Porphyrin-sensitized photodynamic damage of isolated rat liver mitochondria

The respiration rates and the respiratory control ratios of isolated rat liver mitochondria have been measured following exposure to 0–160 kJ/m² of near-ultraviolet radiation (blacklight) in the presence of low concentrations of porphyrins (0.1–0.2 μmol/l).

Depending on the light dose, the concentration and the type of porphyrin, the following sequence of reactions occurred: uncoupling and inhibition of oxidative phosphorylation, energy dissipation, inhibition of respiration and swelling and disruption of the mitochondria.

The detrimental effects could not be elicited in the absence of oxygen, neither could they be elicited by porphyrins or light alone.

At equimolar concentrations, the effectiveness of the porphyrins as photosensitizers were: deuteroporphyrin > protoporphyrin coproporphyrin > murophorphyrin.

The results may be of importance to explain the skin lesions seen when porphyrins of different hydrophobicity accumulate in the skin.     

A mechanism for ethanol-induced damage to liver mitochondrial structure and function

Mitochondria isolated from rats chronically fed ethanol demonstrated a marked inability to produce energy. The respiratory control ratio, the ADP/O ratio and state 3 respiration rates were all decreased. Coupled with other data, a progression of ethanol-induced changes is proposed with site I being altered prior to site II. Quantitation of mitochondrial cytochromes revealed decreases in cytochromes $\text{b}$ and $\text{aa}{}_3$ and an increase in $\text{c}{}_1$. Evaluation of respiration activity in relation to temperature showed ethanol-induced changes in the transition temperature ($\text{T}{}_{\mathrm{f}}$) which may have been related to changes in the lipid composition of the inner membrane. Mitochondrial membranes were separated, and analysis of fatty acids and phospholipids was performed. Various fatty acids were altered in both membranes; however, the outer membrane was altered more severely. A decrease in the arachidonate : linoleate ratio was observed only in the outer membrane; however, there was no ethanol-induced change in degree of unsaturation in either membrane. Phospholipid quantitation showed a reduction of total lipid phosphorous/mg protein in both membrane fractions; however, the inner membrane was most affected. Cardiolipin was the only phospholipid in this membrane which remained unaltered. The evidence indicates that the mechanism for ethanol-induced damage to the liver mitochondrion involves lipid compositional changes as well as changes in cytochromes and possibly other proteins.     

Characterization of calciphorin,the low molecular weight calciu,ionophore, from rat liver mitochondria

Calciphorin, the putative mitochondrial calcium ionophore from rat liver mitochondria, exhibits the inherent properties of the mitochondrial calcium transport system and is similar to the calf heart preparation reported earlier. The protein has a strong selectivity for Ca²⁺, and has a K_d for Ca²⁺ of 56.5 ± 6.6 μM and 13.9 ± 2.1 μM in organic extraction and flow dialysis experiments, respectively. Reduction of the contaminating lipids from 23 ± 6.5 to 1.73 ± 0. moles per mole protein does not alter the affinities, Ca²⁺/protein soichiometry or selectivity for Ca²⁺.     

Impaired glycosylation in liver microsomes of orotic-acid-fed rats

In rats fed orotic acid, the incorporation in liver subcellular fractions of sugars injected intraperitonealy is altered only for mannose, but not for fucose or galactose. Direct determinations of several glycosyltransferases are done in smooth and rough microsomes: fucosyl-, glactosyl-, N-acetylglucosaminyltransferase activities are at quite similar levels in normal and fatty livers. By contrast, sialyltransferase activity is increased (+50%) in smooth microsomes of fatty livers, while mannosyltransferase activity is inhibited by 30%. These alterations are not caused by interfering reactions pyrophosphatases or proteases). For the mannosyltransferase activity, the inhibition is found in the dolichylphorylmannose intermediates. Kinetic studies suggest that there is deficiency of both enzyme and endogenous dolichyl phosphate.     

