Publisher Summary This chapter discusses the sequencing end-labeled DNA with base-specific chemical cleavages. In the chemical DNA sequencing method, one end-labels the DNA, partially cleaves it at each of the four bases in four reactions, orders the products by size on a slab gel, and then reads the sequence from an autoradiogram by noting which base-specific agent cleaved at each successive nucleotide along the strand. This technique sequences the DNA made in and purified from cells. No enzymatic copying in vitro is required, and either single- or double-stranded DNA can be sequenced. Most chemical schemes that cleave at one or two of the four bases involve three consecutive steps: modification of a base, removal of the modified base from its sugar, and DNA strand scission at that sugar. Base-specific chemical cleavage is only one step in sequencing DNA. The chapter presents techniques for producing discrete DNA fragments, end-labeling DNA, segregating end-labeled fragments, extracting DNA from gels, and the protocols for partially cleaving it at specific bases using the chemical reactions. The chapter also discusses the electrophoresis of the chemical cleavage products on long-distance sequencing gels and a guide for troubleshooting problems in sequencing patterns.

Sequencing end-labeled DNA with base-specific chemical cleavages.

https://www.cell.com/cell/pdf/0092-8674(93)90530-4.pdf

Posttranscriptional regulation of the heterochronic gene lin-14 by lin-4 mediates temporal pattern formation in C. elegans

3.7. Palladium Nanoparticles as Catalysts 888 3.8. Other Transition-Metal Complexes 888 3.9. Transition-Metal-Free Reactions 889 4. Applications 889 4.1. Alkynylation of Arenes 889 4.2. Alkynylation of Heterocycles 891 4.3. Synthesis of Enynes and Enediynes 894 4.4. Synthesis of Ynones 896 4.5. Synthesis of Carbocyclic Systems 897 4.6. Synthesis of Heterocyclic Systems 898 4.7. Synthesis of Natural Products 903 4.8. Synthesis of Electronic and Electrooptical Molecules 906

https://www.chem.ccu.edu.tw/~joyce/referance/ericyang/Chem.%20Rev/Chem.%20Rev.%202007,%20107,%20874-922.pdf

The Sonogashira Reaction: A Booming Methodology in Synthetic Organic Chemistry†

Antibodies, the most popular class of molecules providing molecular recognition needs for a wide range of applications, have been around for more than three decades. As a result, antibodies have made substantial contributions toward the advancement of diagnostic assays and have become indispensable in most diagnostic tests that are used routinely in clinics today. The development of the systematic evolution of ligands by exponential enrichment (SELEX) process, however, made possible the isolation of oligonucleotide sequences with the capacity to recognize virtually any class of target molecules with high affinity and specificity. These oligonucleotide sequences, referred to as "aptamers", are beginning to emerge as a class of molecules that rival antibodies in both therapeutic and diagnostic applications. Aptamers are different from antibodies, yet they mimic properties of antibodies in a variety of diagnostic formats. The demand for diagnostic assays to assist in the management of existing and emerging diseases is increasing, and aptamers could potentially fulfill molecular recognition needs in those assays. Compared with the bellwether antibody technology, aptamer research is still in its infancy, but it is progressing at a fast pace. The potential of aptamers may be realized in the near future in the form of aptamer-based diagnostic products in the market. In such products, aptamers may play a key role either in conjunction with, or in place of, antibodies. It is also likely that existing diagnostic formats may change according to the need to better harness the unique properties of aptamers.

Aptamers: An Emerging Class of Molecules That Rival Antibodies in Diagnostics

Publisher Summary This chapter reviews the current state of the knowledge of transcription and translation in Caenorhabditis elegans. Transcription in eukaryotes is accomplished by three RNA polymerases, each transcribing a particular type of RNA; RNA polymerase I transcribes ribosomal RNA, RNA polymerase II transcribes mRNAs and snRNAs, and RNA polymerase III transcribes tRNAs and other low-molecular-weight RNAs. The chapter focuses on RNA polymerase II transcription. The C. elegans gene for the large subunit of RNA polymerase II has been cloned, and has shown to encode a protein that resembles its vertebrate counterparts. For most polymerase II transcribed genes in C. elegans, a sequence fitting the consensus TATA element about 30 bp upstream of the transcriptional start site is found. Recently, a cDNA encoding the TATA box binding protein, or TATA binding protein (TBP) subunit of transcription factor II D (TFIID), has been identified in the nematode. This protein shows extended regions of sequence similarity to vertebrate TBP, binds to a TATA box sequence and can substitute for vertebrate TFIID basal activity in in vitro extracts. These results illustrate a high degree of evolutionary conservation in the basic transcription machinery.

Transcription and translation.

An Approach to Random Mutagenesis of DNA Using Mixtures of Triphosphate Derivatives of Nucleoside Analogues

4-, 5- and 6-Nitroindole have been investigated and compared with 3-nitropyrrole as universal bases in oligodeoxynucleotides. Of these the 5-nitroindole derivative was found to be superior giving higher duplex stability, and behaving indiscriminately towards each of the four natural bases in duplex melting experiments. 3-Nitropyrrole, whilst not discriminating between the natural bases, was found to lead to considerable destabilisation of the duplexes, particularly when multiple substitutions were made, in contrast to the 5-nitroindole nucleoside.

5-Nitroindole as an universal base analogue

Exposure of DNA to methylene blue and visible or ultraviolet light causes guanine-specific modification, and subsequent treatment with piperidine leads to chain cleavage at each guanine residue. Treatment of DNA with osmium tetraoxide in dilute pyridine leads to thymidine-specific modification, and subsequent treatment with piperidine leads to chain cleavage at the modified thymidine residues. Both reactions can be used in conjunction with other base specific modifications described by Maxam and Gilbert (1) for the determination of the nucleotide sequence in DNA.

Base-specific reactions useful for DNA sequencing: methylene blue – sensitized photooxidation of guanine and osmium tetraoxide modification of thymine

3-Nitropyrrole and 5-nitroindole have been assessed as universal bases in primers for dideoxy DNA sequencing and in the polymerase chain reaction (PCR). In contrast to a previous report, we have found that the introduction of more than one 3-nitropyrrole residue at dispersed positions into primers significantly reduced their efficiency in PCR and sequencing reactions. Primers containing 5-nitroindole at multiple dispersed positions were similarly affected; for both bases only a small number of substitutions were tolerated. In PCR experiments neither base, when incorporated into primers in codon third positions, was as effective as hypoxanthine, which was incorporated in six codon third positions in a 20mer oligomer. However, primers containing up to four consecutive 5-nitroindole substitutions performed well in both PCR and sequencing reactions. Consecutive 3-nitropyrrole substitutions were tolerated, but less well in comparable reactions.

Daniel M. Brown

Papers

An Approach to Random Mutagenesis of DNA Using Mixtures of Triphosphate Derivatives of Nucleoside Analogues

5-Nitroindole as an universal base analogue

Base-specific reactions useful for DNA sequencing: methylene blue – sensitized photooxidation of guanine and osmium tetraoxide modification of thymine

3-Nitropyrrole and 5-nitroindole as universal bases in primers for DNA sequencing and PCR.

Sequence analysis of mutations that affect the synthesis, assembly and enzymatic activity of the unc-54 myosin heavy chain of Caenorhabditis elegans.