Cadmium-induced alterations in essential trace element homoeostasis in the tissues of scallop Mizuhopecten yessoensis

Studies were performed regarding the effect of cadmium accumulation on the levels of essential elements (copper, zinc and iron) in the tissues of a marine bivalve mollusc, Mizuhopecten yessoensis, exposed to cadmium at 250 ppb during 2 weeks. It was found that the concentration of cadmium in the tissues increased in the order gonads < gills < hepatopancreas < kidney during exposure time. However, the highest value of concentration factor was recorded in the gills. Our data demonstrate that cadmium accumulation in all mollusc tissues is followed by the alterations in copper, zinc and iron concentration, but that the pattern of these changes varies with each tissue. Cadmium had the most pronounced effects on essential trace element homoeostasis in the kidney. The present study suggests that levels of the essential metals in a particular tissue can be modified depending on the level of cadmium accumulation. The possible mechanisms of the effects of cadmium on the essential trace elements are discussed.     

Safe common agents for improved NMR contrast

As nuclear magnetic resonance imaging techniques have developed, a need for agents which can enhance and improve the natural tissue relaxation time differences has become apparent. Especially valuable would be agents that differentially alter NMR images in a manner related to tissue physiology and disease processes. Sophisticated para-magnetic and free radical contrast agents will be discussed in other papers in this issue. However, in this report, some common agents which are currently used in research and in human clinical studies for other purposes, but which can alter NMR contrast will be discussed. These agents include olive oil, estrogen hormones, diuretics, ethanol, glycerin, and dimethyl sulfoxide. Measurements of their relative effects on T1 and T2 of normal and cancerous breast tissues, a variety of body organs, and brain are presented. Some of these agents may have immediate practical applications in human NMR imaging studies.     

A new nuclear magnetic resonance property of lung

Inflated lung has a nuclear magnetic resonance (NMR) free-induction decay (FID) which is short compared with that of collapsed lung and those of other body tissues. An almost identically short FID is obtained from a slurry of 5-micron alumina particles in water. Interfaces between air and water in lung and between alumina and water in the slurry appear to be the source of spatial internal magnetic inhomogeneities which produce NMR line broadening and the short FID. Paired images that included lung, taken with paired symmetric and asymmetric NMR spin-echo sequences, permit the generation of an image, by subtraction, of the lung isolated from surrounding tissue. These new lung images are neither proton density, T1 (spin-lattice relaxation time), nor T2 (spin-spin relaxation time) images. They complement current NMR images and provide information about regional lung inflation. This previously unrecognized NMR property of lung tissue has potential application in NMR imaging, in quantitative determination of lung water and its distribution, and in the quantitation of regional lung inflation.     

DISTINGUISHING PLANT TISSUES WITH MAGNETIC RESONANCE MICROSCOPY

Using magnetic resonance microscopy at 7 Tesla, spin-lattice relaxation times (Tl), spinspin relaxation times (T2), and spin densities (N(H)) of live squash stem tissues were measured in order to gain an understanding of live tissue water relations and to improve imaging protocols that allow the clear distinction of tissues. T1 and N(H) differences among tissues were found to be much greater than T2 differences. Most tissues can be distinguished with high resolution T1 weighted images. Sclerenchyma and vessel elements are more easily seen with N(H) weighted images because of the relatively low water content of sclerenchyma and high water content of vessel elements. This work demonstrates further improvements in the ability of MR microscopy to distinguish tissues and individual cells and also to make measurements regarding water status at the tissue and cellular level of live plants in a nondestructive manner.     

Influence of paramagnetic ions bound to human serum albumin on water 1HNMR relaxation times

The extent to which various paramagnetic ions (Cu2+, Mn2+ and Gd3+) free and bound to human serum albumin alter the water proton relaxation times at two frequencies has been investigated. NMR relaxation parameters, T1 and T2, were measured at 5 and 10 MHz using a saturation recovery (90 degrees-tau-90 degrees) and a spin-echo (90 degrees-tau-180 degrees) sequence respectively. We found that all three ions enhance their effectiveness in inducing water proton magnetic relaxation when they are bound to human serum albumin and that Gd3+ is the most effective in pure water and Mn2+ in the presence of the protein. Cu2+ has a smaller effect, but it presents an interesting behaviour correlated with the existence of two different binding sites, which is also confirmed by electronic paramagnetic resonance spectra. The results indicate the potential usefulness of large molecular paramagnetic complexes as contrast agents in NMR Imaging.     