31P-NMR studies on phospholipid structure in membranes of intact,functionally-active,rat liver mitochondria

³¹P-NMR studies of intact functional rat liver mitochondria at 37°C demonstrate that the large majority (?95%) of endogenous phospholipids exhibit motional properties consistent with bilayer structure. This property is unaffected by oxidative phosphorylation processes or the presence of Ca²⁺.     

Increased activity of rat liver N2-guanine tRNA methyltransferase II in response to liver damage

Alterations in rat liver transfer RNA (tRNA) methyltransferase activities have been observed after liver damage by various chemicals or by partial hepatectomy. The qualitative and quantitative nature of these activity changes and the time course for their induction have been studied. Since homologous tRNAs are essentially fully modified in vivo, E. coli tRNAs were used as in vitro substrates for the rat liver enzymes in these studies. Each of the liver-damaging agents tested rapidly caused increases in activities of the enzyme(s) catalyzing methyl group transfer to tRNAs that have an unmodified guanine at position 26 from the 5′ end of the molecule. This group of tRNAs includes E. coli tRNA^Nfmet, tRNA^Ala₁, tRNA^Leu₁, or ^Leu₂, and tRNA^Ser₃ (Group 1). In each case N²-methylguanine and N²,N²-dimethylguanine represented 90% or more of the products of these in vitro methylations. The product and substrate specificity observed are characteristic of N²-guanine methyltransferase II ($\text{S-}\text{adenosyl}\text{-}\text{L}\text{-}\text{methionine:tRNA}$ (guanine-2)-methyltransferase, EC 2.1.1.32). In crude and partially purified preparations derived from livers of both control and treated animals this enzyme activity was not diminished significantly by exposure to 50°C for 10 min. The same liver-damaging agents induced little or no change in the activities of enzymes that catalyze methyl group transfer to various other E. coli tRNAs that do not have guanine at position 26 (Group 2). The results of mixing experiments appear to rule out the likelihood that the observed enzyme activity changes are due to stimulatory or inhibitory materials present in the enzyme preperations from control or treated animals. Thus, our experiments indicate that liver damage by each of several different methods, including surgery or administration of chemicals that are strong carcinogens, hepatotoxins, or cancer-promoting substances, all produce changes in liver tRNA methyltransferase activity that represent a selective increase in activity of N²-guanine tRNA methyltransferase II. It is proposed that the specificity of this change is not fortuitous, but is the manifestation of an as yet unidentified regulatory process.     

Three catalytic sites in mitochondrial ATPase

Kinetic data obtained after determining the hydrolytic activity of ATPase from rat liver in preparations where the enzyme had been purified, or in mitochondria, strongly suggest the existence of three different catalytic sites with different affinity for the substrate. The results obtained when measuring the ATPase activity at different substrate concentrations, and in the presence of the inhibitors KOCN or KSCN, or of the activators dinitrophenol and bicarbonate, show that the binding of these compounds to a regulatory site or sites affects in a different degree the hydrolytic activity of each catalytic site.     

Control of state 3 respiration in liver mitochondria from rats subjected to chronic ethanol consumption

Male Sprague-Dawley rats were pair-fed a liquid diet containing 36% of calories as ethanol for at least 31 days. Mitochondria were isolated from the livers and assayed for state 3, state 4 and uncoupled respiration at all three coupling sites. Assay conditions were established that maximized state 3 respiration with each substrate while maintaining a high respiratory control ratio. In mitochondria from ethanol-fed animals, state 3 respiratory rates were decreased at all three coupling sites. The decreased state 3 rate observed at site III was still significantly higher than the state 3 rates observed at site II in mitochondria from either ethanol-fed or control animals. Moreover, the maximal (FCCP-uncoupled) rates with succinate and -ketoglutarate were the same in mitochondria from ethanol-fed and control animals, whereas with glutamate-malate as substrate it was lowered 23% by chronic ethanol consumption. To investigate the role of cytochrome oxidase in modulating the respiratory rate with site I and site II substrates, the effects of cyanide on state 3 and FCCP-uncoupled respiration were determined. When the mitochondria were uncoupled there was no decrease in the rate of succinate oxidation until the rates of ascorbate and succinate oxidation became equivalent. Conversely, parallel inhibition of ascorbate, succinate and glutamate-malate state 3 respiratory rates were observed at all concentrations (1–50 μM) of cyanide utilized. These observations suggest strongly that in coupled mitochondria ethanol-elicited decreases in cytochrome oxidase activity depress the state 3 respiratory rates with site I and II substrates.     

