Tom34 unlike Tom20 does not interact with the leader sequences of mitochondrial precursor proteins

Tom20 and Tom34 are mammalian liver proteins previously identified by others to be components of the mitochondrial import translocation apparatus. It has been shown that Tom20 interacts with the leader sequence of nuclear coded matrix space precursor proteins. Here we show with recombinantly expressed Tom proteins that Tom34 binds the mature portion of the precursor and not the leader. Both these Tom proteins inhibited the import of newly translated precursor of aldehyde dehydrogenase in an in vitro assay. Only Tom20 inhibited the import of a fusion protein of the leader of aldehyde dehydrogenase attached to dihydrofolate reductase. Antibodies against Tom20 coprecipitated both the precursor of aldehyde dehydrogenase (pALDH) and of dihydrofolate reductase (pA-DHFR). Antibodies against Tom34 interacted only when the mature portion of aldehyde dehydrogenase was present. Similar import inhibition patterns were found when other precursor and chimeric constructs we investigated. When Tom34-green fluorescence protein was transfected to HeLa cells it was observed that Tom34 was found through out the cell. It is concluded from our observation that Tom34 is a cytosolic protein, whose role appeared to be to interact with mature portion of some preproteins and may keep them in an unfolded, import compatible state.     

Controlled rotation of biological microscopic objects using optical line tweezers

Controlled, continuous rotation of cells or intracellular objects was achieved using optical tweezers with an elliptic beam profile (line tweezers), which was generated by placing a cylindrical lens in the path of the trapping beam. By rotating the cylindrical lens, rotation of the elliptic trapping beam and hence of the object trapped therein was achieved. Compared to previously reported techniques for rotation of microscopic objects, this approach is much simpler, gives better utilization of available laser power and also allows much easier control of the trap beam profile. We have used this approach for rotation of biological objects varying in size from 2 to 40 m. At 25 mW trapping beam power at the object plane E. coli bacteria could be rotated at speeds approaching 10 Hz and an intracellular object (presumably a calcium oxalate crystal) trapped inside Elodea densa plant cell could be rotated with speeds of up to 4 Hz. To our knowledge, this is the first report for rotation of an intracellular object.     

In silico mutations and molecular dynamics studies on a winged bean chymotrypsin inhibitor protein

Winged bean chymotrypsin inhibitor (WCI) has an intruding residue Asn14 that plays a crucial role in stabilizing the reactive site loop conformation. This residue is found to be conserved in the Kunitz (STI) family of serine protease inhibitors. To understand the contribution of this scaffolding residue on the stability of the reactive site loop, it was mutated in silico to Gly, Ala, Ser, Thr, Leu and Val and molecular dynamics (MD) simulations were carried out on the mutants. The results of MD simulations reveal the conformational variability and range of motions possible for the reactive site loop of different mutants. The N-terminus side of the scissile bond, which is close to a beta-barrel, is conformationally less variable, while the C-terminus side, which is relatively far from any such secondary structural element, is more variable and needs stability through hydrogen-bonding interactions. The simulated structures of WCI and the mutants were docked in the peptide-binding groove of the cognate enzyme chymotrypsin and the ability to form standard hydrogen-bonding interactions at P3, P1 and P2' residues were compared. The results of the MD simulations coupled with docking studies indicate that hydrophobic residues like Leu and Val at the 14th position are disruptive for the integrity of the reactive site loop, whereas a residue like Thr, which can stabilize the C-terminus side of the scissile bond, can be predicted at this position. However, the size and charge of the Asn residue made it most suitable for the best maintenance of the integrity of the reactive site loop, explaining its conserved nature in the family.     

New genes with old modus operandi. The connection between supercoiling and partitioning of DNA in Escherichia coli

The process of partitioning bacterial sister chromosomes into daughter cells seems to be distinct from chromatid segregation during eukaryotic mitosis. In Escherichia coli, partitioning starts soon after initiation of replication, when the two newly replicated oriCs move from the cell centre to quarter positions within the cell. As replication proceeds, domains of the compact, supercoiled chromosome are locally decondensed ahead of the replication fork. The nascent daughter chromosomes are recondensed and moved apart through the concerted activities of topoisomerases and the SeqA (sequestration) and MukB (chromosome condensation) proteins, all of which modulate nucleoid superhelicity. Thus, genes involved in chromosome topology, once set aside as ‘red herrings’ in the search for ‘true’ partition functions, are again recognized as being important for chromosome partitioning in E. coli.     

Escherichia coli cell cycle control genes affect chromosome superhelicity

We have used ethidium bromide titration for direct measurement of the changes in the negative supercoiling of Escherichia coli chromosome caused by mutations inactivating the cell cycle functions mukB and seqA. The amounts of the intercalative agent required to relax the supercoiled chromosome in mukB and seqA mutants were lower and higher, respectively, than for the wild-type parent, confirming that these cell cycle genes modulate the topology of the E. coli chromosome. Plasmid superhelicity measured in these mutant strains showed similar effects albeit of reduced magnitude. As the effects of mukB and seqA mutations were not restricted to the chromosome alone, MukB and SeqA proteins possibly interact with factors involved in the maintenance of intracellular DNA topology. To our knowledge, this is the first direct demonstration of the influence of mukB and seqA genes on the superhelicity of the E. coli chromosome.     

