Loss of density-dependent regulation of multiplication of BALB-3T3 cells chemically transformed in vitro

Balb/3T3 cells show density-dependent regulation of multiplication with the final cell density depending on serum concentration in the media. Chemically transformed Balb/3T3 cells (Balb/3T3-D) pile up on each other, multiply to a high cell density, but have decreased DNA synthesis at very high cell densities. Balb/3T3-D cells require less serum for multiplication compared with original Balb/3T3 cells. A rat serum fraction and a bovine β-globulin fraction stimulate the multiplication of Balb/3T3 cells but only slightly stimulate Balb/3T3-D cells indicating different serum factors stimulate growth of these two cell types. The multiplication properties of Balb/3T3-D cells are very similar to those of SV-40 transformed 3T3 cells, however, these properties were brought about by a single treatment by a chemical carcinogen, without an exogenous virus. The transformation altered the contact of cells to one another, indicating a permanent chemical change in the membrane structure.     

Embryonal carcinoma cell growth and differentiation. Production of and response to molecules with transforming growth factor activity

Transforming growth factors are known to induce anchorage-independent growth of non-transformed cells, and are released by a variety of cells, including MSV-transformed cells. This study demonstrates that the differentiated cells derived from F9 and PC-13 embryonal carcinoma cells, but not the parental cells themselves, respond by increased growth to several factors released by MSV-transformed cells, including partially purified sarcoma growth factor. The chemical properties of the growth-promoting activity are shown to match the chemical properties of the transforming growth factors released by MSV-transformed cells. Furthermore, F9 and PC-13 embryonal carcinoma cells, which do not respond to factors released by MSV-transformed cells, are shown to release factors with transforming growth factor activity. Based on the close relationship between mouse embryonal carcinoma cells and cells of early mouse embryos, it is suggested that molecules with transforming growth factor activity may play a role during the early stages of mammalian development.     

An Atomic Force Microscope Study Revealed Two Mechanisms in the Effect of Anticancer Drugs on Rate-Dependent Young’s Modulus of Human Prostate Cancer Cells

Mechanical properties of cells have been recognized as a biomarker for cellular cytoskeletal organization. As chemical treatments lead to cell cytoskeletal rearrangements, thereby, modifications of cellular mechanical properties, investigating cellular mechanical property variations provides insightful knowledge to effects of chemical treatments on cancer cells. In this study, the effects of eight different anticancer drugs on the mechanical properties of human prostate cancer cell (PC-3) are investigated using a recently developed control-based nanoindentation measurement (CNM) protocol on atomic force microscope (AFM). The CNM protocol overcomes the limits of other existing methods to in-liquid nanoindentation measurement of live cells on AFM, particularly for measuring mechanical properties of live cells. The Young’s modulus of PC-3 cells treated by the eight drugs was measured by varying force loading rates over three orders of magnitude, and compared to the values of the control. The results showed that the Young’s modulus of the PC-3 cells increased substantially by the eight drugs tested, and became much more pronounced as the force load rate increased. Moreover, two distinct trends were clearly expressed, where under the treatment of Disulfiram, paclitaxel, and MK-2206, the exponent coefficient of the frequency- modulus function remained almost unchanged, while with Celebrex, BAY, Totamine, TPA, and Vaproic acid, the exponential rate was significantly increased.     

Single-channel current recordings of acetylcholine receptors in electroplax isolated from theElectrophorus electricus main and Sachs' electric organs

Summary Extensive chemical kinetic measurements of acetylcholine receptor-controlled ion translocation in membrane vesicles isolated from the electroplax ofElectrophorus electricus have led to the proposal of a minimum model which accounts for the activation, desensitization, and voltage-dependent inhibition of the receptor by acetylcholine, suberyldicholine, and carbamoylcholine. Comparison of chemical kinetic measurements of the dynamic properties of the acetylcholine receptor in vesicles with the properties of the receptor in cells obtained from the same organ and animal have been hampered by an inability to make the appropriate measurements withElectrophorus electricus electroplax cells. Here we report a method for exposing and cleaning the surface of electroplax cells obtained from both the Main electric organ and the organ of Sachs and the results of single-channel current recordings which have now become possible. The single-channel current recordings were made in the presence of either carbamoylcholine or suberyldicholine, as a function of temperature and transmembrane voltage. Both the channel open times and the single-channel conductance were measured. The data were found to be consistent with the model based on chemical kinetic measurements using receptor-rich membrane vesicles prepared from the Main electric organ ofE. electricus.     

