Thoru Pederson

Proteins associated with heterogeneous nuclear RNA in eukaryotic cells

Abstract When HeLa cell nuclei axe mechanically disrupted in either hypotonic or isotonic buffers, heterogeneous nuclear RNA is recovered from the post-nucleolar fraction in the form of EDTA-resistant ribonucleoprotein particles, which sediment between 40 S and 250 S in sucrose gradients containing 0.01 m or 0.15 m -NaCl. That the RNA in these particles is HnRNA † is indicated by its heterodisperse sedimentation (20 to 80 S) and its continued synthesis in concentrations of actinomycin D that selectively inhibit the synthesis of ribosomal RNA. The specificity of the HnRNA-protein complexes is evidenced by the failure of deliberate attempts to generate artificial RNP by the addition of deproteinized HnRNA to intact or disrupted nuclei at low ionic strength. The proteins bound to HnRNA are complex. In HeLa cells, HnRNP particles contain proteins with molecular weights from 39,000 to approximately 180,000 (sodium dodecyl sulfate-polyacrylamide gel electrophoresis) and isoelectric points between 4.9 and 8.3 (analytical isoelectric focusing). They are readily distinguishable from proteins in other cell fractions, including those in chromatin. Exposure of HeLa HnRNP particles to 0.5 m -NaCl reduces their average sedimentation velocity by approximately 30%. CsCl density-gradient analysis reveals that this is accompanied by the loss of a major portion of the proteins. However, a significant fraction of the HnRNP (25 to 30%) is resistant to high salt concentrations and continues to band at the same density as native HnRNP (1.43 g/cm 3 ). This is true even after prolonged exposure (24 h) to high salt. The salt-resistant HnRNP is enriched for proteins above 60,000 molecular weight. In at least these two respects, this sub-class of HnRNP resembles “messenger RNP” prepared from cytoplasmic polyribosomes, which is also salt-stable and contains relatively high molecular weight proteins. HnRNP particles can also be recovered from HeLa cell nuclei lysed in high salt but these contain many extra proteins, notably histones, and sediment much faster in sucrose gradients than particles prepared as above. HnRNP is not liberated by extracting HeLa nuclei in 0.14 m -NaCl, pH 8.0 (Samarina et al. , 1967) unless the temperature is 20 °C or higher. In this case the particles are converted to 45 S structures, which contain partially degraded HnRNA. 45 S particles can also be produced by subjecting 40 to 250 S HnRNP to a very limited digestion with pancreatic ribonuclease (1 to 2 hits/molecule). HnRNP particles have similar sedimentation velocities (40 to 300 S) when isolated under physiological ionic conditions from a variety of mammalian cells, including WI38 human diploid fibroblasts, mouse L-cells, monkey kidney cells and rat liver. However, electrophoresis reveals a distinct pattern of HnRNP proteins for each cell type. It is proposed that this cell-specificity reflects a situation in which HnRNA molecules that differ in nucleotide sequence are complexed with different sets of proteins, so that the resulting HnRNP particles are biochemically distinct at each genetic locus. This hypothesis is discussed in relation to the cytology of lampbrush and polytene chromosomes.

The role of superoxide and singlet oxygen in lipid peroxidation promoted by xanthine oxidase

Abstract The peroxidative oxidation of extracted rat liver microsomal lipid, assayed as malondialdehyde production, can be promoted by milk xanthine oxidase in the presence of 0.2 mM FeCl 3 and 0.1 mM EDTA. The reaction is inhibited by the superoxide dismutase activity of erythrocuprein. The reaction is also inhibited by 1,3-diphenylisobenzofuran, which reacts with singlet oxygen to yield dibenzoylbenzene. During inhibition of the lipid peroxidation reaction by 1,3-diphenylisobenzofuran, o-dibenzoylbenzene was produced. The rate of superoxide production by xanthine oxidase was not affected by 1,3-diphenylisobenzofuran. Lipid peroxidation promoted by ascorbic acid is not inhibited by either erythrocuprein or 1,3-diphenylisobenzofuran. Therefore it is suggested that the peroxidative oxidation of unsaturated lipid promoted by xanthine oxidase involves the formation of singlet oxygen from superoxide, and the singlet oxygen reacts with the lipid to form fatty acid hydroperoxides.

