Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts:   Target Concepts:
Query: UNIPROT:P06889 (Mol)
 630,302 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The site-specific recombinases Flp and R from Saccharomyces cerevisiae and Zygosaccharomyces rouxii, respectively, are related proteins that belong to the yeast family of site-specific recombinases. They share approximately 30% amino acid matches and exhibit a common reaction mechanism that appears to be conserved within the larger integrase family of site-specific recombinases. Two regions of the proteins, designated box I and box II, also harbor a significantly high degree of homology at the nucleotide sequence level. We have analyzed the properties of Flp and R variants carrying point mutations within the box I segment in substrate-binding, DNA cleavage, and full-site and half-site strand transfer reactions. All mutations abolish or seriously diminish recombinase function either at the substrate-binding step or at the catalytic steps of strand cleavage or strand transfer. Of particular interest are mutations of Arg-191 of Flp and R, residues which correspond to one of the two invariant arginine residues of the integrase family. These variant proteins bind substrate with affinities comparable to those of the corresponding wild-type recombinases. Among the binding-competent variants, only Flp(R191K) is capable of efficient substrate cleavage in a full recombination target. However, this protein does not cleave a half recombination site and fails to complete strand exchange in a full site. Strikingly, the Arg-191 mutants of Flp and R can be rescued in half-site strand transfer reactions by a second point mutant of the corresponding recombinase that lacks its active-site tyrosine (Tyr-343). Similarly, Flp and R variants of Cys-189 and Flp variants at Asp-194 and Asp-199 can also be complemented by the corresponding Tyr-343-to-phenylalanine recombinase mutant.
Mol Cell Biol 1992 Sep
PMID:Functional analysis of box I mutations in yeast site-specific recombinases Flp and R: pairwise complementation with recombinase variants lacking the active-site tyrosine. 150 81

The FLP recombinase from the 2 microns plasmid of Saccharomyces cerevisiae contains a region from amino acid 185 to 203 that is conserved among several FLP-like proteins from different yeasts. Using site-directed mutagenesis, we have made mutations in this region of the FLP gene. Five of twelve mutations in the region yielded proteins that were unable to bind to the FLP recombination target (FRT) site. A change of arginine at position 191 to lysine resulted in a protein (FLP-R191K) that could bind to the FRT site but could not catalyze recombination. This mutant protein accumulated as a stable protein-DNA complex in which one of the two bound FLP proteins was covalently attached to the DNA. FLP-R191K was defective in strand exchange and ligation and was unable to promote protein-protein interaction with half-FRT sites. The conservation of three residues in all members of the integrase family of site-specific recombinases (His305, Arg308, Tyr343 in FLP) implies a common mechanism of recombination. The conservation of arginine 191 and the properties of the FLP-R191K mutant protein suggest that this arginine also plays an important role in the mechanism of FLP-mediated site-specific recombination.
J Mol Biol 1992 May 20
PMID:Mutagenesis of a conserved region of the gene encoding the FLP recombinase of Saccharomyces cerevisiae. A role for arginine 191 in binding and ligation. 159 23

The proteins expressed by insertion sequence IS911, a member of the widespread IS3 family of elements, have been analyzed. The results indicate that three major species are produced from two consecutive reading frames. A protein of Mr 11,500, ORFA, is synthesized from an upstream reading frame. A larger protein, ORFAB, uses the same initiation codon and is produced by a -1 programmed translational frameshift between orfA and a downstream frame, orfB, whose amino acid sequence shows significant homology with retroviral integrase proteins. The orfB frame is also expressed independently in two alternative forms: the first uses a rare AUU initiation codon in the orfB phase whereas the second appears to initiate in the orfA phase and is produced by a -1 frameshift mechanism similar to that used in ORFAB expression. A specific IS911 integration reaction using a minimal active junction composed of 51 base-pairs of the right inverted repeat and a flanking phase lambda sequence resembling a second end in inverted orientation has been developed to analyze the functions of these proteins by transcomplementation in vivo. The orfA and orfB frames are shown to be essential and production of ORFAB is shown to stimulate integration in this system, suggesting that this fusion protein is the IS911 transposase.
J Mol Biol 1991 Dec 05
PMID:Programmed translational frameshifting and initiation at an AUU codon in gene expression of bacterial insertion sequence IS911. 166 Sep 23

