Celeste Weiss

Intracellular delivery mediated by an ethosomal carrier

The goal of this work was to investigate the efficiency of transcellular delivery into Swiss albino mice 3T3 fibroblasts of molecules with various physico-chemical characteristics from ethosomes, phospholipid vesicular carriers containing ethanol. The probes chosen were: 4-(4-diethylamino) styryl-N-methylpyridinium iodide (D-289), rhodamine red dihexadecanoylglycerophosphoethanolamine (RR) and fluorescent phosphatidylcholine (PC*). The penetration of these fluorescent probes into fibroblasts and nude mice skin was examined by CLSM and FACS. CLSM micrographs showed that ethosomes facilitated the penetration of all probes into the cells, as evident from the high-intensity fluorescence. In comparison, when incorporated in hydroethanolic solution or classic liposomes, almost no fluorescence was detected. The intracellular presence of each of the three probes tested, was evident after 3 min of incubation. Furthermore, with ethosomal D-289, fluorescence was also seen in the fibroblast nucleus. Enhanced delivery of molecules from the ethosomal carrier was also observed in permeation experiments with the hydrophilic calcein and lypophilic RR to whole nude mouse skin. Calcein penetrated the skin to a depth of 160, 80 and 60 microm from ethosomes, hydroethanolic solution and liposomes, respectively. Maximum fluorescence intensities measured for RR delivered from ethosomes, hydroethanolic solution and liposomes were 150, 40 and 20 AU, respectively. Fibroblast viability tests showed that the ethosomal carrier is not toxic to the cultured cells.

Enhanced delivery of drugs into and across the skin by ethosomal carriers

In dermal and transdermal delivery, the skin is used as a portal of entry for drugs, for localized and systemic treatment. Because of the barrier properties of the outer layer of the skin, in many cases, permeation‐enhancing agents are needed to achieve therapeutic levels of drug. Classic liposomal systems were found to be effective at forming drug reservoir in the upper layers of the skin, for local skin therapy. Recently, it was found that ethosomal carriers, phospholipid vesicular systems containing relatively high concentrations of alcohol, were very effective at enhancing dermal and transdermal delivery of both lipophilic and hydrophilic molecules. Fluorescent probes delivered from ethosomal systems reached the deep strata of the skin. Delivery of minoxidil to the pilosebaceous units from ethosomes was much greater compared to delivery from classic liposomes. In addition, clinical studies with aciclovir showed that ethosomal formulations were superior to the currently available topical therapy at treating recurrent herpes labialis. Ethosomal systems were also highly effective at transdermal delivery of drugs. In vivo skin permeation of testosterone from patches containing ethosomal drug were more effective at delivering testosterone through rabbit pinna skin than commercially available Testoderm patches. Results using trihexyphenidyl hydrochloride ethosomes indicated that this system has the potential to be further developed into an antiparkinsonian patch. Lastly, the transdermal delivery of insulin from an ethosomal carrier resulted in lower blood glucose levels in normal and diabetic rats in vivo, with a plateau effect lasting for at least 8 h. Drug Dev. Res. 50:406–415, 2000.

Copper chaperone-dependent and -independent activation of three copper-zinc superoxide dismutase homologs localized in different cellular compartments in Arabidopsis.

Superoxide dismutases (SODs) are important antioxidant enzymes that catalyze the disproportionation of superoxide anion to oxygen and hydrogen peroxide to guard cells against superoxide toxicity. The major pathway for activation of copper/zinc SOD (CSD) involves a copper chaperone for SOD (CCS) and an additional minor CCS-independent pathway reported in mammals. We characterized the CCS-dependent and -independent activation pathways for three CSDs localized in different cellular compartments in Arabidopsis (Arabidopsis thaliana). The main activation pathway for CSD1 in the cytoplasm involved a CCS-dependent and -independent pathway, which was similar to that for human CSD. Activation of CSD2 in chloroplasts depended totally on CCS, similar to yeast (Saccharomyces cerevisiae) CSD. Peroxisome-localized CSD3 via a CCS-independent pathway was similar to nematode (Caenorhabditis elegans) CSD in retaining activity in the absence of CCS. In Arabidopsis, glutathione played a role in CCS-independent activation, as was reported in humans, but an additional factor was required. These findings reveal a highly specific and sophisticated regulation of CSD activation pathways in planta relative to other known CCS-independent activation.

