In situ kinetic parameters of glucose-6-phosphatase in the rat liver lobulus

Zonation of nitrogen and glucose metabolism gene expression upon acute liver damage in mouse

Zonation of metabolic activities within specific structures and cell types is a phenomenon of liver organization and ensures complementarity of variant liver functions like protein production, glucose homeostasis and detoxification. To analyze damage and regeneration of liver tissue in response to a toxic agent, expression of liver specific enzymes was analyzed by in situ hybridization in mouse over a 6 days time course following carbon tetrachloride (CCl4) injection. CCl4 mixed with mineral oil was administered to BALB/c mice by intraperitoneal injection, and mice were sacrificed at different time points post injection. Changes in the expression of albumin (Alb), arginase (Arg1), glutaminase 2 (Gls2), Glutamine synthetase (Gs), glucose-6-phosphatase (G6pc), glycogen synthase 2 (Gys2), Glycerinaldehyd-3-phosphat-Dehydrogenase (Gapdh), Cytochrom p450 2E1 (Cyp2e1) and glucagon receptor (Gcgr) genes in the liver were studied by in situ hybridization and qPCR. We observed significant changes in gene expression of enzymes involved in nitrogen and glucose metabolism and their local distribution following CCl4 injury. We also found that Cyp2e1, the primary metabolizing enzyme for CCl4, was strongly expressed in the pericentral zone during recovery. Furthermore, cells in the damaged area displayed distinct gene expression profiles during the analyzed time course and showed complete recovery with strong albumin production 6 days after CCl4 injection. Our results indicate that despite severe damage, liver cells in the damaged area do not simply die but instead display locally adjusted gene expression supporting damage response and recovery.

The transcriptomic signature of fasting murine liver

Background

The contribution of individual organs to the whole-body adaptive response to fasting has not been established. Hence, gene-expression profiling, pathway, network and gene-set enrichment analysis and immunohistochemistry were carried out on mouse liver after 0, 12, 24 and 72 hours of fasting.

Results

Liver wet weight had declined ~44, ~5, ~11 and ~10% per day after 12, 24, 48 and 72 hours of fasting, respectively. Liver structure and metabolic zonation were preserved. Supervised hierarchical clustering showed separation between the fed, 12–24 h-fasted and 72 h-fasted conditions. Expression profiling and pathway analysis revealed that genes involved in amino-acid, lipid, carbohydrate and energy metabolism responded most significantly to fasting, that the response peaked at 24 hours, and had largely abated by 72 hours. The strong induction of the urea cycle, in combination with increased expression of enzymes of the tricarboxylic-acid cycle and oxidative phosphorylation, indicated a strong stimulation of amino-acid oxidation peaking at 24 hours. At this time point, fatty-acid oxidation and ketone-body formation were also induced. The induction of genes involved in the unfolded-protein response underscored the cell stress due to enhanced energy metabolism. The continuous high expression of enzymes of the urea cycle, malate-aspartate shuttle, and the gluconeogenic enzyme Pepck and the re-appearance of glycogen in the pericentral hepatocytes indicate that amino-acid oxidation yields to glucose and glycogen synthesis during prolonged fasting.

Conclusion

The changes in liver gene expression during fasting indicate that, in the mouse, energy production predominates during early fasting and that glucose production and glycogen synthesis become predominant during prolonged fasting.

Fluorogenic substrate [Ala-Pro]2-cresyl violet but not Ala-Pro-rhodamine 110 is cleaved specifically by DPPIV activity: a study in living Jurkat cells and CD26/DPPIV-transfected Jurkat cells

