Cross Cell Membranes Research Articles

Role of sulfur-containing gaseous substances in the cardiovascular system

Gaseous mediators are important signaling molecules with properties that differ from other, larger signaling molecules. Small gaseous mediators readily cross cell membranes and can access sites on target molecules that would be inaccessible to bulkier molecules. They have a variety of signaling mechanisms, some well understood, some not. The family of gasotransmitters is growing, well known members include nitric oxide (NO) and carbon monoxide (CO). Newer candidates include the sulfur containing gases hydrogen sulfide (H2S), which has been shown to have a wide range of physiological functions, and more recently sulfur dioxide (SO2) has been studied as a potential new gasotransmitter. This review explores the production, regulation and role of the sulfur-containing gases H2S and SO2 at the level of the endothelial and vascular smooth muscle cells as well as the broader effects on the cardiovascular system under both physiological and pathophysiological conditions.

Ultrasound Mediated Drug-Loaded Nanoparticles Crossing Cell Membranes as a New Strategy to Reverse Multidrug Resistance In Human Leukemia Cell Line K562/A02

AbstractAbstract 3969 Objective:Although many strategies have been explored to overcome the multidrug resistance (MDR) in leukemia which has rendered many currently available chemotherapeutic drugs ineffective, the results have been disappointing to the obstacle. The aim of this study was to investigate whether the new strategy of combining drug-loaded nanoparticles (Nps) and ultrasound (US) would show useful effects on the reversal of MDR in human leukemia cell line K562/A02. Methods:In this study, daunorubicin (DNR), a frequently chemotherapeutic agent known to cause DNA damage and induce apoptosis and cell death, was loaded on the TiO2 Nps which is chemically stable, environmental friendly, and shows weak or non cytotoxic to apply as the nano-drug carrier. The MDR leukemia K562/A02 cells were treated with the DNR-loaded TiO2 Nps drug carrier and US exposure. Then, we examined the effectiveness of delivering DNR into the MDR leukemia K562/A02 cells with the electrochemical studies, observed the bio-effects on the cell viability by MTT assays, investigated the induced apoptosis, and assessed the reversal ability and the mechanism of MDR by combining the drug-loaded Nps and US. Results:We observed good biocompatibility of the therapeutic approach. When the K562/A02 cells were incubated with DNR only, the cathodic current decreased by only 10% normalized to the DNR (10 μg/mL) standard, indicating less DNR was absorbed by the MDR cells. The cathodic current decreased by 39% and 63% in the presence of US or DNR-loaded TiO2 Nps, respectively. In comparison, when the cells were treated by the novel strategy of US mediated drug-loaded Nps crossing cell membranes, the cathodic current of DNR in the supernatant decreased greatly by 82% and became the minimal, which suggesting the least amount of DNR remained outside the MDR cells in this case and the largest uptake into the cells by this new strategy. These observations demonstrated that the remarkable synergistic effect of the novel strategy facilitated the accumulation of DNR in the MDR K562/A02 cells. In addition, our MTT assay illustrated comparative sensitization of the MDR K562/A02 cells under the treatment of US or drug-loaded Nps, but especially enhanced effect by combining drug-loaded Nps and US. The resisting fold of the MDR leukemia K562/A02 became obviously lower, decreasing from 58.71 to 16.69. The fresh evidence from caspase-3 immunocytochemistry demonstrated that the strategy could induce the apoptosis in the cells as well. Conclusion:It was therefore concluded that the strategy could have good reversal ability of MDR in tumor. These findings reveal that the reversal of MDR in tumor by US mediated drug-loaded Nps crossing cell membranes could represent promising approach in cancer therapy. Disclosures:No relevant conflicts of interest to declare.

Biological versatility of crotamine – a cationic peptide from the venom of a South American rattlesnake

Importance of the field: Molecules isolated from animals, insects, plants or microorganisms can provide prototypes for design of biopharmaceutical products. Some venom toxins and their derivatives are used in medicine, while others provide templates for development of new drugs.Areas covered in this review: The mild toxin, crotamine, a small basic low-molecular-weight polypeptide purified from the venom of a South American rattlesnake, Crotalus durissus terrificus. Crotamine was discovered more than 50 years ago and only in the past six years has its exceptional biological versatility been demonstrated. Particularly, its cell-penetrating ability, which allows crotamine to cross cell membranes and to accumulate in the nucleus; its use for intracellular vesicle tracking and as a cell cycle marker and its capability for delivering DNA into replicating mammalian cells. Both antimicrobial action and potential selective antitumor activity of crotamine have also been found.What the reader will gain: Multidisciplinary approaches and pathways of discovery placed crotamine in a rare category of versatile biomolecules, in which concentration, molecular target preference, structural ancestry and specificity toward biological membranes play an integral role.Take home message: Crotamine is a druggable peptide with high potential for use as an imaging agent for detecting dividing cells, for intracellular delivery of hydrophilic biomolecules, and as an alternative chemotherapeutic compound against aggressive types of cancer.

