Mosquito mitochondrial transfer RNAs for valine, glycine and glutamate: RNA and gene sequences and vicinal genome organization

Animal mitochondrial genomes

Animal mitochondrial DNA is a small, extrachromosomal genome, typically approximately 16 kb in size. With few exceptions, all animal mitochondrial genomes contain the same 37 genes: two for rRNAs, 13 for proteins and 22 for tRNAs. The products of these genes, along with RNAs and proteins imported from the cytoplasm, endow mitochondria with their own systems for DNA replication, transcription, mRNA processing and translation of proteins. The study of these genomes as they function in mitochondrial systems-'mitochondrial genomics'-serves as a model for genome evolution. Furthermore, the comparison of animal mitochondrial gene arrangements has become a very powerful means for inferring ancient evolutionary relationships, since rearrangements appear to be unique, generally rare events that are unlikely to arise independently in separate evolutionary lineages. Complete mitochondrial gene arrangements have been published for 58 chordate species and 29 non-chordate species, and partial arrangements for hundreds of other taxa. This review compares and summarizes these gene arrangements and points out some of the questions that may be addressed by comparing mitochondrial systems.

Mitochondrial DNA polymorphism in a black fly, Simulium vittatum (Diptera: Simuliidae)

Mitochondrial DNA (mtDNA) was extracted from pooled field-collected samples representing six species of black flies (Cnephia dacotensis, Simulium bivittaum, S. johansenni, S. luggeri, S. piperi, S. vittatum) and compared by restriction fragment length polymorphism (RFLP) analysis. Morphospecies were molecularly distinct, with few shared restriction fragments. Eleven populations of S. vittatum were found that appeared to be homogeneous for a single mitochondrial haplotype. Ten other populations of S. vittatum showed extensive mitochondrial heterogeneity. In part, these samples contained mixtures of two cytologically recognized siblings: IIIL-1 and IS-7. About 70% of the mitochondrial genome of a population pure for sibling IIIL-1 was cloned as five HindIII fragments, which were used as hybridization probes to examine individual black flies. Thirteen mtDNA haplotypes involving permutations of 10 HindIII restriction sites were identified in individual black flies examined from 26 populations. DNA from 168 larvae cut with both EcoR1 and HindIII revealed five additional haplotypes. One HindIII haplotype was present in 84% of 390 larvae examined and predominated in every population examined from New York to California and in both the IIIL-1 and IS-7 siblings. Nebraska populations had individuals with nearly all known haplotypes. The most common haplotype was usually the only form present in warm, silty streams with organic enrichment. Rarer haplotypes were found in cool, spring-fed streams but without clear geographic or phylogenetic components.

Fitting the structurally diverse animal mitochondrial tRNAs(Ser) to common three-dimensional constraints

We propose three-dimensional models for animal mitochondrial (amt) tRNAs lacking the D-domain based on consideration of universal constraints on tRNA to maintain functionality. The available tRNA sequences are classified into two groups, and distinct models are proposed for both classes derived from common structural features. The distance between the anticodon and the acceptor stem is comparable in the models and corresponds to that observed in conventional tRNAs. This fact averts the problem of how a shorter mitochondrial tRNA could function within the context of a protein synthesis machinery suited to full-sized tRNAs. In the models, the angle which defines the relationship between the helical domains composed of the acceptor/T-stem and the anticodon/D-stem is greater than in conventional tRNAs. These structures resemble more a "boomerang" than an "L". However, even in the boomerang model, the inner surface of tRNA would be sufficiently uncluttered to avoid steric clashes when two tRNA molecules cohabit the ribosome.

Molecular organization and evolution of mosquito genomes

Given the importance of mosquitoes as disease vectors, relatively little is known about the molecular organization and evolution of mosquito genomes as compared to other insects such as fruit flies. The advances in recombinant DNA technology and the possibility that mosquito populations could be controlled and genetically manipulated using such technology has stimulated considerable research during the last few years in the areas of genome organization and evolution, genome mapping, endogenous transposable elements, and mapping and characterization of genes conferring susceptibility to different parasites and pathogens. This review summarizes research currently underway in our laboratory and elsewhere in these areas.

A tRNA(Ser)(UCN) gene in Artemia salina mitochondrial DNA: a case of mistaken identity

We have sequenced a segment of mitochondrial DNA (mtDNA) of a crustacean, the brine shrimp, Artemia salina, that includes 3' end-proximal regions of the genes for subunit 1 of the NADH dehydrogenase complex (ND1) and cytochrome b (Cyt b). From our data we conclude that in this mtDNA, as in the mtDNAs of Drosophila species, a tRNA(Ser)(UCN) gene separates the ND1 and Cyt b genes. This is contrary to an earlier report that the A. salina ND1 and Cyt b genes are immediately adjacent to each other.

