Post-transcriptional adenylation of signal recognition particle RNA is carried out by an enzyme different from mRNA Poly(A) polymerase.
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A fraction of the signal recognition particle (SRP) RNA from human, rat, Xenopus, and Saccharomyces cerevisiae cells contains a single post-transcriptionally added adenylic acid residue on its 3'-end; in the case of human SRP RNA, over 60% of the SRP RNA molecules contain a nontemplated adenylic acid residue on their 3'-ends (Sinha, K. M., Gu, J., Chen, Y., and Reddy, R. (1998) J. Biol. Chem. 273, 6853-6859). In this study, we investigated the enzyme that is involved in this 3'-end adenylation of SRP RNA. A U1A protein peptide conjugated to albumin completely inhibited the polyadenylation of a SV40 mRNA by HeLa cell nuclear extract in vitro; however, the 3'-end adenylation of human SRP RNA or Alu RNA, which corresponds to 5' and 3'-ends of SRP RNA, was not affected by this U1A peptide conjugate. SRP RNA from mutant strains of S. cerevisiae with a temperature-sensitive mRNA poly(A) polymerase grown at a restrictive temperature of 37 degrees C also contained a post-transcriptionally added adenylic acid residue just like SRP RNA from wild-type cells and mutant cells grown at permissive temperature of 23 degrees C. In addition, binding of SRP 9/14-kDa protein heterodimer was required for adenylation of Alu RNA in vitro. These lines of evidence, along with other data, show that post-transcriptional adenylation of SRP and Alu RNAs is carried out by a novel enzyme that is distinct from the mRNA poly(A) polymerase, CCA-adding enzyme, and nonspecific terminal transferase. (+info)
Identification and characterization of a transcriptional silencer upstream of the human BRCA2 gene.
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Expression of the breast cancer susceptibility tumor-suppressor protein BRCA2, a protein potentially involved in DNA recombination repair, is tightly regulated throughout development. We have identified a transcriptional silencer at the distal end of the human BRCA2 gene promoter. This silencer is involved in the negative regulation of the expression of this gene in breast cell lines tested but not in HeLa or HepG2 cells. The 221-base-pair silencer region is characterized by a full-length Alu-repeat. Presence of specific BRCA2 silencer-binding proteins in the breast cell extracts indicates the potential regulation of BRCA2 gene expression by these proteins. (+info)
The Alu domain homolog of the yeast signal recognition particle consists of an Srp14p homodimer and a yeast-specific RNA structure.
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The mammalian Alu domain of the signal recognition particle (SRP) consists of a heterodimeric protein SRP9/14 and the Alu portion of 7SL RNA and comprises the elongation arrest function of the particle. To define the domain in Saccharomyces cerevisiae SRP that is homologous to the mammalian Alu domain [Alu domain homolog in yeast (Adhy)], we examined the assembly of a yeast protein homologous to mammalian SRP14 (Srp14p) and scR1 RNA. Srp14p binds as a homodimeric complex to the 5' sequences of scR1 RNA. Its minimal binding site consists of 99 nt. (Adhy RNA), comprising a short hairpin structure followed by an extended stem. As in mammalian SRP9/14, the motif UGUAAU present in most SRP RNAs is part of the Srp14p binding sites as shown by footprint and mutagenesis studies. In addition, certain basic amino acid residues conserved between mammalian SRP14 and Srp14p are essential for RNA binding in both proteins. These findings confirm the common ancestry of the yeast and the mammalian components and indicate that Srp14p together with Adhy RNA represents the Alu domain homolog in yeast SRP that may comprise its elongation arrest function. Despite the similarities, Srp14p selectively recognizes only scR1 RNA, revealing substantial changes in RNA-protein recognition as well as in the overall structure of the complex. The alignment of the three yeast SRP RNAs known to date suggests a common structure for the putative elongation arrest domain of all three organisms. (+info)
Organization and sequence of the gene for the human mitochondrial dicarboxylate carrier: evolution of the carrier family.
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The dicarboxylate carrier (DIC) is a nuclear-encoded protein located in the mitochondrial inner membrane. It catalyses the transport of dicarboxylates such as malate and succinate across the mitochondrial membrane in exchange for phosphate, sulphate and thiosulphate. We have determined the sequences of the human cDNA and gene for the DIC. The gene sequence was established from overlapping genomic clones generated by PCRs by use of primers and probes based upon the human cDNA sequence. It is spread over 8.6 kb of human DNA and is divided into 11 exons. Five short interspersed repetitive Alu sequences are found in intron I. The protein encoded by the gene is 287 amino acids long. In common with the rat protein, it does not have a processed presequence to help to target it into mitochondria. It has been demonstrated by Northern- and Western-blot analyses that the DIC is present in high amounts in liver and kidney, and at lower levels in all the other tissues analysed. The positions of introns contribute towards an understanding of the processes involved in the evolution of human genes for carrier proteins. (+info)
The specific endoribonuclease activity of small nuclear and cytoplasmic alpha-RNPs.