Re and Tc Tricarbonyl Complexes: From the Suppression of NO Biosynthesis in Macrophages to in Vivo Targeting of Inducible Nitric Oxide Synthase

The in vivo molecular imaging of nitric oxide synthase (NOS), the enzyme responsible for the catalytic oxidation of l-arginine to citrulline and nitric oxide (NO), by noninvasive modalities could provide valuable insights into NO/NOS-related diseases. Aiming at the design of innovative (⁹⁹m)Tc(I) complexes for targeting inducible NOS (iNOS) in vivo by SPECT imaging, herein we describe a set of novel (⁹⁹m)Tc(CO)₃ complexes (2-5) and the corresponding rhenium surrogates (2a-5a) containing the NOS inhibitor N(ω)-nitro-l-arginine. The latter is linked through its α-NH₂ or α-COOH group and an alkyl spacer of variable length to the metal center. The complexes 2a (propyl spacer) and 3a (hexyl spacer), in which the α-NH₂ group of the inhibitor is involved in the conjugation to the metal center, presented remarkable affinity for purified iNOS, being similar to that of the free nonconjugated inhibitor (K(i) = 3-8 μM) in the case of 3a (K(i) = 6 μM). 2a and 3a are the first examples of organometallic complexes that permeate through RAW 264.7 macrophage cell membranes, interacting specifically with the target enzyme, as confirmed by the suppression of NO biosynthesis in LPS-treated macrophages (2a, ca. 30% inhibition; 3a, ca. 50% inhibition). The (⁹⁹m)Tc(I)-complexes 2 and 3, stable both in vitro and in vivo, also presented the ability to cross cell membranes, as demonstrated by internalization studies in the same cell model. The biodistribution studies in LPS-pretreated mature female C57BL6 mice have shown that 2 presented an overall higher uptake in most tissues of the LPS-treated mice compared to the control group (30 min postinjection). This increase is significant in lung (3.98 ± 0.63 vs to 0.99 ± 0.13%ID/g), which is known to be the organ with the highest iNOS expression after LPS treatment. These results suggest that the higher uptake in that organ may be related to iNOS upregulation.

Tetracycline compounds with non-antimicrobial organ protective properties: Possible mechanisms of action

Tetracyclines were developed as a result of the screening of soil samples for antibiotics. The first t of these compounds, chlortetracycline, was introduced in 1947. Tetracyclines were found to be highly effective against various pathogens including rickettsiae, as well as both gram-positive and gram-negative bacteria, thus becoming the first class of broad-spectrum antibiotics. Many other interesting properties, unrelated to their antibiotic activity, have been identified for tetracyclines which have led to widely divergent experimental and clinical uses. For example, tetracyclines are also an effective anti-malarial drug. Minocycline, which can readily cross cell membranes, is known to be a potent anti-apoptotic agent. Another tetracycline, doxycycline is known to exert anti-protease activities. Doxycycline can inhibit matrix metalloproteinases which contribute to tissue destruction activities in diseases such as periodontitis. A large body of literature has provided additional evidence for the “beneficial” actions of tetracyclines, including their ability to act as reactive oxygen species scavengers and anti-inflammatory agents. This review provides a summary of tetracycline's multiple mechanisms of action as a means to understand their beneficial effects.

Methods for synthesis and uses of inhibitors of Ghrelin O-acyltransferase inhibitors as potential therapeutic agents for obesity and diabetes

The patent claims inhibitors of ghrelin-O-acyltransferase enzyme. These inhibitors were designed as bisubstrate analogs of the enzymatic reaction and were coupled with one of the peptides able to cross cell membranes, the 11-mer Tat peptide. The compound GO-CoA-Tat was studied in vitro and in vivo; after intraperitoneal administration, it enhances insulin response to a glucose load and leads to a statistically significant weight loss in mouse fed with a high fat diet.

