New gene expression in dimethylsulfoxide-treated friend erythroleukemia cells

Our previous studies had shown that a small amount of single-stranded DNA (ssDNA) separated from the bulk nuclear DNA of different animal cells by an improved method of hydroxylapatite chromatography (HAC) contains two distinct molecular fractions. The major fraction consists of non self-reassociating sequences that are reassociable to the unique component of bulk DNA and in great part hybridizable to homologous RNA. The minor fraction consists of self-reassociable sequences also reassociable to moderately repetitious bulk DNA. In the present work ssDNA from Friend leukemia cells induced to differentiate (ind FLC) by DMSO was compared with ssDNA from untreated control Friend cells (cont FLC). It was shown that the relative amount of ssDNA is greater in ind FLC than in cont FLC (1.5 – 1.6% and 1.2 – 1.3% of the total cell DNA respectively after a second step of HAC purification). The ind FLC-ssDNA contained a greater proportion of self-reassociable sequences (33–35%) as compared with cont FLC-ssDNA (18–20%). Also the relative amounts of ssDNA hybridizable to cytoplasmic RNA from homologous cells was slightly but constantly higher in ind FLC-ssDNA (33–34%) than in cont FLC-ssDNA (29–30%). Cross hybridizations were carried out between highly radioactive ssDNA and cellular RNAs in great excess, whether total cytoplasmic RNAs or polyadenylated mRNAs. At saturation levels, the hybridized ssDNA fraction was separated from the non-hybridized fraction, and both fractions were rehybridized to RNA from ind FLC or cont FLC. The results indicated that about 10% of ind FLC-ssDNA appeared to be specific for DMSO-treated cells. This may correspond to the expression of 1000–2000 different cytoplasmic mRNAs mostly belonging to the low abundance class.     

The cis-acting DNA sequences required in vivo for bacteriophage Mu helper-mediated transposition and packaging

The 37,000 bp double-stranded DNA genome of bacteriophage Mu behaves as a plaque-forming transposable element of Escherichia coli. We have defined the cis-acting DNA sequences required in vivo for transposition and packaging of the viral genome by monitoring the transposition and maturation of Mu DNA-containing pSC101 and pBR322 plasmids with an induced helper Mu prophage to provide the trans-acting functions. We found that nucleotides 1 to 54 of the Mu left end define an essential domain for transposition, and that sequences between nucleotides 126 and 203, and between 203 and 1,699, define two auxiliary domains that stimulate transposition in vivo. At the right extremity, the essential sequences for transposition require not more than the first 62 base pairs (bp), although the presence of sequences between 63 and 117 bp from the right end increases the transposition frequency about 15-fold in our system. Finally, we have delineated the pac recognition site for DNA maturation to nucleotides 32 to 54 of the Mu left end which reside inside of the first transposase binding site (L1) located between nucleotides 1–30. Thus, the transposase binding site and packaging domains of bacteriophage Mu DNA can be separated into two well-defined regions which do not appear to overlap.Abbreviations attL attachment site left - attR attachment site right - bp base pairs - Kb kilobase pair - nt nucleotide - Pu Purine - Py pyrimidine - Tn transposable element State University of New York, Downstate Medical Center, Brooklyn, NY 11204 USA     

Quantitative modeling of membrane deformations by multihelical membrane proteins: application to G-protein coupled receptors

The interpretation of experimental observations of the dependence of membrane protein function on the properties of the lipid membrane environment calls for a consideration of the energy cost of protein-bilayer interactions, including the protein-bilayer hydrophobic mismatch. We present a novel (to our knowledge) multiscale computational approach for quantifying the hydrophobic mismatch-driven remodeling of membrane bilayers by multihelical membrane proteins. The method accounts for both the membrane remodeling energy and the energy contribution from any partial (incomplete) alleviation of the hydrophobic mismatch by membrane remodeling. Overcoming previous limitations, it allows for radially asymmetric bilayer deformations produced by multihelical proteins, and takes into account the irregular membrane-protein boundaries. The approach is illustrated by application to two G-protein coupled receptors: rhodopsin in bilayers of different thickness, and the serotonin 5-HT_2A receptor bound to pharmacologically different ligands. Analysis of the results identifies the residual exposure that is not alleviated by bilayer adaptation, and its quantification at specific transmembrane segments is shown to predict favorable contact interfaces in oligomeric arrays. In addition, our results suggest how distinct ligand-induced conformations of G-protein coupled receptors may elicit different functional responses through differential effects on the membrane environment.     

