Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: 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)

All autonomous non-long terminal repeat (non-LTR) retrotransposons reported to date in vertebrates encode an apurinic/apyrimidinic endonuclease-like enzyme necessary for target sequence cleavage and subsequent target-primed reverse transcription. We describe here vertebrate non-LTR retrotransposons encoding another type of endonuclease more related to type IIS restriction enzymes. Such retrotransposons have been detected until now only in trypanosomes, nematodes, and arthropods. The retrotransposon Rex6 was identified in the genome of several teleost fish including Xiphophorus maculatus (platyfish), Oryzias latipes (medakafish), Oreochromis niloticus (Nile tilapia), and Fugu rubripes (Japanese pufferfish). Rex6 encodes a reverse transcriptase and a putative restriction enzyme-like endonuclease and is a member of the R4 family of non-LTR retrotransposons containing the Dong and R4 elements found in nematodes and insects. Rex6 was active in many species during teleost evolution and underwent several bursts of retrotransposition (some of them being relatively recent) leading to a high copy number of Rex6 in the genome of numerous fish. Extremely truncated Rex6-related sequences were detected by database screening in reptiles, including the snake Trimeresus flavoviridis and the lizard Anolis carolinensis, but not in sequences from the human genome project, suggesting that this element might have been lost from certain vertebrate lineages.
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PMID:Non-LTR retrotransposons encoding a restriction enzyme-like endonuclease in vertebrates. 1134 31

BCNT (a protein named after Bucentaur or craniofacial development protein 1) has a unique structure in Ruminantia. Bovine BCNT contains a region of the endonuclease domain derived from a truncated RTE-1 (previously called Bov-B LINE), a non-LTR retrotransposable repetitive element, and two repeat units (intramolecular repeat, IR) each with 40 amino acids in the C-terminal region. In contrast the human and mouse BCNT proteins contain one repeat unit and lack the RTE-1-derived portion. The 3' UTR of bovine bcnt cDNA also contains an approximately 300-bp portion homologous to the 3'-part of RTE-1. We examined the bovine bcnt genomic DNA sequence to understand how the bovine bcnt gene has been organized. The sequence of 3' UTR homologous portion was found to more closely resemble the Art2 element than the bovine RTE-1. By PCR screening a bovine/hamster hybrid somatic cell panel, the bovine bcnt gene was mapped to chromosome 18, syntenic human chromosome 16q on which human BCNT is located. The bcnt genomic DNA sequence corresponding to the cDNA downstream of a RTE-1 derived portion reveals that each IR unit is flanked by both 5'-side and 3'-side introns and that 3'-UTR consists of one exon. The alignment of the above sequence with a bovine RTE-1 did not show any significant homology downstream of the endonuclease domain. On the other hand, the alignment of the intron sequences with each other revealed that the six sequential homologous segments ranging in size from 40 to 453 bp existed over a 1 kb long sequence between both the 5'- and 3'-side introns flanking each bovine IR unit. In addition, both the 174-bp of 5'-side intron and 80-bp of 3'-side intron neighboring each 120-bp IR exon are significantly homologous among the two bovine IRs, human IR and mouse IR. These results suggest that a truncated bovine RTE-1 was inserted into the intron upstream of an IR unit of an ancestor bcnt gene and that a duplication of a relatively long region that includes IR occurred in the bovine genome.
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PMID:Gene organization of bovine BCNT that contains a portion corresponding to an endonuclease domain derived from an RTE-1 (Bov-B LINE), non-LTR retrotransposable element: duplication of an intramolecular repeat unit downstream of the truncated RTE-1. 1136 1

