Kinetics of formation of 5′ terminal caps in mRNA

A kinetic analysis of the labeling of the methylated components of messenger RNA and heterogeneous nuclear RNA in mouse L cells indicates that the 5′ terminal cap I structures (m⁷GpppX^mpYp) of mRNA are derived from 5′ terminal cap structures of hnRNA. Most of the hnRNA caps are conserved during processing, whereas only a portion of the internal m⁶A residues in hnRNA are conserved. The cap II structures (m⁷GpppX^mpY^mpZp), which constitute the 5′ termini of some mRNAs, arise by a “secondary” methylation that occurs after the mRNAs have entered the cytoplasm. This secondary methylation is apparently restricted to a particular subclass of mRNAs having a high frequency of pyrimidine nucleotides at position Y, a composition at position X which differs from that of the bulk of the cap I-terminated mRNAs, and a relatively slow rate of turnover.     

Exploration of RNA 3′ terminal locations in rat ribosome

The locations of the 3 ends of RNAs in rat ribosome were studied by a fluorescencelabeling method combined with high hydrostatic pressure and agarose electrophoresis. Under physiological conditions, only the 3 ends of 28 S and 5.8 S RNA in 80 S ribosome could be labeled with a high sensitive fluorescent probe – fluorescein 5thiosemicarbazide (FTSC), indicating that the 3 termini of 28 S and 5.8 S RNA were located on or near the surface of 80 S ribosome. The 3 terminus of 5 S RNA could be attacked by FTSC only in the case of the dissociation of the 80 S ribosome into two subunits induced by high salt concentration (1 M KCl) or at high hydrostatic pressure, showing that the 3 end of 5 S RNA was located on the interface of two subunits. However, no fluorescencelabeled 18 S RNA could be detected under all the conditions studied, suggesting that the 3 end of 18 S RNA was either located deeply inside ribosome or on the surface but protected by proteins. It was interesting to note that modifications of the 3 ends of ribosomal RNAs including oxidation with NaIO₄, reduction with KBH₄ and labeling with fluorescent probe did not destroy the translation activity of ribosome, indicating that the 3 ends of RNAs were not involved in the translation activity of ribosome.     

Phylogenetic calibration of the 5′ terminal domain of large rRNA achieved by determining twenty eucaryotic sequences

Summary Due to their high information content and their particular mode of variation, large rRNA molecules potentially represent powerful indicators of phylogenetic relationships. Even partial sequences may suffice to generate reliable estimations, provided they correspond to well-chosen portions of the molecule. We have systematically analyzed a specific portion of the large rRNA (the region extending over nearly 400 nucleotides from the 5 end) as a general index of eucaryotic phylogeny. By means of fast and direct rRNA sequencing, we have determined the sequence of this region for 20 additional eucaryotes, including several representatives of each vertebrate class, an invertebrate metazoan (mussel), a fungus (Schizosaccharomyces pombe), and three higher plants. Comparative treatment of these new data and previously reported rRNA sequences shows that this region can serve as an indicator of eucaryotic phylogeny for evaluating both long-range and short-range relationships. Its conservative domains appear to possess a rather uniform rate of nucleotide changes in all the eucaryotic lineages analyzed and the phylogenetic tree we derived agrees with classical views.     

Bacterial Hen1 is a 3′ terminal RNA ribose 2′-O-methyltransferase component of a bacterial RNA repair cassette

Hen1 is an RNA ribose 2′-O-methyltransferase that modifies the 3′ terminal nucleoside of eukaryal small regulatory RNAs. Here, we report that Hen1 homologs are present in bacterial proteomes from eight different phyla. Bacterial Hen1 is encoded by the proximal ORF of a two-gene operon that also encodes polynucleotide kinase-phosphatase (Pnkp), an RNA repair enzyme. Purified recombinant Clostridium thermocellum Hen1 is a homodimer of a 465-amino acid polypeptide. CthHen1 catalyzes methyl transfer from AdoMet to the 3′ terminal nucleoside of an RNA oligonucleotide, but is unreactive with a synonymous DNA oligonucleotide or an RNA with a single 3′-terminal deoxyribose sugar. CthHen1 is optimally active at alkaline pH and dependent on manganese. Activity is inhibited by AdoHcy and abolished by mutations D291A and D316A in the putative AdoMet-binding pocket. The C-terminal fragment, Hen1-(259–465), comprises an autonomous monomeric methyltransferase domain.     

A new 5′ terminal murine GAPDH exon identified using 5′RACE LaNe

In this work, a ligation-independent, fully gene-specific, nested polymerase chain reaction (PCR) method for the elucidation of 5′ cDNA sequence is described and demonstrated for the first time. Two manifestations of the method, rapid amplification of cDNA ends (RACE) by lariat-dependent nested PCR 5′ (RACE LaNe), at least as simple to perform as conventional RACE, were successfully applied to the murine housekeeping genes phosphoglycerate kinase 1 (PGK1), β-actin (β-ACT), and glyceraldehyde-3-phosphate dehydrogenase (GAPDH) and the alpha thalassemia mental retardation Y homolog (ATRY) gene of the marsupial, Macropus eugenii. Significantly, a new murine GAPDH 5′ exon, separated by 365 kb of intronic sequence from previously annotated GAPDH sequence, was discovered using 5′RACE LaNe.     

