形态特征及其生态适应性比较研究

黄柳和小红柳为浑善达克沙地2种重要的水土保持灌木,黄柳适宜在流动或半流动沙丘上生长,而小红柳适宜在丘间低地生长,二者既可混生,也可形成纯林,存在规律性分布。该研究采用组织离析法和显微照相技术,对黄柳和小红柳的根、茎部导管分子形态特征进行比较研究,探讨导管分子形态特征与其生态适应性的关系,为黄柳和小红柳次生木质部解剖学研究提供资料。结果显示:(1)黄柳和小红柳导管分子均以网纹和两端具尾、一端具尾类型为主,具单穿孔板、互列纹孔。(2)黄柳与小红柳的根部导管分子长度、直径、端壁斜度差异显著,且黄柳较小红柳的直径大、端壁斜度小,为进化特征,而长度较长,为原始特征;但茎部导管分子长度、直径、端壁斜度无显著差异。(3)黄柳与小红柳的导管分子的形态特征与生境间存在一定的相关性,黄柳根部导管具有高输水性而较小红柳适应干旱环境。该研究为黄柳和小红柳造林提供理论指导,并为植物生态适应性的相关研究提供参考。     

Molecular cloning of the o2-m5 allele of Zea mays using transposon marking

Summary The deposition of zein protein in maize endosperm is under the control of several regulatory loci. The isolation of DNA sequences corresponding to Opaque-2 (O2), one of such loci, is described in this paper. The mutable allele, o2-m5 was first induced moving the Ac transposable element present at the wx-m7 allele to the O2 locus. Genetic data suggest that a functional Ac element is responsible for the observed somatic mutability of o2-m5. The isolation of genomic clones containing flanking sequences corresponding to the O2 gene was possible by screening an o2-m5 genomic libary with a probe corresponding to internal Ac sequences usually absent in the defective element Ds. Out of 27 clones isolated with homology to the central part of Ac element, only clones 6IP and 21IP generated a 2.5 kb internal fragment size of an active Ac element when digested with PvuII restriction enzyme. A sequence representing a XhoI fragment of 0.9 kb lying, in the 6IP clone, adjacent to the Ac elements, was subcloned and utilized to prove that it corresponded to a part of the O2 gene. To obtain this information we made use of: (1) DNAs from several reversions originating from the unstable (o2mk-(r) allele, which, when digested with SstI, showed a correct 3.4 kb fragment typical of non-inserted alleles of the O2 locus; and (2) recessive alleles of the O2 locus which were devoid of a 2.0 kb mRNA, present on the contrary in the wild type and in other zein regulating mutants different from O2.This paper is dedicated to the memory of R. Marotta, who actively participated in the realization of this work     

Transposon display supports transpositional activity of <Emphasis Type="Italic">P</Emphasis> elements in species of the <Emphasis Type="Italic">saltans</Emphasis> group of <Emphasis Type="Italic">Drosophila</Emphasis>

Mobilization of two P element subfamilies (canonical and O-type) from Drosophila sturtevanti and D. saltans was evaluated for copy number and transposition activity using the transposon display (TD) technique. Pairwise distances between strains regarding the insertion polymorphism profile were estimated. Amplification of the P element based on copy number estimates was highly variable among the strains (D. sturtevanti, canonical 20.11, O-type 9.00; D. saltans, canonical 16.4, O-type 12.60 insertions, on average). The larger values obtained by TD compared to our previous data by Southern blotting support the higher sensitivity of TD over Southern analysis for estimating transposable element copy numbers. The higher numbers of the canonical P element and the greater divergence in its distribution within the genome of D. sturtevanti (24.8%) compared to the O-type (16.7%), as well as the greater divergence in the distribution of the canonical P element, between the D. sturtevanti (24.8%) and the D. saltans (18.3%) strains, suggest that the canonical element occupies more sites within the D. sturtevanti genome, most probably due to recent transposition activity. These data corroborate the hypothesis that the O-type is the oldest subfamily of P elements in the saltans group and suggest that the canonical P element is or has been transpositionally active until more recently in D. sturtevanti.     

Thehermit transposable element of the Australian sheep blowfly,Lucilia cuprina, belongs to thehAT family of transposable elements

We report the cloning ofhermit, a member of thehAT family of transposable elements from the genome of the Australian sheep blowfly,Lucilia cuprina. Hermit is 2716 bp long and is 49% homologous to the autonomoushobo element,HFL1, at the nucleic acid level.Hermit has 15 bp terminal inverted repeats that share 10 bp with the terminal inverted repeats ofHFL1. Conceptual translation reveals a 583 residue open reading frame (ORF) that is 64% similar and 42% identical to theHFL1 ORF. However, the sequence of thehermit element contains two frameshifts within the putative ORF, indication thathermit is an inactive element. Analysis ofL. cuprina strains from within and outside Australia suggested thathermit is present as a single copy in all the genomes analysed.     

Retrotransposon-based molecular markers for linkage and genetic diversity analysis in wheat

Retrotransposon-based molecular markers have been developed to study bread wheat ( Triticum aestivum) and its wild relatives. SSAP (Sequence-Specific Amplification Polymorphism) markers based on the BARE-1/ Wis-2-1A retrotransposons were assigned to T. aestivum chromosomes by scoring nullisomic-tetrasomic chromosome substitution lines. The markers are distributed among all wheat chromosomes, with the lowest proportion being assigned the D wheat genome. SSAP markers for BARE-1/ Wis-2-1A and three other wheat retrotransposons, Thv19 , Tagermina and Tar1, are broadly distributed on a wheat linkage map. Polymorphism levels associated with these four retrotransposons vary, with BARE-1/ Wis-2-1A and Thv19 both showing approximately 13% of bands polymorphic in a mapping population, Tagermina showing approximately 17% SSAP band polymorphism and Tar1 roughly 18%. This suggests that Tagermina and Tar1 have been more transpositionally active in the recent evolutionary past, and are potentially the more useful source of molecular markers in wheat. Lastly, BARE-1 / Wis-2-1A markers have also been used to characterise the genetic diversity among a set of 35 diploid and tetraploid wheat species including 26 Aegilops and 9 Triticum accessions. The SSAP-based diversity tree for Aegilops species agrees well with current classifications, though the Triticum tree shows several significant differences, which may be associated with polyploidy in this genus.Communicated by M.-A. Grandbastien     

A novel eye morphology induced by a P element in somatic tissue of Drosophila melanogaster.

Summary We found a specific eye morphology designated as Square, which is induced when some Drosophila melanogaster strains harboring P elements are crossed with the 2–3 strain carrying a modified P element, P[ry ⁺, 2–3], which produces transposase in somatic tissue. This phenotype was dominant and also induced in the reciprocal crosses. Square was induced when the 2–3 strain was crossed with Q and M strains such as the sn^w (M) strain carrying three small P elements but not with P strains. Inheritance of Square was also tested and its phenotype was not transmitted to the next generation. These results suggest that Square is caused by the transposition of P elements in somatic cells.