Co-ordinated expression of multiple enzymes in different subcellular compartments in plants

A gene expression system designed for coordinated expression of multiple genes in plants and their targeting to specified subcellular locations was tested. A series of genes encoding polyproteins containing the tobacco vein mottling virus (TVMV) NIa proteinase along with two other reporter genes (those encoding the Escherichia coli acetate kinase (ACK) and Tn9 chloramphenicol acetyl transferase (CAT) enzymes) were assembled. The respective coding sequences of these genes were separated by a TVMV NIa proteinase recognition sequence. In addition, in some instances, chloroplast targeting information (a transit peptide (TP) from a pea rbcS gene) was incorporated into the polyprotein. We found that the NIa proteinase can be used to express, as individual polypeptides, the ACK and CAT proteins, and that these proteins retain enzymatic activity. Polyproteins with the structure TP-NIa-ACK-CAT or TP-ACK-CAT-NIa failed to yield chloroplast-localized ACK and CAT proteins, although the latter did give rise to a chloroplast-localized ACK-CAT polyprotein. These results indicate that the NIa proteinase acts in cis more rapidly than transport of proteins into the chloroplast, but that chloroplast localization can take place before complete processing of the polyprotein. Polyproteins with the structures ACK-NIa-TP-CAT and TP-ACK-NIa-TP-CAT yielded appropriately processed and targeted ACK and CAT. Our results show that subcellular localization signals can be effectively recognized in the context of a polyprotein, and they suggest an appropriate strategy for simultaneous engineering of multiple subcellular compartments in plants.     

Gas chromatographic–mass spectrometric determination of serum mexiletine concentration after derivatization with perfluorooctanoyl chloride, a new derivative

Mexiletine is an antiarrhythmic agent used in the treatment of ventricular arrhythmia. The drug has a narrow therapeutic window which necessitates monitoring its serum concentrations. We describe a gas chromatographic–mass spectrometric analysis of mexiletine using selected ion monitoring. Mexiletine was extracted from alkaline serum with dichloromethane and then derivatized with perfluorooctanoyl chloride. The derivatization reaction was completed in 20 min at 80°C. We used N-propylamphetamine as the internal standard. The ions monitored were m/z 122, 454 and 575 for the derivatized mexiletine and m/z 91, 118, 440 and 452 for the derivatized internal standard. The within-run precision at a serum mexiletine concentration of 1 mg/l was 1.9% (mean=0.98, S.D.=0.019 mg/l, n=7) and the between-run precision was 2.5% (mean=0.99, S.D.=0.025 mg/l, n=7). The assay was linear for serum mexiletine concentrations of 0.2 to 4 mg/l. The detection limit was 0.1 mg/l. The average recoveries of mexiletine and the internal standard were 80% and 84%, respectively at a mexiletine concentration of 1 mg/l. There was no carry over problem in our assay. We observed a good correlation between mexiletine concentrations measured by a reference laboratory (GC) and by our new GC–MS assay.     

Cross-talk between macrophages,smooth muscle cells,and endothelial cells in response to cigarette smoke: the effects on MMP2 and 9

The aim of the present study was to analyze the expression of sex-determining region Y-related high mobility group box 4 (SOX4) in non-small cell lung cancer (NSCLC) and its correlation with clinicopathologic characteristics, including the survival of NSCLC patients. To observe initially the expression status of SOX4 in lung squamous cell carcinoma and adenocarcinoma at gene expression omnibus. The expression of SOX4 mRNA and protein was examined in NSCLC tissues and normal lung tissues through real-time PCR and immunohistochemistry. Meanwhile, the relationship of SOX4 expression levels with clinical characteristics of 168 NSCLC patients was analyzed by immunohistochemistry. Univariate and multivariate analyses were performed to determine the association between SOX4 expression and prognosis of NSCLC patients. In our results, SOX4 expression was increased in NSCLC tissues compared with paired normal lung tissues in microarray data (GSE3268). SOX4 mRNA and protein expression were markedly higher in NSCLC tissues than in normal lung tissues (P = 0.001 and P = 0.001, respectively). Using immunohistochemistry, high levels of SOX4 protein were positively correlated with status of differentiated degree (high vs. middle, P = 0.004; high vs. low, P < 0.001), clinical stage (I–II vs. III–IV, P < 0.001), T classification (T1–T2 vs. T3–T4, P = 0.004), N classification (N0–N1 vs. N2–N3, P = 0.002), and M classification (M0 vs. M1, P = 0.011) in NSCLC. Moreover, the higher level of SOX4 expression was markedly correlated with poor overall survival in NSCLC patients (P < 0.001). Multivariate analysis suggested that increased SOX4 expression was a poor independent prognostic predictor for NSCLC patients (P = 0.002). In conclusion, SOX4 plays an important role on NSCLC progression and prognosis and may serve as a convictive prognostic biomarker for NSCLC patients.