Fluorogenic substrates [Ala-Pro](2)-cresyl violet and Ala-Pro-rhodamine 110 have been tested for microscopic detection of protease activity of dipeptidyl peptidase IV (DPPIV) in living cells. DPPIV activity is one of the many functions of the multifunctional or moonlighting protein CD26/DPPIV. As a model we used Jurkat cells, which are T-cells that lack CD26/DPPIV expression, and CD26/DPPIV-transfected Jurkat cells. Ala-Pro-rhodamine 110 is not fluorescent, but after proteolytic cleavage rhodamine 110 fluoresces. [Ala-Pro](2)-cresyl violet is fluorescent by itself but proteolytic cleavage into cresyl violet induces a shift to longer wavelengths. This phenomenon enables the simultaneous determination of local (intracellular) substrate and product concentrations, which is important for analysis of kinetics of the cleavage reaction. [Ala-Pro](2)-cresyl violet, but not Ala-Pro-rhodamine 110, appeared to be specific for DPPIV. When microscopic analysis is performed on living cells during the first minutes of the enzyme reaction, DPPIV activity can be precisely localized in cells with the use of [Ala-Pro](2)-cresyl violet. Fluorescent product is rapidly internalized into submembrane granules in transfected Jurkat cells and is redistributed intracellularly via internalization pathways that have been described for CD26/DPPIV. We conclude that [Ala-Pro](2)-cresyl violet is a good fluorogenic substrate to localize DPPIV activity in living cells when the correct wavelengths are used for excitation and emission and images are captured in the early stages of the enzyme reaction.

Enzyme cytochemical techniques for metabolic mapping in living cells, with special reference to proteolysis

Specific enzymes play key roles in many pathophysiological processes and therefore are targets for therapeutic strategies. The activity of most enzymes is largely determined by many factors at the post-translational level. Therefore, it is essential to study the activity of target enzymes in living cells and tissues in a quantitative manner in relation to pathophysiological processes to understand its relevance and the potential impact of its targeting by drugs. Proteases, in particular, are crucial in every aspect of life and death of an organism and are therefore important targets. Enzyme activity in living cells can be studied with various tools. These can be endogenous fluorescent metabolites or synthetic chromogenic or fluorogenic substrates. The use of endogenous metabolites is rather limited and nonspecific because they are involved in many biological processes, but novel chromogenic and fluorogenic substrates have been developed to monitor activity of enzymes, and particularly proteases, in living cells and tissues. This review discusses these substrates and the methods in which they are applied, as well as their advantages and disadvantages for metabolic mapping in living cells.

Metabolic heterogeneity of glycogen in hepatocytes of patients with liver cirrhosis: the glycogen of the liver lobule zones in cirrhosis

The concentrations of total glycogen (TG) and its labile (LF) and stable (SF) fractions were determined in hepatocytes of portal and central zones of the normal human liver and in the liver of patients with cirrhosis of viral and alcohol aetiologies. Using PAS reaction, TG, LF and SF were revealed in histological sections of the material obtained by the liver punch biopsies. The concentrations of TG and its fractions were measured by televisional cytophotometry. In liver cirrhosis, the concentrations of TG, LF and SF in both zones of the hepatic lobule have been found to be much higher than in the normal liver. It has been shown that the ratio of the hepatocyte TG concentrations in the portal zone to the central zone both in the normal liver and in viral cirrhosis exceeds 1.0, amounting to 1.264 +/- 0.021 and 1.030 +/- 0.009, respectively. The glycogen fraction composition in the cells of both the liver lobule zones in viral cirrhosis does not differ significantly from the norm. On the contrary, in the liver of patients with alcoholic cirrhosis, the ratio of the TG concentrations in the portal zone to the central zone is reduced to 0.815 +/- 0.016 and is accompanied by qualitative changes of the glycogen composition.

Ala-Pro-cresyl violet, a synthetic fluorogenic substrate for the analysis of kinetic parameters of dipeptidyl peptidase IV (CD26) in individual living rat hepatocytes

