Surendra P. Verma

Structural changes in plasma membranes prepared from irradiated Chinese hamster V79 cells as revealed by Raman spectroscopy

The effect of gamma irradiation on the integrity of plasma membranes isolated from Chinese hamster V79 cells was investigated by Raman spectroscopy. Plasma membranes of control V79 cells show transitions between (-) 10 and 5 degrees C (low-temperature transition), 10 and 22 degrees C (middle-temperature transition), and 32 and 40 degrees C (high-temperature transition). Irradiation (5 Gy) alters these transitions markedly. First, the low-temperature transition shifts to higher temperature (onset and completion temperatures 4 and 14 degrees C). Second, the middle-temperature transition shifts up to the range of about 20-32 degrees C, but the width remains unchanged. Third, the higher temperature transition broadens markedly and shifts to the range of about 15-40 degrees C. Protein secondary structure as determined by least-squares analysis of the amide I bands shows 36% total helix, 55% total beta-strand, and 9% turn plus undefined for control plasma membrane proteins. Plasma membrane proteins of irradiated V79 cells show an increase in total helix (40 and 45% at 5 and 10 Gy, respectively) and a decrease in the total beta-strand (48 and 44% at 5 and 10 Gy, respectively) structures. The qualitative analysis of the Raman features of plasma membranes and model compounds in the 1600 cm-1 region, assigned to tyrosine groups, revealed that irradiation alters the microenvironment of these groups. We conclude that the radiation dose used in the survival range of Chinese hamster V79 cells can cause damage to plasma membrane proteins without detectable lipid peroxidation, and that the altered proteins react differently with lipids, yielding a shift in the thermal transition properties.

Effect of soy‐derived isoflavonoids on the induced growth of MCF‐7 cells by estrogenic environmental chemicals

Isoflavonoids are natural plant compounds and possess antitumorigenic properties. Many environmental chemicals have been found to be estrogenic and can enhance tumor growth in estrogen receptor-positive cells. In the present study, the effects of genistein, daidzein, biochanin A, formononetin, and equol on the proliferation of estrogen receptor-positive MCF-7 cells induced by synthetic chemicals 1-(o-chlorophenyl)-1-(p-chlorophenyl)-2,2,2-trichloroethane (o,p-DDT), 4-nonylphenol (4-NP), and 5-octylphenol (5-OP) found in the environment were investigated. Genistein, biochanin A, equol, and to some extent daidzein, but not formononetin, at < 10 microM can enhance the growth of MCF-7 cells in the absence of environmental chemicals. Formononetin was toxic to MCF-7 cells at the tested concentrations. The environmental chemicals 4-NP, 5-OP, and o,p-DDT and the natural estrogen 17 beta-estradiol at 5, 5, and 10 microM and 5 nM, respectively, induced proliferation of MCF-7 cells. In the presence of isoflavonoids (> 25 microM), the environmental chemical-induced cell proliferation was inhibited. Individually, genistein (IC50 = 25-33 microM) was the most potent inhibitor against the induced proliferation of MCF-7 cells of the isoflavonoids needed for a 50% suppression of growth induced by 4-NP, 5-OP, and o,p-DDT. A mixture of isoflavonoids was the most potent inhibitor against the induced proliferation. Estrogen receptor-dependent and -independent pathways could be involved in the inhibitory actions of isoflavonids. Because it is impossible to have a chemical-free environment, the in vitro data presented here are of practical importance to develop evolving dietary strategies and tactics against the adverse health effects of environmental chemicals.

Organic pesticides modify lipid-lipid and lipid-protein domains in model membranes. A laser Raman study.