Effects of exercise on muscle transverse relaxation determined by MR imaging and in vivo relaxometry.

The purpose of this study was to determine the effects of intense exercise on the proton transverse (T(2)) relaxation of human skeletal muscle. The flexor digitorium profundus muscles of 12 male subjects were studied by using magnetic resonance imaging (MRI; 6 echoes, 18-ms echo time) and in vivo magnetic resonance relaxometry (1,000 echoes, 1.2-ms echo time), before and after an intense handgrip exercise. MRI of resting muscle produced a single T(2) value of 32 ms that increased by 19% (P < 0.05) with exercise. In vivo relaxometry showed at least three T(2) components (>5 ms) for all subjects with mean values of 21, 40, and 137 ms and respective magnitudes of 34, 49, and 14% of the total magnetic resonance signal. These component magnitudes changed with exercise by -44% (P < 0.05), +52% (P < 0.05), and +23% (P < 0.05), respectively. These results demonstrate that intense exercise has a profound effect on the multicomponent T(2) relaxation of muscle. Changes in the magnitudes of all the T(2) components synergistically increase MRI T(2), but changes in the two shortest T(2) components predominate.     

Investigation of adipose tissues in Zucker rats using in vivo and ex vivo magnetic resonance spectroscopy

In vivo single-voxel magnetic resonance spectroscopy (MRS) at 4.7T and ex vivo high-resolution proton magnetic resonance spectroscopy (HR-NMR) at 500 MHz were used to study the composition of adipose tissues in Zucker obese and Zucker lean rats. Lipid composition was characterized by unsaturation and polyunsaturation indexes and mean chain lengths. In vitro experiments were conducted in known mixtures of triglycerides and oils in order to validate the method. To avoid inaccuracies due to partial peak overlapping in MRS, peak quantification was performed after fitting of spectral peaks by using the QUEST algorithm. The intensity of different spectral lines was also corrected for T2 relaxation. Albeit with different sensitivity and accuracy, both techniques revealed that white adipose tissue is characterized by lower unsaturation and polyunsaturation indexes in obese rats compared with controls. HR-NMR revealed similar differences in brown adipose tissue. The present findings confirm the hypothesis that obese and lean Zucker rats have different adipose tissue composition.     

A preliminary study of Cu-, Cd- and Zn-binding components in the hepatopancreas of Palaemon elegans (Crustacea: Decapoda)

Three low molecular weight, metal-binding components have been isolated from the hepatopancreas of the shrimp Palaemon elegans. The two larger components P-I (11-15,000) and P-II (4-6000) were associated with large amounts of copper in field-collected and copper-exposed shrimps and with cadmium in shrimps exposed to elevated Cd concentrations. A smaller component, P-III was associated with zinc. The recovery of these components was dependent upon the use of a protease inhibitor and the reducing agent mercaptoethanol (2-M) during the separation procedure. Copper, zinc and cadmium are not evenly distributed between individual tissues of P. elegans, the highest concentrations occurring in the hepatopancreas, gills and eyes.     

The effect of heavy metals on processes of lipid peroxidation in microsomal membranes from the hepatopancreas of the bivalve mollusc mizuhopecten yessoensis

1. Studies were performed regarding the effects of cadmium and copper on the lipid peroxide contents and on the initial rates of NADPH-dependent and Fe-ascorbic acid-dependent lipid peroxidation in the microsomes of hepatopancreas of the scallop Mizuhopecten yessoensis exposed to these pollutants for 3 weeks.2. The results demonstrated that copper accumulation in hepatopancreas cells was accompanied by a significant increase in hydroperoxide and malondialdehyde contents in microsomal membranes, and by alteration in the both enzymic and non-enzymic lipid peroxidation. Cadmium didn't appear to potentiate lipid peroxidation processes in mollusc tissues.3. Possible reasons for different effects of these metals on lipid peroxidation processes are discussed.     

Multiquantum EPR of the mixed valence copper site in nitrous oxide reductase.