Rapid inactivation of rotaviruses by exposure to acid buffer or acidic gastric juice.

Inactivation rates of three bovine and several primate-origin rotaviruses were determined during exposure to acid buffers at pH 2.0, pH 3.0 or pH 4.0. Each rotavirus was inactivated at pH 2.0 (the acidity most resembling the normal fasting stomach) very rapidly, with half-lives for infectivity determined to be 1 min or less. Each rotavirus was inactivated at a much slower rate at pH 3.0; inactivation at pH 4.0 was minimal. No remarkable differences in acid resistance between different rotavirus strains were detected. Although these determinations were performed at room temperature (23 degrees C), experiments at diverse temperatures indicated an even more rapid rate of viral inactivation by acid at normal body temperature (37 degrees C). Studies of rotavirus exposed to natural human gastric juice at pH 1.8 or pH 2.1 revealed a rate of virus inactivation similar to that observed with glycine buffer of identical pH.

GroES binding regulates GroEL chaperonin activity under heat shock

Chaperonins GroEL14 and GroES7 are heat‐shock proteins implicated in the molecular response to stress. Protein fluorescence, crosslinking and kinetic analysis revealed that the bond between the two otherwise thermoresistant oligomers is regulated by temperature. As temperature increased, the affinity of GroES7 and the release of bound proteins from the chaperonin concomitantly decreased. After heat shock, GroES7 rebinding to GroEL14 and GroEL14GroES7 particles correlated with the restoration of optimal protein folding/release activity. Chaperonins thus behave as a molecular thermometer which can inhibit the release of aggregation‐prone proteins during heat shock and restore protein folding and release after heat shock.

Purification of mammalian mitochondrial chaperonin 60 through in vitro reconstitution of active oligomers

Publisher Summary The chapter presents a study on purification of mammalian mitochondrial chaperonin 60 through in vitro reconstitution of active oligomers. Because of the technical difficulties associated with the mammalian mt-cpn60, functional characterization of the mammalian mt-cpnl0 has largely been restricted to in vitro interactions with GroEL. In this heterologous test system, GroES and the mammalian mt-cpnl 0 are functionally interchangeable by a number of criteria, including the ability to assist GroEL in the facilitation of protein folding. The resounding conclusion from these experiments is that the fundamental mechanism of the GroE-related chaperonins has been highly conserved from bacteria to mitochondria. The chapter describes the purification of monomeric mammalian mt-cpn60 and its subsequent reassembly into functional oligomers using a general approach that has worked well with other GroEL homologs. The chapter describes the purification of monomeric mammalian mitochondrial chaperonin 60, reconstitution of oligomeric mitochondrial chaperonin 60, properties of in vitro -reconstituted particles and several related concepts.

CHAPERONIN 20 mediates iron superoxide dismutase (FeSOD) activity independent of its co‐chaperonin role in Arabidopsis chloroplasts

Iron superoxide dismutases (FeSODs; FSDs) are primary antioxidant enzymes in Arabidopsis thaliana chloroplasts. The stromal FSD1 conferred the only detectable FeSOD activity, whereas the thylakoid membrane- and nucleoid-co-localized FSD2 and FSD3 double mutant showed arrested chloroplast development. FeSOD requires cofactor Fe for its activity, but its mechanism of activation is unclear. We used reversed-phase high-performance liquid chromatography (HPLC), gel filtration chromatography, LC-MS/MS, protoplast transient expression and virus-induced gene silencing (VIGS) analyses to identify and characterize a factor involved in FeSOD activation. We identified the chloroplast-localized co-chaperonin CHAPERONIN 20 (CPN20) as a mediator of FeSOD activation by direct interaction. The relationship between CPN20 and FeSOD was confirmed by in vitro experiments showing that CPN20 alone could enhance FSD1, FSD2 and FSD3 activity. The in vivo results showed that CPN20-overexpressing mutants and mutants with defective co-chaperonin activity increased FSD1 activity, without changing the chaperonin CPN60 protein level, and VIGS-induced downregulation of CPN20 also led to decreased FeSOD activity. Our findings reveal that CPN20 can mediate FeSOD activation in chloroplasts, a role independent of its known function in the chaperonin system.