A new type of fluorogenic substrates for proteases based on the leaving group cresyl violet has been synthesized. Cresyl violet is not fluorescent when amino acids or peptide groups are attached but becomes highly fluorescent after proteolytic liberation. Its fluorescence shows linearity with concentration and barely any fading. The properties of Ala-Pro-cresyl violet as substrate for dipeptidyl peptidase IV (DPPIV) (CD26) for localization and quantification of its activity in individual freshly isolated living rat hepatocytes were investigated using confocal microscopy, image analysis, and flow cytometry. DPPIV activity was localized exclusively in patches at plasma membranes likely being bile canalicular domains. Activity was analyzed quantitatively in individual cells by capturing series of images in time. Production of fluorescence was analyzed on the basis of the series of digital images and it appeared to be nonlinear with time. By calculation of the initial velocity at time zero, activity of DPPIV per individual hepatocyte was calculated. Cresyl violet-dependent fluorescence appeared in a similar way when cells were analyzed by flow cytometry. A dipeptide phosphonate inhibitor inhibited production of fluorescence competitively with a Ki of 7 microM. K(m) values in individual hepatocytes varied in the range of 6-22 microM depending on the individual rat from which the hepatocytes were obtained, whereas the Vmax varied in the range of 4-16 nU. K(m) and Vmax values per individual rat were inversely correlated indicating posttranslational regulation of the kinetic parameters of DPPIV. This relationship was lost when membrane fractions of the same hepatocyte suspensions were analyzed. It is concluded that cresyl violet-based protease substrates are the compounds of choice to localize and quantify protease activity in living cells and tissues.

Quantitative assessment of primary cerium reaction product formed by glucose-6-phosphatase activity in a male rat liver: an image analysis study

Glucose-6-phosphatase (G6Pase) activity has been determined in periportal and pericentral areas of the liver of normal male rats. Measurements were performed on unfixed cryostat sections mounted on semipermeable membranes. In the present study, the oxidized primary reaction product of a cerium-based histochemical method [Ce(IV)perhydroxyphosphate] instead of the final reaction product after a second-step incubation was measured. For quantification of the amount of Ce(IV)perhydroxyphosphate formed the digital image analyzing system Quantimet 500+ was used. Estimated values of optical densities of Ce(IV)perhydroxyphosphate over test areas were employed for calculation of kinetic parameters of (G6Pase). Highest activities of G6Pase (higher Km and Vmax levels) were found in periportal areas of the rat liver, indicating a higher amount of active enzyme molecules and a lower affinity for the substrate. Differences in values for both Km and Vmax between periportal and pericentral zones were highly significant and closely comparable to those for male fed rats. Correlations between Km and Vmax were significant for periportal as well for pericentral liver areas. The results of the present study thus allow the same biological implications as histochemical methods employing a final reaction for quantification of enzyme activities. The present method avoids the drawbacks of enhancement reactions and demonstrates the feasibility of in situ analysis of enzyme kinetic parameters by quantification of oxidized primary cerium reaction products.

The dynamics of local kinetic parameters of glutamate dehydrogenase in rat liver

Kinetic parameters of glutamate dehydrogenase (GDH, EC 1.4.1.2) for glutamate were determined in periportal and pericentral zones of adult male and female rat liver lobules under normal fed conditions and after starvation for 24 h. GDH activity was measured as formazan production over time against a range of glutamate concentrations in serial cryostat sections using image analysis. Captured gray value images were transformed to absorbance images and local initial velocities (Vini) were calculated. A hyperbolic function was used to describe the relationship between substrate concentration and local Vini. Under fed conditions, Vmax values were similar in male and female rats (8 +/- 2 and 16 +/- 2 mumol min-1 cm-3 liver tissue in periportal and pericentral zones, respectively). Starvation increased Vmax, especially in pericentral zones of females (to 27 +/- 1 mumol min-1 cm-3 liver tissue). Under fed conditions, the affinity of GDH for glutamate was similar in male and female rats (2.5 +/- 0.5 mM and 3.5 +/- 0.8 mM in periportal and pericentral zones, respectively). Starvation had no effect on K(m) values in male rats, but in female rats affinity for glutamate decreased significantly in both zones (K(m) values of 4.0 +/- 0.1 mM and 8.6 +/- 0.8 mM, respectively). These local changes in the kinetic parameters of GDH indicate that conversion of glutamate to alpha-oxoglutarate cannot be predicted on the basis of GDH concentrations or zero-order activity in the different zones of liver lobules alone.

