Mechanism of ATP-dependent translocation of E.coli UvrD monomers along single-stranded DNA

Escherichia coli UvrD protein is a 3' to 5' SF1 DNA helicase involved in methyl-directed mismatch repair and nucleotide excision repair of DNA. Using stopped-flow methods we have examined the kinetic mechanism of translocation of UvrD monomers along single-stranded DNA (ssDNA) in vitro by monitoring the transient kinetics of arrival of protein at the 5'-end of the ssDNA. Arrival at the 5'-end was monitored by the effect of protein on the fluorescence intensity of fluorophores (Cy3 or fluorescein) attached to the 5'-end of a series of oligodeoxythymidylates varying in length from 16 to 124 nt. We find that UvrD monomers are capable of ATP-dependent translocation along ssDNA with a biased 3' to 5' directionality. Global non-linear least-squares analysis of the full kinetic time-courses in the presence of a protein trap to prevent rebinding of free protein to the DNA using the methods described in the accompanying paper enabled us to obtain quantitative estimates of the kinetic parameters for translocation. We find that UvrD monomers translocate in discrete steps with an average kinetic step-size, m=3.68(+/-0.03) nt step(-1), a translocation rate constant, kt=51.3(+/-0.6) steps s(-1), (macroscopic translocation rate, mkt=189.0(+/-0.7) nt s(-1)), with a processivity corresponding to an average translocation distance of 2400(+/-600) nt before dissociation (10 mM Tris-HCl (pH 8.3), 20 mM NaCl, 20% (v/v) glycerol, 25 degrees C). However, in spite of its ability to translocate rapidly and efficiently along ssDNA, a UvrD monomer is unable to unwind even an 18 bp duplex in vitro. DNA helicase activity in vitro requires a UvrD dimer that unwinds DNA with a similar kinetic step-size of 4-5 bp step(-1), but an approximately threefold slower unwinding rate of 68(+/-9) bp s(-1) under the same solution conditions, indicating that DNA unwinding activity requires more than the ability to simply translocate directionally along ss-DNA.     

Inhibition of Plasmodium falciparum cysteine proteases by the sugarcane cystatin CaneCPI-4

Malaria is a disease caused by Plasmodium parasites that affects hundreds of millions of people. Plasmodium proteases are involved in invasion, erythrocyte egress and degradation of host proteins. Falcipains are well-studied cysteine peptidases located in P. falciparum food vacuoles that participate in hemoglobin degradation. Cystatins are natural cysteine protease inhibitors that are implicated in a wide range of regulatory processes. Here, we report that a cystatin from sugarcane, CaneCPI-4, is selectively internalized into P. falciparum infected erythrocytes and is not processed by the parasite proteolytic machinery. Furthermore, we demonstrated the inhibition of P. falciparum cysteine proteases by CaneCPI-4, suggesting that it can exert inhibitory functions inside the parasites. The inhibition of the proteolytic activity of parasite cells is specific to this cystatin, as the addition of an anti-CaneCPI-4 antibody completely abolished the inhibition. We extended the studies to recombinant falcipain-2 and falcipain-3 and demonstrated that CaneCPI-4 strongly inhibits these enzymes, with IC₅₀ values of 12 nM and 42 nM, respectively. We also demonstrated that CaneCPI-4 decreased the hemozoin formation in the parasites, affecting the parasitemia. Taken together, this study identified a natural molecule as a potential antimalarial that specifically targets falcipains and also contributes to a better understanding of macromolecule acquisition by Plasmodium falciparum infected RBCs.     

Induction and removal of DNA damage in blood leukocytes of patients with type 2 diabetes mellitus undergoing hemodialysis

Type 2 diabetes mellitus (T2DM) is associated with a high production of reactive oxygen species, which may cause oxidative DNA damage. High levels of genomic damage have been associated with renal failure and hemodialysis. However, no information is available in the literature concerning the levels of DNA damage in T2DM individuals who are dependent on hemodialysis. This study used the comet assay to assess the levels of DNA damage before, immediately after and 48 h after the hemodialysis session in 25 patients with T2DM and in a group of 20 healthy individuals, selected according to mean age, sex and smoking habit. Our results showed increased levels of DNA damage in hemodialysis-dependent T2DM individuals (12.36 ± 8.04) when compared with healthy individuals (7.35 ± 7.41) (p = 0.014). Damage levels increased immediately after the hemodialysis session (19.76 ± 12.40) (p = 0.04), which suggests a possible action of pro-oxidative factors related to the therapy, with a genotoxic effect on cells. Results obtained 48 h after hemodialysis (6.44 ± 5.99) evidenced damage removal (p = 0.001), which may be suggestive of DNA repair.     