The induction of liver microsomal proteins by 3-methylcholanthrene in rats of different age,sex and strain

The treatment of male and female adult and male and female immature rats with 3-methylcholanthrene results in increases in the intensity of two liver microsomal protein bands separated by sodium dodecyl sulphate-polyacrylamide gel electrophoresis. The induced protein species have estimated molecular weights of about 55 000 and 52 500. The time course of the induction of these species has been followed in a semi-quantitative manner. In immature rats an additional band, corresponding to a protein species with a molecular weight of about 43 000, is also increased by 3-methylcholanthrene treatment. In male adults rats exclusively, treatment with 3-methylcholanthrene also results in a decrease in the intensity of a band corresponding to a protein species of about 51 000. The appearance of this band in the liver microsomal fraction of adult male rats occurs following sexual maturation and its presence represents a significant difference in the microsomal proteins between male and female rats, this protein is not detected in younger male rats or in female rats at any age. These findings are discussed in terms of their possible relevance to the cytochrome P-450 content of the endoplasmic reticulum of rat hepatocytes.     

Impairment of liver regeneration during inhibition of mitochondrial protein synthesis by oxytetracycline

Under standard conditions, liver regeneration is not impaired if mitochondrial protein synthesis is completely blocked. By treating rats with oxytetracycline for various periods of time directly prior to partial hepatectomy, livers were led to a condition of relative deficiency in cytochrome c oxidase and ATP synthetase. To this end, oxytetracycline was administered by means of continuous intravenous infusion up to concentrations of 20 μg/ml serum, giving a gradual decrease in cytochrome c oxidase activity. This activity was used as a marker for functionally capable mitochondria and as a tool to monitor the efficiency of inhibition of mitochondrial protein synthesis. It is shown that liver regeneration is strongly impaired after a period of pretreatment of 22 days or more and continuation of oxytetracycline treatment during regeneration. The mitochondrial respiratory capacity is reduced to 14% of the control value under these conditions. To obtain inhibitory levels within the regenerating liver, it was necessary to raise the serum levels slightly above 20 μg/ml. This measure is most likely required because of the poor vascularization of the regenerating liver. The serum levels were kept, however, far below those known to inhibit cytoplasmic protein synthesis. The results show that in normal liver the respiratory capacity must be reduced drastically before energy-requiring processes become affected. In Zajdela hepatoma cells, similar effects are found after reduction of the cytochrome c oxidase activity to 38%. This difference in sensitivity is probably based on the different mitochondrial content of liver cells and the liver-derived Zajdela cells.     

Purification and some properties of ornithine decarboxylase from rat liver

Ornithine decarboxylase (EC 4.1.1.17) was purified to near homogeniety from livers of thioacetamide- and dl-α-hydrazino-δ-aminovaleric acid-treated rats by using three types of affinity chromatography with pyridoxamine phosphate-Sepharose, pyridoxamine phosphate-dipropylenetriamine-Sepharose and heparin-Sepharose. This procedure gave a purification of about 3.5·10⁵-fold with an 8% yield; the specific activity of the final enzyme preparation was 1,1·10⁶ nmol CO₂/h per mg protein. The purified enzyme gave a single band of protein which coincided with activity peak on polyacrylamide gel electrophoresis and also gave a single major band on SDS-polyacrylamide gel electrophoresis. A single precipitin line was formed between the purified enzyme and an antiserum raised against a partially purified enzyme, on Ouchterlony immunodiffusion. The molecular weight of the enzyme was estimated to be 105 000 by polyacrylamide gel electrophoresis at several different gel concentrations; the dissociated subunits had molecular weights of 50 000 on SDS-polyacrylmide gels. The isoelectric point of the enzyme was pH 4.1.     