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For the first time small nuclear ribonucleoprotein particles (alpha-RNP) tightly bound to chromatin as well as cytoplasmic alpha-RNP are shown to possess strong and regulated endonuclease activity specific for mRNAs and hnRNAs. The enzymatic nature of this activity is confirmed, and the optimal conditions detected. This RNase activity is controlled by the action of a differentiating stimulus, dimethylsulfoxide, in human K562 cells. Small alpha-RNP involvement in the coordinated control of stability of pre-messenger RNA and messenger RNA molecules is suggested. (+info)
An Alu element from the K18 gene confers position-independent expression in transgenic mice.
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We have identified a 323-base pair fragment of the 5'-flanking sequence of the K18 gene, which confers position-independent and copy number-dependent expression on two heterologous transgenes. This fragment is composed primarily of an Alu repetitive element. Its activity in mice is correlated with its RNA polymerase III promoter activity and its orientation-dependent ability to inhibit potential transcriptional interference in a transfection assay. However, the activity of the Alu element is not correlated with its enhancer blocking activity, a characteristic of insulator elements. In addition, this Alu element did not block the suppressive effect of co-injecting mouse alpha satellite DNA with the transgene. This Alu element is likely responsible for at least part of the protective effects of the sequences flanking the K18. These results suggest that transcriptionally active Alu elements may eliminate transcriptional interference of neighboring genes. This Alu element is one component of the locus control region associated with the K18 gene. Other Alu repetitive elements may also function to define regulatory domains. (+info)
Alu and translisin recognition site sequences flanking translocation sites in a novel type of chimeric bcr-abl transcript suggest a possible general mechanism for bcr-abl breakpoints.
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BACKGROUND AND OBJECTIVE: We further characterized a novel type of chimeric BCR-ABL mRNA transcript detected in a patient with Philadelphia chromosome positive (Ph+) chronic myeloid leukemia (CML). DESIGN AND METHODS: We used reverse-transcription polymerase chain reaction (RT-PCR) and sequence analysis of the fusion region of the amplified cDNA fragment. Western analysis was performed on total protein. RESULTS: Part of exon e8 of the BCR gene was joined to an intronic sequence of ABL intron Ib spliced on exon a2 of the ABL gene, giving rise to an in-frame e8-int-a2 BCR-ABL transcript. Only part of exon 8 of the BCR gene (e8) (intra-exonic break) was retained. The consequent BCR-int-ABL transcript was translated into a BCR-ABL protein of 1804 amino acid residues with a molecular mass of 197.5 kilodaltons (kDa) called p200 BCR-ABL. The 3' part of bcr exon 8 recombined within or alongside Alu elements at the additional sites. Sequence motifs similar to consensus binding sites of the lymphoid-associated TRAX and translisin proteins were present on both participating strands at 22q11 and 9q34 recombination sites, respectively. No differences in clinical or laboratory findings at diagnosis were found between this patient and CML patients with bcr-abl fusion. INTERPRETATION AND CONCLUSIONS: The presence of Alu sequences and of the translisin binding motif on both sides of the breaks in this novel translocation suggests a possible general mechanism of molecular recombination in CML patients. (+info)
The distribution of human genetic diversity: a comparison of mitochondrial, autosomal, and Y-chromosome data.
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We report a comparison of worldwide genetic variation among 255 individuals by using autosomal, mitochondrial, and Y-chromosome polymorphisms. Variation is assessed by use of 30 autosomal restriction-site polymorphisms (RSPs), 60 autosomal short-tandem-repeat polymorphisms (STRPs), 13 Alu-insertion polymorphisms and one LINE-1 element, 611 bp of mitochondrial control-region sequence, and 10 Y-chromosome polymorphisms. Analysis of these data reveals substantial congruity among this diverse array of genetic systems. With the exception of the autosomal RSPs, in which an ascertainment bias exists, all systems show greater gene diversity in Africans than in either Europeans or Asians. Africans also have the largest total number of alleles, as well as the largest number of unique alleles, for most systems. GST values are 11%-18% for the autosomal systems and are two to three times higher for the mtDNA sequence and Y-chromosome RSPs. This difference is expected because of the lower effective population size of mtDNA and Y chromosomes. A lower value is seen for Y-chromosome STRs, reflecting a relative lack of continental population structure, as a result of rapid mutation and genetic drift. Africa has higher GST values than does either Europe or Asia for all systems except the Y-chromosome STRs and Alus. All systems except the Y-chromosome STRs show less variation between populations within continents than between continents. These results are reassuring in their consistency and offer broad support for an African origin of modern human populations. (+info)