Isolation of the 5′-End of Plant Genes from Genomic DNA by TATA-Box-Based Degenerate Primers

We report a rapid and simple method for isolating the 5′-end of plant genes from genomic DNA by polymerase chain reaction (PCR) with TATA-box-based degenerate primers (TDPs). The TDPs were specially designed according to the TATA box, which is conserved in the promoter region of most plant genes. The unknown 5′-ends of several genes in different plants were isolated by PCR with gene-specific primers of the known core fragment and the TDPs. Our method does not require the arduous RNA manipulations and expensive enzyme treatments of the popular rapid amplification of cDNA ends (RACE) and its variants, and so could be a cheap practical alternative.     

Use of a Base-Labile Protected Derivative of 6-Mercaptohexanol for the Preparation of Oligonucleotides Containing a Thiol Group at the 5′-End

Abstract

The preparation of a base-labile (Dnpe) protected derivative of 6-mercaptohexanol is described. The use of the phosphoramidite derivative of this compound improves both yields and the time needed for the preparation of oligonucleotides containing a thiol group at the 5′-end.     

An RNA Element at the 5′-End of the Poliovirus Genome Functions as a General Promoter for RNA Synthesis

RNA structures present throughout RNA virus genomes serve as scaffolds to organize multiple factors involved in the initiation of RNA synthesis. Several of these RNA elements play multiple roles in the RNA replication pathway. An RNA structure formed around the 5′- end of the poliovirus genomic RNA has been implicated in the initiation of both negative- and positive-strand RNA synthesis. Dissecting the roles of these multifunctional elements is usually hindered by the interdependent nature of the viral replication processes and often pleiotropic effects of mutations. Here, we describe a novel approach to examine RNA elements with multiple roles. Our approach relies on the duplication of the RNA structure so that one copy is dedicated to the initiation of negative-strand RNA synthesis, while the other mediates positive-strand synthesis. This allows us to study the function of the element in promoting positive-strand RNA synthesis, independently of its function in negative-strand initiation. Using this approach, we demonstrate that the entire 5′-end RNA structure that forms on the positive-strand is required for initiation of new positive-strand RNAs. Also required to initiate positive-strand RNA synthesis are the binding sites for the viral polymerase precursor, 3CD, and the host factor, PCBP. Furthermore, we identify specific nucleotide sequences within “stem a” that are essential for the initiation of positive-strand RNA synthesis. These findings provide direct evidence for a trans-initiation model, in which binding of proteins to internal sequences of a pre-existing positive-strand RNA affects the synthesis of subsequent copies of that RNA, most likely by organizing replication factors around the initiation site.     

Delineating the Structural Blueprint of the Pre-mRNA 3′-End Processing Machinery

Processing of mRNA precursors (pre-mRNAs) by polyadenylation is an essential step in gene expression. Polyadenylation consists of two steps, cleavage and poly(A) synthesis, and requires multiple cis elements in the pre-mRNA and a megadalton protein complex bearing the two essential enzymatic activities. While genetic and biochemical studies remain the major approaches in characterizing these factors, structural biology has emerged during the past decade to help understand the molecular assembly and mechanistic details of the process. With structural information about more proteins and higher-order complexes becoming available, we are coming closer to obtaining a structural blueprint of the polyadenylation machinery that explains both how this complex functions and how it is regulated and connected to other cellular processes.     

Synthesis of 2′-5′ Adenylate Trimers Containing 3′-Modified β-D-Xylofuranosyl-Adenine Derivatives at the 2′-End

Abstract

The exciting reports (1,2) on the unusual structure of the oligonucleotide pppAZ1p5′A2′p5′A and its biological activity as a strong inhibitor of cell free protein synthesis (3) motivated various research groups to synthesize this low-molecular-weight 01 igonucleotide and its analogues (4,5). Since the biological activity of the 2′-5′-adenylates is rapidly lost due to cleavage of the 2′-5′-internucleotidic bond by a specific phosphodiesterase working from the 2′-end and affording a 3′-hydroxyl ribo-moiety modifications at this part of the molecule may enhance the stability towards enzymatic degradation and prolong this way the biological activity.     

Interaction of Complementary Oligonucleotides with the 3′-End of Yeast tRNAPHE

Abstract

Interaction of yeast tRNA^Phe with oligodeoxyribonucleotides (ONs), complementary to the nucleotides 62–76 was investigated. Results of gel-mobility shift assay and RNase A probing evidence that the ONs containing the sequence complementary to the tRNA ACCA end can easily invade the hairpin structure under physiological conditions. The limiting step of association process is the tRNA unfolding.     

Characterization of the Quenching of Chlorophyll a Fluorescence by β-Carotene Using the Non-Linear Analysis

Carotenoids (Car) regulate energy flow in photosynthesis by a specific Car-chlorophyll (Chl) interaction in the singlet-excited states, leading to a reduction in Chl fluorescence. We studied quenching of Chl a-fluorescence in benzene by trans--carotene. Non-linear analysis of the quenching process enables to explain the possible molecular mechanism leading to the de-excitation of Chl a. The fluorescence intensity was measured at 670 nm for excitation wavelengths of 380, 430, 640, and 650 nm. The -carotene concentrations ranged from 4×10^–5 M to 5×10^–3 M. When the samples were excited at 640 and 650 nm, the Stern-Volmer plots showed that the quenching process has high rate constants, hence -carotene is a very efficient quencher. Two different types of quenching process could take place.     

