Aggregation of water soluble octaanionic phthalocyanines and their photoinactivation antimicrobial effect in vitro

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Enzyme responsive luminescent ruthenium(II) cephalosporin probe for intracellular imaging and photoinactivation of antibiotics resistant bacteria

The F?rster resonance energy transfer (FRET) based luminescent ruthenium(II) cephalosporin probe has been designed and synthesized, which can be selectively activated by endogenous β-lactamases and thus provided a localized and specific intracellular luminescence imaging and photoinactivation of drug resistant bacterial pathogens.     

Mechanistic aspects of photoinactivation of Candida albicans by exogenous porphyrins

The mechanism of photoinactivation of Candida albicans by 3.5 μM uncharged, cationic or anionic porphyrins under blue light (407-420 nm) was found to be dependent on the uptake of porphyrins into yeast cells, and was also dependent on the presence or absence of proteins in the photosensitization medium. In a very protein-rich medium, a decrease in viability was observed only with the uncharged porphyrin. Photoinactivation by uncharged or cationic porphyrins in a protein-poorer medium resulted in total eradication, whereas no significant decrease was observed with the anionic porphyrin. Phototreatment in PBS resulted in eradication with all three porphyrins. X-ray microanalysis after phototreatment by the uncharged or cationic porphyrins in the protein-poor medium exhibited ion loss, indicating cell-membrane damage. Transmission electron microscopy indicated cellular and chromosomal damage. No ion loss or cell damage was observed in this medium with the anionic porphyrin. The efficiency of photoeradication of C. albicans is dependent on porphyrin uptake, which might lead (upon illumination) to processes that facilitate the formation of reactive oxygen species that damage the cells. Uptake of charged porphyrins is dependent on protein quantity and quality in the photosensitization microenvironment. This fact must be taken into account when using charged photosensitizers.     

Xanthene dyes induce membrane permeabilization of bacteria and erythrocytes by photoinactivation

We analyzed the photoinactivation of the membrane functions of bacteria and erythrocytes induced by xanthene dyes. The dyes tested were rose bengal, phloxine B, erythrosine B and eosin B. These dyes induced the leakage of K(+) from Staphylococcus aureus cells within minutes of photoirradiation, in the order of rose bengal > phloxine B > erythrosine B > eosin B. The ability of dyes to inhibit respiration was weak, except for rose bengal, and the dyes dissipated the membrane potential in similar time traces with changes in K(+) permeability. The xanthene dyes also induced the leakage of K(+) from bovine erythrocytes upon photoirradiation in the same order as that observed with bacteria. Furthermore, we found that the ability to cause the leakage of K(+) from erythrocytes was associated with dye-induced morphological changes, forming a crenated form from the normal discoid. These results are discussed in connection with the ability of xanthene dyes to generate singlet oxygen and bind to bacterial cells, and further compared with the actions of cationic porphyrins, which induced photoinactivation of bacteria through respiratory inhibition.     

Different approaches to potentiate the immune response induced by a 12-mer synthetic peptide

Interest in synthetic immunogenic peptides is increasingly growing due to the continuous achievements in the understanding of the molecular basis of the immune response. Moreover, the use of peptide fragments to generate antibodies capable of recognizing and neutralizing viral particles could be a valuable alternative to conventional vaccines: they are safe, they can be designed to induce defined immune responses and they can be synthesised in large quantities in high purity. However, their relatively low immunogenicity requires the development of effective adjuvants and/or their incorporation into controlled release formulations. Several different strategies have been used for the induction and analysis of protective immune responses induced by short peptides against infectious diseases. In the present article we summarise the different approaches used to potentiate the immune response induced by a continuous epitope of hepatitis A virus: co-linear link of T-cell epitopes in different orientations, incorporation into liposomes, and preparation of homogeneous and heterogeneous Multiple Antigenic Peptides.     

