Intracellular delivery of quantum dot-protein cargos mediated by cell penetrating peptides

We utilize cell penetrating peptide functionalized QDs as specific vectors for the intracellular delivery of model fluorescent protein cargos. Multiple copies of two structurally diverse fluorescent proteins, the 27 kDa monomeric yellow fluorescent protein and the 240 kDa multichromophore b-phycoerythrin complex, were attached to QDs using either metal-affinity driven self-assembly or biotin-Streptavidin binding, respectively. Cellular uptake of these complexes was found to depend on the additional presence of cell-penetrating peptides within the QD-protein conjugates. Once inside the cells, the QD conjugates were mostly distributed within endolysosomal compartments, indicating that intracellular delivery of both QD assemblies was primarily driven by endocytotic uptake. Cellular microinjection of QD-fluorescent protein assemblies was also utilized as an alternate delivery strategy that could bypass the endocytic pathway. Simultaneous signals from both the QDs and the fluorescent proteins allowed verification of their colocalization and conjugate integrity upon delivery inside live cells. Due to their intrinsic fluorescence properties, this class of proteins provides a unique tool to test the ability of QDs functionalized with cell penetrating peptides to mediate the intracellular delivery of both small and large size protein cargos. Use of QD-peptide/fluorescent protein vectors may make powerful tools for understanding the mechanisms of nanoparticle-mediated drug delivery.     

Activity and stability of catalase in blood and tissues of normal and acatalasemic mice

Catalase activity in blood, liver, and kidney of a mutant strain Cs^b has been found to be decreased as compared to the level in normal mice. However, the extent of the reduction largely depends on the conditions used for activity determination, in particular, temperature and duration of the incubation period. In liver, this effect is most pronounced, the observed activity in mutants varying between 21 and 85% of the normal level. This dependence on the assay conditions is mainly due to the unusual heat lability of the variant enzyme, which undergoes rapid inactivation when incubated at 37 C.     

A specific interaction of small molecule entry inhibitors with the envelope glycoprotein complex of the Junín hemorrhagic fever arenavirus

Arenaviruses are responsible for acute hemorrhagic fevers worldwide and are recognized to pose significant threats to public health and biodefense. Small molecule compounds have recently been discovered that inhibit arenavirus entry and protect against lethal infection in animal models. These chemically distinct inhibitors act on the tripartite envelope glycoprotein (GPC) through its unusual stable signal peptide subunit to stabilize the complex against pH-induced activation of membrane fusion in the endosome. Here, we report the production and characterization of the intact transmembrane GPC complex of Junín arenavirus and its interaction with these inhibitors. The solubilized GPC is antigenically indistinguishable from the native protein and forms a homogeneous trimer in solution. When reconstituted into a lipid bilayer, the purified complex interacts specifically with its cell-surface receptor transferrin receptor-1. We show that small molecule entry inhibitors specific to New World or Old World arenaviruses bind to the membrane-associated GPC complex in accordance with their respective species selectivities and with dissociation constants comparable with concentrations that inhibit GPC-mediated membrane fusion. Furthermore, competitive binding studies reveal that these chemically distinct inhibitors share a common binding pocket on GPC. In conjunction with previous genetic studies, these findings identify the pH-sensing interface of GPC as a highly vulnerable target for antiviral intervention. This work expands our mechanistic understanding of arenavirus entry and provides a foundation to guide the development of small molecule compounds for the treatment of arenavirus hemorrhagic fevers.     

Association of Serum Levels of Iron,Copper, and Zinc,and Inflammatory Markers with Bacteriological Sputum Conversion During Tuberculosis Treatment

Iron, copper, and zinc are key micronutrients that play an important role in the immune response to Mycobacterium tuberculosis. The present study aimed to evaluate the association between serum levels of those micronutrients, inflammatory markers, and the smear and culture conversion of M. tuberculosis during 60 days of tuberculosis treatment. Seventy-five male patients with pulmonary tuberculosis (mean age, 40.0?±?10.7 years) were evaluated at baseline and again at 30 and 60 days of tuberculosis treatment. Serum levels of iron, copper, zinc, albumin, globulin, C-reactive protein, and hemoglobin, and smear and cultures for M. tuberculosis in sputum samples were analyzed. Compared to healthy subjects, at baseline, patients with PTB had lower serum iron levels, higher copper levels and copper/zinc ratio, and similar zinc levels. During the tuberculosis treatment, no significant changes in the serum levels of iron, zinc, and copper/zinc were observed. Lower serum copper levels were associated with bacteriological conversion in tuberculosis treatment (tuberculosis-negative) at 30 days but not at 60 days (tuberculosis-positive). C-reactive protein levels and the C-reactive protein/albumin ratio were lower in tuberculosis-negative patients than in tuberculosis-positive patients at 30 and 60 days after treatment. Albumin and hemoglobin levels and the albumin/globulin ratio in patients with pulmonary tuberculosis increased during the study period, regardless of the bacteriological results. High serum globulin levels did not change among pulmonary tuberculosis patients during the study. Serum copper levels and the C-reactive protein/albumin ratio may be important parameters to evaluate the persistence of non-conversion after 60 days of tuberculosis treatment, and they may serve as predictors for relapse after successful treatment.     