From examination of published DNA sequences of genes found inserted at a specific site in integrons, all genes are shown to be associated, at their 3' ends, with a short imperfect inverted repeat sequence, a 59-base element or relative of this element. The similarity of the arrangement of gene inserts in the integron and in the Tn7 transposon family is described. A refined consensus for the 59-base element is reported. Members of this family are highly diverged and the relationship of a group of longer elements to the 59-base elements is demonstrated. The ability of 59-base elements of different length and sequence to act as sites for recombination catalysed by the integron-encoded DNA integrase is demonstrated, confirming that elements of this family have a common function. The ability of elements located between gene pairs to act as recombination sites has also been demonstrated. The recombination cross-over point has been localized to the GTT triplet which is conserved in the core sites, GTTRRRY, found at the 3' end of 59-base elements. Recombination at the core site found in inverse orientation at the 5' end of the 59-base elements was not detected, and the sequences responsible for orientation of the recombination event appear to reside within the 59-base element. A model for site-specific insertion of genes into integrons and Tn7-like transposons is proposed. Circular units consisting of a gene associated with a 59-base element are inserted into an ancestral element which contains neither a gene nor a 59-base element.(ABSTRACT TRUNCATED AT 250 WORDS)
Mol Microbiol 1991 Aug
PMID:Site-specific insertion of genes into integrons: role of the 59-base element and determination of the recombination cross-over point. 166 53

The retroid family consists of all genetic elements that encode a potential reverse transcriptase (RT). Members of this family include a diversity of eukaryotic genetic elements (viruses, transposable elements, organelle introns, and plasmids) and the retrons of prokaryotes. Some retroid elements have, in addition to the RT gene, other genes in common with the retroviruses. On the basis of RT sequence similarity, the retroposon group is defined as the eukaryotic long interspersed nuclear elements, the transposable elements of (1) Drosophila melanogaster (I and F factors), (2) Trypanosoma brucei (ingi element), (3) Zea mays (Cin4), (4) Bombyx mori (R2Bm), and members of the group II introns and plasmids of yeast mitochondria. The data presented here elucidate the extent of the relationships between the retroposons and other retroid-family members. Protein-sequence alignment data demonstrate that subsets of the retroposons contain different assortments of retroviral-like genes. Sequence similarities can be detected between the capsid, protease, ribonuclease H, and integrase proteins of retroviruses and several retroposon sequences. The relationships among the retroposon capsid-like sequences are congruent with the RT sequence phylogeny. In contrast, the similarity between ribonuclease H sequences varies in different subbranches of the retroposon lineage. These data suggest that xenologous recombination (i.e., the replacement of a homologous resident gene by a homologous foreign gene) and/or independent gene assortment have played a role in the evolution of the retroposons.
Mol Biol Evol 1991 Nov
PMID:Evolution of retroposons by acquisition or deletion of retrovirus-like genes. 166 70

In matings between Lactococcus lactis strains, the conjugative transposons Tn916 and Tn919 are found in the chromosome of the transconjugants in the same place as in the chromosome of the donor, indicating that no transposition has occurred. In agreement with this, the frequency of L. lactis transconjugants from intraspecies matings is the same whether the donor contains the wild-type form of the transposon or the mutant Tn916-int1, which has an insertion in the transposon's integrase gene. However, in intergeneric crosses with Bacillus subtilis or Enterococcus faecalis donors, Tn916 and Tn919 transpose to different locations on the chromosome of the L. lactis transconjugants. Moreover, Tn916 and Tn919 could not be transferred by conjugation from L. lactis and B. subtilis, E. faecalis or Streptococcus pyogenes. This suggests that excision of these elements does not occur in L. lactis. When cloned into E. coli with adjacent chromosomal DNA from L. lactis, the conjugative transposons were able to excise, transpose and promote conjugation. Therefore, the inability of these elements to excise in L. lactis is not caused by a permanent structural alteration in the transposon. We conclude that L. lactis lacks a factor required for excision of conjugative transposons.
Mol Microbiol 1991 Dec
PMID:A host factor absent from Lactococcus lactis subspecies lactis MG1363 is required for conjugative transposition. 166 20