Movement of nuclear poly(A) RNA throughout the interchromatin space in living cells

BACKGROUND Messenger RNA (mRNA) is transcribed and processed in the nucleus of eucaryotic cells and then exported to the cytoplasm through nuclear pores. It is not known whether the movement of mRNA from its site of synthesis to the nuclear pore is directed or random. Directed movement would suggest that there is an energy-requiring step in addition to the step required for active transport through the pore, whereas random movement would indicate that mRNAs can make their way to the nuclear envelope by diffusion. RESULTS We devised a method to visualize movement of endogenous polymerase II transcripts in the nuclei of living cells. Oligo(dT) labeled with chemically masked (caged) fluorescein was allowed to penetrate cells and hybridize to nuclear poly(A) RNA. Laser spot photolysis then uncaged the oligo(dT) at a given intranuclear site and the resultant fluorescent, hybridized oligo(dT) was tracked using high-speed imaging microscopy. Poly(A) RNA moved away from the uncaging spot in all directions with a mean square displacement that varied linearly with time, and the same apparent diffusion coefficient was measured for the movement at both 37 degrees C and 23 degrees C. These properties are characteristic of a random diffusive process. High resolution three-dimensional imaging of live cells containing both Hoechst-labeled chromosomes and uncaged oligo(dT) showed that, excluding nucleoli, the poly(A) RNA could access most, if not all, of the non-chromosomal space in the nucleus. CONCLUSIONS Poly(A) RNA can move freely throughout the interchromatin space of the nucleus with properties characteristic of diffusion.

NADPH-dependent lipid peroxidation catalyzed by purified NADPH-cytochrome c reductase from rat liver microsomes

Abstract A purified preparation of rat liver microsomal NADPH-cytochrome c reductase has been shown to catalyze the NADPH-dependent peroxidation of isolated microsomal lipid. In addition to ADP and ferric ion required for NADPH-dependent lipid peroxidation in whole microsomes, this system requires high ionic strength and a critical concentration of EDTA. The peroxidation activity can be inhibited by superoxide dismutase suggesting that the superoxide anion, produced by this flavoprotein, is involved in the lipid peroxidation reaction.

Evidence for superoxide generation by NADPH-cytochrome C reductase of rat liver microsomes☆

Abstract Rat liver microsomes are capable of catalyzing an NADPH-dependent oxidation of epinephrine to adrenochrome that is inhibited by superoxide dismutase. Activity is greater and more sensitive to inhibition by superoxide dismutase at pH 8.5 than pH 7.7. The epinephrine oxidation activity copurifies with NADPH-cytochrome c reductase.

Multicolor CRISPR labeling of chromosomal loci in human cells

Significance The detection of specific genes in fixed cells was first accomplished in 1969 by Gall and Pardue. The development of analogous methods applicable to living cells is now at hand. At the forefront of this advance (2013–2014), we and other investigators have used transcription activator-like effectors (TALEs) conjugated with fluorescent proteins to tag genomic loci in live cells. More recently, the CRISPR/Cas9 system has provided a more flexible approach to targeting specific loci. In this paper, we describe the labeling of human genomic loci in live cells with three orthogonal CRISPR/Cas9 components, allowing multicolor detection of genomic loci with high spatial resolution, which provides an avenue for barcoding elements of the human genome in the living state. The intranuclear location of genomic loci and the dynamics of these loci are important parameters for understanding the spatial and temporal regulation of gene expression. Recently it has proven possible to visualize endogenous genomic loci in live cells by the use of transcription activator-like effectors (TALEs), as well as modified versions of the bacterial immunity clustered regularly interspersed short palindromic repeat (CRISPR)/CRISPR-associated protein 9 (Cas9) system. Here we report the design of multicolor versions of CRISPR using catalytically inactive Cas9 endonuclease (dCas9) from three bacterial orthologs. Each pair of dCas9-fluorescent proteins and cognate single-guide RNAs (sgRNAs) efficiently labeled several target loci in live human cells. Using pairs of differently colored dCas9-sgRNAs, it was possible to determine the intranuclear distance between loci on different chromosomes. In addition, the fluorescence spatial resolution between two loci on the same chromosome could be determined and related to the linear distance between them on the chromosome’s physical map, thereby permitting assessment of the DNA compaction of such regions in a live cell.