DNA polymorphisms in the 5′-flanking region of the HLA-DQA1 gene

The HLA-DQA1 gene exhibits haplotype-specific restriction fragment polymorphisms due to DNA rearrangements. We found that some of these polymorphisms extend into the 5 flanking region of the gene and are distinct from other HLA-DQA1 related DNA polymorphisms so far reported. Sequencing of genomic DNA subclones derived from the 5 flanking region of HLA-DQA1 showed the presence, in a DR4 haplotype, of two repetitive elements of the Alu family, oriented in opposite directions and bracketing an approximately 3 kilobase region immediately adjacent to the promoter of the gene. When DNAs extracted from several cell lines were analyzed by genomic hybridization using single-copy probes relative to these intervening sequences, polymorphisms were observed. No structural alterations of the gene immediately outside the DNA portion delimited by the two Alu elements were observed, thus suggesting that polymorphisms of the 5 end of HLA-DQA1 may be limited to the intervening region between the two Alu repeats. The latter includes upstream regulatory elements controlling the expression of the genes. The possibility that the structure of the DNA in this region may influence the regulation of HLA-DQA1 gene expression in different haplotypes is discussed.The nucleotide sequence data reported in this paper have been submitted to the GenBank nucleotide sequence database and have been assigned the accession number M72411. Address correspondence and offprint requests to: J. Guardiola.     

Inhibition of a novel subspecies of DNA polymerase α by 2′-deoxy-2′-azidoadenosine 5′-triphosphate

DNA polymerase α₁, a subspecies of DNA polymerase α of Ehrlich ascites tumor cells, was associated with a novel RNA polymerase activity and utilized poly(dT) and single-stranded circular fd DNA as a template without added primer in the presence of ribonucleoside triphosphates and a specific stimulating factor. DNA synthesis in the above system was inhibited by the ATP analogue, 2′-deoxy-2′-azidoadenosine 5′-triphosphate more than the DNA synthesis with poly(dT)·oligo(rA) by DNA polymerase α₁ and RNA synthesis by mouse RNA polymerases I and II. Kinetic analysis showed that the analogue inhibited DNA polymerase α₁ activity on poly(dT) competitively with respect to ATP, suggesting that the analogue inhibited RNA synthesis by the associated RNA polymerase activity.     

Segregation and Linkage Analysis of 75 Novel Microsatellite DNA Markers in Pair Crosses of Japanese Abalone (Haliotis discus hannai) Using the 5′-Tailed Primer Method

We present novel microsatellite markers of the Japanese abalone (Haliotis discus hannai) for general mapping studies in this species. A total of 75 microsatellite markers were developed, and the allele-transmission patterns of these markers were studied in three families generated by pair crosses. For allele scoring, we employed the 5′-tailed primer polymerase chain reaction (PCR) technique, which substantially reduces the cost for fluorescent labeling of primers. Of the 225 possible marker-family combinations (75 markers × 3 families), 18 cases of informative null-allele segregation were inferred. When such null-allele segregations were allowed, more than 70% of the 75 markers in the families turned out to be markers with an expected segregation ratio of 1:1:1:1, allowing maximal exploitation of the codominant nature of microsatellite markers. There were 16 instances of segregation distortion at the 5% significance level. The test for independence of segregation assigned the 75 markers into 17 linkage groups, which is in close agreement with the haploid chromosome number of H. discus hannai (n = 18). Six markers could not be placed into any linkage group. We suggest that these markers could help construct a H. discus hannai linkage map.     

The 5′-Purine-Pyrimidine-3′ Stacks are More Stabilizing in a Self-3′-Pyrinudine-Purine-5′ complementary DNA Duplex than the 5′-Purine-Purine-3′ 3′-Pyrimidine-Pyrimidine-5′ Stack

Abstract

First experimental evidence is herein reported supporting the earlier quantum chemical calculations that 5′-Punne-pyrimiidine-3′ 3′ -Pyrimidine-Punne-5 stack is more stable than 5′-Pyrimiidine-Punne-3′ 3′-Punne-Pyrimidine-5′.     

Analysis of DNA Sequencing Reaction Products Made with 7-Halo-7-deaza-2′-deoxyguanosine-5′-triphosphate

Abstract

7-Chloro- and 7- Iodo-7-Deaza-2′-Deoxyguanosine-5′-Triphosphates were employed as substrates replacing dGTP, dITP, or 7-Deaza-2′-Deoxyguanosine-5′-Triphosphate in sequencing reactions with Thermo Sequenase^TM. Analysis of the reaction products by denaturing gel electrophoresis indicates DNA containing these halogenated analogs can form strong secondary structures.     

A Unique Primer with an Inosine Chain at the 5′-Terminus Improves the Reliability of SNP Analysis Using the PCR-Amplified Product Length Polymorphism Method

Polymerase chain reaction-amplified product length polymorphism (PCR-APLP) is one of the most convenient and reliable methods for single nucleotide polymorphism (SNP) analysis. This method is based on PCR, but uses allele-specific primers containing SNP sites at the 3′-terminus of each primer. To use this method at least two allele-specific primers and one “counter-primer”, which serves as a common forward or reverse primer of the allele-specific primers, are required. The allele-specific primers have SNP sites at the 3′-terminus, and another primer should have a few non-complementary flaps at the 5′-terminus to detect SNPs by determining the difference of amplicon length by PCR and subsequent electrophoresis. A major disadvantage of the addition of a non-complementary flap is the non-specific annealing of the primer with non-complementary flaps. However, a design principle for avoiding this undesired annealing has not been fully established, therefore, it is often difficult to design effective APLP primers. Here, we report allele-specific primers with an inosine chain at the 5′-terminus for PCR-APLP analysis. This unique design improves the competitiveness of allele-specific primers and the reliability of SNP analysis when using the PCR-APLP method.