Different membrane behaviour and cellular uptake of three basic arginine-rich peptides

Cell penetrating peptides (CPPs) are peptides displaying the ability to cross cell membranes and transport cargo molecules inside cells. Several uptake mechanisms (endocytic or direct translocation through the membrane) are being considered, but the interaction between the CPP and the cell membrane is certainly a preliminary key point to the entry of the peptide into the cell. In this study, we used three basic peptides: RL9 (RRLLRRLRR-NH2), RW9 (RRWWRRWRR-NH2) and R9 (RRRRRRRRR-NH2). While RW9 and R9 were internalised into wild type Chinese Hamster Ovary cells (CHO) and glycosaminoglycan-deficient CHO cells, at 4°C and 37°C, RL9 was not internalised into CHO cells. To better understand the differences between RW9, R9 and RL9 in terms of uptake, we studied the interaction of these peptides with model lipid membranes. The effect of the three peptides on the thermotropic phase behaviour of a zwitterionic lipid (DMPC) and an anionic lipid (DMPG) was investigated with differential scanning calorimetry (DSC). The presence of negative charges on the lipid headgroups appeared to be essential to trigger the peptide/lipid interaction. RW9 and R9 disturbed the main phase transition of DMPG, whereas RL9 did not induce significant effects. Isothermal titration calorimetry (ITC) allowed us to study the binding of these peptides to large unilamellar vesicles (LUVs). RW9 and R9 proved to have about ten fold more affinity for DSPG LUVs than RL9. With circular dichroism (CD) and NMR spectroscopy, the secondary structure of RL9, RW9 and R9 in aqueous buffer or lipid/detergent conditions was investigated. Additionally, we tested the antimicrobial activity of these peptides against Escherichia coli and Staphylococcus aureus, as CPPs and antimicrobial peptides are known to share several common characteristics. Only RW9 was found to be mildly bacteriostatic against E. coli. These studies helped us to get a better understanding as to why R9 and RW9 are able to cross the cell membrane while RL9 remains bound to the surface without entering the cell.

Selective gene silencing by viral delivery of short hairpin RNA

RNA interference (RNAi) technology has not only become a powerful tool for functional genomics, but also allows rapid drug target discovery and in vitro validation of these targets in cell culture. Furthermore, RNAi represents a promising novel therapeutic option for treating human diseases, in particular cancer. Selective gene silencing by RNAi can be achieved essentially by two nucleic acid based methods: i) cytoplasmic delivery of short double-stranded (ds) interfering RNA oligonucleotides (siRNA), where the gene silencing effect is only transient in nature, and possibly not suitable for all applications; or ii) nuclear delivery of gene expression cassettes that express short hairpin RNA (shRNA), which are processed like endogenous interfering RNA and lead to stable gene down-regulation. Both processes involve the use of nucleic acid based drugs, which are highly charged and do not cross cell membranes by free diffusion. Therefore, in vivo delivery of RNAi therapeutics must use technology that enables the RNAi therapeutic to traverse biological membrane barriers in vivo. Viruses and the vectors derived from them carry out precisely this task and have become a major delivery system for shRNA. Here, we summarize and compare different currently used viral delivery systems, give examples of in vivo applications, and indicate trends for new developments, such as replicating viruses for shRNA delivery to cancer cells.

Targeting nitric oxide synthase with 99mTc/Re-tricarbonyl complexes containing pendant guanidino or isothiourea moieties