Mannose functionalized chitosan nanosystems for enhanced antimicrobial activity against multidrug resistant pathogens

Escalating antimicrobial resistance is causing a major threat to the public health. Failure of traditional antibiotics urges the development of alternative therapeutics, which include biopolymeric nanosystems with intrinsic antimicrobial potential. In the present study, mannose functionalized chitosan nanosystems (M-CNS) were fabricated through reductive amination of chitosan with mannose and further its ionic gelation. Changes in zeta potential and characteristic peaks in FTIR spectra revealed surface functionalization of chitosan with mannose. Zeta-sizer studies disclosed relatively higher size (180 ± 5 nm) of mannosylated CNS as compared to CNS (162 ± 7 nm). Inversely, the zeta-potential was reduced from +32.2 mV to +25.4 mV for M-CNS. Scanning electron microscopy verified the slight increase in size for M-CNS. Antimicrobial evaluation of designed nanosystems as alternative antibacterial agent was assessed by time-kill, polystyrene adherence and antibiofilm assays against both Gram-positive and Gram-negative pathogens. Results indicated that mannose functionalized CNS inhibited the growth of resistant Escherichia coli and Listeria monocytogenes, while demonstrating anti-adherence and biofilm disruption activity. Furthermore, highly resistant Pseudomonas aeruginosa and Staphylococcus aureus were also susceptible against M-CNS. This study unveiled the potential of M-CNS against pathogenic, multidrug resistant, biofilm forming bacteria; thus, making them an ideal candidate for developing alternative-medicines to cure the emerging resistant infections.     

Effect of fluoride anions on gramicidin photoinactivation sensitized by sulfonated aluminum phthalocyanines.

Interaction of potent photodynamic agents, sulfonated aluminum phthalocyanines (AlPcSn where n is a number of sulfonic groups), with biological membranes was studied here using model systems: sensitized photoinactivation of gramicidin channels in planar lipid bilayers and adsorption on lipid monolayers. Fluoride anions known to form complexes with aluminum were found to inhibit both the adsorption of aluminum phthalocyanines on lipid monolayers, as measured with a Langmuir trough by surface pressure and surface potential changes, and photodynamic efficacy of the dyes, as studied by gramicidin channel photoinactivation. The similar effects were caused by the alkalinization of the medium. Fluoride anions appeared to be much more effective in the case of AlPcS4 as compared to AlPcS3. The suppression of the photodynamic potency of aluminum phthalocyanines was attributed to desorption of the dyes from lipid bilayers induced by fluoride or hydroxyl ions. With AlPcS4 an enhancement of the dye aggregation leading to a decrease in the sensitizing activity was probably involved in the fluoride effect as revealed by absorption and fluorescence spectral measurements. Capillary electrophoresis was employed to understand the mechanism of the dye desorption. The results of these experiments indicated that the reduction in the membrane affinity was associated with an increase in the negative charge of the dye molecules due to the binding of fluoride or hydroxyl ions.     

Strategies for single-drop microextraction optimisation and validation. Application to the detection of potential antimicrobial agents

Convenient methods that are capable of determining potentially antimicrobial compounds in both vapour and liquid phases are required (inter alia) to facilitate the development of active packaging materials using natural substances. The suitability of single-drop microextraction (SDME) coupled with gas chromatography-mass spectrometry (GC-MS) for this purpose has been assessed by evaluating its ability to determine a range of analytes (mainly terpenes) in vapour samples and three liquid food simulants - distilled water, 10% (v/v) water/ethanol, and 3% (w/v) acetic acid - by headspace-SDME (HS-SDME) and direct immersion-SDME (DI-SDME), respectively. In this contribution, a screening strategy based on the Hildebrand solubility parameter has been used to build a solvent priority list. Solvents were then tested following the list, taking into account additional factors such as low volatility for HS-SDME or buoyancy and relative miscibility for DI-SDME. Other experimental parameters affecting the performance of SDME (such as drop volume, sampling time and temperature, drop position in the sample vial, sample vial size, stirring rate, filling rate and ionic strength of the sample) were investigated using a Plackett-Burman screening design. The method optimisation was completed by means of response surface modelling (RSM). The methods were validated by characterising relevant performance parameters including their robustness, linear range, accuracy (trueness and precision) and capability of detection as described by the International Organization for Standardization.     

