Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:3.1.30.2 (endonuclease)
 18,621 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The circular, 17,443 nucleotide-pair mitochondrial (mt) DNA molecule of the sea anemone, Metridium senile (class Anthozoa, phylum Cnidaria) is presented. This molecule contains genes for 13 energy pathway proteins and two ribosomal (r) RNAs but, relative to other metazoan mtDNAs, has two unique features: only two transfer RNAs (tRNA(f-Met) and tRNA(Trp)) are encoded, and the cytochrome c oxidase subunit I (COI) and NADH dehydrogenase subunit 5 (ND5) genes each include a group I intron. The COI intron encodes a putative homing endonuclease, and the ND5 intron contains the molecule's ND1 and ND3 genes. Most of the unusual characteristics of other metazoan mtDNAs are not found in M. senile mtDNA: unorthodox translation initiation codons and partial translation termination codons are absent, the use of TGA to specify tryptophan is the only genetic code modification, and both encoded tRNAs have primary and secondary structures closely resembling those of standard tRNAs. Also, with regard to size and secondary structure potential, the mt-s-rRNA and mt-1-rRNA have the least deviation from Escherichia coli 16S and 23S rRNAs of all known metazoan mt-rRNAs. These observations indicate that most of the genetic variations previously reported in metazoan mtDNAs developed after Cnidaria diverged from the common ancestral line of all other Metazoa.
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PMID:The mitochondrial genome of the sea anemone Metridium senile (Cnidaria): introns, a paucity of tRNA genes, and a near-standard genetic code. 953 27

A retrotransposon named Lian-Aa1 was discovered in an intron of an AaHR3-1 gene of the yellow fever mosquito, Aedes aegypti. This retrotransposon contained a long open reading frame with 1,219 amino acids that included endonuclease, reverse transcriptase, and RNase H domains. It was shown that in the Rock strain of Ae. aegypti, there were up to 1,380 copies of Lian elements, equivalent to 0.8% of the entire genome. Five additional copies of Lian elements were isolated, mapped by restriction digestion, and partially sequenced. The 5' and 3' ends of the Lian family were determined by comparing the terminal sequences of the six copies and were subsequently confirmed by the identification of putative target duplications flanking Lian-Aa1 and Lian-Aa2. The Lian family is likely a novel family of non-long-terminal-repeat (non-LTR) retrotransposons that terminate in a repeat of (CTGA-TAC)2. On average, the six copies of Lian elements showed only 0.6% sequence divergence at the nucleotide level in both a 735-bp region at the 5' end and a 1,124-bp coding region. Genomic Southern blots also revealed a very high degree of similarity among hundreds of Lian elements, suggesting very recent activity of Lian. Furthermore, all six analyzed Lian elements were closely associated with one or more different families of repetitive elements. It is possible that these associations could reflect the complex relationship between Lian elements and the rest of the Ae. aegypti genome. Phylogenetic analyses based on the reverse transcriptase, domains of 36 non-LTR retrotransposons including Lian-Aa1 identified five major subgroups that were supported by bootstrap replications. In contrast to the majority of non-LTR retrotransposons, Lian-Aa1 has an RNase H domain that is similar to a few other non-LTR retrotransposons and some retroviruses, which is consistent with the previously proposed independent assortment of different domains during the evolution of retroelements.
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PMID:Structural, genomic, and phylogenetic analysis of Lian, a novel family of non-LTR retrotransposons in the yellow fever mosquito, Aedes aegypti. 965 85

Long interspersed elements, or LINEs, are retrotransposons that move via an RNA intermediate. In mice, one polymorphic variant of L1 has amplified relatively recently, giving rise to the A-type subfamily in species belonging to the genus and subgenus Mus. Retrotransposition of LINE-1 (L1) requires the function of the L1-encoded reverse transcriptase that is produced from open reading frame 2 (ORF2). Here, we employ a convenient yeast genetic assay to determine the reverse transcriptase activity of the ORF2 obtained from three A-type L1 elements: one, a cDNA from the RNA in ribonucleoprotein particles; another with a purported inactivating mutation; and the third, a hypothetical ancestral construct. Because there are no examples of A-type elements that have transposed recently to inactivate a gene, this assay is the first step towards demonstrating the functional capability of mouse A-type LINE-1 elements. One of the three elements was believed to have been inactivated during evolution by the substitution of leucine for a highly conserved phenylalanine or tryptophan residue among known reverse transcriptases. This mutation did not inactivate the L1 reverse transcriptase in the yeast assay; thus, all three of the elements tested encoded reverse transcriptase activity. We further examined the minimal reverse transcriptase domain within ORF2 by creating a series of deletions. The results demonstrate that removal of the L1 endonuclease domain from the N-terminal region of ORF2 does not affect reverse transcriptase activity as determined by this assay, and that approximately half of the ORF2 coding sequence from mouse A-type L1 elements is required for functional reverse transcriptase.
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PMID:Functional reverse transcriptases encoded by A-type mouse LINE-1: defining the minimal domain by deletion analysis. 966 81