The blocked and methylated 5′ terminal sequence of a specific cellular messenger: the mRNA for silk fibroin of bombyx mori

The messenger RNA for silk fibroin, labeled with ³²PO₄ and methyl-³H L-methionine, was purified to near homogeneity from the posterior silk gland of the silkworm Bombyx mori, and the sequence of a methylated, RNAase T2-resistant structure was determined. This sequence is similar structurally to 5′ terminal blocked and methylated sequences found on the total populations of polyadenylated eucaryotic cellular and certain viral mRNAs. The RNAase T2-resistant oligomer from fibroin mRNA was cleaved by nuclease P1 into three components: a blocked and methylated sequence containing three phosphates; a 2′-0-methyl UMP residue (pU^m), and an unmethylated CMP (pC). The blocked and methylated sequence comigrated in three chromatographic systems with the blocked and methylated terminus of silkworm cytoplasmic polyhedrosis virus mRNA, which has the structure m⁷GpppA^m. The fibroin mRNA cap was cleaved by nucleotide pyrophosphatase to yield 7-methyl GMP (pm⁷G) and 2′-0-methyl AMP (pA^m). This sequence also appeared to be terminally located, with the m⁷G joined by a 5′-5′ pyrophosphate linkage to the A^m. It was concluded that the 5′ terminal sequence of fibroin mRNA molecules is m⁷G(5′)ppp(5′)A^mpU^mpCp. The regulation of expression of the highly specialized gene for fibroin is discussed in light of this finding.     

Use of 3,3′-diaminobenzidine as a biochemical electron donor for studies on terminal cytochrome oxidase activity inAzotobacter vinelandii

Azotobacter vinelandii cells readily oxidize the dye 3,3′-diaminobenzidine (DAB), which has been previously used as an electron donor for studies on the mitochondrial cytochromec oxidase reaction. The DAB oxidase activity inA. vinelandii cells was 10-fold lower than that noted for theN,N,N′,N′-tetramethyl-p-phenylenediamine (TMPD) oxidase reaction, which is commonly used to measure terminal oxidase activity both in bacteria and mitochondria. Analyses of cell-free extracts show that DAB oxidase activity is concentrated almost exclusively in theA. vinelandii membrane fractions, most notably in the “R₃” electron transport particle (ETP). Oxidation studies, which employed both whole cells and the ETP fraction, show DAB oxidase activity to be markedly sensitive to KCN, NaN₃, and NH₂OH. A manometric assay system was developed which readily measured DAB oxidase activity in bacteria. Preliminary studies indicate that ascorbate-DAB oxidation inAzotobacter vinelandii measures terminal cytochrome oxidase activity in a manner similar to the TMPD oxidase reaction.     

Structural requirement of C‐terminal region of chicken lysozyme signal peptide

Abstract

The mechanisms of signal peptide cleavage has not been fully elucidated yet. In previous investigation, we have examined the effect of chicken lysozyme signal peptide mutations on the secretion of human lysozyme. During this study, we determined that the hydrophobic bulky amino acid Val at position ‐1 inhibited the function of signal peptide. To determine why the ‐1Val suppressed the function of signal peptide, turn‐promoting amino acids Pro and Gly were introduced after ‐lVal to prevent the signal peptide from forming α‐helix and induce β‐turn around the cleavage site. This mutation resulted in no processing of signal peptide and no secretion of human lysozyme. However, the replacement of ‐1Val with Ala permitted a functional signal. Based on these results, three dimensional models around the cleavage site of each signal peptide were made, which show that bulky side chain at ‐1 residue of signal peptide limits the reaction space for signal peptidase and suppresses cleavage by steric hindrance. We suggest that the bulky side chain at ‐1 residue suppresses the signal peptide cleavage by its local steric hindrance and not by a change in whole structure around the cleavage site. On the other hand, introduction of Pro at position +1 did not inhibit signal cleavage completely resulting in poor secretion and processing efficiency although Pro in position +1 has been recently reported to block cleavage of the prokaryotic signal peptide. The mechanism of cleavage of prokaryotic signal may be different than that of eukaryotic signal.     

Synthesis of 3′-Amino-3′-deoxyguanosine 5′-Triphosphate

Abstract

Phosphorylation of 2′-0-acetyl-3′-trifluoroacetamido-3′-deoxy-N²-palmitoylguanosine with N-morpholino-O, O-bis(1-benzotriazolyl)phos-phate gives a 5′-phosphotriester. Removal of the benzotriazolyl group and addition of pyrophosphoric acid gave, after deblocking all protecting groups, GTP(3′NH₂).     