The visualization of inducible nitric oxide synthase (iNOS) in vivo with specific radioactive probes could provide a valuable insight into the diseases associated with upregulation of this enzyme. Aiming at that goal, we have synthesized a novel family of conjugates bearing a pyrazolyl-diamine chelating unit for stabilization of the fac-[M(CO) 3] + core (M = 99mTc, Re) and pendant guanidino ( L 1 = guanidine, L 2 = N-hydroxyguanidine, L 3 = N-methylguanidine, L 4 = N-nitroguanidine) or S-methylisothiourea ( L 5 ) moieties for iNOS recognition. L 1 – L 5 reacted with fac-[M(CO) 3(H 2O)] +, yielding complexes of the type fac-[M(CO) 3(k 3-L)] + (M = Re/ 99mTc; 1/ 1a, L = L 1 ; 2/ 2a, L = L 2 ; 3/ 3a, L = L 3 ; 4/ 4a, L = L 4 ; 5/ 5a, L = L 5 ), which were fully characterized by the usual analytical methods in chemistry and radiochemistry, including X-ray diffraction analysis in the case of 1. The rhenium complexes 1– 5 were prepared as “cold” surrogates of the 99mTc(I) complexes. Enzymatic assays with murine purified iNOS demonstrated that L 1 , L 2 , 1 and 2 are poor NO-producing substrates. These assays have also shown that metallation of L 4 and L 5 ( K i > 1000 μM) gave complexes with increased inhibitory potency ( 4, K i = 257 μM; 5, K i = 183 μM). The organometallic rhenium complexes permeate through LPS-treated RAW 264.7 macrophage cell membranes, interacting specifically with the target enzyme, as confirmed by the partial suppression of NO biosynthesis ( ca. 20% in the case of 4 and 5) in this cell model. The analog 99mTc(I)-complexes 1a– 5a are stable in vitro, being also able to cross cell membranes, as demonstrated by internalization studies in the same cell model with compound 4a (4h, 37 °C; 33.8% internalization). Despite not being as effective as the α-amino-acid-containing metal-complexes previously described by our group, the results reported herein have shown that similar 99mTc(I)/Re(I) organometallic complexes with pendant amidinic moieties may hold potential for targeting iNOS expression in vivo.

Effect of Association with Sulfate on the Electrophoretic Mobility of Polyarginine and Polylysine

Domains rich in cationic amino acids are ubiquitous in peptides with the ability to cross cell membranes, which is likely related to the binding of such polypeptides to anionic groups on the membrane surface. To shed more light on these interactions, we investigated specific interactions between basic amino acids and oligopeptides thereof and anions by means of electrophoretic experiments and molecular dynamics simulations. To this end, we measured the electrophoretic mobilities of arginine, lysine, tetraarginine, and tetralysine in sodium chloride and sodium sulfate electrolytes as a function of ionic strength. The mobility was found to be consistently lower in sodium sulfate than in sodium chloride at the same ionic strength. The decrease in mobility in sodium sulfate was greater for tetraarginine than for tetralysine and was larger for tetrapeptides compared to the corresponding free amino acids. On the basis of molecular dynamics simulations and Bjerrum theory, we rationalize these results in terms of enhanced association between the amino acid side chains and sulfate. Simulations also predict a greater affinity of sulfate to the guanidinium side chain groups of arginine than to the ammonium groups of lysine, as the planar guanidinium geometry allows simultaneous strong hydrogen bonding to two sulfate oxygens. We show that the sulfate binding to arginine, but not to lysine, is cooperative. These results are consistent with the greater decrease in the mobility of arginine compared to that of lysine upon addition of sulfate salt. The nonspecific mobility retardation by sulfate is ascribed to its electrostatic interaction with the cationic amino acid side chain groups.

A Highly Selective Low-Background Fluorescent Imaging Agent for Nitric Oxide

We introduce a novel sensing mechanism for nitric oxide (NO) detection with a particular easily synthesized embodiment (NO(550)), which displays a rapid and linear response to NO with a red-shifted 1500-fold turn-on signal from a dark background. Excellent selectivity was observed against other reactive oxygen/nitrogen species, pH, and various substances that interfere with existing probes. NO(550) crosses cell membranes but not nuclear membranes and is suitable for both intra- and extracellular NO quantifications. Good cytocompatibility was found during in vitro studies with two different cell lines. The high specificity, dark background, facile synthesis, and low pH dependence make NO(550) a superior probe for NO detection when used as an imaging agent.

Glycerol uptake by erythrocytes from warm- and cold-acclimated Cope’s gray treefrogs

