DNA-passivated CdS nanocrystals: luminescence, bioimaging, and toxicity profiles

A class of luminescent semiconductor quantum dots is described that exhibit low cellular toxicity without the use of bulky surface coatings. Nucleic acids, either in the form of mononucleotides or DNA oligonucleotides, are used as a ligand system in the aqueous synthesis of CdS nanocrystals. The materials produced exhibit diameters on the order of 4 nm and luminescence in the range of 500-700 nm. Importantly, DNA-CdS is stable in buffers of high ionic strength for many hours. When tested for toxicity in HeLa cells, minimal decreases in cell viability were observed, indicating that the DNA-CdS nanocrystals are highly stable in biological media. Uptake of the nanocrystals into unfixed mammalian cells was tested, and internalization was observed. The results reported indicate that the use of DNA as a ligand system for water-soluble semiconductor nanocrystals represents a worthwhile strategy for the production of new biological imaging agents.     

Cellular consequences of copper complexes used to catalyze bioorthogonal click reactions

Copper toxicity is a critical issue in the development of copper-based catalysts for copper(I)-catalyzed azide-alkyne cycloaddition (CuAAC) reactions for applications in living systems. The effects and related toxicity of copper on mammalian cells are dependent on the ligand environment. Copper complexes can be highly toxic, can induce changes in cellular metabolism, and can be rapidly taken up by cells, all of which can affect their ability to function as catalysts for CuAAC in living systems. Herein, we have evaluated the effects of a number of copper complexes that are typically used to catalyze CuAAC reactions on four human cell lines by measuring mitochondrial activity based on the metabolism of 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide (MTT) to study toxicity, inductively coupled plasma mass spectrometry to study cellular uptake, and coherent anti-Stokes Raman scattering (CARS) microscopy to study effects on lipid metabolism. We find that ligand environment around copper influences all three parameters. Interestingly, for the Cu(II)-bis-L-histidine complex (Cu(his)(2)), cellular uptake and metabolic changes are observed with no toxicity after 72 h at micromolar concentrations. Furthermore, we show that under conditions where other copper complexes kill human hepatoma cells, Cu(I)-L-histidine is an effective catalyst for CuAAC labeling of live cells following metabolic incorporation of an alkyne-labeled sugar (Ac(4)ManNAl) into glycosylated proteins expressed on the cell surface. This result suggests that Cu(his)(2) or derivatives thereof have potential for in vivo applications where toxicity as well as catalytic activity are critical factors for successful bioconjugation reactions.     

Bacteria‐Assisted Activation of Antimicrobial Polypeptides by a Random‐Coil to Helix Transition

The application of antimicrobial peptides (AMPs) is largely hindered by their non‐specific toxicity against mammalian cells, which is usually associated with helical structure, hydrophobicity, and charge density. A random coil‐to‐helix transition mechanism has now been introduced into the design of AMPs, minimizing the toxicity against mammalian cells while maintaining high antimicrobial activity. By incorporating anionic phosphorylated tyrosine into the cationic polypeptide, the helical structure of AMPs was distorted owing to the side‐chain charge interaction. Together with the decreased charge density, the AMPs exhibited inhibited toxicity against mammalian cells. At the infectious site, the AMPs can be activated by bacterial phosphatase to restore the helical structure, thus contributing to strong membrane disruptive capability and potent antimicrobial activity. This bacteria‐activated system is an effective strategy to enhance the therapeutic selectivity of AMPs.     

Neutron activation analysis of corrosion products from gold coated ear piercing studs

Neutron activation analysis was applied to the determination of elements Au, Cr, Fe, Ni and Zn released in NaCl solution and in a culture medium in which gold coated studs were immersed for corrosion tests. The coating defects and corrosion effects on the stud surfaces were studied by scanning electron microscopy and energy dispersive spectroscopy analysis. The cytotoxicity assay of culture medium from corrosion test showed toxicity in a culture of mammalian cells.     

