Distribution of free N-acetylneuraminic acid in rat organs

The concentration of free N-acetylneuraminic acid in various rat organs was estimated by gas chromatography/mass spectrometry. Its concentration was in the range of 3.95 to 104.72 micrograms/g wet tissues, being particularly high in the endocrine glands. The ratio of free N-acetylneuraminic acid to total N-acetylneuraminic acid varied from 0.031 to 0.183, being especially high in the adrenal gland (0.181) and heart (0.183).     

Distribution and pharmacokinetics of dinitrosyl iron complexes in rat organs

Dinitrosyl iron complexes (DNICs) have been traced in rat blood and organs after intravenous infusion of Oxacom. It is shown that the active principle (DNIC with glutathione) is rapidly distributed through the organism and deposited in blood and organs as protein-bound DNICs. The specific levels of DNIC in the main body organs are comparable, whereas its apparent lifetimes relate as blood < heart = lung < liver < kidney. Spin trapping assays indicate that protein-bound DNICs are a major but not the only form of NO deposition; the next largest depot is most probably formed by S-nitrosothiols. The gradual release of NO from such pools ensures the smooth and prolonged hypotensive effect of Oxacom.     

Distribution of the lithium ion in endocrine organs of the rat

Lithium ions accumulated consistently in the pituitary and thyroid of rats at concentrations significantly greater than in plasma. There was also a significant, although lower, accumulation of Li⁺ in the adrenal gland. No accumulation of lithium ion was noted in the testis or in the ovary. The possible significance of these findings with regard to some of the side effects of lithium carbonate treatment is discussed.     

Distribution of various nickel compounds in rat organs after oral administration

In this study, eight kinds of nickel (Ni) compounds were orally administered to Wistar male rats and the distribution of each compound was investigated 24 h after the administration. The Ni compounds used in this experiment were nickel metal [Ni−M], nickel oxide (green) [NiO(G)], nickel oxide (black) [NiO(B)], nickel subsulfide [Ni₃S₂], nickel sulfide [NiS], nickel sulfate [NiSO₄], nickel chloride [NiCl₂], and nickel nitrate [Ni(NO₃)₂]. The solubilities of the nickel compounds in saline solution were in the following order; [Ni(NO₃)₂>NiCl₂>NiSO₄]≫[NiS>Ni₃S₂]>[NiO(B)>Ni−M>NiO(G)]. The Ni level in the visceral organs was higher in the rats given soluble Ni compounds; Ni(NO₃)₂, NiCl₂, NiSO₄, than that in the rats receiving other compounds. In the rats to which soluble Ni compounds were administered, 80–90% of the recovered Ni amounts in the examined organs was detected in the kidneys. On the other hand, the Ni concentration in organs administered scarcely soluble Ni compounds; NiO(B), NiO(G), and Ni−M were very low. The estimated absorbed fraction of each Ni compounds was increased with the increase of the solubility. These results suggest that the kinetic behavior of Ni compounds administered orally is closely related with the solubility of Ni compounds, and that the solubility of Ni compounds is one of the important factors for determining the health effect of Ni compounds.     

Distribution of aluminum in different brain regions and body organs of rat

In the present study, an attempt has been made to investigate the distribution of aluminum in different regions of brain and body organs of male albino rats, following subacute and acute aluminum exposure. Aluminum was observed to accumulate in all regions of the brain with maximum accumulation in the hippocampus. Subcellular distribution of aluminum indicated that there was maximum localization in the nucleus followed by cytosolic, microsomal, and mitochondrial deposition. Elution profile of cytosolic proteins on G-75 Sephadex column revealed a substantial amount of aluminum bound to high-mol-wt protein fraction. Aluminum was also seen to compartmentalize in almost all the tissues of the body to varying extents, and the highest accumulation was in the spleen.     

Distribution and quantification of alpha1-integrin subunit in rat organs

Summary The ₁₁-integrin is known to be a receptor for collagen and laminin mediating cell-matrix interactions. A monoclonal antibody, 33.4, which specifically inhibits the ₁-integrin-mediated in vitro cell-collagen binding of rat hepatocytes and hepatoma-derived A-cells (Löster et al., 1994), was used to purify by immunoaffinity chromatography the ₁-integrin subunit from rat liver in large quantities for inducing a polyclonal antiserum. In immunoblot analysis on membrane extracts of several rat organs this polyclonal antiserum recognized only a 190 kDa-band, suggesting that it is highly specific for the ₁-integrin subunit. A sandwich-ELISA with monoclonal antibody 33.4 and the polyclonal antiserum against the ₁-integrin subunit, respectively, enabled the quantitative expression pattern of the ₁-integrin subunit to be studied in different rat organs. With the exceptions of brain (not detectable) and muscle (low concentration), the ₁-integrin subunit was detectable in almost all organs of the digestive, respiratory and urogenital system as well as in lymphatic organs. The highest relative concentrations of ₁-integrin subunit were found in uterus, lung and spleen, whereas in seminal vesicle, stomach, parotid gland, epididymis, kidney and liver only modest concentrations were evident. The organ distribution and localization of ₁-integrin subunit were studied by immunohistochemistry with monoclonal and polyclonal antibodies. Immunoreactivity was present in the plasma membranes of all smooth muscle cells, vascular endothelial cells of many organs and fibrocyte-fibroblast sheaths in the heart and kidney. Since these cells are in close contact with collagen-containing basal membranes as well as reticular fibrils, strong evidence exists that in rat tissues the ₁-integrin subunit is expressed at sites where collagen is present and might be involved in vivo in cell—ollagen binding.Dedicated to Professor Peter Sitte on the occasion of his 65th birthday     

Distribution of leucine 2,3-aminomutase activity in various organs of the rat and in subcellular organelles of rat liver

Leucine 2,3-aminomutase, the cobalamine-dependent enzyme involved in the conversion of β-leucine to leucine, has been shown to be widely distributed in rat organs. The activity is highest in skeletal and cardiac muscle, lower in brain, liver, and kidney, and very low in small intestine. In rat liver, the activity is nearly all in the cytosolic fraction.     

Adipogenic activities in rat organs

Adipose conversion of 3T3-L1 cells depends on adipogenic factors present in serum. In order to find their origin, adipogenic activity in extracts from adrenals, kidneys, testes, ovaries, liver, spleen, sceletal muscle and adipose tissue of the rat was studied. If tissues were homogenized with aqueous buffers at low pH, no adipogenic activity could be extracted. Treatment with chloroform/methanol followed by phase separation however revealed considerable adipogenic activity in the organic phase from adrenals, kidneys, ovaries, testes and sceletal muscle and additionally in the aqueous phase of liver. Further purification by liquid chromatography and reversed phase HPLC led to the identification of adipogenic activities from adrenals and kidneys as corticosterone and 11-dehydrocorticosterone. Adipogenic activity from liver in contrast is pronase-sensitive, exhibits an apparent molecular mass of 4 kDa and is probably a peptide.