A novel quantitative histochemical assay to measure endogenous substrate concentrations in tissue sections. Fundamental aspects

A quantitative histochemical assay has been developed for measurement of endogenous substrate concentrations in cryostat sections using a colorimetric visualization technique. Model sections of frozen gelatin solutions with known concentrations of glucose-6-phosphate (G6P) were sandwiched with a second cryostat section containing glucose-6-phosphate dehydrogenase (G6PDH) and all other compounds (with the exception of G6P) that are necessary for the demonstration of G6PDH activity with a tetrazolium salt method. After 60 min of incubation, G6P was converted with concomitant formazan production. The amount of formazan generated was measured cytophotometrically and used as a parameter of the G6P concentration in the first section. A calibration graph was obtained with a high correlation coefficient, allowing the conversion of mean integrated absorbance values into absolute substrate concentrations. The method was highly reproducible, and the recovery of G6P was 85 +/- 4% irrespective section thickness (4-20 microns) and G6P concentration (0.08-1.6 mM) in the sections. The sensitivity of the tetrazolium-linked method appeared to be 100 microM in 20 microns thick sections. This sensitivity enables the measurement of physiological substrate concentrations in tissue sections. Spatial resolution was approximately 150 microns, indicating a relatively high rate of diffusion of G6P during the reaction. The model study shows that the method described here allows the quantitative determination of substrate concentrations in tissue sections. These endogenous substrate concentrations are necessary for the calculation of local metabolic fluxes when determined in combination with local enzyme activities and kinetics, thus giving a more accurate reflection of in situ metabolic heterogeneity of tissues.

Heterogeneity of kinetic parameters of enzymes in situ in rat liver lobules

In the present review, metabolic compartmentation in liver lobules is discussed as being dynamic and more complex than thus far assumed on the basis of numbers of mRNA or protein molecules or the capacity (zero-order activity) of enzymes. Isoenzyme distribution patterns and local kinetic parameters of enzymes may vary over the different zones of liver lobules. As a consequence, metabolic fluxes in vivo at physiological substrate concentrations may be completely different from those that are assumed on the basis of the number of molecules or the capacity of enzymes present in zones of liver lobules. For a more correct estimation of the levels of metabolic processes in the different compartments of liver tissue, local kinetic parameters and substrate concentrations have to be determined to calculate local metabolic fluxes. Direct measurements of metabolic fluxes in vivo with the use of noninvasive techniques is a promising alternative and the techniques will become increasingly important in future metabolic research.

Effects of partial hepatectomy, phenobarbital and 3-methylcholanthrene on kinetic parameters of glucose-6-phosphate and phosphogluconate dehydrogenase in situ in periportal, intermediate and pericentral zones of rat liver lobules

Glucose-6-phosphate dehydrogenase (G6PDH) and phosphogluconate dehydrogenase (PGDH) are heterogeneously distributed in liver lobules of female rats. The maximum activity of both enzymes is approximately twice higher in intermediate and pericentral zones than in periportal zones. Enzyme activities and their distribution patterns were manipulated by partial hepatectomy and treatment with phenobarbital (PB) or 3-methylcholanthrene (3-MC). Vmax values of G6PDH for glucose-6-phosphate decreased mainly in intermediate and pericentral zones after partial hepatectomy, whereas they increased after PB treatment. Vmax values of PGDH for phosphogluconate decreased after partial hepatectomy in both zones, whereas other treatments did not have any effect. The affinity of G6PDH for glucose-6-phosphate was similar in all zones and it was decreased 2-3 fold by PB and 3-MC treatment. The affinity of PGDH for phosphogluconate was 1.4-2.3 times lower in intermediate and pericentral zones than in periportal zones of all livers tested and was not affected by treatment. From these data it can be concluded that not only the maximum activity of enzymes may differ in periportal, intermediate and pericentral zones of the liver lobule but also the affinity of enzymes for their substrates. The implication of these findings is that metabolic flux rates as they occur in vivo in these different metabolic compartments may be significantly different from predictions on the basis of maximum enzyme activities as detected immunohistochemically, microchemically or cytophotometrically.