In vivo genotoxicity of the pyrethroid pesticide beta-cyfluthrin using the comet assay in the fish Bryconamericus iheringii

Environmental pollution by pesticide residues is a major environmental concern due to the extensive use of these substances in agriculture. The insecticide beta-cyfluthrin is a synthetic pyrethroid widely used in agricultural and other domestic activities. The aim of the present study was to assess the genotoxic effects of a sublethal exposure of the fish Bryconamericus iheringii (Characidae) to a commercial formulation of beta-cyfluthrin using the comet assay. Fish were exposed to sublethal concentrations (4.2 and 5.6 microg/L) of beta-cyfluthrin under static conditions during 24- and 48-h exposure periods. Fish in tap water were used as negative controls. Results obtained by the comet assay revealed genotoxic effects of the pyrethroid in the higher concentration and at the longer exposure period. The mean DNA damage index of fish exposed to 5.6 microg/L beta-cyfluthrin for 48 h was significantly higher (145.9 +/- 51.8) than in the control group (69.3 +/- 39.5). These findings indicate that native fish species might be at risk for genotoxic damage in waters contaminated with beta-cyfluthrin.     

A patient presenting a 22q13 deletion associated with an apparently balanced translocation t(16;22): An illustrative case in the investigation of patients with low ARSA activity

A 10-year-old speechless, mentally deficient male, with low arylsulfatase A (ARSA) activity, and presumably, methachromatic leukodystrophy, underwent genetic evaluation. As the clinical picture was not compatible with this diagnosisan ARSA gene and chromosome analysis were performed, showing the presence of a pseudodeficiency ARSA allele and a de novo apparently balanced t(16;22)(p11.2;q13) translocation. A deletion on the long arm of chromosome 22 encompassing the ARSA gene, as shown by FISH and array-CGH, indicated a 22q13 deletion syndrome. This case illustrates the importance of detailed cytogenetic investigation in patients presenting low arylsulfatase A activity and atypical/unspecific clinical features.     

Combining ability of summer-squash lines with different degrees of parthenocarpy and PRSV-W resistance

The aim was to assess heterosis in a set of 16 summer-squash hybrids, and evaluate the combining capacity of the respective parental lines, which differed as to the degree of parthenocarpy and resistance to PRSV-W (Papaya Ringspot Virus-Watermelon strain). The hybrids were obtained using a partial diallel cross design (4 × 4). The lines of parental group I were 1 = ABX-037G-77-03-05-01-01-bulk, 2 = ABX-037G-77-03-05-03-10-bulk, 3 = ABX-037G-77-03-05-01-04-bulk and 4 = ABX-037G-77-03-05-05-01-bulk, and of group II, 1' = ABX-037G-77-03-05-04-08-bulk, 2' = ABX-037G-77-03-05-02-11-bulk, 3' = Clarice and 4' = Caserta. The 16 hybrids and eight parental lines were evaluated for PRSV-W resistance, parthenocarpic expression and yield in randomized complete-block designs, with three replications. Parthenocarpy and the resistance to PRSV-W were rated by means of a scale from 1 to 5, where 1 = non-parthenocarpic or high resistance to PRSV-W, and 5 = parthenocarpic or high susceptibility to PRSV-W. Both additive and non-additive gene effects were important in the expression of parthenocarpy and resistance to PRSV-W. Whereas estimates of heterosis in parthenocarpy usually tended towards a higher degree, resistance to PRSV-W was towards higher susceptibility. At least one F(1) hybrid was identified with a satisfactory degree of parthenocarpy, resistance to PRSV-W and high fruit-yield.     

Self-assembly of Escherichia coli MutL and its complexes with DNA

The Escherichia coli MutL protein regulates the activity of several enzymes, including MutS, MutH, and UvrD, during methyl-directed mismatch repair of DNA. We have investigated the self-association properties of MutL and its binding to DNA using analytical sedimentation velocity and equilibrium. Self-association of MutL is quite sensitive to solution conditions. At 25 °C in Tris at pH 8.3, MutL assembles into a heterogeneous mixture of large multimers. In the presence of potassium phosphate at pH 7.4, MutL forms primarily stable dimers, with the higher-order assembly states suppressed. The weight-average sedimentation coefficient of the MutL dimer in this buffer ( ?s(20,w)) is equal to 5.20 ± 0.08 S, suggesting a highly asymmetric dimer (f/f(o) = 1.58 ± 0.02). Upon binding the nonhydrolyzable ATP analogue, AMPPNP/Mg(2+), the MutL dimer becomes more compact ( ?s(20,w) = 5.71 ± 0.08 S; f/f(o) = 1.45 ± 0.02), probably reflecting reorganization of the N-terminal ATPase domains. A MutL dimer binds to an 18 bp duplex with a 3'-(dT(20)) single-stranded flanking region, with apparent affinity in the micromolar range. AMPPNP binding to MutL increases its affinity for DNA by a factor of ～10. These results indicate that the presence of phosphate minimizes further MutL oligomerization beyond a dimer and that differences in solution conditions likely explain apparent discrepancies in previous studies of MutL assembly.