Monitoring transfected cells without selection agents by using the dual-cassette expression EGFP vectors

Conventional methods of selecting gene transfected cells by toxic agents may yield ambiguous results. It is difficult to determine whether cell death is due to selection agents or gene transfection, owing to the substantial overlap of the time-courses for both effects. Therefore, to determine transfection-induced cell toxicity, the mammalian expression vector pEGFP-N1 (CLONTECH Lab., Palo Alto, CA, USA) has been modified to the dual-cassette expression vectors named pEGFP-Ks by the relocation of its EGFP expression cassette. We have precisely monitored the cells transfected with this vector on our custom culture dishes, thereby bypassing the need for selection agent or fluorescent cell sorting. This is a useful method to screen genes encoding potential toxic or useful proteins without performing undesirable selection agent and also can be used to monitor the transfected cells for various purposes, either the inhibition or proliferation of mammalian cells for applications in biotechnology.     

Copper, nickel, and zinc cyclam-amino acid and cyclam-peptide complexes may be synthesized with "click" chemistry and are noncytotoxic

We describe the synthesis of cyclam metal complexes derivatized with amino acids or a tripeptide using a copper(I)-catalyzed Huisgen "click" reaction. The linker triazole formed during the synthesis plays an active coordinating role in the complexes. The reaction conditions do not racemize the amino acid stereocenters. However, a methylene group adjacent to the triazole is susceptible to H/D exchange under ambient conditions, an observation which has potentially important implications for structures involving stereocenters adjacent to triazoles in click-derived structures. The successful incorporation of several amino acids is described, including reactive tryptophan and cysteine side chains. All complexes are formed rapidly upon introduction of the relevant metal salt, including synthetically convenient cases where trifluoroacetate salts of cyclam derivatives are used directly in the metalation. None of the metal complexes displayed any cytotoxicity to mammalian cells, suggesting that the attachment of such complexes to amino acids and peptides does not induce toxicity, further supporting their potential suitability for labeling/imaging studies. One Cu(II)-cyclam-triazole-cysteine disulfide complex displayed moderate activity against MCF-10A breast nontumorigenic epithelial cells.     

Non-toxic thermotropic liquid crystals for use with mammalian cells

This paper reports the results of a study that aimed to identify thermotropic liquid crystals that are not toxic to mammalian cells. Mesogenic compounds were mixed to create eight liquid crystalline phases, each with a unique set of functional groups. We investigated the toxicity of each liquid crystalline phase using two mammalian cell lines—3T3 fibroblast and SV-40 transformed human corneal epithelial (HCEC) cells. Using dual fluorescent staining assays based on calcein acetoxymethylester (Calcein-AM) and ethidium homodimer, we measured correspondingly the number of viable and dead cells following immersion of the cells in the liquid crystals. It was found that most of the liquid crystals, such as commonly used 5CB and E7, caused cell death after contact with cells for four hours. However, we identified a class of liquid crystals containing fluorophenyl groups that possess minimal or no toxicity (as indicated by results of assays based on Calcein-AM and ethidium homodimer) to cells. Following immersion in fluorophenyl liquid crystals for four hours, the cells were observed to proliferate in culture medium at rates similar to control cells exposed to phosphate-buffered saline (PBS) for four hours. In contrast, treatment of cells for 24 hours with either PBS or liquid crystals (media containing no nutrients and growth factors) resulted in cell death.     