Cope's gray treefrogs, Hyla chrysoscelis, accumulate glycerol during the period of cold acclimation that leads to the development of freeze tolerance. Glycerol must cross cell membranes in numerous processes during this time, including exit from hepatocytes where glycerol is synthesized and entry into other tissues, where glycerol is cryoprotective. Thus, we hypothesized that erythrocytes from H. chrysoscelis would be permeable to glycerol and that that permeability would be up-regulated during cold acclimation. Further, we hypothesized that glycerol permeability would be associated with the expression of aquaporins, particularly those from the glyceroporin sub-family. Erythrocytes from warm-acclimated treefrogs had high glycerol permeability at 20°C, as assessed by the time required for osmotic lysis following suspension in 0.2 M glycerol. That osmotic lysis, as well as uptake of radio-labeled glycerol, was inhibited by 0.3 mM HgCl(3). Permeability assessed via osmotic lysis was markedly reduced at 5°C. These properties were similar in animals deriving from northern (Ohio) and southern (Alabama) populations, although suggestive (through statistical interactions) of greater glycerol permeability in northern animals. Erythrocytes expressed mRNA and protein for a previously described glyceroporin, HC-3. In cold-acclimated animals, HC-3 protein expression was up-regulated, but we could not detect a concomitant enhancement of glycerol permeability.

Biofunctionalized Phospholipid-Capped Mesoporous Silica Nanoshuttles for Targeted Drug Delivery: Improved Water Suspensibility and Decreased Nonspecific Protein Binding

A main challenge in nanobiomedicine is the engineering of nanostructures or nanomaterials that can efficiently encapsulate drugs at high load, cross cell membranes, and controllably release their cargo at target sites. Although mesoporous silica nanoparticles (MSNs) are safe, versatile, and promising carrier materials for targeted drug delivery, their aggregation phenomena under physiological conditions (or salt-containing environments) and their nonspecific binding in protein-containing solutions (or serum) limit their applications in biological science and biomedicine. To address this challenge, we have developed a novel delivery system, termed a nanoshuttle, comprising a nanoscale PEGylated-phospholipid coating and 13-(chlorodimethylsilylmethyl)heptacosane-derivatized MSNs, in which therapeutic or imaging agents may be trapped and ligand-assisted targeted delivery may be achieved through surface functionalization of the phospholipids. As a proof of concept in this study, we selected fluorescein isothiocyanate and folate as the imaging tracer and targeted ligand, respectively. Relative to the bare MSNs, the lipid-capped MSNs exhibited superior suspensibility in phosphate-buffered saline and much lower nonspecific binding in vitro. Furthermore, enhanced specific cellular uptake by Hela cells occurred after administering the folate-sensitized phospholipid-capped MSNs. Our results suggest that these highly versatile multifunctional MSNs are promising vectors for nanomedicine applications.

Reconvene and reconnect the antioxidant hypothesis in human health and disease.

The antioxidants are essential molecules in human system but are not miracle molecules. They are neither performance enhancers nor can prevent or cure diseases when taken in excess. Their supplemental value is debateable. In fact, many high quality clinical trials on antioxidant supplement have shown no effect or adverse outcomes ranging from morbidity to all cause mortality. Several Chochrane Meta-analysis and Markov Model techniques, which are presently best available statistical models to derive conclusive answers for comparing large number of trials, support these claims. Nevertheless none of these statistical techniques are flawless. Hence, more efforts are needed to develop perfect statistical model to analyze the pooled data and further double blind, placebo controlled interventional clinical trials, which are gold standard, should be implicitly conducted to get explicit answers. Superoxide dismutase (SOD), glutathione peroxidase and catalase are termed as primary antioxidants as these scavenge superoxide anion and hydrogen peroxide. All these three enzymes are inducible enzymes, thereby inherently meaning that body increases or decreases their activity as per requirement. Hence there is no need to attempt to manipulate their activity nor have such efforts been clinically useful. SOD administration has been tried in some conditions especially in cancer and myocardial infarction but has largely failed, probably because SOD is a large molecule and can not cross cell membrane. The dietary antioxidants, including nutrient antioxidants are chain breaking antioxidants and in tandem with enzyme antioxidants temper the reactive oxygen species (ROS) and reactive nitrogen species (RNS) within physiological limits. Since body is able to regulate its own requirements of enzyme antioxidants, the diet must provide adequate quantity of non-enzymic antioxidants to meet the normal requirements and provide protection in exigent condition. So far, there is no evidence that human tissues ever experience the torrent of reactive species and that in chronic conditions with mildly enhanced generation of reactive species, the body can meet them squarely if antioxidants defense system in tissues is biochemically optimized. We are not yet certain about optimal levels of antioxidants in tissues. Two ways have been used to assess them: first by dietary intake and second by measuring plasma levels. Lately determination of plasma/serum level of antioxidants is considered better index for diagnostic and prognostic purposes. The recommended levels for vitamin A, E and C and beta carotene are 2.2-2.8μmol/l; 27.5-30μmol/l; 40-50μmol/l and 0.4-0.5μmol/l, respectively. The requirement and recommended blood levels of other dietary antioxidants are not established. The resolved issues are (1) essential to scavenge excess of radical species (2) participants in redox homeostasis (3) selective antioxidants activity against radical species (4) there is no universal antioxidant and 5) therapeutic value in case of deficiency. The overarching issues are (1) therapeutic value as adjuvant therapy in management of diseases (2) supplemental value in developing population (3) selective interactivity of antioxidant in different tissues and on different substrates (4) quantitative contribution in redox balance (5) mechanisms of adverse action on excess supplementation (6) advantages and disadvantages of prooxidant behavior of antioxidants (7) behavior in cohorts with polymorphic differences (8) interaction and intervention in radiotherapy, diabetes and diabetic complications and cardiovascular diseases (9) preventive behavior in neurological disorders (10) benefits of non-nutrient dietary antioxidants (11) markers to assess optimized antioxidants status (12) assessment of benefits of supplementation in alcoholics and heavy smokers. The unresolved and intriguing issues are (1) many compounds such as vitamin A and many others possessing both antioxidant and non-antioxidant properties contribute to both the activities in vivo or exclusively only to non-antioxidant activity and (2) since human tissues do not experience the surge of FR, whether there is any need to develop stronger synthetic antioxidants. Theoretically such antioxidants may do more harm than good.