Contribution of the P2X7 1513A/C loss-of-function polymorphism to extrapulmonary tuberculosis susceptibility in Tunisian populations

The P2X7 receptor has been found to be linked to an increased risk for tuberculosis in some populations. In this study, we investigate whether the P2X7 receptor plays a role in increasing susceptibility to tuberculosis in Tunisia. We examined two 1513A/C and -762T/C polymorphisms at the P2X7 receptor in 168 patients with pulmonary TB (pTB), 55 patients with extrapulmonary TB (epTB) and 150 blood donors from Tunisia. Genotyping of 1513A/C and -762T/C polymorphisms was performed in purified genomic DNA using PCR-restriction fragment length polymorphism and allele-specific PCR, respectively. The 1513C, CC and AC loss-of-function allele and genotypes were overrepresented in the epTB group compared with the control group (45% vs. 17%, P=10(-8) ; 24% vs. 4%, P=3 × 10(-7) ; 42% vs. 27%, P=10(-3) , respectively). Additionally, they were associated with 3.83-, 11.86- and 3.15-fold risks of developing this clinical tuberculosis form, respectively. No associations between the -762T/C polymorphism and tuberculosis disease, as well as disease anatomic location were observed. Collectively, our results suggest that the P2X7 1513A/C loss-of-function polymorphism may contribute to susceptibility to epTB in Tunisian populations.     

Association of TNF-α and IL-10 polymorphisms with tuberculosis in Tunisian populations

Cytokine Th1/Th2 balance is known to play a key role in controlling Mycobacterium tuberculosis infection. Based upon the functional role of the TNF-α [-308 G(low)?→?A(high) (rs1800629)] and IL-10 [-1082 A(low)?→?G(high) (rs1800870), -819 T(low)?→?C(high) (rs1800871) and -592 A(low)?→?C(high) (rs1800872)] single nucleotide polymorphisms (SNPs) on production levels, we genotyped 76 patients with pulmonary tuberculosis (TB) (pTB), 55 patients with extrapulmonary TB (epTB) and 95 healthy blood donors by polymerase chain reaction fragment length polymorphism (PCR-RFLP). We observed that -308 A allele was associated with increased risk susceptibility to epTB (OR?=?1.96; 95% CI, 1.04-3.71; P?=?0.024). The -1082 AG genotype was significantly associated with increased risk development of epTB (odds ratio [OR]?=?3.69; 95% confidence intervals [CI], 1.73-7.92; P corrected for the number of genotypes [Pc]?=?0.0003). By contrast, -1082 AA genotype appeared to be associated with resistance to pTB (OR?=?0.38; 95% CI, 0.19-0.74; Pc?=?0.006) and epTB (OR?=?0.22; 95% CI, 0.1-0.48; Pc?=?0.00006). High-producer IL-10 GCC haplotype seemed to be associated with 2.11-fold (95% CI, 1.28-3.46; Pc?=?0.003) and 2.57-fold (95% CI, 1.5-4.4; Pc?=?0.0006) increased susceptibility to pTB and epTB, respectively. Combination of TNF-α/IL-10 high producer genotypes was associated with increased 3.13-fold (95% CI, 1.23-8.05; Pc?=?0.028) susceptibility to epTB. However, combined TNF-α/IL-10 low producer genotypes appeared to have protect effect to pTB (OR?=?0.44, 95% CI, 0.21-0.89; Pc?=?0.04) and epTB (OR?=?0.26, 95% CI, 0.1-0.62; Pc?=?0.0028). Collectively, our results showed that analysed SNPs in the TNF-α and IL-10 gene polymorphisms play key role in susceptibility to or protection against TB development in Tunisian populations.     

Toxicities effects of pharmaceutical, olive mill and textile wastewaters before and after degradation by Pseudomonas putida mt-2

Background  

Removal of numerous classes of chemical pollutants from the industrial wastewater such as textile, pharmaceutical and olive mill using conventional wastewater treatment, is incomplete and several studies suggested that improvement of this situation would require the application of biological treatment techniques. Dyes, polyphenols and drugs are an environmental pollutants extremely toxics to plants and other living organisms including humans. These effluents were previously treated by Pseudomonas putida. The main of this work was to evaluate the in vivo toxicity of the three wastewaters.     

Cyclooxygenase-2-issued prostaglandin e(2) enhances the production of endogenous IL-10, which down-regulates dendritic cell functions

PGE(2) is a well-known immunomodulator produced in the immune response by APCs, such as dendritic cells (DCs), the most potent APC of the immune system. We investigated the PGE(2) biosynthetic capacity of bone marrow-derived DC (BM-DC) and the effects of PG on the APC. We observed that BM-DC produce PGE(2) and other proinflammatory mediators, such as leukotriene B(4) and NO, after LPS exposure. Constitutively present in BM-DC, cyclooxygenase (COX)-1 did not contribute significantly to the total pool of PGE(2) compared with the LPS-induced COX-2-produced PGE(2). Treatment of BM-DC with exogenous PGE(2) induced the production of large amounts of IL-10 and less IL-12p70. In addition, selective inhibition of COX-2, but not COX-1, was followed by significant decrements in PGE(2) and IL-10, a concomitant restoration of IL-12 production, and an enhancement of DC stimulatory potential. In contrast, we found no demonstrable role for leukotriene B(4) or NO. In view of the potential of PGE(2) to stimulate IL-10, we examined the possibility that the suppressive effect of PGE(2) is mediated via IL-10. We found that exogenous IL-10 inhibits IL-12p70 production in the presence of NS-398, a COX-2 selective inhibitor, while the inhibitory effects of PGE(2) were totally reversed by anti-IL-10. We conclude that COX-2-mediated PGE(2) up-regulates IL-10, which down-regulates IL-12 production and the APC function of BM-DC.