Carbon nanostructured materials for applications in nano-medicine, cultural heritage, and electrochemical biosensors

This review covers applications of pristine and functionalized single-wall carbon nanotubes (SWCNTs) in nano-medicine, cultural heritage, and biosensors. The physicochemical properties of these engineered nanoparticles are similar to those of ultrafine components of airborne pollution (UF) and might have similar adverse effects. UF may impair cardiovascular autonomic control (inducing a high-risk condition for adverse cardiovascular effects), cause mammalian embryo toxicity, and increase geno-cytotoxic risk. SWCNTs coated with a biopolymer, for example polyethylenimine (PEI), become extremely biocompatible, hence are useful for in-vivo and in-vitro drug delivery and gene transfection. It is also possible to successfully immobilize a human enteric virus on PEI/SWCNT composites, suggesting application as a carrier in non-permissive media. The effectiveness of carbon nanostructured materials in the cleaning, restoration, and consolidation of deteriorated historical surfaces has been widely shown by the use of carbon nanomicelles to remove black dendritic crust from stone surfaces. The nanomicelles, here, have the twofold role of delivery and controlled release of the cleaning agents. The high biocompatibility of functionalized SWCNTs with enzymes and proteins is a fundamental feature used in the assembly of electrochemical biosensors. In particular, a third-generation protoporphyrin IX-based biosensor has been assembled for amperometric detection of nitrite, an environmental pollutant involved in the biodeterioration and black encrustation of historical surfaces.     

Bismuth(III) Flavonolates: The Impact of Structural Diversity on Antibacterial Activity,Mammalian Cell Viability and Cellular Uptake

A series of homoleptic and heteroleptic bismuth(III) flavonolate complexes derived from six flavonols of varying substitution have been synthesised and structurally characterised. The complexes were evaluated for antibacterial activity towards several problematic Gram-positive (Staphylococcus aureus, methicillin-resistant Staphylococcus aureus (MRSA), and vancomycin-resistant Enterococcus (VRE)) and Gram-negative (Escherichia coli, Pseudomonas aeruginosa) bacteria. The cell viability of COS-7 (monkey kidney) cells treated with the bismuth flavonolates was also studied to determine the effect of the complexes on mammalian cells. The heteroleptic complexes [BiPh(L)₂] (in which L=flavonolate) showed good antibacterial activity towards all of the bacteria but reduced COS-7 cell viability in a concentration-dependent manner. The homoleptic complexes [Bi(L)₃] exhibited activity towards the Gram-positive bacteria and showed low toxicity towards the mammalian cell line. Bismuth uptake studies in VRE and COS-7 cells treated with the bismuth flavonolate complexes indicated that Bi accumulation is influenced by both the substitution of the flavonolate ligands and the degree of substitution at the bismuth centre.     

Composition of three essential oils, and their mammalian cell toxicity and antimycobacterial activity against drug resistant-tuberculosis and nontuberculous mycobacteria strains

Tuberculosis (TB) is the most ancient epidemic disease in the world and a serious opportunistic disease in HIV/AIDS patients. The increase in multidrug resistant Mycobacterium tuberculosis (MDR-TB, XDR-TB) demands the search for novel antimycobacterial drugs. Essential oils (EOs) have been widely used in medicine and some EOs and their major components have been shown to be active against M. tuberculosis. The aim of this work was to evaluate the antimycobacterial and cell toxicity activities of three EOs derived from Salvia aratocensis, Turnera diffusa and Lippia americana, aromatics plants collected in Colombia. The EOs were isolated by hydrodistillation and analyzed by GC/MS techniques. The EOs were tested against 15 Mycobacterium spp using a colorimetric macrodilution method and against mammalian Vero and THP-1 cells by MTT. The activity was expressed as minimal concentration in microg/mL that inhibits growth, and the concentration that is cytotoxic for 50 or 90% of the cells (CC50 and CC90). The major components were epi-alpha-cadinol (20.1%) and 1,10-di-epi-cubenol (14.2%) for Salvia aratocensis; drima-7,9(11)-diene (22.9%) and viridiflorene (6.6%) for Turnera diffusa; and germacrene D (15.4%) and trans-beta- caryophyllene (11.3%) for Lippia americana. The most active EO was obtained from S. aratocensis, with MIC values below 125 microg mL(-1) for M. tuberculosis Beijing genotype strains, and 200 to 500 microg mL(-1) for nontuberculous mycobacterial strains. The EOs were either partially or non toxic to Vero and THP-1 mammalian cells with CC50 values from 30 to > 100 microg mL(-1), and a CC90 > 100 microg mL(-1). The EOs obtained from the three aromatic Colombian plants are an important source of potential compounds against TB. Future studies using the major EO components are recommended.     

