A miniature insertion element transposable in Microcystis sp. FACHB 854

A 186-bp sequence with imperfect terminal inverted repeats and target direct repeats but without any transposase-encoding capacity was found to be transposable in an isolate derived from Microcystis sp. FACHB 854. This miniature insertion element, designated as ISM854-1, and with its homologues present at least 10 copies in the genome of Microcystis FACHB 854, is inserted into the 8-bp long and AT-rich target sequences, but none or few in other Microcystis strains. A variant of ISM854-1, denoted ISM854-1A, has perfect inverted repeat sequences and may transpose in pairs in a structure like a composite transposon. This is the first report of non-autonomous transposition of a mini-IS in a cyanobacterium.     

Similarity of the Cin1 repetitive family of Zea mays to eukaryotic transposable elements

It has been suggested that the middle repetitive class of sequences that make up a large proportion of the eukaryotic genome have been amplified and dispersed by DNA transposition. Transposition is a phenomenon first postulated by Barbara McClintock on the basis of her genetic analysis of mutants in Zea mays. Since then, DNA transposition has been studied genetically in various plant systems and is well documented on the molecular level in both prokaryotes and eukaryotes. This has included the isolation of DNA inserts at various loci in several plants; however, the prevalence of transposition in plants is not established. We report here DNA nucleotide sequence data which show that some members of the Cin1 middle repetitive family of maize have features characteristic of known transposable elements. One cloned Cin1 repeat has a 6-base pair (bp) perfect inverted repeat sequence at its ends. The terminal five base pairs (5' TGTTG . . . CAACA 3') are identical to the termini of Drosophila copia transposable elements. Two other Cin1 alleles are flanked by 5-bp direct repeats. A comparison is made with the long terminal repeat (LTR) of the copia-Ty1-retrovirus families of moveable genetic elements.     

Transposition of Tn554 does not generate a target duplication

Transposable elements from prokaryotic and eukaryotic organisms are discrete DNA segments bounded by inverted or directly repeated sequences that insert into non-homologous DNA in a reaction that is independent of the general recombination functions of the host. The mechanisms proposed generally involve a staggered double-stranded scission of the target DNA, ligation to the nicked ends of the transposable element, and replication of the element, resulting in the generation of a directly repeated oligonucleotide target sequence flanking the new copy of the element. Most transposons have a relatively low degree of target site specificity coupled with a low insertion frequency. Tn554, a Staphylococcus aureus transposon which specifies resistances to erythromycin and spectinomycin, displays an unusually high degree of insertion specificity. Tn554 transposes with high efficiency to a unique ('primary') site in the S. aureus chromosome and only rarely (less than 10(-6) per transductant) to other, secondary sites. We report here the nucleotide sequences surrounding the junctions of Tn554 in three independent 'primary' insertions and two 'secondary' insertions of the transposon. Two unusual features are revealed: first, the termini of Tn554 contain neither inverted nor directly repeated sequences. Second, transposition of Tn554 does not generate the short direct repeats of the target DNA that are characteristic of other transposable elements. These results suggest that the mechanism of Tn554 insertion may be significantly different from that of other transposons.     

The plant MITE mPing is mobilized in anther culture

Transposable elements constitute a large portion of eukaryotic genomes and contribute to their evolution and diversification. Miniature inverted-repeat transposable elements (MITEs) constitute one of the main groups of transposable elements and are distributed ubiquitously in the genomes of plants and animals such as maize, rice, Arabidopsis, human, insect and nematode. Because active MITEs have not been identified, the transposition mechanism of MITEs and their accumulation in eukaryotic genomes remain poorly understood. Here we describe a new class of MITE, called miniature Ping (mPing), in the genome of Oryza sativa (rice). mPing elements are activated in cells derived from anther culture, where they are excised efficiently from original sites and reinserted into new loci. An mPing-associated Ping element, which has a putative PIF family transposase, is implicated in the recent proliferation of this MITE family in a subspecies of rice.     

DNA sequence at the end of IS1 required for transposition

The insertion sequence IS1 belongs to a class of bacterial transposable genetic elements that can form compound transposons in which two copies of IS1 flank an otherwise non-transposable segment of DNA. IS1 differs from other known elements of this class (such as IS10, IS50 and IS903) in several respects. It is one of the smallest known insertion elements, exhibits a relatively complex array of open reading frames, is present in the chromosomes of various Enterobacteria, in some cases in many copies, and its insertion can result in the duplication of either 8 or 9 base pairs (bp) in the target DNA. Furthermore, although, like other members of the compound class, it seems to undergo direct transposition, IS1 also promotes replicon fusion (co-integrate formation) at a relatively high frequency. Like all other elements studied to date, the integrity of the extremities of IS1 are essential for efficient transposition. We have constructed a test system to determine the minimal DNA sequences at the extremities of IS1 required for transposition. Sequential deletions of the end sequences reveal that 21-25 bp of an isolated extremity are sufficient for transposition. A specific sequence 13-23 bp from the ends, defining the edge of the minimal sequence, is implicated as an essential site. The sites, symmetrically arrayed at both ends of IS1, correspond to the apparent consensus sequence of the known binding sites for the Escherichia coli DNA-binding protein (called integration host factor or IHF) which is required for the site-specific recombination that leads to integration of bacteriophage lambda into the bacterial genome. The sites at the ends of IS1 may thus bind a host protein, such as JHF or a related protein, that is involved in regulating the transposition apparatus.     