Studies of ethylene-forming system in rat liver extract

Evidence of enzymatic formation of ethylene from methionine by rat liver extracts is presented. The ethylene production is closely associated with growth of the animal. The conversion of l-methionine to ethylene is oxygen dependent. Substrate analogue studies show that the ethylene-forming system is structurally specific and requires in the center of the molecule α-CH₂-CH₂- with one end attached to an unencumbered sulfur atom from a thioether moiety and the other end attached to a carboxyl group. Sylfhydryl agents are found to be very effective inhibitors of the ethylene-forming system. The finding of α-keto-4-methylthiobutyric acid to be a more efficient precursor of ethylene production suggests the possibility that α-keto-4-methylthiobutyric acid may be an intermediate in the biosynthesis of ethylene from methionine in mammalian tissues.     

Serum IGF-1 levels correlate negatively to liver damage in diabetic rats

Abstract

Diabetes and insulin resistance frequently cause liver damage. Diabetes also causes reduction in liver and blood IGF-1 levels. We investigated the relation between liver damage and IGF-1 levels in diabetic rats. Fourteen Wistar albino rats were divided into control and diabetic groups. Diabetes was induced by streptozotocin. Rats were sacrificed for biochemical and histologic examinations 2 weeks after streptozotocin injection. Serum and liver IGF-1 levels were decreased, liver malondialdehyde (MDA) levels were increased, glutathione peroxidase (GPx) enzymes activities were decreased and serum alanine aminotransferase (ALT) levels were increased in diabetic group. Microscopic examination of liver revealed that normal tissue organization was disrupted in streptozotocin-induced diabetic rats. There was a strongly positive correlation between blood glucose levels and liver injury, and blood and liver IGF-1 levels. There was a strongly negative correlation between blood IGF-1 levels and hepatic injury. Our results suggest that reduction of blood IGF-1 levels correlates with hepatic injury and circulating IGF-1 levels may have predictive value for determining hepatic damage that results from diabetes. In addition, circulating IGF-1 levels are correlated with glutathione levels and the oxidative stress status of diabetic rat liver.     

Role of substrates in Sr2+-induced oscillations of ionic fluxes in rat liver mitochondria

(1) The reason for substrate specificity of Sr²⁺-induced oscillating cation fluxes in isolated rat liver mitochondria was investigated. (2) With succinate as substrate, rotenone prevented oscillation. In this case the mitochondria were only partially able to take up added Sr²⁺ and did not take up any of the released K⁺. Addition of substances decreasing the mitochondrial $\text{NADH}\text{NAD}{}^{\mathrm{+}}$ ratio (oxaloacetate or acetoacetate) restored the ability for reuptake of K⁺ and for complete uptake of Sr²⁺ and, therefore, oscillation. (3) Inhibition of substrate-level phosphorylation by arsenite or uncoupling of substrate-level phosphorylation by arsenate in the presence of oligomycin also suppressed the reuptake of cations. This effect of inhibition of substrate-level phosphorylation on oscillation could be circumvented by addition of ATP in the presence of oligomycin. (4) Prevention of the intramitochondrial regeneration of 2-oxoglutarate from acetyl-CoA and oxaloacetate by fluorocitrate or from endogenous glutamate by aminoxyacetate shortened the time during which oscillation with succinate as substrate could be observed. (5) From the key role of substrate level phosphorylation it is concluded that for the reuptake of K⁺ and Sr²⁺ during oscillation, sufficient GTP generation by the succinyl thiokinase (EC 6.2.1.4) reaction is essential. Therefore substrate level phosphorylation seems to be a necessary energy source additional to the respiratory chain. Since the latter process drives the active cation movements, the former may be required for the restoration of a sufficiently low proton conductance of the mitochondrial inner membrane. Oscillation in the absence of exogenous ATP therefore demands 2-oxoglutarate as substrate or the intramitochondrial generation of 2-oxoglutarate for the maintenance of a sufficient GTP production for a longer time.     