The complexity of chloroplast chaperonins

Type I chaperonins are large oligomeric protein ensembles that are involved in the folding and assembly of other proteins. Chloroplast chaperonins and co-chaperonins exist in multiple copies of two distinct isoforms that can combine to form a range of labile oligomeric structures. This complex system increases the potential number of chaperonin substrates and possibilities for regulation. The incorporation of unique subunits into the oligomer can modify substrate specificity. Some subunits are upregulated in response to heat shock and some show organ-specific expression, whereas others possess additional functions that are unrelated to their role in protein folding. Accumulating evidence suggests that specific subunits have distinct roles in biogenesis of ribulose-1,5-bisphosphate carboxylase oxygenase (Rubisco).

The bradykinin receptor — a putative receptor-operated channel in PC12 cells: studies of neurotransmitter release and inositol phosphate accumulation

Bradykinin (BK) induced [3H]norepinephrine [( 3H]NE) release and phosphatidylinositol turnover were investigated in PC12 cells. Induction of [3H]NE release by BK is mediated by activation of BK-B2-receptors, as determined using type specific BK receptor antagonists. BK induces [3H]NE release with a half maximal effective concentration of 30 +/- 0.5 nM, and reaches maximal net fractional release of 9.0 +/- 1% with 200 nM BK. The BK-induced release is Ca2+ dependent, reaching maximal release at 1.0 mM Ca2+, is pertussis toxin insensitive (1 microgram/ml), slightly increased by a dibutyryl cAMP (1 mM) and not affected by inhibitors of the cyclooxygenase or lipoxygenase pathways. Voltage-sensitive Ca2+ channel blockers, verapamil (10 microM), nifedipine (10 microM), and omega-conotoxin (CgTx 10 nM), do not block the BK-induced release. However, a considerable inhibitory effect was obtained by divalent cations Co2+ (ED50 = 0.2 mM) and Ni2+ (ED50(2)+ = 1 mM). These results indicate the involvement of a Ca2+ channel in the BK-mediated release which is different from the L- or N-type voltage sensitive calcium channels. Whereas [Ca2+]ex is essential for the BK-induction of catecholamine release, the rise in level of InsPs induced by BK in the presence or in the absence of [Ca2+]ex is similar up to concentration of 1 microM. This indicates that the rise in InsPs induced by BK is not sufficient to cause neurotransmitter release. Moreover, subsequent addition of Ca2+ to BK-stimulated cells in Ca(2+)-free medium yields no release. Hence, no activity triggered by BK alone could be further stimulated by Ca2+ for induction of release.(ABSTRACT TRUNCATED AT 250 WORDS)

On the oligomeric state of chloroplast chaperonin 10 and chaperonin 20.

Type I chaperonins are fundamental protein folding machineries that function in eubacteria, mitochondria and chloroplasts. Eubacteria and mitochondria contain chaperonin systems comprised of homo-oligomeric chaperonin 60 tetradecamers and co-chaperonin 10 heptamers. In contrast, the chloroplast chaperonins are heterooligomeric tetradecamers that are composed of two subunit types, alpha and beta. Additionally, chloroplasts contain two structurally distinct co-chaperonins. One, ch-cpn10, is probably similar to the mitochondrial and bacterial co-chaperonins, and is composed of 10 kDa subunits. The other, termed ch-cpn20 is composed of two cpn10-like domains that are held together by a short linker. While the oligomeric structure of ch-cpn10 remains to be elucidated, it was previously suggested that ch-cpn20 forms tetramers in solution, and that this is the functional oligomer. In the present study, we investigated the properties of purified ch-cpn10 and ch-cpn20. Using bifunctional cross-linking reagents, gel filtration chromatography and analytical ultracentrifugation, we show that ch-cpn10 is a heptamer in solution. In contrast, ch-cpn20 forms multiple oligomers that are in dynamic equilibrium with each other and cover a broad spectrum of molecular weights in a concentration-dependent manner. However, upon association with GroEL, only one type of co-chaperonin-GroEL complex is formed.