A fluorescent quantum dot conjugate to probe the interaction of Enterolobium contortisiliquum trypsin inhibitor with cancer cells.

Serine proteases play crucial biological roles and have their activity controlled by inhibitors, such as the EcTI, a serine protease inhibitor purified from Enterolobium contortisiliquum seeds, which has anticancer activity. This study aimed to conjugate EcTI with quantum dots (QDs), fluorophores with outstanding optical properties, and investigate the interaction of QDs-EcTI nanoprobe with cancer cells. The conjugation was evaluated by fluorescence correlation spectroscopy (FCS) and fluorescence microplate assay (FMA). EcTI inhibitory activity after interaction with QDs was also analyzed. From FCS, the conjugate presented a hydrodynamic diameter about 4× greater than bare QDs, suggesting a successful conjugation. This was supported by FMA, which showed a relative fluorescence intensity of ca. 3815% for the nanosystem, concerning bare QDs or EcTI alone. The EcTI inhibitory activity remained intact after its interaction with QDs. From flow cytometry analyses, approximately 62% of MDA-MB-231 and 90% of HeLa cells were labeled with the QD-EcTI conjugate, suggesting that their membranes have different protease levels to which EcTI exhibits an affinity. Concluding, the QD-EcTI represents a valuable nanotool to study the interaction of this inhibitor with cancer cells using fluorescence-based techniques with the potential to unravel the intricate dynamics of interplays between proteases and inhibitors in cancer biology.

Bauhinia monandra leaf lectin (BmoLL) conjugated with quantum dots as fluorescent nanoprobes for biological studies: application to red blood cells.

Carbohydrates perform important physiological functions in eukaryotic and prokaryotic cells. Indeed, alterations in glycan patterns may be associated with disorders. The analysis of these sugars can be reached using nanoprobes composed by lectins associated with fluorescent nanoparticles. This study reports the conjugation of a galactose-binding lectin (BmoLL) isolated from Bauhinia monandra leaves with quantum dots (QDs) by adsorption. QDs-BmoLL conjugates showed bright fluorescence and the hemagglutination assay revealed that the lectin preserved its carbohydrate-binding ability after the conjugation. To evaluate the efficiency/specificity of the bioconjugate, ABO human red blood cells (RBCs) were used as biological models and the labeling was analyzed by flow cytometry. Among ABO blood groups, higher labeling (71.7 ± 5.9%) was detected for B-type RBCs, whose antigens have galactose in their structure. The specificity of labeling was confirmed since A- and O-types RBCs incubated with QDs-BmoLL, as well as B-type cells incubated with previously galactose-inhibited conjugates, were labeled below 6%. In AB-type RBCs, which simultaneously have B and A (N-acetylgalactosamine) antigens on their membrane, the labeling was ca. 14.1 ± 4.8%. Therefore, a successful conjugation was reached and QDs-BmoLL conjugates can be considered promising fluorescent nanoprobes for biological investigations.

Evaluating glucose and mannose profiles in Candida species using quantum dots conjugated with Cramoll lectin as fluorescent nanoprobes.

Glycoconjugates found on cell walls of Candida species are fundamental for their pathogenicity. Laborious techniques have been employed to investigate the sugar composition of these microorganisms. Herein, we prepared a nanotool, based on the fluorescence of quantum dots (QDs) combined with the specificity of Cramoll lectin, to evaluate glucose/mannose profiles on three Candida species. The QDs-Cramoll conjugates presented specificity and bright fluorescence emission. The lectin preserved its biological activity after the conjugation process mediated by adsorption interactions. The labeling of Candida species was analyzed by fluorescence microscopy and quantified by flow cytometry. Morphological analyses of yeasts labeled with QDs-Cramoll conjugates indicated that C. glabrata (2.7 µm) was smaller when compared to C. albicans (4.0 µm) and C. parapsilosis sensu stricto (3.8 µm). Also, C. parapsilosis population was heterogeneous, presenting rod-shaped blastoconidia. More than 90% of cells of the three species were labeled by conjugates. Inhibition and saturation assays indicated that C. parapsilosis had a higher content of exposed glucose/mannose than the other two species. Therefore, QDs-Cramoll conjugates demonstrated to be effective fluorescent nanoprobes for evaluation of glucose/mannose constitution on the cell walls of fungal species frequently involved in candidiasis.