Observation of single-stranded DNA on mica and highly oriented pyrolytic graphite by atomic force microscopy

Atomic force microscopy was used to image single-stranded DNA (ssDNA) adsorbed on mica modified by Mg(2+), by 3-aminopropyltriethoxysilane or on modified highly oriented pyrolytic graphite (HOPG). ssDNA molecules on mica have compact structures with lumps, loops and super twisting, while on modified HOPG graphite ssDNA molecules adopt a conformation without secondary structures. We have shown that the immobilization of ssDNA under standard conditions on modified HOPG eliminates intramolecular base-pairing, thus this method could be important for studying certain processes involving ssDNA in more details.     

Expression of an expanded polyglutamine domain in yeast causes death with apoptotic markers

Huntington's disease is caused by specific mutations in huntingtin protein. Expansion of a polyglutamine (polyQ) repeat of huntingtin leads to protein aggregation in neurons followed by cell death with apoptotic markers. The connection between the aggregation and the degeneration of neurons is poorly understood. Here, we show that the physiological consequences of expanded polyQ domain expression in yeast are similar to those in neurons. In particular, expression of expanded polyQ in yeast causes apoptotic changes in mitochondria, caspase activation, nuclear DNA fragmentation and death. Similar to neurons, at the late stages of expression the expanded polyQ accumulates in the nuclei and seems to affect the cell cycle of yeast. Interestingly, nuclear localization of the aggregates is dependent on functional caspase Yca1. We speculate that the aggregates in the nuclei disturb the cell cycle and thus contribute to the development of the cell death process in both systems. Our data show that expression of the polyQ construct in yeast can be used to model patho-physiological effects of polyQ expansion in neurons.     

Substrates induce conformational changes in human anion exchanger 1 (hAE1) as observed by fluorescence resonance energy transfer

The one-for-one exchange of Cl(-) and HCO(3)(-) ions is catalyzed by human erythrocyte anion exchanger 1 (hAE1) through a ping-pong mechanism whereby the protein exists in two main conformations, with the single anion-binding site exposed at either the cytoplasmic (inner) side (E(i)) or the extracellular side (E(o)), with interconversion between the two states being possible only after anion binding. Steady-state and time-resolved resonance energy transfer (FRET) techniques were used to determine the distance of the binding site for diTBA (bis-(1,3-diethylthiobarbituric acid)trimethine oxonol), a high affinity fluorescent oxonol inhibitor of hAE1, from a benchmark site (probably Lys-430) labeled by external fluorescein maleimide (FM). Using red cell ghost membranes, energy transfer distances were measured in media containing different anions between FM as the donor, covalently attached to one monomer, and diTBA as the acceptor, reversibly bound to the adjacent monomer of a hAE1 dimer. Energy transfer increased significantly in chloride or bicarbonate buffers relative to conditions where no transportable anions were present, that is, in citrate buffer. These differences in transfer efficiencies were interpreted in light of the conformational distributions of hAE1 in various buffers and the possible effects of diTBA itself on the distribution. The analysis indicates that the diTBA binding site comes closer to the FM site by approximately 7 A in chloride buffer as compared to that in citrate (or equivalent changes in diTBA orientation occur) because of the effects of anion binding. This provides the first direct physical evidence for structural changes in hAE1 induced by substrates.     

The SuUR gene influences the distribution of heterochromatic proteins HP1 and SU(VAR)3–9 on nurse cell polytene chromosomes of Drosophila melanogaster

We have investigated the distribution of three heterochromatic proteins [SUppressor of UnderReplication (SUUR), heterochromatin protein 1 (HP1), and SU(VAR)3–9] in chromosomes of nurse cells (NCs) and have compared the data obtained with the distribution of the same proteins in salivary gland (SG) chromosomes. In NC chromosomes, the SU(VAR)3–9 protein was found in pericentric heterochromatin and at 223 sites on euchromatic arms, while in SG chromosomes, it was mainly restricted to the chromocenter. In NC chromosomes, the HP1 and SUUR proteins bind to 331 and 256 sites, respectively, which are almost twice the number of sites in SG chromosomes. The distribution of the HP1 and SU(VAR)3–9 proteins depends on the SuUR gene. A mutation in this gene results in a dramatic decrease in the amount of SU(VAR)3–9 binding sites in autosomes. In the X chromosome, these sites are relocated in comparison to the SuUR ⁺, and their total number only varies slightly. HP1 binding sites are redistributed in chromosomes of SuUR mutants, and their overall number did not change as considerably as SU(VAR)3–9. These data together point to an interaction of these three proteins in Drosophila NC chromosomes.Electronic Supplementary Material Supplementary material is available for this article at.     