Multifunctional divalent vancomycin: the fluorescent imaging and photodynamic antimicrobial properties for drug resistant bacteria

A simple and specific divalent vancomycin-porphyrin has been developed. This divalent vancomycin-porphyrin conjugate indicates promising properties in fluorescent imaging and photodynamic inactivation of vancomycin-sensitive and vancomycin-resistant enterococci (VRE) bacterial strains.     

A cytochrome c variant resistant to heme degradation by hydrogen peroxide

BACKGROUND: Cytochrome c has peroxidase-like activity and can catalyze the oxidation of a variety of organic substrates, including aromatic, organosulfur and lipid compounds. Like peroxidases, cytochrome c is inactivated by hydrogen peroxide. During this inactivation the heme prosthetic group is destroyed. RESULTS: Variants of the iso-1-cytochrome c were constructed by site-directed mutagenesis and were found to be more stable in the presence of hydrogen peroxide than the wild type. No heme destruction was detected in a triple variant (Tyr67-->Phe/Asn52-->Ile/Cys102-->Thr) with the catalytic hydrogen peroxide concentration of 1 mM, even following the loss of catalytic activity, whereas both double variants Tyr67-->Phe/Cys102-->Thr and Asn52-->Ile/Cys102-->Thr showed a greater rate of peroxide-induced heme destruction than observed with the wild-type protein. CONCLUSIONS: Heme destruction and catalytic inactivation are two independent processes. An internal water molecule (Wat166) is shown to be important in the heme destruction process. The absence of a protein radical in the resistant variant suggests that the protein radical is necessary in the heme destruction process, but presumably is not involved in the reactions leading up to the protein inactivation.     

A humidity blocker approach to overcoming the humidity interference with cationic photopolymerization

A humidity blocker approach to overcoming the humidity interference with cationic photopolymerization is proposed and validated. Environmental humidity is one of the major interfering factors in cationic photopolymerization, and cationic photopolymerization is found to be inhibited by high humidity. When curing cycloaliphatic epoxide based cationic UV curable materials flexibilized by various reactive diluents under different humidity conditions, it was found that the more hydrophobic materials exhibited higher monomer conversion under higher humidity. To obtain cationic UV curable materials that are less influenced by humidity, a humidity blocker approach was proposed and monomer conversion of materials containing both hydroxy‐functional reactive diluents and epoxy‐siloxane were examined using real‐time FTIR. The hydroxy‐functional reactive diluents act as an internal hydroxyl source that enhances monomer conversion through chain transfer mechanism, and the hydrophobic epoxy‐siloxane acts as a humidity blocker, mitigating the inhibiting effects of humidity. Cationic UV curable materials with an optimized combination of these two components exhibited higher and more consistent monomer conversion under a range humidity conditions. © 2008 Wiley Periodicals, Inc. J Polym Sci Part A: Polym Chem 46: 4344–4351, 2008     

Overproduction of riboflavin by anArthrobacter sp. mutant resistant to 5-fluorouracil

Effects of pH and dissolved oxygen concentration on batchwise riboflavin production by a 5-fluorouracil (5-FU)-resistant mutant ofArthrobacter sp. were investigated. The reaction was carried out in a jar fermentor. The optimal pH of culture medium was around 7.3. Dissolved oxygen concentration was almost constant during fermentation at 600 rpm of agitation rate. Production of riboflavin reached a maximum of 160 mg/L after 70 h fermentation under the agitation rate of 600 rpm, aeration rate of 1.0 L/min, and pH 7.0.     

Defective transport of thymidine by cultured cells resistant to 5-bromodeoxyuridine.