Genetic effects of injection of Rous sarcoma virus DNA into polar plasm of early Drosophila melanogaster embryos

Retroviral proviruses and the transposable elements of eukaryotic genomes are structurally similar. The biological significance of eukaryotic transposable elements has not been examined extensively but it is known that, like prokaryotic transposons, these elements can induce mutations in adjacent genes and cause their transposition. It is of interest to determine whether retroviral proviruses have the same mutagenic and gene transposing ability as transposable elements, particularly because the retrovirus genome is assumed to have originated from transposable elements of lower eukaryotes. The transfer of DNA sequences into animal zygotes or embryos by microinjection is a promising experimental approach for eluxidating their functions: when foreign DNAs were introduced into a mouse germ line, mutations were induced and at least in some mice, the mutation was caused by the insertion of a retroviral sequence. We have introduced Rous sarcoma virus (RSV) DNA into a germ line of Drosophila melanogaster, and describe here the resultant genetic effects.     

DNA sequences at the ends of transposon Tn5 required for transposition

Transposons are a class of genetic elements that can move from one site in a cell's genome to another independently of the cell's general recombination system. Little is known about the mechanism of transposition of compound transposons such as Tn5, but it is thought that a transposon-encoded protein (a transposase) must recognize the outer ends of the element and, together with host factors, catalyse the transfer of the internal DNA into a new site in a manner that may involve replication. It has previously been shown that the synthesis of an IS50R-encoded protein (protein 1) is an essential requirement for Tn5 transposition. Here we demonstrate that a structure containing only the outer 186 base pairs (bp) of both inverted repeats is capable of being efficiently complemented to transpose in Escherichia coli, provided IS50R is located close by on the same replicon. In addition, Bal31-generated deletions indicate that 16-18 bp of the outer end of IS50L are required for transposition. This 16-18-bp sequence contains the 8-9-bp small inverted repeat present at each end of IS50 plus a 9-bp sequence which is homologous to an interrelated sequence present in four copies in the chromosomal origin of replication in a variety of Gram-negative bacteria. This sequence organization suggests that the ends of Tn5 may function to provide a recognition site for the Tn5 transposase adjacent to a sequence recognized by the host replication system.     

Host genome surveillance for retrotransposons by transposon-derived proteins

Transposable elements and their remnants constitute a substantial fraction of eukaryotic genomes. Host genomes have evolved defence mechanisms, including chromatin modifications and RNA interference, to regulate transposable elements. Here we describe a genome surveillance mechanism for retrotransposons by transposase-derived centromeric protein CENP-B homologues of the fission yeast Schizosaccharomyces pombe. CENP-B homologues of S. pombe localize at and recruit histone deacetylases to silence Tf2 retrotransposons. CENP-Bs also repress solo long terminal repeats (LTRs) and LTR-associated genes. Tf2 elements are clustered into 'Tf' bodies, the organization of which depends on CENP-Bs that display discrete nuclear structures. Furthermore, CENP-Bs prevent an 'extinct' Tf1 retrotransposon from re-entering the host genome by blocking its recombination with extant Tf2, and silence and immobilize a Tf1 integrant that becomes sequestered into Tf bodies. Our results reveal a probable ancient retrotransposon surveillance pathway important for host genome integrity, and highlight potential conflicts between DNA transposons and retrotransposons, major transposable elements believed to have greatly moulded the evolution of genomes.     

The map-based sequence of the rice genome

Rice, one of the world's most important food plants, has important syntenic relationships with the other cereal species and is a model plant for the grasses. Here we present a map-based, finished quality sequence that covers 95% of the 389 Mb genome, including virtually all of the euchromatin and two complete centromeres. A total of 37,544 non-transposable-element-related protein-coding genes were identified, of which 71% had a putative homologue in Arabidopsis. In a reciprocal analysis, 90% of the Arabidopsis proteins had a putative homologue in the predicted rice proteome. Twenty-nine per cent of the 37,544 predicted genes appear in clustered gene families. The number and classes of transposable elements found in the rice genome are consistent with the expansion of syntenic regions in the maize and sorghum genomes. We find evidence for widespread and recurrent gene transfer from the organelles to the nuclear chromosomes. The map-based sequence has proven useful for the identification of genes underlying agronomic traits. The additional single-nucleotide polymorphisms and simple sequence repeats identified in our study should accelerate improvements in rice production.     