Ribokinase from E. coli: expression, purification, and substrate specificity

Ribokinase (RK) was expressed in the Escherichia coli ER2566 cells harboring the constructed expression plasmid encompassing the rbsK gene, encoding ribokinase. The recombinant enzyme was purified from sonicated cells by double chromatography to afford a preparation that was ca. 90% pure and had specific activity of 75 micromol/min mg protein. Catalytic activity of RK: (i) is strongly dependent on the presence of monovalent cations (potassium>ammonium>cesium), and (ii) is cooperatively enhanced by divalent magnesium and manganese ions. Besides D-ribose and 2-deoxy-D-ribose, RK was found to catalyze the 5-O-phosphorylation of D-arabinose, D-xylose, and D-fructose in the presence of ATP, and potassium and magnesium ions; L-ribose and L-arabinose are not substrates for the recombinant enzyme. A new radiochemical method for monitoring the formation of D-pentofuranose-5-[32P]phosphates in the presence of [gamma-32P]ATP and RK is reported.     

Genetically encoded fluorescent indicator for intracellular hydrogen peroxide

We developed a genetically encoded, highly specific fluorescent probe for detecting hydrogen peroxide (H(2)O(2)) inside living cells. This probe, named HyPer, consists of circularly permuted yellow fluorescent protein (cpYFP) inserted into the regulatory domain of the prokaryotic H(2)O(2)-sensing protein, OxyR. Using HyPer we monitored H(2)O(2) production at the single-cell level in the cytoplasm and mitochondria of HeLa cells treated with Apo2L/TRAIL. We found that an increase in H(2)O(2) occurs in the cytoplasm in parallel with a drop in the mitochondrial transmembrane potential (DeltaPsi) and a change in cell shape. We also observed local bursts in mitochondrial H(2)O(2) production during DeltaPsi oscillations in apoptotic HeLa cells. Moreover, sensitivity of the probe was sufficient to observe H(2)O(2) increase upon physiological stimulation. Using HyPer we detected temporal increase in H(2)O(2) in the cytoplasm of PC-12 cells stimulated with nerve growth factor.     

SREBP-1 dimerization specificity maps to both the helix-loop-helix and leucine zipper domains: use of a dominant negative

The mammalian SREBP family contains two genes that code for B-HLH-ZIP proteins that bind sequence-specific DNA to regulate the expression of genes involved in lipid metabolism. We have designed a dominant negative (DN), termed A-SREBP-1, that inhibits the DNA binding of either SREBP protein. A-SREBP-1 consists of the dimerization domain of B-SREBP-1 and a polyglutamic acid sequence that replaces the basic region. A-SREBP-1 heterodimerizes with either B-SREBP-1 or B-SREBP-2, and both heterodimers are more stable than B-SREBP-1 bound to DNA. Circular dichroism thermal denaturation studies show that the B-SREBP-1.A-SREBP-1 heterodimer is -9.8 kcal mol(-1) dimer(-1) more stable than the B-SREBP-1 homodimer. EMSA assays demonstrate that A-SREBP-1 can inhibit the DNA binding of either B-SREBP-1 or B-SREBP-2 in an equimolar competition but does not inhibit the DNA binding of the three B-HLH-ZIP proteins MAX, USF, or MITF, even at 100 molar eq. Chimeric proteins containing the HLH domain of SREBP-1 and the leucine zipper from either MAX, USF, or MITF indicate that both the HLH and leucine zipper regions of SREBP-1 contribute to its dimerization specificity. Transient co-transfection studies demonstrate that A-SREBP-1 can inhibit the transactivation of SREBP-1 and SREBP-2 but not USF. A-SREBP-1 may be useful in metabolic diseases where SREBP family members are overexpressed.     

A gradient of silent substitution rate in the human pseudoautosomal region

It has been demonstrated that recombination in the human p-arm pseudoautosomal region (p-PAR) is at least twenty times more frequent than the genomic average of approximately 1 cM/Mb, which may affect substitution patterns and rates in this region. Here I report the analysis of substitution patterns and rates in 10 human, chimpanzee, gorilla, and orangutan genes across the p-PAR. Between species silent divergence in the p-PAR forms a gradient, increasing toward the telomere. The correlation of silent divergence with distance from the p-PAR boundary is highly significant (rho = 0.911, P < 0.001). After exclusion of the CpG dinucleotides this correlation is still significant (rho = 0.89, P < 0.01), thus the substitution rate gradient cannot be explained solely by the differences in the extent of methylation across the p-PAR. Frequent recombination in the PAR may result in a relatively strong effect of biased gene conversion (BGC), which, because of the increased probability of fixation of the G or C nucleotides at (A or T)/(G or C) segregating sites, may affect substitution rates. BGC, however, does not seem to be the factor creating the substitution rate gradient in the p-PAR, because the only gradient is still detactable if only A<-->T and G<-->C substitutions are taken into account (rho = 0.82, P < 0.01). I hypothesize that the substitution rate gradient in the p-PAR is due to the mutagenic effect of recombination, which is very frequent in the distal human p-PAR and might be lower near the p-PAR boundary.