The Penelope element is the key element responsible for mobilization of other transposable elements in the course of hybrid dysgenesis in Drosophila virilis. Penelope has an unusually complex, highly variable organization in all studied species of the virlis group. Thc BRIDGE1 element from the fish Fugu rubripes is homologous to Penelope, and database searches detected additional homologous sequences among Expressed Sequence Tags from the flatworm Schistosoma mansonii and the nematode Ancylostoma caninum. Phylogenetic analysis shows that the reverse transcriptase of the Penelope group does not belong to any of the characterized major retroelement lineages, but apparently represents a novel branch of non-LTR retroelements. Sequence profile analysis results in the prediction that the C-terminal domain of the Penelope polyprotein is an active endonuclease related to intron-encoded endonucleases and the bacterial repair endonuclease UvrC, which could function as an integrase. No retroelements containing a predicted endonuclease of this family have been described previously. Phylogenetic analysis of Penelope copies isolated from several species of the virilis group reveals two subfamilies of Penelope elements, one of which includes full-length copies whose nucleotide sequences are almost identical, whereas the other one consists of highly diverged defective copies. Phylogenetic analysis of Penelope suggests both vertical transmission of the element and probable horizontal transfers. These findings support the notion that Penelope invasions occurred repeatedly in the evolution of the virilis group.
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PMID:The structure and evolution of Penelope in the virilis species group of Drosophila: an ancient lineage of retroelements. 1144 48

The mobile element Penelope is activated and mobilizes several other transposons in dysgenic crosses in Drosophila virilis. Its structure proved to be complex and to vary greatly in all examined species of the virilis group. Phylogenetic analysis of the reverse transcriptase (RT) domain assigned Penelope to a new branch, rather than to any known family, of LTR-lacking retroelements. Amino acid sequence analysis showed that the C-terminal domain of the Penelope polyprotein is an active endonuclease, which is related to intron-encoded endonucleases and to bacterial repair endonuclease UrvC, and may act as an integras. Retroelements coding for a putative endonuclease that differs from typical integrase have thus far not been known. The N-terminal domain of the Penelope polyprotein was shown to contain a protease with significant homology to HIV-1 protease. Phylogenetic analysis divided the Penelope copies from several virilis species into two subfamilies, one including virtually identical full-length copies, and the other comprising highly divergent defective copies. The results suggest both vertical and horizontal transfer of the element. Possibly, Penelope invasion recurred during evolution and contributed to genome rearrangement in the virilis species. Chromosome aberrations detected in D. virilis, which is now being invaded by Penelope, is direct evidence for this assumption.
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PMID:[Structure and evolutionary role of the Penelope mobile element in Drosophila species of the virilis group]. 1160 33

In the genome of the South African frog, Xenopus laevis, there are two complex families of transposable elements, Tx1 and Tx2, that have identical overall structures, but distinct sequences. In each family there are approximately 1500 copies of an apparent DNA-based element (Tx1D and Tx2D). Roughly 10% of these elements in each family are interrupted by a non-LTR retrotransposon (Tx1L and Tx2L). Each retrotransposon is flanked by a 23-bp target duplication of a specific D element sequence. In earlier work, we showed that the endonuclease domain (Tx1L EN) located in the second open reading frame (ORF2) of Tx1L encodes a protein that makes a single-strand cut precisely at the expected site within its target sequence, supporting the idea that Tx1L is a site-specific retrotransposon. In this study, we express the endonuclease domain of Tx2L (Tx2L EN) and compare the target preferences of the two enzymes. Each endonuclease shows some preference for its cognate target, on the order of 5-fold over the non-cognate target. The observed discrimination is not sufficient, however, to explain the observation that no cross-occupancy is observed - that is, L elements of one family have never been found within D elements of the other family. Possible sources of additional specificity are discussed. We also compare two hypotheses regarding the genome duplication event that led to the contemporary pseudotetraploid character of Xenopus laevis in light of the Tx1L and Tx2L data.
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PMID:Comparative studies of the endonucleases from two related Xenopus laevis retrotransposons, Tx1L and Tx2L: target site specificity and evolutionary implications. 1176 45