Lack of sexual dimorphism in alcohol-induced liver damage (ALD) in rats treated chronically with ethanol-containing low carbohydrate diets: The role of ethanol metabolism and endotoxin

Evidence has been presented suggesting that females are significantly more susceptible to alcohol-induced liver damage (ALD) than males. In the current study, we examined sexual dimorphism in hepatic pathology, metabolism and cytokine profiles using two different rat models of ALD. Male and female Sprague-Dawley or Wistar rats were fed ethanol-containing low-carbohydrate liquid diets using oral or intragastric methods for 42 or 60 days. In both models, ethanol treatment produced similar significant liver hyperplasia accompanied by increases in plasma ALT, steatosis, inflammation and necrosis (p < 0.05). Greater pathology scores were observed in the intragastrically infused rats. Males did not differ significantly from females in serum ALT values or pathology despite greater elevations in TNFalpha and IL-1beta mRNAs in ethanol-treated female rat livers (p < 0.05). Furthermore, there was no sexual dimorphism in blood ethanol concentrations or CYP2E1-induction even though sexually dimorphic alterations in other hepatic cytochrome P450 enzymes were observed. These data do not support previous observations that female rats have a greater susceptibility to ethanol-induced hepatotoxicity than males.     

Control of oxidative phosphorylation by Complex I in rat liver mitochondria: implications for aging

We compared NAD-dependent state 4 and state 3 respiration, NADH oxidation and Complex I specific activity in liver mitochondria from 4- and 30-month-old rats. All the activities examined were significantly decreased with aging. In both groups of animals, the flux control coefficients measured by rotenone titration indicated that Complex I is largely rate controlling upon NADH aerobic oxidation while, in state 3 respiration, it shares the control with other steps in the pathway. Moreover, we observed a trend wherein flux control coefficients of Complex I became higher with age. This indication was strengthened by examining the rotenone inhibition thresholds showing that Complex I becomes more rate controlling, over all the examined activities, during aging. Our results point out that age-related alterations of the mitochondrial functions are also present in tissues considered less prone to accumulate mitochondrial DNA mutations.     

Antiestrogen binding sites in rat liver nuclei

Isolated, intact rat liver nuclei have high-affiity (K_d=10⁻⁹ M) binding sites that are highly specific for nonsteroidal antiestrogens, especially for compounds of the triphenylethylene series. Nuclear [³H]tamoxifen binding capacity is thermolabile, being most stable at 4°C and rapidly lost at 37°C. More [³H]tamoxifen, however, is specifically bound at incubation temperatures of 25°C and 37°C than at 4°C although prewarming nuclei has no effect, suggesting exchange of [³H]tamoxifen for an unidentified endogenous ligand. Nuclear antiestrogen binding sites are destroyed by trypsin but not by deoxyribonuclease I or ribonuclease A. The nuclear antiestrogen binding protein is not solubilized by 0.6 M potassium chloride, 2 M sodium chloride, 0.6 M sodium thiocyanate, 3 M urea, 20 mM pyridoxal phosphate, 1% (w/v) digitonin or 2% (w/v) sodium cholate but is extractable by sonication, indicating that it is tightly bound within the nucleus. Rat liver nuclear matrix contains high-affinity (K_d=10⁻⁹ M) [³H]tamoxifen binding sites present in 5-fold higher concentrations (4.18 pmol/mg DNA) than in intact nuclei (0.78±0.10 (S.D.) pmol/mg DNA). Low-speed rat liver cytosol (20 000×g, 30 min) contains high-capacity (955±405 (S.D.) fmol/mg protein), low-affinity (K_d=10.9±4.5 (S.D.) nM) antiestrogen binding sites. In contrast, high-speed cytosol (100 000×g, 60 min) contains low-capacity (46±15 (S.D.) fmol/mg protein), high-affinity (K_d=0.61± 0.20 (S.D.) nM) binding sites. Low-affinity cytosolic sites constitute more than 90% of total liver binding sites, high-affinity cytosolic sites 0.3%–3.2%, and nuclear sites less than 0.5% of total sites.     