RTE-1 is a non-long-terminal-repeat (non-LTR) retrotransposable element first found in the Caenorhabditis elegans genome. It encodes a 1,024-amino-acid open reading frame (ORF) containing both apurinic-apyrimidic endonuclease and reverse-transcriptase domains. A possible first ORF of only 43 amino acids overlaps with the larger ORF and may be the site of translation initiation. Database searches and phylogenetic analysis indicate that representatives of the RTE clade of non-LTR retrotransposons are found in the bovine and sheep genomes of mammals and in the silkmoth and mosquito genomes of insects. In addition, the previously identified SINEs, Art2 and Pst, from ruminate and viper genomes are shown to be truncated RTE-like retrotransposable elements. RTE-derived SINE elements are also found in mollusc and flatworm genomes. Members of the RTE clade are characterized by unusually short 3' untranslated regions that are predominantly composed of AT-rich trimer, tetramer, and/or pentamer repeats. This study establishes RTE as a very widespread clade of non-LTR retrotransposons. RTE represents the third distinct class of non-LTR retrotransposons in the vertebrate lineage (after Line 1 elements in mammals and CR1 elements in birds and reptiles).
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PMID:The RTE class of non-LTR retrotransposons is widely distributed in animals and is the origin of many SINEs. 972 77

The reverse transcription of RNA in DNA is responsible for the generation of large families of repetitive sequences called retroposons or non-LTR retrotransposons. Recent reports established that the integration of mammalian SINE and LINE retroposons occurs at nonrandom staggered breaks, probably resulting from the action of a LINE-encoded endonuclease (Feng et al. 1996; Jurka 1997; Jurka et al. 1998). We report here that plant SINE S1 retroposons also integrate at nonrandom staggered breaks. One of the two nicks involved in S1 integration is associated mainly with the 5'-Y/AAANNNG-3' motif. The other nick at opposite DNA strand occurs preferably within 14-16 bp, a situation also observed for mammalian retroposons, but is not associated with any specific motif. Further studies on the distribution of dinucleotides surrounding the two nicking sites showed that, as for mammalian retroposons, S1 retroposons integrate at sites rich in TA, CA, and TG dinucleotides. These dinucleotides were reported as specific DNA sites where special DNA structures called "kinks" may occur under bending constraints. Nicking sites are preceded by peaks in frequency of di-pyrimidine followed by peaks of di-purine. These results suggest that the general A/T richness of a given DNA region and the presence of short runs of pyrimidines followed by short runs of purines could represent a favorable context for the integration of retroposons. In such a context, an endonuclease upon fixation could be able to generate the kink at the pyrimidine/purine transition and to nick the DNA. The similarities in target site selection observed for plant and mammalian retroposons suggest that retroposition is a surprisingly well conserved process.
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PMID:Similar target site selection occurs in integration of plant and mammalian retroposons. 976 91

This study describes the consensus sequence of a full-length (4585bp) non-LTR retrotransposon from the fugu fish, Fugu rubripes. The retrotransposon, termed Maui, is represented by a group of very similar LINE elements found as multiple copies within the fish genome. Two long open reading frames (ORFs) are predicted from the sequence. The first ORF has a domain resembling a novel zinc finger motif recently found in both a turtle and a chicken (CR1) non-LTR retrotransposon. The second ORF includes sequences homologous to the endonuclease, reverse transcriptase and carboxy-terminal domains found in other non-LTR retrotransposons. Sequence comparisons of the predicted translation products of the two ORFs indicate that Maui is most closely related to a class of non-LTR retrotransposons represented by the CR1-like elements (chicken repeat 1 elements) that are present in several avian species and have recently been described in the turtle Platemys spixii. The sequence of the 3' untranslated region also supports this relationship since Maui resembles the CR1 like elements in not having a poly-A tail.
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PMID:A LINE element from the pufferfish (fugu) Fugu rubripes which shows similarity to the CR1 family of non-LTR retrotransposons. 1002 50

During the course of work aimed at isolating a rice gene from Oryza australiensis by PCR, the oligonucleotide primers used were found to generate a fragment that showed sequence homology to the endonuclease (EN) region of the maize non-LTR retrotransposon (LINE) Cin4. We carried out further PCRs using oligonucleotide primers that hybridized to these sequences, and found that they amplified several fragments, each with homology to the EN regions, from Oryza sativa cv. Nipponbare as well as O. australiensis. We mapped the approximate locations of two rice LINE homologues by screening clones in a YAC library made from a rice (O. sativa) genome, and found that each homologue was present in a low copy number apparently at nonspecific regions on rice chromosomes. We then carried out PCR using degenerate oligonucleotide primers which hybridized to the rice LINE homologues and Cin4 to ascertain whether LINE homologues are present in a variety of members of the plant kingdom, including angiosperms, gymnosperms, bracken, horsetail and liverwort. Cloning and nucleotide sequencing revealed that 53 clones obtained from 27 out of 33 plant species contained LINE homologues. In addition to these homologues, we identified four homologues with EN regions in the Arabidopsis thaliana genome by a computer search of databases. The nucleotide sequences of almost all the LINE homologues were greatly diverged, but the derived amino acid sequences were well conserved, and all contained glutamic acid and tyrosine residues at almost the same relative positions as in the the active site regions of AP (apurinic/apyrimidinic)-endonucleases. The EN regions in the LINE homologues from closely related plant species show a closer phylogenetic relationship, indicating that sequence divergence during vertical transmission has been a major influence upon the evolution of plant LINEs.
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PMID:Non-LTR retrotransposons (LINEs) as ubiquitous components of plant genomes. 1007 Dec 12