Tetracyclines: a pleitropic family of compounds with promising therapeutic properties. Review of the literature

There must be something unique about a class of drugs (discovered and developed in the mid-1940s) where there are more than 130 ongoing clinical trials currently listed. Tetracyclines were developed as a result of the screening of soil samples for antibiotic organisms. The first of these compounds chlortetracycline was introduced in 1948. Soon after their development tetracyclines were found to be highly effective against various pathogens including rickettsiae, Gram-positive, and Gram-negative bacteria, thus, becoming a class of broad-spectrum antibiotics. The mechanism of action of tetracyclines is thought to be related to the inhibition of protein synthesis by binding to the 30S bacterial ribosome. Tetracyclines are also an effective anti-malarial drug. Over time, many other "protective" actions have been described for tetracyclines. Minocycline, which can readily cross cell membranes, is known to be a potent anti-apoptotic agent. Its mechanism of action appears to relate to specific effects exerted on apoptosis signaling pathways. Another tetracycline, doxycycline is known to exert antiprotease activities. Doxycycline can inhibit matrix metalloproteinases, which contribute to tissue destruction activities in diseases such as gingivitis. A large body of literature has provided additional evidence for the "beneficial" actions of tetracyclines, including their ability to act as oxygen radical scavengers and anti-inflammatory agents. This increasing volume of published work and ongoing clinical trials supports the notion that a more systematic examination of their possible therapeutic uses is warranted. This review provides a summary of tetracycline's multiple mechanisms of action and while using the effects on the heart as an example, this review also notes their potential to benefit patients suffering from various pathologies such as cancer, Rosacea, and Parkinson's disease.

Dendrimer Internalization and Intracellular Trafficking in Living Cells

The ability of dendrimers to cross cell membranes is of much interest for their application in drug and gene delivery. Recent studies demonstrate that dendrimers are capable to enter cells by endocytosis, but the intracellular pathway following their internalization remains controversial. In this study we use confocal fluorescence microscopy to elucidate the intracellular trafficking properties of PAMAM dendrimers with high spatial and temporal resolution in living HeLa cells. Macromolecules of different chemical functionality (neutral, cationic and lipidated), size (from G2 up to G6) and surface charge are investigated and their internalization properties correlated with the molecular structure. Toxicity and internalization data are discussed that allow the identification of dendrimers maximizing intracellular uptake with the minimum effect on cell viability. Time-lapse imaging and colocalization assays with fluorescent biomarkers for endocytic vesicles demonstrate that dendrimers are internalized by both clathrin-dependent endocytosis and macropinocytosis and are eventually delivered to the lysosomal compartment. Moreover we analyzed the uptake of dendrimers in additional cell lines of practical interest for therapeutic purposes. These measurements together with a direct comparison with TAT peptides demonstrate that PAMAM dendrimers possess similar properties to these widely used cell-penetrating peptides and thanks to their chemical tunability may represent a valid alternative for drug and gene delivery.

