Rates of entry and oxidation of acetate,glucose, d(?)-β-hydroxybutyrate,palmitate, oleate and stearate,and rates of production and oxidation of propionate and butyrate in fed and starved sheep

1. Rates of entry and oxidation of a range of metabolites have been measured in tracheostomized sheep (diet, 800g. of lucerne chaff and 100g. of maize/day) by combining isotope-dilution techniques with the continuous measurement of total respiratory gas exchange, and ¹⁴CO₂ production during the intravenous or intraruminal infusion of ¹⁴C-labelled substrates. 2. Mean entry rates in fed and starved (24hr.) sheep respectively, expressed as mg./min./kg. body wt.^0·75, were: glucose, 5·0 (range 4·8–5·1, 2 observations) and 3·8 (3·2–4·2, 4); acetate, 10·8 (9·1–13·5, 4) and 5·8 (1); d(−)-β-hydroxybutyrate, 1·4 (1) and 1·5 (0·8–2·4, 4); palmitate, oleate and stearate (starved sheep only) 1·0 (0·6–1·9, 7), 0·9 (0·2–1·6, 10) and 0·9 (0·5–1·1, 11) respectively. 3. Production rates of propionate and butyrate in continuously feeding sheep were 6·4 (4·7–8·3, 4) and 4·3 (3·4–6·1, 4) mg./min./kg.^0·75 respectively, and in starved (24hr.) sheep were 2·5 (2·2–2·9, 2) and 1·0 (0·8–1·2, 2) mg./min./kg.^0·75 respectively. 4. Calculated terminal values for the specific radioactivity of respiratory ¹⁴CO₂ during measurements of entry rates and production rates were used to calculate the contributions of individual substrates to overall oxidative metabolism. Mean values for fed and starved sheep respectively were: glucose, 9·1 (8·6–9·6, 2) and 11·2 (5·9–15·1, 4)%; acetate, 31·6 (26·8–38·1, 4) and 22·1 (1)%; d(−)-β-hydroxybutyrate, 10·4 (1) and 4·8 (1·9–7·7, 4)%; propionate, 23·0 (13·8–29·9, 4) and 7·1 (6·8–7·4, 2)%; butyrate, 16·5 (13·7–20·5, 4) and 5·3 (5·2–5·3, 2)%; palmitate, oleate and stearate (starved sheep only), 4·7 (2·0–7·7, 7), 4·0 (1·2–6·6, 10) and 4·4 (3·8–5·8, 9)% respectively. The sum of these values for individual substrates in fed and starved sheep, excluding that of β-hydroxybutyrate and after correction of the glucose value for the known interrelations of this substrate with propionate, accounted for 76% and 58% respectively of total production of carbon dioxide. 5. Calculations based on the proportion of substrate entry directly oxidized indicated that the substrates studied accounted for 63% (fed sheep) and 43% (starved sheep) of total energy expenditure measured by oxygen uptake. The contribution of β-hydroxybutyrate was excluded, and corrections were made for glucose–propionate interrelations, and for the different rates of oxidation of the methyl and carboxyl fragments of acetate. 6. The present results have been combined with those obtained earlier in this Laboratory to examine the relationships between rates of substrate entry and oxidation, and concentrations of substrate in blood. Rates of entry of acetate, glucose, d(−)-β-hydroxybutyrate, palmitate and oleate (but not stearate) were well correlated with concentration in blood, and substrate contribution to production of carbon dioxide showed a similar correlation to blood concentration, except with glucose. 7. It was concluded that the general technique is of potential value in providing valid quantitative parameters of animal metabolism.     

The conversion of orotic acid into uridine 5′-monophosphate by isolated perfused normal and regenerating rat livers

The release of (14)CO(2) from [7-(14)C]orotic acid was measured in isolated perfused normal and regenerating rat livers. With some limitations, the release of (14)CO(2) from [7-(14)C]orotic acid can be used to estimate UMP synthesis in perfused livers. Isolated perfused livers rapidly pick up labelled orotic acid added to perfusate and convert most of it into UMP. Perfused regenerating livers produce approx. 2.5 times as much UMP/g of liver as do perfused normal livers. However, the absolute amount of orotic acid converted into UMP is higher in perfused normal livers than in perfused regenerating livers. Perfused regenerating livers do not differ in their orotic acid uptake and UMP synthesis from livers of comparable size in which regeneration is not taking place. The total amount of orotic acid taken up by the liver (rather than the rate of uptake) and the size of the liver appear to be the determining factors in UMP production. The results suggest that the decrease in liver size caused by partial hepatectomy may be in itself sufficient to account for an increase in the flow of metabolites in the pyrimidine pathway at the early stages of liver regeneration.     

Acetyl-coenzyme A hydrolase,an artifact? The conversion of acetyl-coenzyme A into acetate by the combined action of carnitine acetyltransferase and acetylcarnitine hydrolase