Effect of transformation of chicken cells by Rous sarcoma virus on in vitro phosphorylation of nuclear non-histone proteins

Mouse macrophages were treated with 42 different glycans in vitro. Macrophages were stimulated—as judged by morphology, cell size, 5′-nucleotidase activity and the incorporation of [¹⁴C]glucosamine by some insoluble glycans, e.g. yeast glucan. Not all insoluble glycans were stimulatory (e.g. chitin). Laminaran, with a monosaccharide content and bonding pattern similar to that of yeast glucan, could be rendered stimulatory by cross-linking and insolubilization. There was a clear correlation between stimulatory effect and the ability to convert complement factor C3. Preincubation of sera with yeast—presumably producing complement cleavage products—potentiated the stimulatory effect of yeast glucan. It is suggested that endocytosis of glycans with subsequent intracellular triggering of a complement reaction is the underlying mechanism of glycan stimulation.     

Macrophages function as a ferritin iron source for cultured human erythroid precursors

Iron is essential for the survival as well as the proliferation and maturation of developing erythroid precursors (EP) into hemoglobin-containing red blood cells. The transferrin-transferrin receptor pathway is the main route for erythroid iron uptake. Using a two-phase culture system, we have previously shown that placental ferritin as well as macrophages derived from peripheral blood monocytes could partially replace transferrin and support EP growth in a transferrin-free medium. We now demonstrate that in the absence of transferrin, ferritin synthesized and secreted by macrophages can serve as an iron source for EP. Macrophages trigger an increase in both the cytosolic and the mitochondrial labile iron pools, in heme and in hemoglobin synthesis, along with a decrease in surface transferrin receptors. Inhibiting macrophage exocytosis, binding extracellular ferritin with specific antibodies, inhibiting EP receptor-mediated endocytosis or acidification of EP lysosomes, all resulted in a decreased EP growth when co-cultured with macrophages under transferrin-free conditions. The results suggest that iron taken up by macrophages is incorporated mainly into their ferritin, which is subsequently secreted by exocytosis. Nearby EP are able to take up this ferritin probably through clathrin-dependent, receptor-mediated endocytosis into endosomes, which following acidification and proteolysis release the iron from the ferritin, making it available for regulatory and synthetic purposes. Thus, macrophages support EP development under transferrin-free conditions by delivering essential iron in the form of metabolizable ferritin.     

Not Just an Oil Slick: How the Energetics of Protein-Membrane Interactions Impacts the Function and Organization of Transmembrane Proteins

The membrane environment, its composition, dynamics, and remodeling, have been shown to participate in the function and organization of a wide variety of transmembrane (TM) proteins, making it necessary to study the molecular mechanisms of such proteins in the context of their membrane settings. We review some recent conceptual advances enabling such studies, and corresponding computational models and tools designed to facilitate the concerted experimental and computational investigation of protein-membrane interactions. To connect productively with the high resolution achieved by cognate experimental approaches, the computational methods must offer quantitative data at an atomistically detailed level. We show how such a quantitative method illuminated the mechanistic importance of a structural characteristic of multihelical TM proteins, that is, the likely presence of adjacent polar and hydrophobic residues at the protein-membrane interface. Such adjacency can preclude the complete alleviation of the well-known hydrophobic mismatch between TM proteins and the surrounding membrane, giving rise to an energy cost of residual hydrophobic mismatch. The energy cost and biophysical formulation of hydrophobic mismatch and residual hydrophobic mismatch are reviewed in the context of their mechanistic role in the function of prototypical members of multihelical TM protein families: 1), LeuT, a bacterial homolog of mammalian neurotransmitter sodium symporters; and 2), rhodopsin and the β1- and β2-adrenergic receptors from the G-protein coupled receptor family. The type of computational analysis provided by these examples is poised to translate the rapidly growing structural data for the many TM protein families that are of great importance to cell function into ever more incisive insights into mechanisms driven by protein-ligand and protein-protein interactions in the membrane environment.