Tissue and subcellular distribution of glucokinase in rat liver and their changes during fasting-refeeding

The distribution of glucokinase in rat liver under both normal feeding and fasting-refeeding conditions was investigated immunohistochemically. Under normal feeding conditions, glucokinase immunoreactivity was observed in both nuclei and cytoplasm of parenchymal cells. The nuclei were stained intensely and evenly, whereas the cytoplasm showed weak immunoreactivity of different degrees of staining intensity depending on the location of the cells. The cytoplasm of perivenous hepatocytes was stained more intensely, though not so much more, than that of periportal hepatocytes. The cytoplasm of hepatocytes surrounding the terminal hepatic venule (THV), of hepatocytes surrounding the portal triad, and of some other hepatocytes showed a stronger immunoreactivity than that of residual hepatocytes. The nuclear immunoreactivity in hepatocytes surrounding the portal triad and in some other hepatocytes was weak or absent, and positive immunoreactivity was detected at the plasma membrane of some of these cells. After 72 h of fasting, glucokinase immunoreactivity was markedly decreased in all hepatocytes. After the start of refeeding, the cytoplasmic immunoreactivity began to increase first in the parenchymal cells surrounding the THV and extended to those in the intermediate zone followed by those in the periportal zone. In contrast, the increase in nuclear immunoreactivity started in hepatocytes situated in the intermediate zone adjacent to the perivenous zone and then extended to those in the perivenous zone followed by those in the periportal zone. Hepatocytes surrounding either THV or portal triad showed a distinctive change in immunoreactivity during the refeeding period. After 10 h of refeeding, strong immunoreactivity was observed in both the cytoplasm and the nuclei of all hepatocytes, and appreciable glucokinase immunoreactivity was detected at the plasma membrane of some hepatocytes. These findings are discussed from the standpoint of a functional role of glucokinase in hepatic glucose metabolism.

The diverse Michaelis constants and maximum velocities of lactate dehydrogenase in situ in various types of cell

The kinetics of lactate dehydrogenase in mouse cardiac muscle fibres, skeletal muscle fibres, gastric parietal cells, parotid gland ductal and acinar cells, oocytes and mouse and human hepatocytes were studied as a function of substrate concentration in sections of unfixed mouse and human tissues incubated at 37 degrees C on lactate agarose gel films. The absorbances of the final reaction products deposited in single cells of various types were measured continuously as a function of incubation time using an image analysis system. The initial velocities (vi) of the dehydrogenase were calculated from two equations deduced previously by us, vi = a1 zero A (equation 1) and vi = v + a2 zero A (equation 2), where v and zero A are, respectively, the gradient (steady-state velocity) and intercept of the linear regression line of absorbance on time for incubation times between 1 and 3 min, and a1 and a2 are constants characteristic for each cell type. Hanes plots using vi calculated from equation 2 gave more consistent estimates of the Michaelis constant (Km) and the maximum reaction velocity (Vmax) than those employing either steady-state velocity measurements or vi calculated from equation 1. The Km thus found for mouse skeletal muscle fibres (10.4-12.5 mM) and hepatocytes (14.3-16.7 mM) agreed well with values determined previously in biochemical assays. However, the Km for cardiac muscle fibres (13.4 mM) was higher. The Km of the enzyme in gastric parietal cells, parotid gland cells and oocytes was in the range 7.6-9.7 mM.(ABSTRACT TRUNCATED AT 250 WORDS)