Cleavage of pm7G from mRNA 5′terminal cap structures by pyrophosphatase activity in embryonic chick lens cells

The presence of pyrophosphatase activity in embryonic lens cells which cleaves pm⁷G and ppGm from m⁷G(5)pppGm was demonstrated. It was also found that m⁷G(5) pppG, but not G(5)pppG, was hydrolyzed, and conversion of m⁷GpppG to m⁷G^*pppG, in which the 5-membered ring of the m⁷G moiety is open, abolished its hydrolysis. For the caps hydrolyzed, pm⁷G was released only in the presence of lens cellular fraction; pm⁷G inhibited cap hydrolysis.     

C1′ Acylated Derivatives of 2′-Deoxyuridine. Photolabile Precursors of 2′-Deoxyuridin-1′-yl

Abstract

ABSTRACT

C1′ acylated derivatives of 2′-dcoxyuiidinc (1a-c) were synthesised from 1-[3-deoxy-β-D-psieofiiraiiosylliii.acil (6). The acyl group is introduced via the C1′ aldehyde (11). Following nucleophilic addition, the ketones (1a-c) are obtained via periodinane oxidation and desilylation with NH₄F.     

Concise and Efficient Synthesis of 3′-O-Tetraphosphates of 2′-Deoxyadenosine and 2′-Deoxycytidine

We describe concise and efficient synthesis of biologically very important 3′-O-tetraphosphates namely 2′-deoxyadenosine-3′-O-tetraphosphate (2′-d-3′-A4P) and 2′-deoxycytidine-3′-O-tetra-phosphate (2′-d-3′-C4P). N⁶-benzoyl-5′-O-levulinoyl-2′-deoxyadenosine was converted into N⁶-benzoyl-5′-O-levulinoyl-2′-deoxyadenosine-3′-O-tetraphosphate in 87% yield using a one-pot synthetic methodology. One-step concurrent deprotection of N⁶-benzoyl and 5′-O-levulinoyl groups using concentrated aqueous ammonia resulted 2′-d-3′-A4P in 74% yield. The same synthetic strategy was successfully employed to convert N⁴-benzoyl-5′-O-levulinoyl-2′-deoxycytidine into 2′-d-3′-C4P in 68% yield.     

Synthesis of 3′-N-Substituted 3′-Amino-3′-Deoxythymidine Derivatives

Abstract

A series of 3′-N-substituted 3′-amino-3′-deoxythymidine derivatives with alkyl, alkenyl and alkylaryl substituents was synthesized by two methods. The first method involved the reaction of 1-(2,3-dideoxy-3-0-mesyl-5-0-trityl-β-D-threo-pentofuranosyl)thymine with an appropriate amine. In the second method, 3′-amino-5′-0-trityl-3′-deoxy-thymidine served as a synthetic precursor which was reacted with an appropiate aldehyde or ketone followed by sodium borohydride reduction. An improved synthesis of 3′-amino-3′-deoxythymidine from 3′ -azido-5′-0-trityl-3′-deoxythymidine using sodium borohydride was also described.     

Characterization of terminal deoxynucleotidyl transferase and polymerase μ in zebrafish

Terminal deoxynucleotidyl transferase (TdT) contributes to the junctional diversity of immunoglobulin and T-cell receptors by incorporating nucleotides in a template-independent manner. A closely related enzyme, polymerase μ (polμ), a template-directed polymerase, plays a role in general end-joining double-strand break repair. We cloned zebrafish TdT and polμ and found them to be 43% identical in amino acid sequence. Comparisons with sequences of other species revealed conserved residues typical for TdT in the zebrafish sequence that support the template independence of this enzyme. Some but not all of these features were identified in zebrafish polμ. In adult fish, TdT expression was most prominent in thymus, pro- and mesonephros, the primary lymphoid organs in teleost fish and in spleen, intestine, and the tissue around the intestine. Polμ expression was detected not only in pro- and mesonephros, the major sites for B-lymphocyte development, but also in ovary and testis and in all tissue preparations to a low extent. TdT expression starts at 4 dpf and increases thereafter. Polμ is expressed at all times to a similar extent. In situ studies showed a strong expression of TdT and polμ in the thymic cortex of 8-week-old fish. The characterization of zebrafish TdT and polμ provide new insights in fish lymphopoiesis and addresses the importance and evolution of TdT and polμ themselves.     

Efficient Synthesis of 2′-Amino-2′-deoxypyrimidine 5′-Triphosphates

Abstract

The synthesis of 2′-amino-2′-deoxypyrimidine 5′-triphosphates is described. The 2′-amino-2′-deoxyuridine 5′-triphosphate is obtained from uridine in four steps with 25% overall yield. The 2′-amino-2′-deoxycytidine 5′-triphosphate is obtained from uridine in seven steps with 13% overall yield.