The Agrocybe aegerita mitochondrial genome contains two inverted repeats of the nad4 gene arisen by duplication on both sides of a linear plasmid integration site

The Agrocybe aegerita mitochondrial genome possesses two polB genes with linear plasmid origin. The cloning and sequencing of the regions flanking Aa-polB P1 revealed two large inverted repeats (higher than 2421 nt) separated by a single copy region of 5834 nt. Both repeats contain identical copies of the nad4 gene. The single copy region contains two disrupted genes with plasmid origin Aa-polB P1 and a small ORF homologous to a small gene described in two basidiomycete linear plasmids. The phylogenetic analyses argue in favor of a same plasmid origin for both genes but, surprisingly, these genes were separated by a mitochondrial tRNA-Met. Both strands of the complete region containing the two nad4 inverted copies and the tRNA-Met appear to be transcribed on large polycistronic mRNAs. A model summarizing the events that would have occurred is proposed: (1) capture of the tRNA by the plasmid before its integration in the mtDNA or acquisition of the tRNA gene by recombination after the plasmid integration, (2) integration of the plasmid in the mtDNA, accompanied by a large duplication containing the nad4 gene and (3) erosion of the plasmid sequences by large deletions and mutations.     

Circular mitochondrial genome of Candida albicans contains a large inverted duplication.

The mitochondrial DNA (mtDNA) of the dimorphic fungus Candida albicans has a molecular size of 41 kilobase pairs as judged by summation of the fragment sizes produced by digestion with restriction endonucleases EcoRI, PvuII, and a combination of both enzymes. Five of the six EcoRI fragments comprising the mitochondrial genome have been cloned into the plasmid vector, pBR322. Restriction mapping revealed a circular map as predicted by previous observations with the electron microscope. The use of nick-translated, purified mtDNA to probe digests of mtDNA from other strains of C. albicans revealed a common restriction pattern. Use of nick-translated, cloned EcoRI fragments to probe digests of mtDNA revealed a large (at least 5 kilobase pairs), inverted duplication as well as a smaller (less than 0.4 kilobase pairs) region of related sequences.     

The genome of lipid-containing bacteriophage PRD1, which infects gram-negative bacteria, contains long, inverted terminal repeats.

The bacteriophage PRD1 is a lipid-bearing phage that infects a wide variety of gram-negative bacteria, including Escherichia coli and Salmonella typhimurium when they contain the appropriate plasmid. It contains a linear duplex DNA molecule that is covalently bound by its 5' ends to a terminal protein. We report here that the PRD1 genome contains a 111-base-pair terminal inverted repeat which does not bear homology to that of any known linear duplex DNAs with terminal proteins. We further report that its 3' termini are susceptible to enzymatic digestion by exonuclease III.     

Nucleotide sequence analysis of the unusually long terminal inverted repeats of a giant linear plasmid, SCP1.

SCP1 is a giant linear plasmid of 350 kb coding for the methylenomycin biosynthetic genes in Streptomyces coelicolor. The unusually long terminal inverted repeats present on both ends of SCP1 were analyzed on the nucleotide sequence level. Analysis of six clones containing the terminal 0.35-kb XbaI fragment revealed a slight heterogeneity in the nucleotide sequences of the SCP1 ends. Moreover, it was indicated that this fragment contained seven palindromic inverted repeats and a GT-rich region in the 5'-end strand. The size of the terminal inverted repeats was determined to be 81 kb by the cloning and sequencing of their end-points. An insertion sequence, IS466 was shown to be present just at the end of the right terminal inverted repeat.     

The basidiomycete Lentinus edodes linear mitochondrial DNA plasmid contains a segment exhibiting a high autonomously replicating sequence activity in Saccharomyces cerevisiae.

A linear DNA plasmid, designated pLLE1, has been isolated from a mitochondrial fraction of a strain of Lentinus edodes. pLLE1(11.0 kbp) was sensitive to the 3'----5'-acting exonuclease III and resistant to the 5'----3'-acting lambda exonuclease. It showed no homology with mitochondrial and nuclear genomic DNAs of plasmidless strain as well as the pLLE1-harboring host strain of L. edodes. The 1434-bp fragment (sequences) capable of autonomous replication in the yeast Saccharomyces cerevisiae (ARSs) was cloned from pLLE1 DNA with YIp32 (pBR322 containing yeast LEU2 DNA), which displayed a high ARS activity. The cloned 1434-bp fragment was shown to lie near to the end of pLLE1 DNA (nucleotides about 800-2200) and contained three consecutive ARS consensus sequences (A/T)TTTAT(A/G)TTT(A/T) of S. cerevisiae and dispersive eight ARS consensus-like sequences. The subcloned 366-bp fragment containing the three ARSs retained original ARS activity of the 1434-bp fragment.     