A concentration gradient of glucose from liver to plasma

Concentrations of glucose in plasma water and liver water were determined in rats under a number of conditions. In fasted and fed postadsorptive rats, the concentration of glucose in plasma water averaged 5.5 +/- 0.5 and 6.8 +/- 0.2 mmol/L, respectively. The concentration in liver water was 8.2 +/- 0.9 and 11.1 +/- 1.1 mmol/L, respectively (mean +/- SD). The concentration ratio of liver water to plasma water (LW/PW) was 1.52 +/- 0.1 (range, 1.4 to 1.7; n = 7) in fasted rats and 1.64 +/- 0.39 (range, 1.38 to 2.0; n = 10 [mean +/- SD]) in fed rats. Fasted rats treated with glucagon contained no liver glycogen. The concentration of glucose in plasma water was 7.1 +/- 0.3 mmol/L and in liver water 9.2 +/- 0.5 mmol/L, and the LW/PW averaged 1.35 +/- 0.08 (range, 1.23 to 1.45; n = 8). Insulin-injected hypoglycemic rats contained very little glycogen. The LW/PW was 2.7 +/- 0.2. In fasted rats infused intragastrically with 30 mg/min/kg glucose, the concentration of glucose in mixed portal-arterial plasma water entering the liver averaged 10.3 +/- 0.8 mmol/L and that in liver water 12.4 +/- 1.3 mmol/L (mean +/- SD), with the LW/PW averaging 1.21 +/- 0.1 (range, 1.08 to 1.4; n = 8). Fasted rats were infused with 3.4 mg/min/kg sodium lactate labeled with 14C and 13C and with a trace amount of [3-3H]glucose. The glucose concentration in arterial plasma water averaged 6.4 +/- 1.0 mmol/L and in liver water 14.6 +/- 4.4 mmol/L (mean +/- SD).(ABSTRACT TRUNCATED AT 250 WORDS)

Cerium methods for light and electron microscopical histochemistry

Methods based on the use of cerium to detect the activity of oxidases and phosphatases are rapidly expanding. Both classes of enzymes can be demonstrated with cerium at the electron and light microscopical level. The in situ detection of H2O2 production with cerium is another application that has great potential, particularly in experimental pathological research. The fine precipitate of the cerium-containing final reaction product, cerium perhydroxide or cerium phosphate, enables a very precise localization. With such techniques, important advances have been made in cell biology, such as the discovery of new organelles, functional subcompartmentization of peroxisomes, tubular lysosomes and the elucidation of the function of extracellular ATPases. At the light microscopical level, the activity of enzymes can be quantified in situ because the production of final reaction product in the cerium methods is proportional to enzyme activity in tissue sections or cells. Cerium precipitates have strong reflectance properties and this enables their use in confocal scanning laser microscopy. In the present review, the principles of cerium methods are outlined and applications in cell biology and pathology are discussed.

Experimentally induced colon cancer metastases in rat liver increase the proliferation rate and capacity for purine catabolism in liver cells

Metastases in rat liver were generated experimentally by intraportal injection of colon cancer cells to investigate the effects of cancerous growth on the metabolism of surrounding liver tissue. Maximum activities (capacity) of glucose-6-phosphate dehydrogenase, phosphogluconate dehydrogenase, lactate dehydrogenase, succinate dehydrogenase, alkaline phosphatase, 5'-nucleotidase, xanthine oxidoreductase, purine nucleoside phosphorylase and adenosine triphosphatase have been determined. Two types of metastases were found, a small type surrounded by stroma and a larger type in direct contact with hepatocytes. Both types affected the adjacent tissue in a similar way suggesting that the interactions were not mediated by stroma. High capacity of the degradation pathway of extracellular purines released from dead cells of either tumours or host tissue was found in stroma and sinusoidal cells. Metastases induced both an increase in the number of Kupffer cells and proliferation of hepatocytes. The distribution pattern in the liver lobulus of most enzymes investigated did not change distinctly. However, activity of alkaline phosphatase, succinate dehydrogenase and phosphogluconate dehydrogenase was increased in hepatocytes directly surrounding metastases. These data imply that the overall metabolic zonation in liver lobuli is not dramatically disturbed by the presence of cancer cells despite the fact that various metabolic processes in liver cells are affected.