Mössbauer spectroscopy of iron metabolism and iron intracellular distribution in liver of rats

Mössbauer spectroscopy was used to investigate the distribution of iron in rat organs and its localisation in liver subcellular fractions. A ⁵⁷Fe-sucrose complex solution was injected by 0.5 ml doses into tail veins of anmals every day, during a 6-day period. Mössbauer spectra were measured in spleen, blood, liver and liver subcellular fractions. The Mössbauer spectrum of a spleen sample has two symmetrical doublets, one with δ=0.6 mm/s and Δ=0.7 mm/s, and the other with δ=1.0 mm/s and Δ=2.35 mm/s. The Mössbauer spectrum of blood has parameters which are close to those for carboxyhemoglobin and oxyhemoglobin complexes. After the addition of sodium citrate, the proportion of the carboxyhemoglobin complexes increases. The Mössbauer spectrum of liver has a two-component pattern with two symmetrical doublets, the first with δ=0.6 mm/s and Δ=0.63 mm/s and the second with δ=1.4 mm/s and Δ=3.45 mm/s. The first component, which was identified as ferritin, is present in all subcellular fractions (800 × g_av sediment fraction, mitochondrial/lysosomal, microsomal and supernatant fractions), with its content in microsomal fraction. After the addition of NaBH₄ to mitochondrial/lysosomal fraction, about 20 % of the iron contained in ferritin was reduced. In the Mössbauer spectrum this is reflected by an appearance of a doublet with δ=0.85 mm/s and Δ=3.7 mm/s.     

Identification of receptors in the liver that mediate endocytosis of circulating tissue kallikreins

The liver plays an important role in the clearance, by receptor-mediated endocytosis, of circulating glycoproteins. It has been demonstrated that tissue kallikreins, which are acid glycoproteins, circulate in plasma, where they are poorly inhibited by plasma proteins. We have shown that the liver is the main organ that clears tissue kallikreins from the circulation. We now report the identification of receptors involved in this clearance. Using a perfused rat-liver system, and as models, pig pancreatic (PPK) and horse urinary (HoUK) kallikreins, we have found that: (a) the binding of PPK to the perfused liver was inhibited by 50 mM methyl α-d-mannoside and 20 μM mannan, was partially inhibited by 50 mM mannose and was unaffected by 1.5 μM asialofetuin; (b) binding of HoUK to the perfused liver was inhibited by 1.5 μM asialofetuin, 50 mM galactose and 50 mM lactose and was unaffected by 50 mM mannose; (c) the clearance rate of both kallikreins followed the equation y = a·x^b; (d) their binding was Ca²⁺-dependent and their clearance was inhibited by 3 mM chloroquine and 10 mM methylamine. Using isolated liver cells and tritiated HoUK, we calculated that 500 000 receptors/cell were present and the Scatchard plot showed that there were two apparent affinity constants: 0.24·10⁹ 1/M)(high-affinity) and 0.3·10⁸ 1/M (low-affinity). These results show that PPK is recognized by a liver mannose receptor and HoUK by the galactose receptor. The liver uptake of native and circulating tissue kallikreins thus emerges as a mechanism by which their levels in plasma are regulated.