The inactivation of tet genes on a plasmid by the duplication of one inverted repeat of a transposon-like structure which itself mediates tetracycline resistance

Derivatives of a naturally occurring IncFII tetracycline resistance plasmid (pUB889) which are unable to confer resistance to tetracycline, and which were isolated from both partners of a married couple, have been examined. The tet genes are part of a transposon-like structure which is closely related to, but distinct from, Tn10. The lesions in the two plasmids examined are identical and involve the insertion of a nucleotide sequence of 0.9 × 10⁶ within the region encoding tetracycline resistance, expression of which is lost as a consequence. The extra DNA is homologous with the nucleotide sequence, a pair of which form the inverted repeats of the Tn10-like structure. We conclude that this nucleotide sequence comprises an IS element. The epidemiological implications arising from the origin of these plasmids are discussed.     

The octopine-type Ti plasmid pTiA6 of Agrobacterium tumefaciens contains a gene homologous to the chromosomal virulence gene acvB.

Although the majority of genes required for the transfer of T-DNA from Agrobacterium tumefaciens to plant nuclei are located on the Ti plasmid, some chromosomal genes, including the recently described acvB gene, are also required. We show that AcvB shows 50% identity with the product of an open reading frame, designated virJ, that is found between the virA and virB genes in the octopine-type Ti plasmid pTiA6. This reading frame is not found in the nopaline-type Ti plasmid pTiC58. acvB is required for tumorigenesis by a strain carrying a nopaline-type Ti plasmid, and virJ complements this nontumorigenic phenotype, indicating that the products of these genes have similar functions. A virJ-phoA fusion expressed enzymatically active alkaline phosphatase, indicating that VirJ is at least partially exported. virJ is induced in a VirA/VirG-dependent fashion by the vir gene inducer acetosyringone. Primer extension analysis and subcloning of the virJ-phoA fusion indicate that the acetosyringone-inducible promoter lies directly upstream of the virJ structural gene. Although the roles of the two homologous genes in tumorigenesis remain to be elucidated, strains lacking acvB and virJ (i) are proficient for induction of the vir regulon, (ii) are able to transfer their Ti plasmids by conjugation, and (iii) are resistant to plant wound extracts. Finally, mutations in these genes cannot be complemented extracellularly.     

The two homeodomains of the ZmHox2a gene from maize originated as an internal gene duplication and have evolved different target site specificities.

The maize ZmHox2a gene encodes two homeodomains which originated by a 699 bp duplication within an ancestral precursor. The sequences of the two ZmHox2a homeodomains are highly diverged in the N-terminal arm, while residues in the helical part have mostly been conserved. We show here that both ZmHox2a homeodomains are functional DNA-binding motifs but exhibit different target site specificities. CASTing experiments reveal a TCCT motif recognized by HD1 but a GATC tetranucleotide as the recognition sequence of HD2. Mutation of the central nucleotides in both tetranucleotide core motifs abolishes DNA binding. A domain swap experiment indicates that target site specificity is achieved in a combinatorial manner by the contributions of the diverged N-terminal arms together with the slightly different recognition helices. Computer modelling suggests that K47 and H54 in the recognition helices preferentially contact the bases at the 3'-terminus of the tetranucleotide target sequences.     

The complete mitochondrial genome sequence of Euphausia pacifica (Malacostraca: Euphausiacea) reveals a novel gene order and unusual tandem repeats

Euphausiid krill are dominant organisms in the zooplankton population and play a central role in marine ecosystems. Euphausia pacifica (Malacostraca: Euphausiacea) is one of the most important and dominant crustaceans in the North Pacific Ocean. In this paper, we described the gene content, organization, and codon usage of the E. pacifica mitochondrial genome. The mitochondrial genome of E. pacifica is 16 898 bp in length and contains a standard set of 13 protein-coding genes, 2 ribosomal RNA genes, and 22 transfer RNA genes. Translocation of three transfer RNAs (trnL(1), trnL(2), and trnW) was found in the E. pacifica mitochondrial genome when comparing with the pancrustacean ground pattern. The rate of K(a)/K(s) in 13 protein-coding genes among three krill is much less than 1, which indicates a strong purifying selection within this group. The largest noncoding region in the E. pacifica mitochondrial genome contains one section with tandem repeats (4.7 x 154 bp), which are the largest tandem repeats found in malacostracan mitochondrial genomes so far. All analyses based on nucleotide and amino acid data strongly support the monophyly of Stomatopoda, Penaeidae, Caridea, Brachyura, and Euphausiacea. The Bayesian analysis of nucleotide and amino acid datasets strongly supports the close relationship between Euphausiacea and Decapoda, which confirms traditional findings. The maximum likelihood analysis based on amino acid data strongly supports the close relationship between Euphausiacea and Penaeidae, which destroys the monophyly of Decapoda.