Intraepithelial neoplasia, surrogate endpoint biomarkers, and cancer chemoprevention

Neoplasia is a progression of molecular, cellular, and tissue changes starting with a critical cell mutation and advancing by clonal evolution, involving further multiple mutations and expanding mutated clones. This process is characterized by five general stages: latency, focal growth of normal-appearing but disorganized cells, abnormal-appearing cells (dysplasia), microinvasion, and finally, metastasis. The two driving forces of neoplastic progression in an epithelium are mutagenesis and mitogenesis. These forces frequently occur concurrently, produced by exposure of the epithelium to environmental and endogenous mutagens and mitogens. The major strategy of chemoprevention is to block the effects of both mutagens and mitogens during the early stages of predysplasia and dysplasia. Surrogate endpoint biomarkers (SEBs) are tissue, cellular, and molecular changes that correlate with the later development of cancer. Because of the savings in cost, labor, and time, SEBs are urgently needed to replace the use of cancer incidence reduction as the endpoint for chemopreventive agent clinical trials. The advent of computer-assisted cytometry allows each of the seven basic criteria of dysplasia to be individually assayed as an SEB. Since the dysplastic changes that characterize intraepithelial neoplasia are embodied in the causal pathway to invasive neoplasia, they are already validated as predictors of cancer incidence. More attention should be paid to the quality control of SEB assays, including control of variation in cell composition of tissue samples, assay protocol, instrumentation used, and observer performance. The dose-response relationship between a known chemopreventive agent and the SEB should also be evaluated. The Division of Cancer Prevention and Control, National Cancer Institute, has begun a program to test chemopreventive agents in short-term Phase II clinical trials using dysplasia-based SEBs. The SEBs are assayed, when possible, by computerized cytometry. Trials are being conducted for oral leukoplakia, cutaneous actinic keratosis, superficial bladder cancer, pulmonary metaplasia/dysplasia, cervical dysplasia (CIN III), and adenomatous colonic polyps.

Quantitative determination of calcium-activated myosin adenosine triphosphatase activity in rat skeletal muscle fibres

A quantitative histochemical technique was developed for determining the kinetics of the calcium-activated myosin ATPase (Ca(2+)-myosin ATPase) reaction in rat skeletal muscle fibres. Using this technique, the maximum velocity (Vmax) and the apparent Michaelis-Menten rate constant for ATP (K(app)) of the Ca(2+)-myosin ATPase reaction were measured in type-identified fibres of the rat medial gastrocnemius (MG) muscle. The Vmax and the K(app) of the Ca(2+)-myosin ATPase reaction were lowest in type I fibres and highest (i.e., approx. two times greater) in type IIb fibres. The K(app) in type IIa fibres was similar to that in type I. However, the Vmax was 1.5 times greater in type IIa fibres, compared to type I fibres. Evidence is presented to suggest that the type IIb fibre population in the MG does not represent a single myosin isozyme. In addition, the broad range of Vmax and K(app) values indicates that there is marked heterogeneity in the myosin heavy chain and myosin light chain composition of myosin isozymes among individual fibres.

Molecular extinction coefficients of lead sulfide and polymerized diaminobenzidine as final reaction products of histochemical phosphatase reactions

Molar extinction coefficients of precipitated lead sulfide (PbS) and polymerized diaminobenzidine (polyDAB) have been determined at wavelengths of 450 nm and 480 nm, respectively, for quantitative histochemical analysis of phosphatase reactions. These values are essential for the conversion of cytophotometric (mean integrated) absorbance values to absolute units of substrate converted per unit time and volume of tissue. This conversion allows direct comparison of histochemical and biochemical data. The molar extinction coefficient of PbS at 450 nm was found to be 3,800 and therefore, per mole phosphate liberated, the molar extinction coefficient is 5,700 because 3 moles phosphate are captured by 2 moles lead at neutral or alkaline pH. Parallel experiments with the cerium-DAB method revealed that the molar extinction coefficient of polyDAB at 480 nm is 5,500 with respect to liberated phosphate. The molar extinction coefficients were applied for comparison of data from biochemical and histochemical assays of glucose-6-phosphatase activity in rat livers. A significant correlation was found between both sets of data. The values were in the same order of magnitude with histochemical values approximately 1.4 times higher than biochemical values.