The apurinic/apyrimidinic endonucleases (APE) contain several highly conserved sequence motifs. The glutamic acid residue in a consensus motif, LQE96TK98 in human APE (hAPE-1), is crucial because of its role in coordinating Mg2+, an essential cofactor. Random mutagenesis of the inactive E96A mutant cDNA, followed by phenotypic screening in Escherichia coli, led to isolation of an intragenic suppressor with a second site mutation, K98R. Although the Km of the suppressor mutant was about sixfold higher than that of the wild-type enzyme, their kcat values were similar for AP endonuclease activity. These results suggest that the E96A mutation affects only the DNA-binding step, but not the catalytic step of the enzyme. The 3' DNA phosphoesterase activities of the wild-type and the suppressor mutant were also comparable. No global change of the protein conformation is induced by the single or double mutations, but a local perturbation in the structural environment of tryptophan residues may be induced by the K98R mutation. The wild-type and suppressor mutant proteins have similar Mg2+ requirement for activity. These results suggest a minor perturbation in conformation of the suppressor mutant enabling an unidentified Asp or Glu residue to substitute for Glu96 in positioning Mg2+ during catalysis. The possibility that Asp70 is such a residue, based on its observed proximity to the metal-binding site in the wild-type protein, was excluded by site-specific mutation studies. It thus appears that another acidic residue coordinates with Mg2+ in the mutant protein. These results suggest a rather flexible conformation of the region surrounding the metal binding site in hAPE-1 which is not obvious from the X-ray crystallographic structure.
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PMID:Intragenic suppression of an active site mutation in the human apurinic/apyrimidinic endonuclease. 1007 6

R2 elements are non-LTR retrotransposons that insert in the 28S rRNA genes of arthropods. Partial sequence data from many species have previously suggested that these elements have been vertically inherited since the origin of this phylum. Here, we compare the complete sequences of nine R2 elements selected to represent the diversity of arthropods. All of the elements exhibited a uniform structure. Identification of their conserved sequence features, combined with our biochemical studies, allows us to make the following inferences concerning the retrotransposition mechanism of R2. While all R2 elements insert into the identical sequence of the 28S gene, it is only the location of the initial nick in the target DNA that is rigidly conserved across arthropods. Variation at the R2 5' junctions suggests that cleavage of the second strand of the target site is not conserved within or between species. The extreme 5' and 3' ends of the elements themselves are also poorly conserved, consistent with a target primed reverse transcription mechanism for attachment of the 3' end and a template switch model for the attachment of the 5' end. Comparison of the approximately 1,000-aa R2 ORF reveals that it can be divided into three domains. The central 450-aa domain can be folded by homology modeling into a tertiary structure resembling the fingers, palm, and thumb subdomains of retroviral reverse transcriptases. The carboxyl terminal end of the R2 protein appears to be the endonuclease domain, while the amino-terminal end contains zinc finger and c-myb-like DNA-binding motifs.
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PMID:The domain structure and retrotransposition mechanism of R2 elements are conserved throughout arthropods. 1033 Dec 76

A comprehensive phylogenetic analysis was conducted of non-long-terminal-repeat (non-LTR) retrotransposons based on an extended sequence alignment of their reverse transcriptase (RT) domain. The 440 amino acid positions used included a region proposed to be similar to the "thumb" of the right-handed RT structure found in retroviruses. All identified non-LTR elements could be grouped into 11 distinct clades. Using the rates of sequence change derived from studies of the vertical inheritance of R1 and R2 elements in arthropods as a comparison, we found no evidence for the horizontal transmission of non-LTR elements. Assuming vertical descent, the phylogeny suggested that non-LTR elements are as old as eukaryotes, with each of the 11 clades dating back to the Precambrian era. The analysis enabled us to propose a simple chronology for the acquisition of different enzymatic domains in the evolution of the non-LTR class of retrotransposons. The first non-LTR elements were sequence specific by virtue of a restriction-enzyme-like endonuclease located downstream of the RT domain. Evolving from this original group were elements (eight clades) that acquired an apurinic-apyrimidic endonuclease-like domain upstream of the RT domain. Finally, four of these clades have inherited an RNase H domain downstream of the RT domain. The phylogenies of the AP endonuclease and RNase H domains were also determined for this report and are consistent with the monophyletic acquisition of these domains. These studies represent the most comprehensive effort to date to trace the evolution of a major class of transposable elements.
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PMID:The age and evolution of non-LTR retrotransposable elements. 1036 57


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