哺乳动物细胞的光电行为及其在生化分析中应用

研究了乳动物细胞的光电行为，利用这种细胞的光电效应又研究了ＮａＮ３对细胞２内电子传递和５－氟尿嘧啶（５－ＦＵ）对细胞代谢活动的影响。结果表明，该方法用于研究细胞内电子传递机制和药物对肿瘤细胞的作用既简单又切实可行。     

Structure–activity relationship of polyamine conjugates for uptake via polyamine transport system

Structural Chemistry - High toxicity of anticancer drugs led to development of targeted drug delivery directly to the specific organs. Polyamine transport system (PTS) of mammalian cells is one of...     

Biological Effects of Black Phosphorus Nanomaterials on Mammalian Cells and Animals

The remarkable progress of applied black phosphorus nanomaterials (BPNMs) is attributed to BP's outstanding properties. Due to its potential for applications, environmental release and subsequent human exposure are virtually inevitable. Therefore, how BPNMs impact biological systems and human health needs to be considered. In this comprehensive Minireview, the most recent advancements in understanding the mechanisms and regulation factors of BPNMs’ endogenous toxicity to mammalian systems are presented. These achievements lay the groundwork for an understanding of its biological effects, aimed towards establishing regulatory principles to minimize the adverse health impacts.     

Primate beta-defensins--structure, function and evolution

Host defense peptides (HDPs) are endogenous antibiotics that play a multifunctional role in the innate immunity of mammals. Among these, beta-defensins contribute to mucosal and epithelial defense, also acting as signal molecules for cellular components of innate and adaptive immunity. Numerous members of this family have been identified in mammalian and avian species, and genomic studies in human and mouse indicate a considerable complexity in their gene organization. Recent reports on the evolution of primate and rodent members of this family indicate quite a complex pattern of variation. In this review we briefly discuss the evolution of mammalian beta-defensins in relation to other types of defensins, and then concentrate on the evolution of beta-defensins 1 to 4 in primates. In particular, the surprisingly varied patterns of evolution, which range from neutral or weakly purifying, to positive selection to a high level of conservation are analyzed in terms of possible genetics, structural or functional implications, as well as to observed variations on the antimicrobial activity in vitro. The role of polymorphisms in the genes encoding for these host defense peptides in determining susceptibility to human diseases are also briefly considered.     

Selective disruption of early/recycling endosomes: release of disulfide-linked cargo mediated by a N-alkyl-3beta-cholesterylamine-capped peptide

The use of endocytic uptake pathways to deliver poorly permeable molecules into mammalian cells is often plagued by entrapment and degradation of material in late endosomes and lysosomes. As a strategy to prevent the exposure of cargo to these highly hydrolytic membrane-sealed compartments, we synthesized derivatives of the membrane anchor N-alkyl-3beta-cholesterylamine that selectively target linked compounds to less hydrolytic early/recycling endosomes. By targeting a pH-dependent membrane-lytic dodecapeptide and a disulfide-linked fluorophore to these compartments in Chinese hamster ovary cells or Jurkat lymphocytes, membranes of early/recycling endosomes were selectively disrupted, resulting in cleavage of the disulfide and escape of the fluorophore into the cytosol and nucleus with low toxicity. The ability of appropriately designed N-alkyl-3beta-cholesterylamines to deliver cargo into and release disulfide-linked cargo from relatively nonhydrolytic early/recycling endosomes may be useful for the delivery of a variety of sensitive molecules into living mammalian cells.     