Approximately 50% of the ribosomal DNA (rDNA) units of Drosophila melanogaster are inactivated by two different 28 S RNA ribosomal gene insertions (type I and type II). We present here the nucleotide sequence of complete type I and type II elements. Conceptual translation of these sequences revealed open reading frames (ORFs) encoding amino acid residues conserved in all retrotransposable elements. Full-length type I elements are 5.35 x 10(3) base-pairs in length and contain two overlapping ORFs. The smaller ORF (471 amino acid residues) has similarity to gag genes, while the larger ORF (1021 residues) has similarity to pol genes. Full-length type II elements are 3.6 x 10(3) base-pairs and contain one large ORF (1056 residues) that appears to represent a gag-pol fusion. Type I and type II elements are similar in structure, in the proteins they encode, and in insertion specificity to the R1Bm and R2Bm retrotransposable elements of Bombyx mori. We suggest that the D. melanogaster elements be called R1Dm and R2Dm, to reflect their structure as retrotransposons. Comparison of the R1 and R2 elements from these two widely different species revealed regions of the ORF that are likely to play an important role in the propagation of the elements. Four distinct regions of sequence conservation separated by regions of little or no sequence similarity were detected for both the R1 and R2 elements: (1) cysteine motifs of the gag gene, with three such motifs for R1 and one motif for R2; (2) a reverse transcriptase domain; (3) an integrase domain located carboxyl terminal to the reverse transcriptase region; and (4) a small region amino terminal to the reverse transcriptase domain, whose function is not known. The level of identity of the amino acid residues for these segments is 28 to 34% between the R1 elements, and 34 to 39% for the R2 elements. Finally, it may be predicted that the mechanism of unequal crossover might eventually eliminate R1 and R2 from the rDNA locus. The long history of selection at the protein level exhibited by these elements indicates that it is their active transposition that maintains them in the locus. The high level of sequence homogeneity between copies of each element within the same species is consistent with the high turnover rate expected to result from these processes.
J Mol Biol 1990 Mar 05
PMID:Type I (R1) and type II (R2) ribosomal DNA insertions of Drosophila melanogaster are retrotransposable elements closely related to those of Bombyx mori. 169 Aug 12

A single copy of the retrotransposon TED, from the moth Trichoplusia ni (a lepidopteran noctuid), was identified within the DNA genome of the baculovirus Autographa californica nuclear polyhedrosis virus. Determination of the complete nucleotide sequence (7,510 base pairs) of the integrated copy indicated that TED belongs to the family of retrotransposons that includes Drosophila melanogaster elements 17.6 and gypsy and thus represents the first nondipteran member of this invertebrate group to be identified. The internal portion of TED, flanked by long terminal repeats (LTRs), is composed of three long open reading frames comparable in size and location to the gag, pol, and env genes of the vertebrate retroviruses. Sequence similarity with the dipteran elements was the highest within individual domains of TED open reading frame 2 (pol region) that are also conserved among the retroviruses and encode protease, reverse transcriptase, and integrase functions, respectively. Mapping the 5' and 3' termini of TED RNAs indicated that the LTRs have a retroviral U3-R-U5 structural organization that is capable of directing the synthesis of transcripts that represent potential substrates for reverse transcription and intermediates in transposition. Abundant RNAs were also initiated from a site within the 5' LTR that matches the consensus motif for the promoter of late, hyperexpressed baculovirus genes. The presence of this viruslike promoter within TED and its subsequent activation only after integration within the viral genome suggest a possible symbiotic relationship with the baculovirus that could extend transposon host range.
Mol Cell Biol 1990 Jun
PMID:Gene organization and transcription of TED, a lepidopteran retrotransposon integrated within the baculovirus genome. 169 64

The gene coding for starch phosphorylase (EC 2.4.1.1) was isolated from a potato genomic library constructed in lambda EMBL3. It is an unusually long plant gene (16.4 kb) which encodes a preprotein of 966 amino acids. The phosphorylase coding sequence is interrupted by 14 introns whose positions do not match those of the introns in the human glycogen phosphorylase gene. A 78 amino acid central peptide unique to plant plastidial phosphorylases is hypothesized to have arisen through the mis-splicing of an intron-exon junction site in an ancestral gene. The fifth intron of the phosphorylase is very large (approximately 7 kb) and contains a copia-like transposable element inserted in the opposite orientation to that of the phosphorylase gene. This element has been named Tst1; it is bordered on the 5' and 3' sides by long terminal repeats of 285 and 283 bp respectively, which define an internal domain of 4492 bp. Tst1 contains 4 open reading frames (ORFs) that encode protein domains for a reverse transcriptase, an integrase, an RNA-binding site and a protease. Transcription of the phosphorylase gene appears to proceed unimpaired through the copia element.
Mol Gen Genet 1990 Oct
PMID:Occurrence of a copia-like transposable element in one of the introns of the potato starch phosphorylase gene. 170 27

Members of the IS3 family of insertion sequences are found in a wide range of bacteria. At least 10 members of this family carry two major open reading frames: a small upstream frame (0 phase), and a longer downstream frame in the -1 phase. The downstream frame shows significant similarity at the amino acid level. A highly conserved region of this frame also exhibits notable similarity with a region of the integrase (endonuclease) domain of retroviruses. Although the overall transposition mechanism of the insertion sequence and retroviral elements is certainly different, the two groups may share additional common features, including a -1 frameshift resulting in the production of a fusion protein.
Mol Microbiol 1990 Oct
PMID:Functional similarities between retroviruses and the IS3 family of bacterial insertion sequences? 196 20


<< Previous 1 2 3 4 5 6 7 8 9 10 Next >>