A line of HeLa cells resistant to 5-bromo-2'-deoxyuridine (BUdR) was established by continuous culture in growth medium containing BUdR; during the selection period, BUdR concentrations, initially 15 micrometer, were gradually increased to 100 micrometer. Cells of a clone (HeLa/B5) established from this line were also resistant to 5-fluoro-2'-deoxyuridine (FUdR), but not to the free base, 5-fluorouracil. Although extracts of HeLa/B5 cells exhibited levels of thymidine kinase activity comparable to those of parental cells, rates of uptake of BUdR, FUdR, and thymidine into intact cells were much reduced. The kinetics of uptake of uridine and adenosine, nucleosides which appear to be transported independently of thymidine in HeLa cells, were similar for HeLa/B5 and the parental line (HeLa/O). Relative to thymidine uptake by HeLa/O cells, that by HeLa/B5 cells was distinctly less sensitive to nitrobenzylthioinosine (NBMPR), a specific inhibitor of nucleoside transport in various types of animal cells. Despite this difference in NBMPR sensitivity, both cell lines possessed the same number of high affinity NBMPR binding sites per mg cell protein. The altered kinetics of thymidine uptake and the NBMPR insensitivity of that function in HeLA/B5 cells suggest that resistance to BUdR is due to an altered thymidine transport mechanism.     

Novel abietane diterpenoids and aromatic compounds from Cladonia rangiferina and their antimicrobial activity against antibiotics resistant bacteria

From Cladonia rangiferina were isolated two novel abietane diterpenoids, hanagokenols A (1) and B (2). Also in this investigation, four known abitetane diterpenoids (3-6), four known labdane diterpenoids (7-10), one known isopimarane diterpenoid (11), and six known aromatic compounds were isolated. These structures were elucidated primarily through extensive NMR experiments. Hanagokenol A (1) was a unique abietane diterpene having an ether linkage between C-6 and C-18 of sugiol. Hanagokenol B (2) is also a unique secoabietane diterpene, having gamma-lactone which occurred by cleavage and subsequently oxidation between C-6/C-7 of 12-hydroxydehydroabietinol. Furthermore, all the isolated compounds (1-17) were tested for the antimicrobial activity against methicillin-resistant Staphylococcus aureus (MRSA) and vancomycin-resistant Enterococci (VRE).     

Exploring antibiotic resistant mechanism by microcalorimetry

In an effort to probe the reaction of antibiotic hydrolysis catalyzed by B3 metallo-??-lactamase (M??L), the thermodynamic parameters of penicillin G hydrolysis catalyzed by M??L L1 from Stenotrophomonas maltophilia were determined by microcalorimetric method. The values of activation free energy ??G _?? ^?? are 88.26, 89.44, 90.49, and 91.57?kJ?mol^?1 at 293.15, 298.15, 303.15, and 308.15?K, respectively, activation enthalpy ??H _?? ^?? is 24.02?kJ?mol^?1, activation entropy ??S _?? ^?? is ?219.2511?J?mol^?1?K^?1, apparent activation energy E is 26.5183?kJ?mol^?1, and the reaction order is 1.0. The thermodynamic parameters reveal that the penicillin G hydrolysis catalyzed by M??L L1 is an exothermic and spontaneous reaction.     

A new, simple approach to confer permanent antimicrobial properties to hydroxylated surfaces by surface functionalization

A new, simple method to obtain ultrathin polycationic monolayers on hydroxylated surfaces is described which uses a bifunctional copolymer comprising a reactive part (trimethoxysilane) and positive charges (quaternary ammonium salts) to confer antimicrobial properties.     

Combination of anti-angiogenic therapy and immune checkpoint blockade normalizes vascular-immune crosstalk to potentiate cancer immunity