This work demonstrates the use of multiquantum EPR to study the magnetic properties of copper complexes and copper proteins. Pure absorption spectra are obtained because of the absence of field modulation. The signal intensity of 3-quantum spectra is proportional to the spin lattice relaxation time T1, while its linewidth in a frequency difference sweep is T1(-1). A change in lineshape for the EPR detectable mixed value [Cu(1.5) . . . Cu(1.5)] site in nitrous oxide reductase is attributed to suppression of the forbidden transitions. The data confirm the unusually fast relaxation time for this site, which requires temperatures of less than 100 K to resolve hyperfine structure. The T1's for the mixed valence [Cu(1.5) . . . Cu(1.5)] site in nitrous oxide reductase are very similar to T1's for the Cua site in cytochrome c oxidase. The similar relaxation properties, together with previous multifrequency EPR results, support the hypothesis that the EPR detectable sites in cytochrome c oxidase and nitrous oxide reductase are mixed valence [Cu(1.5) . . . Cu(1.5)] configurations.     

Effect of cadmium exposure on lactate dehydrogenase activity in the hepatopancreas and abdominal muscle of the fiddler crab,Uca pugilator

1. Lactate dehydrogenase (LDH) activity in the hepatopancreas and abdominal muscle of fiddler crabs, Uca pugilator, was determined after 24 and 48 hr of exposure to 2 ppm cadmium chloride.2. For the cadmium exposed crabs, LDH activity in the hepatopancreas decreased, whereas that in the abdominal muscle increased.3. The increased LDH activity in the abdominal muscle may reflect increased dependence on anaerobic carbohydrate metabolism in fiddler crabs exposed to cadmium in their environment.     

Proton exchange as a relaxation mechanism for T1 in the rotating frame in native and immobilized protein solutions.

T1 relaxation in the rotating frame (T1rho) is a sensitive magnetic resonance imaging (MRI) contrast for acute brain insults. Biophysical mechanisms affecting T1rho relaxation rate (R1rho) and R1rho dispersion (dependency of R1rho on the spin-lock field) were studied in protein solutions by varying their chemical environment and pH in native, heat-denatured, and glutaraldehyde (GA) cross-linked samples. Low pH strongly reduced R1rho in heat-denatured phantoms displaying proton resonances from a number of side-chain chemical groups in high-resolution 1H NMR spectra. At pH of 5.5, R1rho dispersion was completely absent. In contrast, in the GA-treated phantoms with very few NMR visible side chain groups, acidic pH showed virtually no effect on R1rho. The present data point to a crucial role of proton exchange on R1rho and R1rho dispersion in immobilized protein solution mimicking tissue relaxation properties.     

Magnetic resonance image attributes of the bovine ovarian follicle antrum during development and regression

The magnetic resonance images and maps of bovine ovaries acquired at defined phases of follicular development and regression were studied to determine whether magnetic resonance image attributes of the follicular antrum reflect the physiological status of dominant and subordinate ovarian follicles. Ovariectomies were performed at day 3 of wave one, day 6 of wave one, day 1 of wave two and at >/= day 17 after ovulation. The timings of ovariectomies were selected to acquire growing, early static, late static and regressing follicles of the first wave and preovulatory follicles of the ovulatory wave. Pre-selection and subordinate follicles were also available for analysis. Serum samples were taken on the day of ovariectomy and follicular fluid samples were taken after imaging. Numerical pixel value and pixel heterogeneity in a spot representing approximately 95% of the follicular antrum were quantified in T(1)- and T(2)-weighted images. T(1) and T(2) relaxation rates (T(1) and T(2)), proton density, apparent diffusion coefficients and their heterogeneities were determined from the computed magnetic resonance maps. The antra of early atretic dominant follicles showed higher T(2)-weighted mean pixel value (P < 0.008) and heterogeneity (P < 0. 01) and lower T(2) heterogeneity (P < 0.008) than growing follicles. Subordinate follicles in the presence of a preovulatory dominant follicle had higher T(1), T(1) heterogeneity, proton density, proton density heterogeneity, and lower mean pixel value in T(1)-weighted images than subordinate follicles of the anovulatory wave (P < 0.04). T(1) relaxation rate heterogeneity and proton density heterogeneity were positively correlated with follicular fluid oestradiol concentration (r = 0.4 and 0.3; P < 0.04). T(2) relaxation rate heterogeneity was positively correlated with follicular fluid progesterone concentration (r = 0.4; P < 0.008). Quantitative differences in magnetic resonance image attributes of the antrum observed among phases of follicular development and regression coincided with changes in the ability of the dominant follicle to produce steroid hormones and ovulate, and thus were indicative of physiological status and follicular health.     