Complete nucleotide sequence and genomic organization of Periplaneta fuliginosa densonucleosis virus

We have cloned the replicative form of thePeriplaneta fuliginosa densonucleosis virus (PfDNV) genome and determined its complete sequence. The sequence has 5 454 nucleotides (nt), the genome consists of an internal unique sequence flanked by inverted terminal repeats (201 nt). The first 122 nt at the 5′ end and the terminal 122 nt at the 3′ end of both plus and minus strands can fold into a typical hairpin structure. The genome contains seven major open reading frames (ORFs). The plus strand has 4 ORFs occupying the 5′ half of the plus strand, whereas the others span the 5′ half of the minus strand. Two potential promoters were found at map units (m.u.) 3 and 97. Computer analysis of sequence homologies with other parvoviruses suggests that the plus strand ofPf DNV encodes very likely the nonstructural proteins and the minus strand probably encodes the structural proteins.     

水稻基因整合平台系统供体质粒pURKMT的构建

提高水稻产量,改良稻米品质是育种学家广泛研究的课题．随着现代生物技术的发展,水稻已成为植物基因工程的重要研究对象．许多实验室已成功地建立了一系列供外源基因转化水稻的系统．但是这些转化系统主要应用Ｔｉ质粒衍生的载体,通过Ｔ－ＤＮＡ左右两端的序列将目的基...     

Identification and functional analysis of 23 novel box C／D snoRNAs from Oryza sativa

In a cDNA library generated from rice small nuclear RNAs,30box C/D small nucleolar RNAs (snoRNAs) were identiffied through preliminary screen.Except 7 known snoRNAs such as U14,all snoRNAs were identified in rice for the first time experimentally.Among the 23 novel snoRNAs,11 snoRNAs appear rice-specific,6 snoRNAs are unique to plants,the remaining 6 snoRNAs have their counterparts in both Arabidopsis and yeast or mammals according to the conserved antisense sequencs that guide 2‘-O-ribose methylation of rRNA,17 of the 23 novel snoRNAs were predicted to guide 24 2‘‘-O-ribose methylations at the specificsites of rice 5.8S,18S,25S rRNAs,among which 19 methylated sites were determined by primer extension at low dNTP concentrations.The remaining 6 snoRNAs devoid of rRNA antisense elements may represent novel snoRNA species in rice.The results show that constructing a cDNA library from small nuclear RNAs is an effective experimental approach for novel snoRNA is identification.The novel snoRNAs are important in elucidating the genomic organization and expression of plant snoRNA genes and the mechanism through which 2‘‘-O-ribose methylations took place in rRNAs.     

Covalently closed circles of adenovirus 5 DNA

The genome of adenoviruses is a double-stranded linear DNA molecule with inverted terminal repeats about 100 base pairs (bp) in length and a terminal protein covalently linked to the 5' nucleotide of each strand. Both of these features permit the formation of DNA circles, the inverted repeats allowing the circularization of single-stranded DNA and the terminal protein the joining of one or more molecules to yield double-stranded circles or concatemers. However, although the existence of covalently closed circles has been postulated, double-stranded viral DNA purified from virions or infected cells by conventional methods (that is, using proteases and phenol or chloroform) has always been obtained in a linear form. Here, we present evidence for the existence in adenovirus 5 (Ad5) infected cells of novel structures resulting from covalent head-to-tail joining of viral DNA molecules and show that these structures are due at least in part to the formation of covalently closed circles.     

The terminal nucleotides of retrovirus DNA are required for integration but not virus production

Deletion of specific nucleotides at either end of the long terminal repeat of the avian retrovirus, spleen necrosis virus, results in replication-competent but integration-defective virus. This result supports two conclusions: (1) the 5-base pair terminal inverted repeats and three to seven adjacent nucleotides are required for integration; (2) integration of retrovirus DNA is not required for retrovirus gene expression.     

High-frequency precise excision of the Drosophila foldback transposable element

Precise excision of transposable elements in prokaryotes is a rare event which occurs at a significantly lower rate than transposition and other element-mediated events. Thus, we were intrigued by a eukaryotic transposable element which seemed capable of precise excision at high frequencies. The white-crimson (wc) mutation in Drosophila, a highly unstable allele of the X-linked eye colour locus, white, resulted from the insertion of a member of the foldback (FB) transposable element family. This mutation reverts to its parental phenotype at a frequency of greater than 1 in 10(3) X chromosomes. Characterization of these revertants by Southern blots of genomic DNA indicated that they resulted from loss of the wc insertion. Here we report the nucleotide sequence of the excision point in these revertants, and conclude that the FB element responsible for the wc mutation is capable of precise excision at high frequencies.