The effect of hexachlorocyclohexane (all isomers) on the thermal transition properties of phospholipid liposomes was determined by Raman spectroscopy. Raman spectra of liposomes with and without the presence of hexachlorocyclohexanes were recorded in the C-H stretching region which shows three major bands around 2850, 2880 and 2930 cm-1. Thermal transition properties were estimated from plots of I2880/I2850 and or I2930/I2850 vs. temperature, where I represents the intensity of the respective band. Our data on phospholipid liposomes reveal that delta- and gamma-hexachlorocyclohexanes drastically reduce and broaden the main thermal transitions of phospholipids at toxic level concentrations. These effects are more pronounced in liposomes containing 18 or more carbon atom long acyl chains. Alpha- and beta-isomers at similar concentrations show a minimum effect on the thermal transition properties of phospholipids. Raman analysis of phospholipid liposomes containing melittin, interestingly, reveal that the delta-isomer unlike the gamma-isomer strongly alters the transition properties of boundary lipids. These data suggest that the effect of hexachlorocyclohexanes on the thermal transition properties of membranes is stereo specific and that the delta-isomer preferably disrupts the lipid-protein domains. Results are explained on the basis of the dynamic flexibility owing to the equatorial and axial chlorine atoms of various hexachlorocyclohexane isomers.

Role of proteins in protection against radiation-induced damage in membranes

The effect of gamma irradiation on liposomes in the presence of a large number of commercially available proteins has been studied. Experiments were designed to demonstrate that the configuration of both acyl chain and cis C = C bonds created by lipid-protein associations are crucial in autocatalyzed radiation-induced lipid peroxidation. Raman spectroscopy was used to characterize these states. Raman spectra in the C-C stretching region show three prominent bands at 1064, 1090, and 1125 cm-1, assigned to trans, gauche, and trans C-C bonds, respectively. A single symmetrical C = C stretching band assigned to the cis isomer occurs at 1660 cm-1. The intensity ratios (I1064/I1090) and (I1660/I1440) are used as Raman probes to define the conformational states of acyl chains and C = C bonds, respectively. Our data show that the ratio (I1064/I1090) decreases in the presence of proteins, indicating that these proteins induce more gauche structures. Upon irradiation, the ratio (I1064/I1090) increases by about 30% in the absence of proteins and by about 15% in the presence of proteins. This shows that proteins retain the gauche structures in irradiated samples. The ratio (I1660/I1440) decreases in liposomes containing proteins, showing that proteins modify the configuration of cis C = C bonds. Upon irradiation, this ratio decreases by about 45-50% in samples without proteins and by about 10% in samples with proteins. These data show that proteins inhibit the radiation-induced configurational changes in the cis C = C bonds. The determination of radiation-induced peroxides (as malondialdehyde equivalents) in liposomes reveals that proteins inhibit the formation of peroxide products at low molar ratio and that the preventive capacity of different proteins is different. We conclude that proteins alter the conformation of both acyl chains and cis C = C bonds in liposomes and that these altered states are less sensitive to radiation-induced peroxidation.

Hexachlorocyclohexane pesticides reduce survival and alter plasma membrane structure of Chinese hamster V79 cells

We studied the cytotoxic effects of alpha-, beta-, gamma-, and delta-hexachlorocyclohexanes (HCCH) on the survival of Chinese hamster V79 cells using clonogenic assays. Lethal dose yielding 50% cell survival (LD50) suggests the following order of cytotoxicity: delta-(+)gamma-HCCH (LD50 4 micrograms/ml) (1:1, w/w, mixture) > delta-HCCH (LD50 6 micrograms/ml) > gamma-HCCH (LD50 13 micrograms/ml) > alpha-HCCH (LD50 approx. 35 micrograms/ml) >> beta-HCCH. Structural changes in plasma membranes prepared from HCCH-treated V79 cells at dose yielding 10% cell survival (LD10) were analyzed using Raman spectroscopy. Raman spectra of plasma membranes show bands at 2850, 2880-2890, and 2935 cm-1 in the C-H stretching region. The plot of the ratio (I2880-2890/I2850) vs temperature for control plasma membranes shows two transitions between -5 and 5 degrees C and between 12 and 20 degrees C. Plasma membranes prepared from gamma- and delta-HCCH-treated Chinese hamster V79 cells show single transitions between -4 and 11 degrees C and between -2 and 11 degrees C, respectively. These changes in the thermal transition properties suggest that both gamma- and delta-HCCH alter lipid and lipid-protein phases of the plasma membrane of V79 cells. Raman analysis of the amide I and amide III region spectra further suggest that delta-HCCH also alters the secondary structure and the environment of highly amidated segments of plasma membrane proteins. We suggest that the primary action of biologically active HCCH isomers is to disrupt the organization of the plasma membrane and that may affect cell viability.

