Docking Prediction, Antifungal Activity, Anti-Biofilm Effects on Candida spp., and Toxicity against Human Cells of Cinnamaldehyde.

OBJECTIVE: This study evaluated the antifungal activity of cinnamaldehyde on Candida spp. In vitro and in situ assays were carried out to test cinnamaldehyde for its anti-Candida effects, antibiofilm activity, effects on fungal micromorphology, antioxidant activity, and toxicity on keratinocytes and human erythrocytes. Statistical analysis was performed considering α = 5%. RESULTS: The minimum inhibitory concentration (MIC) and minimum fungicidal concentration (MFC) of cinnamaldehyde ranged from 18.91 µM to 37.83 µM. MIC values did not change in the presence of 0.8 M sorbitol, whereas an 8-fold increase was observed in the presence of ergosterol, suggesting that cinnamaldehyde may act on the cell membrane, which was subsequently confirmed by docking analysis. The action of cinnamaldehyde likely includes binding to enzymes involved in the formation of the cytoplasmic membrane in yeast cells. Cinnamaldehyde-treated microcultures showed impaired cellular development, with an expression of rare pseudo-hyphae and absence of chlamydoconidia. Cinnamaldehyde reduced biofilm adherence by 64.52% to 33.75% (p < 0.0001) at low concentrations (378.3-151.3 µM). Cinnamaldehyde did not show antioxidant properties. CONCLUSIONS: Cinnamaldehyde showed fungicidal activity through a mechanism of action likely related to ergosterol complexation; it was non-cytotoxic to keratinocytes and human erythrocytes and showed no antioxidant activity.

SB-83, a 2-Amino-thiophene derivative orally bioavailable candidate for the leishmaniasis treatment.

Leishmaniasis, affecting more than 12 million people worldwide has become a severe public-health problem. The therapeutic arsenal against leishmaniasis is mainly administered by parenteral route; it is toxic, expensive, and associated with recurrence risk. The need for further therapeutic compounds research is pressing. In previous studies, we demonstrated the antileishmanial activities of ten 2-amino-thiophene derivatives, which evidenced the action of a compound, called SB-83, having expressive antileishmania activity in an in vitro infection model. In the present work, we describe preclinical studies of the thiophenic derivative SB-83, such as acute toxicity, genotoxicity, in vivo oral efficacy in a murine model, and in vitro antileishmanial activity against an L. amazonensis SbIII-resistant strain. Determining acute preclinical toxicity, the LD50 of SB-83 was estimated at 2500 mg/kg orally, with few behavioral changes in Swiss mice. Further, treatment with 2000 mg/kg of SB-83 did not induce in vivo genotoxic activity in the peripheral blood micronucleus assay. In 7 weeks of oral treatment, SB-83 reduced paw lesion size in L. amazonensis infected mice by 52.47 ± 5.32%, and decreased the parasite load of the popliteal lymph node and spleen at the highest dose tested (200 mg/kg) respectively by 42.57 ± 3.14%, and 100%, without presenting weight change or other changes of clinical importance in the biochemical and hematological profiles. The treatment of promastigotes and intracellular amastigotes of SbIII sensitive and resistant strains with SB-83 did not produce differences in antileishmania activity, which suggests no cross-resistance. Thus, this work demonstrated that SB-83 has potential as a new active drug candidate even when orally administered, which may become a new therapeutic alternative for the treatment of leishmaniasis.

New thiophene-acridine compounds: Synthesis, antileishmanial activity, DNA binding, chemometric, and molecular docking studies.

In this study, we synthesized eight new compounds containing the 2-amino-cycloalkyl[b]thiophene and acridine moieties (ACT01 and ACS01 -ACS07 ). None tested compounds presented human erythrocyte cytotoxicity. The new compounds presented antipromastigote activity, where ACS01 and ACS02 derivatives presented significant antileishmanial activity, with better performance than the reference drugs (tri and pentavalent antimonials), with respective IC50 values of 9.60 ± 3.19 and 10.95 ± 3.96 µm. Additionally, these two derivatives were effective against antimony-resistant Leishmania (Leishmania) amazonensis strains. In addition, binding and fragmentation DNA assays were performed. It was observed that the antileishmanial activity of ACS01 is not associated with DNA fragmentation of the promastigote forms. However, it interacted with DNA with a binding constant of 104  m-1 . In partial least-squares studies, it was observed that the most active compounds (ACS01 and ACS02 ) showed lower values of amphiphilic moment descriptor, but there was a correlation between the lipophilicity of the molecules and antileishmanial activity. Furthermore, the docking molecular studies showed interactions between thiophene-acridine derivatives and the active site of pyruvate kinase enzyme with the major contribution of asparagine 152 residue for the interaction with thiophene moiety. Thus, the results suggested that the new thiophene-acridine derivatives are promising molecules as potential drug candidates.