MicroRNAs with a nucleolar location

There is increasing evidence that noncoding RNAs play a functional role in the nucleus. We previously reported that the microRNA (miRNA), miR-206, is concentrated in the nucleolus of rat myoblasts, as well as in the cytoplasm as expected. Here we have extended this finding. We show by cell/nuclear fractionation followed by microarray analysis that a number of miRNAs can be detected within the nucleolus of rat myoblasts, some of which are significantly concentrated there. Pronounced nucleolar localization is a specific phenomenon since other miRNAs are present at only very low levels in the nucleolus and occur at much higher levels in the nucleoplasm and/or the cytoplasm. We have further characterized a subset of these miRNAs using RT-qPCR and in situ hybridization, and the results suggest that some miRNAs are present in the nucleolus in precursor form while others are present as mature species. Furthermore, we have found that these miRNAs are clustered in specific sites within the nucleolus that correspond to the classical granular component. One of these miRNAs is completely homologous to a portion of a snoRNA, suggesting that it may be processed from it. In contrast, the other nucleolar-concentrated miRNAs do not show homology with any annotated rat snoRNAs and thus appear to be present in the nucleolus for other reasons, such as modification/processing, or to play roles in the late stages of ribosome biosynthesis or in nonribosomal functions that have recently been ascribed to the granular component of the nucleolus.

Selective and Nonselective Packaging of Cellular RNAs in Retrovirus Particles

ABSTRACT Assembly of retrovirus particles normally entails the selective encapsidation of viral genomic RNA. However, in the absence of packageable viral RNA, assembly is still efficient, and the released virus-like particles (termed “Ψ−” particles) still contain roughly normal amounts of RNA. We have proposed that cellular mRNAs replace the genome in Ψ− particles. We have now analyzed the mRNA content of Ψ− and Ψ+ murine leukemia virus (MLV) particles using both microarray analysis and real-time reverse transcription-PCR. The majority of mRNA species present in the virus-producing cells were also detected in Ψ− particles. Remarkably, nearly all of them were packaged nonselectively; that is, their representation in the particles was simply proportional to their representation in the cells. However, a small number of low-abundance mRNAs were greatly enriched in the particles. In fact, one mRNA species was enriched to the same degree as Ψ+ genomic RNA. Similar results were obtained with particles formed from the human immunodeficiency virus type 1 (HIV-1) Gag protein, and the same mRNAs were enriched in MLV and HIV-1 particles. The levels of individual cellular mRNAs were ∼5- to 10-fold higher in Ψ− than in Ψ+ MLV particles, in agreement with the idea that they are replacing viral RNA in the former. In contrast, signal recognition particle RNA was present at the same level in Ψ− and Ψ+ particles; a minor fraction of this RNA was weakly associated with genomic RNA in Ψ+ MLV particles.

In search of nonribosomal nucleolar protein function and regulation

The life of the nucleolus has proven to be more colorful and multifaceted than had been envisioned a decade ago. A large number of proteins found in this subnuclear compartment have no identifiable tie either to the ribosome biosynthetic pathway or to the other newly established activities occurring within the nucleolus. The questions of how and why these proteins end up in this subnuclear compartment remain unanswered and are the focus of intense current interest. This review discusses our thoughts on the discovery of nonribosomal proteins in the nucleolus.

MicroRNA-206 colocalizes with ribosome-rich regions in both the nucleolus and cytoplasm of rat myogenic cells

MicroRNAs are small, ≈21- to 24-nt RNAs that have been found to regulate gene expression. miR-206 is a microRNA that is expressed at high levels in Drosophila, zebrafish, and mouse skeletal muscle and is thought to be involved in the attainment and/or maintenance of the differentiated state. We used locked nucleic acid probes for in situ hybridization analysis of the intracellular localization of miR-206 during differentiation of rat myogenic cells. Like most microRNAs, which are presumed to suppress translation of target mRNAs, we found that miR-206 occupies a cytoplasmic location in cultured myoblasts and differentiated myotubes and that its level increases in myotubes over the course of differentiation, consistent with previous findings in muscle tissue in vivo. However, to our surprise, we also observed miR-206 to be concentrated in nucleoli. A probe designed to be complementary to the precursor forms of miR-206 gave no nucleolar signal. We characterized the intracellular localization of miR-206 at higher spatial resolution and found that a substantial fraction colocalizes with 28S rRNA in both the cytoplasm and the nucleolus. miR-206 is not concentrated in either the fibrillar centers of the nucleolus or the dense fibrillar component, where ribosomal RNA transcription and early processing occur, but rather is localized in the granular component, the region of the nucleolus where final ribosome assembly takes place. These results suggest that miR-206 may associate both with nascent ribosomes in the nucleolus and with exported, functional ribosomes in the cytoplasm.