Studying Single Red Blood Cells Under a Tunable External Force by Combining Passive Microrheology with Raman Spectroscopy

The dynamic micromechanical and structural properties of single human red blood cells are studied using a combination of dual trap optical tweezers and confocal Raman spectroscopy. Such a combination permits us to show a direct relationship between the rheological properties and chemical structure conformation. The frequency dependence of the complex stiffness of the cells was measured using both one and two probe response functions under identical experimental conditions. Both the microrheology and Raman measurements were performed at different stretching forces applied to the cell. A detailed analysis of the auto- and cross-correlated probe motions allows exploring the local and overall viscoelastic properties of the cells over a controlled range of the deformations. The observed growth of the cell viscoelasticity with stretching was associated with structural changes in the cell membrane monitored via the Raman spectroscopy.     

The Dependence of the Magnetic-Resonance Contrast Imaging Properties of Ultrasmall Nanoparticles of Complex Iron Oxide on Their Chemical Composition

In this paper, we considered the optimization of the magnetic-resonance imaging properties of nanosystems that are based on ultrasmall nanoparticles of complex iron oxide by modifying their chemical composition with Zn, Mn, Mg, or Co. The relationship between the chemical composition, crystal structure, magnetic phase, and contrast-imaging properties of the nanoparticles was investigated. The comparative cytotoxicity of the nanoparticle solutions on HeLa cells was studied. The prospects for these types of nanosystems for the development of contrast MRI agents with the predominant effect on the T1 or T2 parameters of the body tissues were shown.     

Preparation and properties of reduced chitooligomers

In order to prevent the browning of the chitooligomer product prepared from enzymatic hydrolysis, the chitooligomers were reduced by potassium borohydride. The chemical structures and physical properties of the reduced chitooligomers were characterized by magnetic resonance spectra, X-ray diffraction, UV-spectrophotometry, thermogravimetric analysis, differential thermal analysis. The chemical stability of the chitooligomers increased after reduction. The reduced chitooligomers had no oral acute toxicity, and they had almost the same inhibition effect against the sarcoma 180 tumor cells in mice by intraperitoneal injection as the fresh chitooligomers.     

Taxanes with high potency inducing tubulin assembly overcome tumoural cell resistances

We have found that four taxanes with chemical modifications at positions C10 and C13 were active against all types of taxane resistant cell lines, resistant by P-gp overexpression, by mutations in the β-tubulin binding site or by overexpression of the highly dynamic βIII-tubulin isotype.We have characterized the interaction of taxanes with high activity on chemotherapy resistant tumoural cells with microtubules, and also studied their cellular effects. The biochemical property enhanced in comparison with other taxanes is their potency at inducing tubulin assembly, despite the fact that their interactions with the microtubule binding sites (pore and luminal) are similar as studied by NMR and SAXS. A differential interaction with the S7–S9 loop (M-loop) is responsible for their enhanced assembly induction properties. The chemical changes in the structure also induce changes in the thermodynamic properties of the interaction, indicating a higher hydrophilicity and also explaining their properties on P-gp and βIII overexpressing cells and on mutant cells.The effect of the compounds on the microtubular network is different from those observed with the classical (docetaxel and paclitaxel) taxanes, inducing different bundling in cells with microtubules being very short, indicating a very fast nucleation effect and reflecting their high assembly induction power.     

The distribution of chlorine e6 and its derivatives in HeLa cells studied using luminescence microscopy

The influence of the chemical structure of porphyrin pigments on their accumulation and localization in HeLa cells has been examined by the scanning fluorescence microphotometry. It has been found that the replacement of carboxyl groups of chlorine e6 for methyl and amino groups has no influence on the pigment distributions in cells. All the pigments are bound by cell membrane structures. The chemical modification of chlorine e6 structure is essential for the ability of pigment to be accumulated by cells that can be used to increase the efficiency of cancer phototherapy. The charge and hydrophobic properties of pigment molecules are of great importance for accumulating porphyrin sensitizers by cells.     

Effect of surface modification of rat erythrocytes of different ages on their partitioning behavior in charge-sensitive two-polymer aqueous phases

Partitioning differences between cells in two-polymer aqueous phase systems originate from subtle differences between the surface properties of cells. Because of the exponential relation between the parameters affecting the partition ratio (P) and the P itself, differences in membrane components suspected of effecting the differential partitioning of closely related cell populations cannot be directly established by conventional chemical assay techniques. In order to study the chemical nature of the components responsible for the age-related changes in surface properties of rat red cells we have devised an approach which uses a combination of isotopic labeling of erythrocyte subpopulations of distinct cell age with different enzyme and/or chemical treatments followed by countercurrent distribution in charge-sensitive two-polymer aqueous phase systems. These studies show that: neuraminidase-susceptible sialic acid is not responsible for the cell age-related surface differences detected by partitioning; the component(s) responsible for the cell age-related surface differences can be extracted (from aldehyde-fixed red cells) with ethanol or cleaved with dilute sulfuric acid. Our data are consistent with the hypothesis that ganglioside-linked sialic acid is the chemical moiety responsible for the cell charge-associated surface differences among rat red blood cells of different ages.     