Mediterranean fruit fly, Ceratitis capitata (Wiedemann), mitochondrial DNA: genes and secondary structures for six t-RNAs

The polymerase chain reaction was used to amplify six mitochondrial t-RNAs for Ala, Arg, Asn, Ser, Glu and Phe between genes for mitochondrial NADH dehydrogenases 3 and 5. With respect to Drosophila yakuba the gene order and direction of transcription is completely conserved. Analysis of secondary structure shows complete conservation of the anticodon loops but a number of differences in the dihydrouridine and T psi C loops with respect to Drosophila. However, differences are such that tertiary interactions that stabilize stacking are preserved. The use of the reported sequence in combination with PCR to explore population variability is discussed.

The mitochondrial genome of the mosquito Anopheles gambiae: DNA sequence, genome organization, and comparisons with mitochondrial sequences of other insects

The entire 15,363 bp mitochondrial genome was cloned and sequenced from the mosquito Anopheles gambiae. With respect to the protein-coding genes, rRNA genes and the control region, the gene order was identical to that reported for other insects. There were significant differences, however, in the position and orientation of specific tRNA loci. The overall nucleotide composition was heavily biased towards adenine and thymine, which accounted for 77.6% of all nucleotides. Comparisons were made with the mitochondrial genomes of other insects on the basis genome size and organization, DNA and putative amino acid sequence data, nucleotide substitutions, codon usage and bias, and patterns of AT enrichment.

Parallel origins of duplications and the formation of pseudogenes in mitochondrial DNA from parthenogenetic lizards (Heteronotia binoei; Gekkonidae)

Analysis of mitochondrial DNAs (mtDNAs) from parthenogenetic lizards of the Heteronotia binoei complex with restriction enzymes revealed an approximately 5-kb addition present in all 77 individuals. Cleavage site mapping suggested the presence of a direct tandem duplication spanning the 16S and 12S rRNA genes, the control region and most, if not all, of the gene for the subunit 1 of NADH dehydrogenase (ND1). The location of the duplication was confirmed by Southern hybridization. A restriction enzyme survey provided evidence for modifications to each copy of the duplicated sequence, including four large deletions. Each gene affected by a deletion was complemented by an intact version in the other copy of the sequence, although for one gene the functional copy was heteroplasmic for another deletion. Sequencing of a fragment from one copy of the duplication which encompassed the tRNA(leu)(UUR) and parts of the 16S rRNA and ND1 genes, revealed mutations expected to disrupt function. Thus, evolution subsequent to the duplication event has resulted in mitochondrial pseudogenes. The presence of duplications in all of these parthenogens, but not among representatives of their maternal sexual ancestors, suggests that the duplications arose in the parthenogenetic form. This provides the second instance in H. binoei of mtDNA duplication associated with the transition from sexual to parthenogenetic reproduction. The increased incidence of duplications in parthenogenetic lizards may be caused by errors in mtDNA replication due to either polyploidy or hybridity of their nuclear genomes.

Mitochondrial DNA of the blowfly Phormia regina: restriction analysis and gene localization

A study of an invertebrate mitochondrial genome, that of the blowfly Phormia regina, has been initiated to compare its structural and functional relatedness to other metazoan mitochondrial genomes. A restriction map of mitochondrial DNA (mtDNA) isolated from sucrose gradient-purified mitochondria has been established using a combination of single and double restriction endonuclease digestions and hybridizations with isolated mtDNA fragments, revealing a genome size of 17.5 kilobases (kb). A number of mitochondrial genes including those encoding the 12 S and 16 S ribosomal RNA, the cytochrome c oxidase I subunit (COI) and an unidentified open reading frame (URF2) have been located on the Phormia mtDNA by Southern blot analysis using as probes both isolated mtDNA fragments and oligonucleotides derived from the sequences of previously characterized genes from rat and Drosophila yakuba mtDNAs. These data indicate that for those regions examined, the mitochondrial genome organization of blowfly mtDNA is the same as that of Drosophila yakuba, the order being COI-URF2-12 S-16 S. These data also report the presence of an A + T-rich region, located as a 2.5-kb region between the URF2 and the 12 S rRNA genes, and its amplification by the polymerase chain reaction is described.

Different mitochondrial gene orders among insects: exchanged tRNA gene positions in the COII/COIII region between an orthopteran and a dipteran species

We have cloned and sequenced a 2.65 kb segment of the mtDNA molecule of the orthopteran insect Locusta migratoria. It harbors the genes for four mitochondrial tRNAs, for cytochrome c oxidase subunits II and III and for ATPase subunits 6 and 8. The order of the locust genes resembles that of Drosophila yakuba: in both insects the genes for COII and ATPase 8 are separated from each other by the genes encoding tRNA(lys) and tRNA(asp), but in the locust, the positions of the two tRNA genes are reversed. This leads to a different mitochondrial gene order in the two insects.