Low levels of the pesticide, δ-hexachlorocyclohexane, lyses human erythrocytes and alters the organization of membrane lipids and proteins as revealed by Raman spectroscopy

We studied the nature of the interaction of delta-hexachlorocyclohexane (delta-HCCH), a pesticide having a stereoisomeric structure similar to inositol, with red blood cells. Cell survival data, measured as percent of hemoglobin released by delta-HCCH, show that the cell lysis increases with post exposure time. delta-HCCH at 55-60 micrograms/ml causes about 70% cell lysis after 24 h of exposure. The nature of interaction of delta-HCCH with membrane components was evaluated by studying the thermotropic transitions and protein structure of ghosts using Raman spectroscopy. Control ghosts show transitions with onset/completion temperatures 30 degrees C/38 degrees C (high temperature transition) and 3 degrees C/10 degrees C (middle temperature transition) when monitored by the I2935/I2850 ratio. The interaction of delta-HCCH drastically broadens the high temperature transition and shifts it to the temperature range of 10-29 degrees C. The plots of (I2880-90/I2850) vs. temperature show two transitions for control ghosts, one extending from -10 degrees C to 3 degrees C (lower temperature transition) and the other from about 7 degrees C to about 15 degrees C (middle temperature transition). Ghosts lysed with delta-HCCH shows only a single and a very broad transition in the range of about -3 degrees C to about 15 degrees C. These changes in the thermal transition properties suggest that delta-HCCH alters lipid and lipid-protein phases of erythrocyte membranes. The comparison of Raman spectra in the amide I and III regions of erythrocyte ghosts and purified band 3 with several amidated compounds reveals that cytoskeleton proteins contain highly amidated residues (probably glutamine and asparagine). The interaction of delta-HCCH with erythrocytes drastically alters the environment of these amidated residues indicating the involvement of cytoskeleton proteins. We conclude that the interaction of delta-HCCH with red blood cells disrupt membrane structure and change the environment of cytoskeleton proteins that could cause cell lysis.

Ionizing Radiation Target Groups of Band 3 Inserted into Egg Lecithin Liposomes as Determined by Raman Spectroscopy

The purified integral membrane protein, band 3, from human erythrocytes was inserted into egg lecithin liposomes. The insertion of band 3 was determined from thermal transition data from the analysis of the C--H stretching region bands recorded at temperatures from 25 to -22 degrees C. Raman spectra show that band 3 considerably broadens and lowers the thermal transition of egg lecithin liposomes, suggesting the insertion of band 3. The band 3-inserted liposomes were irradiated with gamma-rays (40 Gy) and the radiation target groups were determined by the analysis of the structural sensitive Raman bands in the 1600-1700 cm-1 (amide I), 1200-1300 cm-1 (amide III) and 550-1030 cm-1 (side chain amino groups) regions. The radiation-sensitive groups as identified from Raman spectra in the region 550-1030 cm-1 are tyrosines and cysteines. The radiation-induced changes in the secondary structure were determined from amide I and III bands. Quantitative estimation using the curve fitting method shows that band 3 contains 44% total helix, 48% beta strand and 8% undefined plus turns (error +/- 4%). The secondary structure changes to 35% total helix, 42% total beta-strand and 23% turned and undefined upon irradiating band 3 containing liposomes. We suggest that ionizing radiation preferably damages tyrosine and cysteine side chain residues and reduces the amount of alpha-helical configuration of band 3.

Raman spectroscopic evidence for structural changes in poly-L-lysine induced by an approximately 50 mT static magnetic field

We have explored the mechanism of coupling of an approximately 50 mT static magnetic field with the alpha helices of poly-L-lysine. Structural changes in poly-L-lysine were determined by Raman spectroscopy. Our testable hypothesis is that static magnetic fields of this magnitude can couple with the alpha-helical segments of the polypeptide, and, as a result, the structure of the polypeptide is significantly altered. Our model further suggests that a static magnetic field can promote protein unfolding and can prevent refolding.