Advances in the chemistry of small molecule fluorescent probes

Small molecule fluorophores are essential tools for chemical biology. A benefit of synthetic dyes is the ability to employ chemical approaches to control the properties and direct the position of the fluorophore. Applying modern synthetic organic chemistry strategies enables efficient tailoring of the chemical structure to obtain probes for specific biological experiments. Chemistry can also be used to activate fluorophores; new fluorogenic enzyme substrates and photoactivatable compounds with improved properties have been prepared that facilitate advanced imaging experiments with low background fluorescence. Finally, chemical reactions in live cells can be used to direct the spatial distribution of the fluorophore, allowing labeling of defined cellular regions with synthetic dyes.     

Bactericidal activity of the tail of Pseudomonas aeruginosa bacteriophage PS17.

The tail of bacteriophage PS17 of Pseudomonas aeruginosa was shown to be bactericidal, and its properties were compared with those of pyocin R1. Temperature-sensitive mutants were isolated from PS17, and the products at nonpermissive temperature were morphologically characterized. Bactericidal substances were found in the lysates of such mutants that were defective in the head formation but not in the tail formation. Phage tails were purified from the lysate of one such mutant, and its chemical and biological properties were studied. Isolated tails killed sensitive cells by a single-hit process and repressed the uptake of leucine in sensitive cells. These results were consistent with the previous findings on the serological and morphological relationship between PS17 and pyocin R1. However, certain differences were also shown between them in shape and protein composition.     

Regulation of amino acid transport in L6 myoblasts. II. Different chemical properties of transport after amino acid deprivation

The mechanism of stimulation of amino acid transport system A caused by amino acid deprivation in L6 cells was investigated. In cells loaded with alpha-aminoisobutyric acid (AIB), amino acid deprivation increased the rate of proline uptake only after the intracellular [AIB] dropped below 7 mM. Efflux of proline was not sensitive to the presence of proline in the outer medium (with or without external Na+), suggesting that efflux through system A (and possibly uptake) is not susceptible to transinhibition. Transport (stimulated uptake) into amino acid-deprived cells and that into amino acid-supplemented cells differed in several chemical properties: 1) In the former group, transport was higher at lower pH values than in the latter, and the optimum pH values were 7.5 and 7.8, respectively. 2) Unlike proline uptake in supplemented cells, uptake in deprived cells was inhibited by 50% with N-ethylmaleimide (1 mM) or by 50 microM p-chloromercuribenzoate (PCMBS). Inhibition by PCMBS was not due to collapse of the Na+ gradient. The mercurial inhibited only the deprivation-induced stimulation of transport, bringing the rate of proline uptake to the "basal" uptake level observed in amino acid-supplemented cells. Proline uptake was not stimulated by a second deprivation following treatment with PCMBS and a supplementation-deprivation cycle. However, in untreated cells, or by reversing mercaptide formation with dithiotreitol, the second deprivation stimulated transport. Deprivation at 4 degrees C did not elicit stimulation of proline uptake. Cycloheximide prevented the stimulation and decreased the rate of proline uptake in deprived cells more efficiently than in supplemented cells. Actinomycin D prevented stimulation when added at the onset of deprivation. The above data indicate that stimulation of transport by deprivation is protein synthesis-dependent and that the stimulated transport had chemical properties distinct from the "basal" transport in supplemented cells. The evidence presented is consistent with a model of activation of a finite pool of transporters upon deprivation, the chemical characteristics of which differ from those of the "basal" transport system.     

Morphological and chemical analyses of red pine (Pinus resinosa ait.) buds

Summary On a known red pine, K-deficient to non-K-deficient, site continuum which has been examined for tree morphological and chemical properties along with soil physical and chemical properties, results of bud analyses are presented and discussed as a possible diagnostic technique. Simple correlations between all pairs of bud morphological properties and between these properties and tree height, and between all pairs of bud chemical properties and between these properties and tree height were examined; and the results of the bud nutrient element concentrations and tree height were subjected to a multiple regression analysis.The results demonstrated the potential value of bud chemical analysis for diagnostic purposes.     