Imperatoxin A, a Cell-Penetrating Peptide from Scorpion Venom, as a Probe of Ca2+-Release Channels/Ryanodine Receptors

Scorpion venoms are rich in ion channel-modifying peptides, which have proven to be invaluable probes of ion channel structure-function relationship. We previously isolated imperatoxin A (IpTxa), a 3.7 kDa peptide activator of Ca2+-release channels/ryanodine receptors (RyRs) [1,2,3] and founding member of the calcin family of scorpion peptides. IpTxa folds into a compact, mostly hydrophobic molecule with a cluster of positively-charged, basic residues polarized on one side of the molecule that possibly interacts with the phospholipids of cell membranes. To investigate whether IpTxa permeates external cellular membranes and targets RyRs in vivo, we perfused IpTxa on intact cardiomyocytes while recording field-stimulated intracellular Ca2+ transients. To further investigate the cell-penetrating capabilities of the toxin, we prepared thiolated, fluorescent derivatives of IpTxa. Biological activity and spectroscopic properties indicate that these derivatives retain high affinity for RyRs and are only 5- to 10-fold less active than native IpTxa. Our results demonstrate that IpTxa is capable of crossing cell membranes to alter the release of Ca2+ in vivo, and has the capacity to carry a large, membrane-impermeable cargo across the plasma membrane, a finding with exciting implications for novel drug delivery.

New insights of transmembranal mechanism and subcellular localization of noncovalently modified single-walled carbon nanotubes.

Translocation and localization of single-walled carbon nanotubes (SWNTs) in normal and cancerous cells have significant biomedical implications. In this study, SWNTs functionalized with different biomolecules in cells were observed with confocal laser scanning microscopy. Functionalized with PL-PEG, SWNTs were found to localize exclusively in mitochondria of both tumor and normal cells due to mitochondrial transmembrane potential, but they were found mainly in lysosomes of macrophages due to phagocytosis. However, when conjugated with different molecules, the subcellular localization of the surface-modified SWNT-PL-PEG depended on how SWNTs enter the cells: inside mitochondria if crossing cell membrane or inside lysosomes if being endocytosized. We also show that mitochondrial SWNT-PL-PEG, when irradiated with a near-infrared light, can induce cell apoptosis due to mitochondrial damages. These findings provide a better mechanistic understanding of cellular localization of SWNTs, which could lead to advanced biomedical applications such as the design of molecular transporters and development of SWNT-assisted cancer therapies.

Cell-penetrating Peptides with Intracellular Actin-remodeling Activity in Malignant Fibroblasts

Cell-penetrating peptides can cross cell membranes and are commonly seen as biologically inert molecules. However, we found that some cell-penetrating peptides could remodel actin cytoskeleton in oncogene-transformed NIH3T3/EWS-Fli cells. These cells have profound actin disorganization related to their tumoral transformation. These arginine- and/or tryptophan-rich peptides could cross cell membrane and induce stress fiber formation in these malignant cells, whereas they had no perceptible effect in non-tumoral fibroblasts. In addition, motility (migration speed, random motility coefficient, wound healing) of the tumor cells could be decreased by the cell-permeant peptides. Although the peptides differently influenced actin polymerization in vitro, they could directly bind monomeric actin as determined by NMR and calorimetry studies. Therefore, cell-penetrating peptides might interact with intracellular protein partners, such as actin. In addition, the fact that they could reverse the tumoral phenotype is of interest for therapeutic purposes.

Fenton-Treated Functionalized Diamond Nanoparticles as Gene Delivery System

When raw diamond nanoparticles (Dnp, 7 nm average particle size) obtained from detonation are submitted to harsh Fenton-treatment, the resulting material becomes free of amorphous soot matter and the process maintains the crystallinity, reduces the particle size (4 nm average particle size), increases the surface OH population, and increases water solubility. All these changes are beneficial for subsequent Dnp covalent functionalization and for the ability of Dnp to cross cell membranes. Fenton-treated Dnps have been functionalized with thionine and the resulting sample has been observed in HeLa cell nuclei. A triethylammonium-functionalized Dnp pairs electrostatically with a plasmid having the green fluorescent protein gene and acts as gene delivery system permitting the plasmid to cross HeLa cell membrane, something that does not occur for the plasmid alone without assistance of polycationic Dnp.