QSAR for acetylcholinesterase inhibition and toxicity of two classes of phosphoramidothioates

Methamidophos (Met) is a weak inhibitor of housefly head AChE but at the same time it is highly toxic to the common housefly. The lethality of Met is believed to be due to AChE inhibition. An extensive QSAR study may help in determining the mode of action of Met in vivo and in vitro and provide a rational for its high insecticidal toxicity. Acephate (Ace), like Met, is a poor inhibitor of AChE in vitro and has a comparable to Met insect toxicity in vivo. Contrary to Met, though, Ace has much lower mammalian toxicity. Understanding the structural properties which make insecticides toxic to insects but not to mammals is of great importance, since mammals (including humans) are inadvertently exposed to these compounds. Our results were consistent with the model in which both the in vitro and in vivo toxicity of Met depends on the inhibition of the active center of AChE by the unchanged Met. An optimal susceptibility to hydrolysis is needed for Met and its analogs to have high insecticidal activity since in order to phosphorylate AChE they need to be hydrolyzed and at the same time their stability is of great importance in vivo for accumulating at the site of action. The insecticidal activity of Ace analogs may be due to direct interaction with the active center of the AChE. The mammalian toxicity of Ace analogs may be due to interaction with an 'allosteric' reaction center in the AChE.     

Synthesis and antimicrobial,antiproliferative and anti-inflammatory activities of novel 1,3,5-substituted pyrazoline sulphonamides

The design of novel molecules is imperative for the discovery of potent drugs in the medicinal chemistry field. In this work, new 1,3,5-substituted pyrazoline sulphonamides were synthesised using a two-step process with microwave assistance and evaluated biologically for their antimicrobial, antiproliferative, and anti-inflammatory properties. Most of the sulphonamides bearing 3-OH or 4-Cl groups exhibited significant inhibition of two Gram-positive bacteria, Bacillus subtillis and Staphylococcus aureus, and the yeast Candida albicans. Six compounds showed good activity against the cancer cell lines cervix carcinoma (Hep-2C) and human lung carcinoma (A549) with IC₅₀ in the range 16.03 ± 1.63 to 22.75 ± 0.19 μM and 18.64 ± 1.02 to 20.66 ± 2.09 μM, respectively, and exhibited low toxicity against mammalian Vero cells. In evaluating in vitro anti-inflammatory behaviour, five compounds showed high inhibition of NO production over the standard reference, with low toxicity against murine macrophage cell line RAW 264.7. Further investigation found that two compounds, 1b and 18b, exhibited the highest activity when testing mouse ear oedema. The findings are promising for the discovery of potent new drugs.     

GLASS and PLASTIC PHOTOLUMINESCENCE: INTERACTION WITH AQUEOUS MEDIA and CULTURED MAMMALIAN CELLS

Several types of glass and plastic materials were shown to exhibit intense photoluminescence when irradiated with UV. Water or phosphate buffered saline (PBS) contained within vessels of the respective materials when irradiated, also demonstrated relatively long-lived luminescence. A significant percentage (30%) of cultured mammalian cells were killed when exposed to UV-irradiated glass beads. The nature of the luminescence of water or PBS, or whether this or the photoluminescence of glass is directly responsible for cell toxicity, is unknown. However, we call attention to this phenomenon as a potential complicating factor in photobiological studies.     

The versatility of carbohydrates in antimicrobial applications

The worsening situation of global drug resistance is urgently demanding for novel antimicrobial agents. Considerable efforts have been concentrated on developing new antibacterial therapies with new mode of actions, exerting no selective pressure on bacterial mutation, and minimizing toxicity to host cells. In this context, active targeting can greatly contribute to selectivity between pathogens and mammalian cells in which carbohydrates, playing important roles in numerous biological processes, can be employed as targeting ligands or “trojan horse.” This short account has discussed the recent results of carbohydrate-based antimicrobial agents developed by our group. Other excellent works by other scientists and possible directions in the future are also discussed.