A new method for determining nucleotide sequences in DNA is described. It is similar to the “plus and minus” method [Sanger, F. & Coulson, A. R. (1975) J. Mol. Biol. 94, 441-448] but makes use of the 2′,3′-dideoxy and arabinonucleoside analogues of the normal deoxynucleoside triphosphates, which act as specific chain-terminating inhibitors of DNA polymerase. The technique has been applied to the DNA of bacteriophage ϕX174 and is more rapid and more accurate than either the plus or the minus method.

/pdf/dna-sequencing-with-chain-terminating-inhibitors-t64rmetxr4.pdf

DNA sequencing with chain-terminating inhibitors

Oligodendrocytes, the myelin-forming cells of the central nervous system (CNS), and astrocytes constitute macroglia. This review deals with the recent progress related to the origin and differentiation of the oligodendrocytes, their relationships to other neural cells, and functional neuroglial interactions under physiological conditions and in demyelinating diseases. One of the problems in studies of the CNS is to find components, i.e., markers, for the identification of the different cells, in intact tissues or cultures. In recent years, specific biochemical, immunological, and molecular markers have been identified. Many components specific to differentiating oligodendrocytes and to myelin are now available to aid their study. Transgenic mice and spontaneous mutants have led to a better understanding of the targets of specific dys- or demyelinating diseases. The best examples are the studies concerning the effects of the mutations affecting the most abundant protein in the central nervous myelin, the p...

/pdf/biology-of-oligodendrocyte-and-myelin-in-the-mammalian-3ggbjcby4w.pdf

Biology of Oligodendrocyte and Myelin in the Mammalian Central Nervous System

Improvements in genomic and molecular methods are expanding the range of potential applications for circulating tumour DNA (ctDNA), both in a research setting and as a 'liquid biopsy' for cancer management. Proof-of-principle studies have demonstrated the translational potential of ctDNA for prognostication, molecular profiling and monitoring. The field is now in an exciting transitional period in which ctDNA analysis is beginning to be applied clinically, although there is still much to learn about the biology of cell-free DNA. This is an opportune time to appraise potential approaches to ctDNA analysis, and to consider their applications in personalized oncology and in cancer research.

/pdf/liquid-biopsies-come-of-age-towards-implementation-of-3ovu7jzn3f.pdf

Liquid biopsies come of age: towards implementation of circulating tumour DNA

Thousands of loci in the human and mouse genomes give rise to circular RNA transcripts; at many of these loci, the predominant RNA isoform is a circle. Using an improved computational approach for circular RNA identification, we found widespread circular RNA expression in Drosophila melanogaster and estimate that in humans, circular RNA may account for 1% as many molecules as poly(A) RNA. Analysis of data from the ENCODE consortium revealed that the repertoire of genes expressing circular RNA, the ratio of circular to linear transcripts for each gene, and even the pattern of splice isoforms of circular RNAs from each gene were cell-type specific. These results suggest that biogenesis of circular RNA is an integral, conserved, and regulated feature of the gene expression program.

/pdf/cell-type-specific-features-of-circular-rna-expression-4ao4gawmcm.pdf

Cell-type specific features of circular RNA expression.

Post-transcriptional gene regulation (PTGR) concerns processes involved in the maturation, transport, stability and translation of coding and non-coding RNAs. RNA-binding proteins (RBPs) and ribonucleoproteins coordinate RNA processing and PTGR. The introduction of large-scale quantitative methods, such as next-generation sequencing and modern protein mass spectrometry, has renewed interest in the investigation of PTGR and the protein factors involved at a systems-biology level. Here, we present a census of 1,542 manually curated RBPs that we have analysed for their interactions with different classes of RNA, their evolutionary conservation, their abundance and their tissue-specific expression. Our analysis is a critical step towards the comprehensive characterization of proteins involved in human RNA metabolism.

/pdf/a-census-of-human-rna-binding-proteins-1mii7pfs5y.pdf

A census of human RNA-binding proteins.

Transfer-messenger RNA-SmpB Protein Regulates Ribonuclease R Turnover by Promoting Binding of HslUV and Lon Proteases

Reactions at the 3' Terminus of Transfer Ribonucleic Acid A SINGLE ENZYME CATALYZES THE INCORPORATION OF ADENOSINE MONOPHOSPHATE AND CYTIDINE MONOPHOSPHATE INTO TRANSFER RIBONUCLEIC ACID

The synthetic tRNA precursors, tRNA-C-114C]U and tRNA-C-C-A-[14C]C-C, as well as poly (a) and diesterase-treated tRNA, have been used to identify and purify potential 3'processing nucleases. Four activities have been separated by this analysis; and three of them have been characterized. Two of the enzymes, which are well-separated on hydroxylapatite columns, act on poly(A), require K+ and Mg2+ for activity, and have molecular weights of about 90,000. These activities have properties previously ascribed to RNase II. The third enzyme does not act on poly(A), requires Mg2+ for activity, and has a molecular weight of about 60,000. It is identical to RNase D, previously characterized as an exonuclease acting on tRNAs with altered structure. Each of the enzymes can remove nucleotides from the tRNA precursor containing extra nucleotides beyond the 3'terminus, whereas they are relatively inactive with intact tRNA or tRNA-C-U. The greatest specificity was displayed by RNase D. The possibility that RNase D is a 3'processing nuclease is discussed.

Purification of potential 3′ processing nucleases using synthetic tRNA precursors

Ribonucleases (RNases) play an essential role in essentially every aspect of RNA metabolism, but they also can be destructive enzymes that need to be regulated to avoid unwanted degradation of RNA molecules. As a consequence, cells have evolved multiple strategies to protect RNAs against RNase action. They also utilize a variety of mechanisms to regulate the RNases themselves. These include post-transcriptional regulation, post-translational modification, trans-acting inhibitors, cellular localization, as well as others that are less well studied. In this review, I will briefly discuss how RNA molecules are protected and then examine in detail our current understanding of the mechanisms known to regulate individual RNases.

Murray P. Deutscher

Papers

Transfer-messenger RNA-SmpB Protein Regulates Ribonuclease R Turnover by Promoting Binding of HslUV and Lon Proteases

Reactions at the 3' Terminus of Transfer Ribonucleic Acid A SINGLE ENZYME CATALYZES THE INCORPORATION OF ADENOSINE MONOPHOSPHATE AND CYTIDINE MONOPHOSPHATE INTO TRANSFER RIBONUCLEIC ACID

Purification of potential 3′ processing nucleases using synthetic tRNA precursors

How bacterial cells keep ribonucleases under control

Transfer RNA is a substrate for RNase D in vivo.