R2 is a non-long terminal repeat (non-LTR) retrotransposon that inserts into the 28 S rRNA genes of arthropods. The element encodes two enzymatic activities: an endonuclease that specifically cleaves the 28 S gene target site, and a reverse transcriptase (RT) that can use the 3' end of the cleaved DNA to prime reverse transcription. R2 RT only utilizes RNA templates that contain the 3' untranslated region of the R2 element as templates in this target primed reverse transcription (TPRT) reaction. Here, detailed biochemical characterization of the R2 RT indicates that the enzyme is capable of making multiple, consecutive jumps between RNA templates. The terminal 3' nucleotide of the "acceptor" RNA and the 5' nucleotide of the "donor" RNA are frequently reverse transcribed in these jumps, indicating that the acceptor RNA does not anneal to the cDNA derived from the donor RNA template. These template jumps occur during TPRT as well as in non-specific extension reactions in which reverse transcription is primed by an oligonucleotide annealed to the RNA template. Analysis of these RT assays done in the absence of the target DNA also revealed that the R2 RT can initiate reverse transcription near the 3' end of any RNA molecule using the 3' end of a second RNA molecule as primer. Again there is no requirement for sequence complementarity between the RNA used as template and the RNA used as primer. These properties of the R2 RT differ substantially from those of retroviral RTs but have similarities to the RT of the Mauriceville retroplasmid of Neurospora crassa. We present a model which relates these unusual properties of the R2 RT to structural differences from retroviral RTs as well as correlates these properties to the likely retrotransposition mechanism of R2 and other non-LTR retrotransposons.
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PMID:The reverse transcriptase of the R2 non-LTR retrotransposon: continuous synthesis of cDNA on non-continuous RNA templates. 1186 11

Mobile elements that use reverse transcriptase to make new copies of themselves are found in all major lineages of eukaryotes. The non-long terminal repeat (non-LTR) retrotransposons have been suggested to be the oldest of these eukaryotic elements. Phylogenetic analysis of non-LTR elements suggests that they have predominantly undergone vertical transmission, as opposed to the frequent horizontal transmissions found for other mobile elements. One prediction of this vertical model of inheritance is that the oldest lineages of eukaryotes should exclusively harbor the oldest lineages of non-LTR retrotransposons. Here we characterize the non-LTR retrotransposons present in one of the most primitive eukaryotes, the diplomonad Giardia lamblia. Two families of elements were detected in the WB isolate of G. lamblia currently being used for the genome sequencing project. These elements are clearly distinct from all other previously described non-LTR lineages. Phylogenetic analysis indicates that these Genie elements (for Giardia early non-LTR insertion element) are among the oldest known lineages of non-LTR elements consistent with strict vertical descent. Genie elements encode a single open reading frame with a carboxyl terminal endonuclease domain. Genie 1 is site specific, as seven to eight copies are present in a single tandem array of a 771-bp repeat near the telomere of one chromosome. The function of this repeat is not known. One additional, highly divergent, element within the Genie 1 lineage is not located in this tandem array but is near a second telomere. Four different telomere addition sites could be identified within or near the Genie elements on each of these chromosomes. The second lineage of non-LTR elements, Genie 2, is composed of about 10 degenerate copies. Genie 2 elements do not appear to be site specific in their insertion. An unusual aspect of Genie 2 is that all copies contain inverted repeats up to 172 bp in length.
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PMID:Ancient lineages of non-LTR retrotransposons in the primitive eukaryote, Giardia lamblia. 1196 Oct 96

During the course of a random sequencing project of the genome of the dimorphic yeast Yarrowia lipolytica, we have identified sequences that were repeated in the genome and that matched the reverse transcriptase (RT) sequence of non-long terminal repeat (non-LTR) retrotransposons. Extension of sequencing on each side of this zone of homology allowed the definition of an element over 6 kb long. The conceptual translation of this sequence revealed two open reading frames (ORFs) that displayed several characteristics of non-LTR retrotransposons: a Cys-rich motif in the ORF1, an N-terminal endonuclease, a central RT, and a C-terminal zinc finger domain in the ORF2. We called this element Ylli (for Y. lipolytica LINE). A total of 19 distinct repeats carrying the 3' untranslated region (UTR) and all ending with a poly-A tail were detected. Most of them were very short, 17 being 134 bp long or less. The number of copies of Ylli was estimated to be around 100 if these short repeats are 5' truncations. No 5' UTR was clearly identified, indicating that entire and therefore active elements might be very rare in the Y. lipolytica strain tested. Ylli does not seem to have any insertion specificity. Phylogenetic analysis of the RT domain unambiguously placed Ylli within the L1 clade. It forms a monophyletic group with the Zorro non-LTR retrotransposons discovered in another dimorphic yeast Candida albicans. BLAST comparisons showed that ORF2 of Ylli is closely related to that of the slime mold Dictyostelium discoideum L1 family, TRE.
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PMID:Ylli, a non-LTR retrotransposon L1 family in the dimorphic yeast Yarrowia lipolytica. 1196 Nov