Spectroscopic studies on the copper(II) complexes of carnosine

Carnosine complexes with copper(II) ions were studied with magnetic resonance techniques over a wide range of ligand to metal ratios at various pH values. Water proton relaxation rates increased with decreasing carnosine to copper ratios until a molar ratio of 48 was reached. Over the ratio range of 48–2 carnosine molecules per copper ion, the relaxation rate decreased so that in the 2:1 carnosine-copper(II) complex, the water-copper(II) distance was estimated to be 1.92 Å. Proton NMR studies revealed the broadening of imidazole proton lines at high mole ratios followed by other histidyl protons as the ratio decreased. The β-alanyl methylene protons were the last to be broadened by the addition of copper(II) ions. Carbon to copper(II) distances were determined for the carnosine to copper mole ratios of 500:1 and 5000:1. EPR spectra obtained at 93°K revealed the probable existence of four carnosine imidazoles as the sole coordinated ligands to copper(II) at high dipeptide-to-metal ratios (>10). At mole ratios below four, nuclear hyperfine lines characteristic of both monomeric and dimeric carnosine-copper(II) forms were observed. These results reveal that imidazole from carnosine is the sole ligand contributed to copper(II) for coordination over the pH range 5 to 7 at high carnosine to copper(II) ratios     

Pulsed nuclear magnetic resonance studies of human bone marrow.

Pulsed nuclear magnetic resonance (NMR) studies of human bone marrow reveal that the proton spin-lattice relaxation times (T1) of acute myeloid leukemia (AML) and chronic myeloid leukemia (CML) are much greater than the T1 of normal bone marrow.     

NMR relaxation times of water protons in human colon cancer cell lines and clones

Established lines of human colon cancer cells from several sources (LS180, LS174T, HT29, SW480, SW1345) had water proton nuclear magnetic resonance (NMR) spin-lattice relaxation times (T1) of 460 +/- 45 msec to 982 +/- 9 msec and spin-spin relaxation times (T2) of 83 +/- 6 msec to 176 +/- 6 msec. Two clones derived from single cells of line LS174T were similar in T1 and T2 to the parent line. Differences among the cell lines were not totally a function of cellular hydration. Normal adult and fetal human primary colon cells were wetter and had higher T1 and T2 values than established cell lines. Relaxation times in this study substantiate variations seen for human colon tumors in earlier studies. Established cell lines maintained water relaxation times similar to tumor tissue values. Along with other morphological and biochemical criteria, the relaxation times suggest that these established human colon cancer cell lines may serve as a good experimental model for the study of human colon cancer.     

Copper(II) complexes of carnosine, glycylglycine, and glycylglycine-imidazole mixtures

Carnosine complexes with copper(II) ions were studied with magnetic resonance techniques over a wide range of ligand to metal ratios at various pH values. Water proton relaxation rates increased with decreasing carnosine to copper ratios until a molar ratio of 48 was reached. Over the ratio range of 48–2 carnosine molecules per copper ion, the relaxation rate decreased so that in the 2:1 carnosine-copper(II) complex, the water-copper(II) distance was estimated to be 1.92 Å. Proton NMR studies revealed the broadening of imidazole proton lines at high mole ratios followed by other histidyl protons as the ratio decreased. The β-alanyl methylene protons were the last to be broadened by the addition of copper(II) ions. Carbon to copper(II) distances were determined for the carnosine to copper mole ratios of 500:1 and 5000:1. EPR spectra obtained at 93°K revealed the probable existence of four carnosine imidazoles as the sole coordinated ligands to copper(II) at high dipeptide-to-metal ratios (>10). At mole ratios below four, nuclear hyperfine lines characteristic of both monomeric and dimeric carnosine-copper(II) forms were observed. These results reveal that imidazole from carnosine is the sole ligand contributed to copper(II) for coordination over the pH range 5 to 7 at high carnosine to copper(II) ratios     

Water-soluble polysaccharides as carriers of paramagnetic contrast agents for magnetic resonance imaging: synthesis and relaxation properties.

Water-soluble, carbohydrate-based, paramagnetic metal chelate derivatives have been investigated as potential organ-selective contrast media for magnetic resonance imaging (m.r.i.). The in vitro proton spin-lattice relaxation properties of compounds with different paramagnetic metals, chelating agents, and carbohydrate matrixes have been studied. Typically, these complexes were 60-260% more efficient proton-relaxation agents than the corresponding low-molecular-weight metal chelates at 10 MHz, but less efficient than the corresponding protein derivatives. As expected, carbohydrates that contained manganese or gadolinium were more effective relaxation agents than iron, copper, erbium, or nickel derivatives.