Cancer immunotherapy with immune checkpoint inhibitors (ICIs) has revolutionized the treatment of advanced cancers. However, the tumor microenvironment (TME) functions as a formidable barrier that severely impairs the efficacy of ICIs. While the crosstalk between tumor vessels and immune cells determines the nature of anti-tumor immunity, it is skewed toward a destructive cycle in growing tumors. First, the disorganized tumor vessels hinder CD8⁺ T cell trafficking into the TME, disable effector functions, and even kill T cells. Moreover, VEGF, the key driver of angiogenesis, interferes with the maturation of dendritic cells, thereby suppressing T cell priming, and VEGF also induces TOX-mediated exhaustion of CD8⁺ T cells. Meanwhile, a variety of innate and adaptive immune cells contribute to the malformation of tumor vessels. Protumoral M2-like macrophages as well as T_H2 and Treg cells secrete pro-angiogenic factors that accelerate uncontrolled angiogenesis and promote vascular immaturity. While CD8⁺ T and CD4⁺ T_H1 cells suppress angiogenesis and induce vascular maturation by secreting IFN-γ, they are unable to infiltrate the TME due to malformed tumor vessels. These findings led to preclinical studies that demonstrated that simultaneous targeting of tumor vessels and immunity is a viable strategy to normalize aberrant vascular-immune crosstalk and potentiate cancer immunotherapy. Furthermore, this combination strategy has been evidently demonstrated through recent pivotal clinical trials, granted approval from FDA, and is now being used in patients with kidney, liver, lung, or uterine cancer. Overall, combining anti-angiogenic therapy and ICI is a valid therapeutic strategy that can enhance cancer immunity and will further expand the landscape of cancer treatment.Subject terms: Cancer immunotherapy, Cancer microenvironment, Tumour angiogenesis, Tumour immunology, Targeted therapies     

Inhibition of various steps in the replication cycle of vesicular stomatitis virus contributes to its photoinactivation by AlPcS4 or Pc4 and red light

Vesicular stomatitis virus (VSV) was used as a model virus to study the processes involved in photoinactivation by aluminum phthalocyanine tetrasulfonate (AlPcS4) or silicon phthalocyanine HOSiPcOSi(CH3)2(CH2)3N(CH3)2 (Pc4) and red light. Previously a very rapid decrease in the intracellular viral RNA synthesis after photodynamic treatment was observed. This decrease was correlated to different steps in the replication cycle. Binding of VSV to host cells and internalization were only slightly impaired and could be visualized by electron microscopy. The capability of the virus to fuse with membranes in an acidic endosomal environment was studied using both pyrene-labeled liposomes and a hemolysis assay as a model. These tests indicate a rapid decrease of fusion capacity after AlPcS4 treatment, which correlated with the decrease in RNA synthesis. For Pc4 treatment no such correlation was found. The fusion process is the first step in the replication cycle, affected by AlPcS4 treatment, but also in vitro RNA polymerase activity was previously shown to be inhibited. Inactivation of VSV by Pc4 treatment is apparently caused by damage to a variety of viral components. Photodynamic treatment of virus suspensions with both sensitizers causes formation of 8-oxo-7,8-dihydroguanosine in viral RNA as measured by HPLC with electrochemical detection. This damage might be partly responsible for inhibition of the in vitro viral RNA polymerase activity by photodynamic treatment.     

Exploring antibiotic resistant mechanism by microcalorimetry II

In an effort to understand the reaction of antibiotic hydrolysis with B2 metallo-??-lactamases (M??Ls), the thermodynamic parameters of imipenem hydrolysis catalyzed by metallo-??-lactamase ImiS from Aeromonas veronii bv. sobria were determined by microcalorimetric method. The values of activation free energy $ \Updelta G_{ \ne }^{\theta } $ are 86.400?±?0.043, 87.543?±?0.034, 88.772?±?0.024, and 89.845?±?0.035?kJ?mol^?1 at 293.15, 298.15, 303.15, and 308.15?K, respectively, activation enthalpy $ \Updelta H_{ \ne }^{\theta } $ is 18.586?±?0.009?kJ?mol^?1, activation entropy $ \Updelta S_{ \ne }^{\theta } $ is ?231.34?±?0.12?J?mol^?1?K^?1, apparent activation energy E is 21.084?kJ?mol^?1, and the reaction order is 1.5. The thermodynamic parameters reveal that the imipenem hydrolysis catalyzed by metallo-??-lactammase ImiS is an exothermic and spontaneous reaction.