Evidence that the isomerization of D-ribose and L-rhamnose is catalyzed by the same enzyme in Mycobacterium smegmatis.

D-Ribose isomerase was purified and crystallized from cells of Mycobacterium smegmatis grown on either D-ribose or L-rhamnose. Isomerase activity for both of these sugars remained together throughout the purification. The isomerase from L-rhamnose-grown cells had the same chemical and physical properties as the enzyme isolated from D-ribose grown cells. In addition, immunological studies indicated that both activities were in the same protein since antisera prepared against either of the crystals cross-reacted with the other and gave lines of symmetry by the agar gel diffusion method.     

Immunogenic changes of murine lymphoma cells following in vitro treatment with aryl-triazene derivatives

A series of dimethyl aryl-triazene derivatives and related monomethyl compounds were studied for their efficacy in mediating a strong increase in immunogenicity (i.e., chemical xenogenization, CX) of murine leukemic cells following in vitro treatment. It was found that all compounds under investigation were able to induce CX. The dimethyl derivatives were able to induce CX only after metabolic activation, whereas related monomethyl compounds were active per se. The antigenicity acquired by triazene-treated leukemic cells was very marked; intact hosts histocompatible with the parental line were able to reject up to 10(7) cells. Antigenic tumor cells retained their immunogenic properties even after a large number of transplant generations in the absence of the drug. This means that marked immunogenicity of triazene-treated cells is a stable and heritable characteristic.     

Staining and osmotic properties of young gametophytes ofPolypodium vulgare L. and their bearing on rhizoid function

Summary The rhizoids of gametophytes ofPolypodium vulgare L. rapidly absorb vital stains whereas the protonemal cells are impermeable to these stains, which can only enter the cells from the rhizoids. The protonemal cells which bear rhizoids were found to have a slightly higher osmotic equivalent than did the rhizoids or the protonemal cells on either side. From the results of several staining procedures it was demonstrated that the rhizoid walls contain free carboxyl groups and thus possess cation exchange properties. Most of the carboxyl groups are probably present in a yellow-brown wall matrix substance, which shows high resistance to acid and alkali extraction. The precise nature of this substance has not been determined but it could be an acid mucopolysaccharide. Carboxyl groups are detectable in the protonemal cell walls only after saponification and are probably esterified in the untreated wall. Several other chemical and physiological differences were found between the rhizoids and the protonemal cells and it was concluded that the specific properties of the rhizoids are related to their function as organs of uptake.     

Influence of medium consumption on cell elasticity

The mechanical behavior of a living cell is highly dynamic and constantly adapts to its local environment. Changes in temperature and chemical stimuli, such as pH, may alter the structure of the cell and its mechanical response. Thus, the mechanical properties may serve as an indicator for the cellular state. We applied dielectrophoretic forces to suspension cells by means of two microelectrodes. The resultant stretching was analyzed on consecutive cultivation days with respect to the influence of medium consumption. Systematic experiments clearly showed that the medium consumption affected the viscoelastic properties of the investigated human leukemia cells HL-60. The shift in pH value and the culture medium depletion were identified as potentially responsible for the differing temporal development of the cell deformation. Both factors were investigated separately and a detailed analysis indicated that the changes observed in the cellular stiffness were primarily attributable to nutrient depletion.     

Contribution of the nucleus to the mechanical properties of endothelial cells.

The cell nucleus plays a central role in the response of the endothelium to mechanical forces, possibly by deforming during cellular adaptation. The goal of this work was to precisely quantify the mechanical properties of the nucleus. Individual endothelial cells were subjected to compression between glass microplates. This technique allows measurement of the uniaxial force applied to the cell and the resulting deformation. Measurements were made on round and spread cells to rule out the influence of cell morphology on the nucleus mechanical properties. Tests were also carried out with nuclei isolated from cell cultures by a chemical treatment. The non-linear force-deformation curves indicate that round cells deform at lower forces than spread cells and nuclei. Finite-element models were also built with geometries adapted to actual morphometric measurements of round cells, spread cells and isolated nuclei. The nucleus and the cytoplasm were modeled as separate homogeneous hyperelastic materials. The models simulate the compression and yield the force-deformation curve for a given set of elastic moduli. These parameters are varied to obtain a best fit between the theoretical and experimental data. The elastic modulus of the cytoplasm is found to be on the order of 500N/m(2) for spread and round cells. The elastic modulus of the endothelial nucleus is on the order of 5000N/m(2) for nuclei in the cell and on the order of 8000N/m(2) for isolated nuclei. These results represent an unambiguous measurement of the nucleus mechanical properties and will be important in understanding how cells perceive mechanical forces and respond to them.