Visceral leishmaniasis (VL) is a vector-borne disease affecting humans and domestic animals that constitutes a serious public health problem in many countries. Although many antigens have been examined so far as protein- or DNA-based vaccines, none of them conferred complete long-term protection. The use of the lizard non-pathogenic to humans Leishmania (L.) tarentolae species as a live vaccine vector to deliver specific Leishmania antigens is a recent approach that needs to be explored further. In this study, we evaluated the effectiveness of live vaccination in protecting BALB/c mice against L. infantum infection using prime-boost regimens, namely Live/Live and DNA/Live. As a live vaccine, we used recombinant L. tarentolae expressing the L. donovani A2 antigen along with cysteine proteinases (CPA and CPB without its unusual C-terminal extension (CPB-CTE)) as a tri-fusion gene. For DNA priming, the tri-fusion gene was encoded in pcDNA formulated with cationic solid lipid nanoparticles (cSLN) acting as an adjuvant. At different time points post-challenge, parasite burden and histopathological changes as well as humoral and cellular immune responses were assessed. Our results showed that immunization with both prime-boost A2-CPA-CPB-CTE-recombinant L. tarentolae protects BALB/c mice against L. infantum challenge. This protective immunity is associated with a Th1-type immune response due to high levels of IFN-γ production prior and after challenge and with lower levels of IL-10 production after challenge, leading to a significantly higher IFN-γ/IL-10 ratio compared to the control groups. Moreover, this immunization elicited high IgG1 and IgG2a humoral immune responses. Protection in mice was also correlated with a high nitric oxide production and low parasite burden. Altogether, these results indicate the promise of the A2-CPA-CPB-CTE-recombinant L. tarentolae as a safe live vaccine candidate against VL.
AIM:To examine the frequency of antibiotic resistance in Iranian Helicobacter pylori (H pylori) strains isolated from two major hospitals in Tehran.
METHODS:Examination of antibiotic resistance was performed on 120 strains by modified disc diffusion test and PCR-RFLP methods. In addition, in order to identify the possible causes of the therapeutic failure in Iran, we also determined the resistance of these strains to the most commonly used antibiotics (metronidazole, amoxicillin, and tetracycline) by modified disc diffusion test.
RESULTS:According to modified disc diffusion test, 1.6% of the studied strains were resistant to amoxicillin, 16.7% to clarithromycin, 57.5% to metronidazole, and there was no resistance to tetracycline. Of the clarithromycin resistant strains, 73.68% had the A2143G mutation in the 23S rRNA gene, 21.05% A2142C, and 5.26% A2142G. None of the sensitive strains were positive for any of the three point mutations. Of the metronidazole resistant strains, deletion in rdxA gene was studied and detected in only 6 (5%) of the antibiogram-based resistant strains. None of the metronidazole sensitive strains possessed rdxA gene deletion.
CONCLUSION:These data show that despite the fact that clarithromycin has not yet been introduced to the Iranian drug market as a generic drug, nearly 20% rate of resistance alerts toward the frequency of macrolide resistance strains, which may be due to the widespread prescription of erythromycin in Iran. rdxA gene inactivation, if present in Iranian H pylori strains, may be due to other genetic defects rather than gene deletion.
Leishmaniasis caused by protozoan parasites of the genus Leishmania. Intracellular infections treatment such as leishmaniasis is frequently hampered by limited access of drugs to infected cells. Moreover, most of the current drugs are confined to some toxic compounds, and there are increasing incidences of development of drug resistance. Hence, production of a new antileishmanial compound is crucial. Paromomycin sulphate (PM) is a promising antileishmanial drug. One strategy to improve drug effectiveness is to use appropriate delivery systems. Solid lipid nanoparticle (SLN) is as an excellent substitute delivery system to other colloidal carrier. In the present study, PM was loaded in solid lipid nanoparticles (PM-SLN) and the in vivo efficacy was studied against Leishmania (L.) major-infected BALB/c mice. For this reason, the footpad swelling was measured and real-time PCR was performed to quantify the parasite load after infectious challenge. The level of cytokines including interleukin-4 (IL-4) and gamma interferon (IFN-γ) and nitric oxide was evaluated. Altogether, this study showed that the PM-SLN formulation is a safe compound and SLN in PM-SLN compound is effective for treatment of leishmaniasis by improving the effectiveness of PM in killing the parasite and switching towards Th1 response.
-Purpose. Leishmaniasis is a major health problem in many tropical and sub-tropical countries and development of a safe and easily-available vaccine has high priority. Although several antigens potentially capable of inducing protective immunity have been studied, in the absence of pharmaceutical industry interest they have remained as fine publications only. Amongst them, Cathepsin L-like cysteine proteinases (CPs) have received considerable attention and type I and II CPs have been used in a heterologous prime-boost vaccination regime for experimental visceral leishmaniasis in dogs. Due to the promising results of the mentioned vaccination regime, we aimed to evaluate cationic solid lipid nanoparticles (cSLNs) for in vitro delivery of cpa, cpb and cpb CTE intended to be used as a cocktail DNA vaccine in our forthcoming studies. Methods: cSLNs were formulated of cetyl palmitate, cholesterol, DOTAP and Tween 80 via melt emulsification method followed by high shear homogenization. Different formulations were prepared by anchoring pDNAs on the surface of cSLNs via charge interaction. The formulations were characterized according to their size and zeta potential as well as pDNA integrity and stability against DNase I treatment. Lipoplexes' cytotoxicity was investigated on COS-7 cells by MTT test. The effect of the DOTAP:pDNA ratio on protection ability and cytotoxicity was also studied. In vitro transfection efficiency was qualified by florescent microscopy and quantified using flow cytometry technique. Results: cSLN-pDNA complexes were formulated with suitable size and zeta potential. Efficiency/cytotoxicity ratio of cSLN-pDNAs formulations was comparable to linear PEI-25kDa-pDNAs polyplexes while exhibiting significantly lower cytotoxicity. Conclusion: Tested formulations were able to deliver immunogenic CP genes efficiently. This data proves the ability of this system as a promising DNA vaccine carrier for leishmaniasis to cover the main drawback of naked pDNA delivery that is rapidly elimination from the circulation.
Leishmaniasis is a parasitic disease transmitted through the bite of an infected phlebotomine sand fly and caused by protozoan parasites of the genus Leishmania. There is no available vaccine for leishmaniasis in human, and the current chemotherapy approaches are hampered by different clinical problems. Most of available drugs are confined to a limited number of toxic chemical compounds, which some parasite strains have evolved drug resistance against. Hence, drug discovery and production of a new anti leishmanial compound is essential. One promising strategy is using the nanoparticle delivery systems with the aim of accelerating the efficacy of the available treatments. In the present study, paromomycin sulfate (PM) was formulated in solid lipid nanoparticles (SLN) and the in vivo efficacy was investigated against Leishmania tropica in BALB/c mice model. To do so, the increase in footpad thickness was measured and real-time PCR was performed to quantify the parasite load after infectious challenge. The level of nitric oxide and cytokines including interleukin-4 (IL-4) and gamma interferon (IFN -γ) were assessed. Altogether, the results show that PM loaded into SLN is significantly more effective than PM alone in inhibiting the parasite propagation and switching towards Th1 response.
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