Nano-electrospray ionization time-of-flight mass spectrometry (ESI-MS) was used to study the conformational consequences of metal ion binding to the colicin E9 endonuclease (E9 DNase) by taking advantage of the unique capability of ESI-MS to allow simultaneous assessment of conformational heterogeneity and metal ion binding. Alterations of charge state distributions on metal ion binding/release were correlated with spectral changes observed in far- and near-UV circular dichroism (CD) and intrinsic tryptophan fluorescence. In addition, hydrogen/deuterium (H/D) exchange experiments were used to probe structural integrity. The present study shows that ESI-MS is sensitive to changes of the thermodynamic stability of E9 DNase as a result of metal ion binding/release in a manner consistent with that deduced from proteolysis and calorimetric experiments. Interestingly, acid-induced release of the metal ion from the E9 DNase causes dramatic conformational instability associated with a loss of fixed tertiary structure, but secondary structure is retained. Furthermore, ESI-MS enabled the direct observation of the noncovalent protein complex of E9 DNase bound to its cognate immunity protein Im9 in the presence and absence of Zn(2+). Gas-phase dissociation experiments of the deuterium-labeled binary and ternary complexes revealed that metal ion binding, not Im9, results in a dramatic exchange protection of E9 DNase in the complex. In addition, our metal ion binding studies and gas-phase dissociation experiments of the ternary E9 DNase-Zn(2+)-Im9 complex have provided further evidence that electrostatic interactions govern the gas phase ion stability.
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PMID:Probing metal ion binding and conformational properties of the colicin E9 endonuclease by electrospray ionization time-of-flight mass spectrometry. 1207 Mar 27

We report the first stopped-flow fluorescence analysis of transition metal binding (Co(2+), Ni(2+), Cu(2+), and Zn(2+)) to the H-N-H endonuclease motif within colicin E9 (the E9 DNase). The H-N-H consensus forms the active site core of a number of endonuclease groups but is also structurally homologous to the so-called treble-clef motif, a ubiquitous zinc-binding motif found in a wide variety of metalloproteins. We find that all the transition metal ions tested bind via multistep mechanisms. Binding was further dissected for Ni(2+) and Zn(2+) ions through the use of E9 DNase single tryptophan mutants, which demonstrated that most steps reflect conformational rearrangements that occur after the bimolecular collision, many common to the two metals, while one appears specific to zinc. The kinetically derived equilibrium dissociation constants (K(d)) for transition metal binding to the E9 DNase agree with previously determined equilibrium measurements and so confirm the validity of the derived kinetic mechanisms. Zn(2+) binds tightest to the enzyme (K(d) approximately 10(-)(9) M) but does not support endonuclease activity, whereas the other metals (K(d) approximately 10(-)(6) M) are active in endonuclease assays implying that the additional step seen for Zn(2+) traps the enzyme in an inactive but high affinity state. Metal-induced conformational changes are likely to be a conserved feature of H-N-H/treble clef motif proteins since similar Zn(2+)-induced, multistep binding was observed for other colicin DNases. Moreover, they appear to be independent both of the conformational heterogeneity that is naturally present within the E9 DNase at equilibrium, as well as the conformational changes that accompany the binding of its cognate inhibitor protein Im9.
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PMID:Multistep binding of transition metals to the H-N-H endonuclease toxin colicin E9. 1216 38


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