36 research outputs found
Assessment of liposome disruption to quantify drug delivery in vitro
Efficient liposome disruption inside the cells is a key for success with any type of drug delivery system. The efficacy of drug delivery is currently evaluated by direct visualization of labeled liposomes internalized by cells, not addressing objectively the release and distribution of the drug. Here, we propose a novel method to easily assess liposome disruption and drug release into the cytoplasm. We propose the encapsulation of the cationic dye Hoechst 34,580 to detect an increase in blue fluorescence due to its specific binding to negatively charged DNA. For that, the dye needs to be released inside the cell and translocated to the nucleus. The present approach correlates the intensity of detected fluorescent dye with liposome disruption and consequently assesses drug delivery within the cells.Eugénia Nogueira (SFRH/BD/81269/2011), Célia F. Cruz (SFRH/BD/
100927/2014) and Ana Loureiro (SFRH/BD/81479/2011) hold scholarships
from Fundação para a Ciência e a Tecnologia (FCT). This study
was funded by the European Union Seventh Framework Programme
(FP7/2007-2013) under grant agreement NMP4-LA-2009-228827
NANOFOL. This study was also supported by FEDER through POFC –
COMPETE and by national funds from FCT through the project PEst-UID/
BIA/4050/2013 and the strategic funding of ID/BIO/04469/2013 unit.We
thank the Immuno-haemotherapy Department of Hospital de São João
(Porto, Portugal) for providing buffy coats from healthy volunteers
Crystal structures of type-II inositol polyphosphate 5-phosphatase INPP5B with synthetic inositol polyphosphate surrogates reveal new mechanistic insights for the inositol 5-phosphatase family
The inositol polyphosphate 5-phosphatase
INPP5B hydrolyzes the
5-phosphate group from water- and lipid-soluble signaling messengers.
Two synthetic benzene and biphenyl polyphosphates (BzP/BiPhPs), simplified
surrogates of inositol phosphates and phospholipid headgroups, were
identified by thermodynamic studies as potent INPP5B ligands. The
X-ray structure of the complex between INPP5B and biphenyl 3,3′,4,4′,5,5′-hexakisphosphate
[BiPh(3,3′,4,4′,5,5′)P<sub>6</sub>, IC<sub>50</sub> 5.5 μM] was determined at 2.89 Å resolution. One inhibitor
pole locates in the phospholipid headgroup binding site and the second
solvent-exposed ring binds to the His-Tag of another INPP5B molecule,
while a molecule of inorganic phosphate is also present in the active
site. Benzene 1,2,3-trisphosphate [Bz(1,2,3)P<sub>3</sub>] [one ring
of BiPh(3,3′,4,4′,5,5′)P<sub>6</sub>] inhibits
INPP5B ca. 6-fold less potently. Co-crystallization with benzene 1,2,4,5-tetrakisphosphate
[Bz(1,2,4,5)P<sub>4</sub>, IC<sub>50</sub> = 6.3 μM] yielded
a structure refined at 2.9 Å resolution. Conserved residues among
the 5-phosphatase family mediate interactions with Bz(1,2,4,5)P<sub>4</sub> and BiPh(3,3′,4,4′,5,5′)P<sub>6</sub> similar to those with the polar groups present in positions 1, 4,
5, and 6 on the inositol ring of the substrate. 5-Phosphatase specificity
most likely resides in the variable zone located close to the 2- and
3-positions of the inositol ring, offering insights to inhibitor design.
We propose that the inorganic phosphate present in the INPP5B–BiPh(3,3′,4,4′,5,5′)P<sub>6</sub> complex mimics the postcleavage substrate 5-phosphate released
by INPP5B in the catalytic site, allowing elucidation of two new key
features in the catalytic mechanism proposed for the family of phosphoinositide
5-phosphatases: first, the involvement of the conserved Arg-451 in
the interaction with the 5-phosphate and second, identification of
the water molecule that initiates 5-phosphate hydrolysis. Our model
also has implications for the proposed “moving metal”
mechanism
Dicationic Alkylammonium Bromide Gemini Surfactants. Membrane Perturbation and Skin Irritation
Dicationic alkylammonium bromide gemini surfactants represent a class of amphiphiles potentially effective as skin permeation enhancers. However, only a limited number of studies has been dedicated to the evaluation of the respective cytotoxicity, and none directed to skin irritation endpoints. Supported on a cell viability study, the cytotoxicity of gemini surfactants of variable tail and spacer length was assessed. For this purpose, keratinocyte cells from human skin (NCTC 2544 cell line), frequently used as a model for skin irritation, were employed. The impact of the different gemini surfactants on the permeability and morphology of model vesicles was additionally investigated by measuring the leakage of calcein fluorescent dye and analyzing the NMR spectra of 31P, respectively. Detail on the interaction of gemini molecules with model membranes was also provided by a systematic differential scanning calorimetry (DSC) and molecular dynamics (MD) simulation. An irreversible impact on the viability of the NCTC 2544 cell line was observed for gemini concentrations higher than 25 mM, while no cytotoxicity was found for any of the surfactants in a concentration range up to 10 mM. A higher cytotoxicity was also found for gemini surfactants presenting longer spacer and shorter tails. The same trend was obtained in the calorimetric and permeability studies, with the gemini of longest spacer promoting the highest degree of membrane destabilization. Additional structural and dynamical characterization of the various systems, obtained by 31P NMR and MD, provide some insight on the relationship between the architecture of gemini surfactants and the respective perturbation mechanism
Structural Basis for Phosphoinositide Substrate Recognition, Catalysis, and Membrane Interactions in Human Inositol Polyphosphate 5 Phosphatases
SummarySHIP2, OCRL, and INPP5B belong to inositol polyphosphate 5-phophatase subfamilies involved in insulin regulation and Lowes syndrome. The structural basis for membrane recognition, substrate specificity, and regulation of inositol polyphosphate 5-phophatases is still poorly understood. We determined the crystal structures of human SHIP2, OCRL, and INPP5B, the latter in complex with phosphoinositide substrate analogs, which revealed a membrane interaction patch likely to assist in sequestering substrates from the lipid bilayer. Residues recognizing the 1-phosphate of the substrates are highly conserved among human family members, suggesting similar substrate binding modes. However, 3- and 4-phosphate recognition varies and determines individual substrate specificity profiles. The high conservation of the environment of the scissile 5-phosphate suggests a common reaction geometry for all members of the human 5-phosphatase family
Creation of a novel class of potent and selective MutT Homologue 1 (MTH1) inhibitors using fragment-based screening and structure-based drug design
Recent literature has both suggested and questioned MTH1 as a novel cancer target. BAY-707 was just published as a target validation small molecule probe for assessing the effects of pharmacological inhibition of MTH1 on tumor cell survival, both in vitro and in vivo. (1) In this report, we describe the medicinal chemistry program creating BAY-707, where fragment-based methods were used to develop a series of highly potent and selective MTH1 inhibitors. Using structure-based drug design and rational medicinal chemistry approaches, the potency was increased over 10,000 times from the fragment starting point while maintaining high ligand efficiency and drug-like properties
Interaction and complexation of phospholipid vesicles and triblock copolymers
10.1021/jp906929uJournal of Physical Chemistry B1134514934-14942JPCB