1. The nature of the acetyl-CoA hydrolase (EC 3.1.2.1) reaction in rat and sheep liver homogenates was investigated. 2. The activity determined in an incubated system was 5.10 and 3.28nmol/min per mg of protein for rat and sheep liver homogenate respectively. This activity was not affected by the addition of l-carnitine, but was decreased by the addition of d-carnitine. 3. No acetyl-CoA hydrolase activity could be detected in rat or sheep liver homogenates first treated with Sephadex G-25. This treatment decreased the carnitine concentrations of the homogenates to about one-twentieth. Subsequent addition of l-carnitine, but not d-carnitine, restored the apparent acetyl-CoA hydrolase activity. 4. Sephadex treatment did not affect acetyl-carnitine hydrolase activity of the homogenates, which was 5.8 and 8.1nmol/min per mg of protein respectively for rat and sheep liver. 5. Direct spectrophotometric assay of acetyl-CoA hydrolase, based on the reaction of CoA released with 5,5'-dithiobis-(2-nitrobenzoic acid), clearly demonstrated that after Sephadex treatment no activity could be measured. 6. Carnitine acetyltransferase (EC 2.3.1.7) activity measured in the same assay system in response to added l-carnitine was very low in normal rat liver homogenates, owing to the apparent high acetyl-CoA hydrolase activity, but was increased markedly after Sephadex treatment. The V(max.) for this enzyme in rat liver homogenates was increased from 3.4 to 14.8nmol/min per mg of protein whereas the K(m) for l-carnitine was decreased from 936 to 32mum after Sephadex treatment. 7. Acetyl-CoA hydrolase activity could be demonstrated in disrupted rat liver mitochondria but not in separated outer or inner mitochondrial membrane fractions. Activity could be demonstrated after recombination of outer and inner mitochondrial membrane fractions. The outer mitochondrial membrane fraction showed acetylcarnitine hydrolase activity and the inner mitochondrial membrane fraction showed carnitine acetyltransferase activity. 8. The results presented here demonstrate that acetyl-CoA hydrolase activity in rat and sheep liver is an artifact and the activity is due to the combined activity of carnitine acetyltransferase and acetylcarnitine hydrolase.     

The effect of acetate on the regulation of the branched chain α-keto acid and the pyruvate dehydrogenase complexes in the perfused rat liver

The regulatory consequences of acetate infusion on the pyruvate and the branched chain α-keto acid dehydrogenase reactions in the isolated, perfused rat liver were investigated. Metabolic flux through these two decarboxylation reactions was monitored by measuring the rate of ¹⁴CO₂ production from infused 1-¹⁴C-labeled substrates. When acetate was presented to the liver as the sole substrate the rate of ketogenesis which resulted was maximal at concentrations of acetate in excess of 10 mm. The increase in hepatic ketogenesis during acetate infusion was not accompanied by an alteration of the mitochondrial oxidation-reduction state as measured by the ratio of β-hydroxybutyrate/ acetoacetate in the effluent perfusate. While acetate infusion did not affect the rate of α-keto[1-¹⁴C]isocaproate decarboxylation, the rate of α-keto[1-¹⁴C]isovalerate decarboxylation was stimulated appreciably upon acetate addition. No change was observed in the amount of extractable branched chain α-keto acid dehydrogenase during acetate infusion. The rate of [1-¹⁴C]pyruvate decarboxylation was stimulated in the presence of acetate at low (<1 mm) but not at high (>1 mm) perfusate pyruvate concentrations. The stimulation of the metabolic flux through the pyruvate dehydrogenase reaction upon acetate infusion was accompanied by an increase in the activation state of the pyruvate dehydrogenase complex from 25.7 to 35.6% in the active form. In a liver perfused in the presence of the pyruvate dehydrogenase kinase inhibitor, dichloroacetate, at a low concentration of pyruvate (0.05 mm) the infusion of acetate did not affect the rate of pyruvate decarboxylation. As the rate of mitochondrial acetoacetate efflux is increased during acetate infusion the stimulation of pyruvate and α-ketoisovalerate decarboxylation is attributed to an accelerated rate of exchange of mitochondrial acetoacetate for cytosolic pyruvate or α-ketoisovalerate on the monocarboxylate transporter.     

Studies on the biosynthesis of protein by lactating guinea-pig mammary gland: Characteristics of the synthesis of α-lactalbumin and total protein by slices and cell-free systems

1. Slices of lactating guinea-pig mammary gland were incubated with radioactive amino acids and the various subcellular fractions separated by centrifugation after disruption of the cells by mincing and homogenization. The most active fraction for protein synthesis appeared to be the `mitochondrial'. 2. When the subcellular fractions were prepared without previous incubation of the cells and were then incubated with radioactive amino acid and an energy-generating system, the `mitochondrial fraction' was at least as active for protein synthesis as the `microsomal fraction'. 3. The ribosomes in the microsomal fraction are mainly unattached to membrane whereas those in the mitochondrial fraction are probably attached to fragments of the rough-surfaced endoplasmic reticulum. This latter fraction contains few mitochondria. 4. The combined mitochondrial and microsomal fractions incorporated radioactive amino acids into α-lactalbumin. 5. The radioactive leucine isolated from tryptic and chymotryptic peptides of α-lactalbumin synthesized in the cell-free system was not of uniform specific radioactivity. This was consistent with the polypeptide being assembled by the sequential addition of amino acids. 6. Evidence is presented for the polypeptide chain of α-lactalbumin being assembled from the N-terminus and for chain initiation in the cell-free system. 7. It is concluded that cell-free extracts of lactating mammary gland synthesize α-lactalbumin.     

The differential actions of cortisol on the accumulation of α-lactalbumin and casein in midpregnant mouse mammary gland in culture

The dose-response relationship between cortisol and the accumulation of the two milk proteins, casein and α-lactalbumin, was studied in organ culture of mammary gland from midpregnant mice. The accumulation of casein was low in culture with insulin but was enhanced by the further addition of prolactin. Further increases in casein were effected by the addition of cortisol in increasing concentrations up to 3 × 10^?6 M, which was optimal for the accumulation of this protein. The content of α-lactalbumin in explants was similarly low in culture with insulin alone, but, in contrast, was increased to a maximal level by the addition of insulin and prolactin. The addition of cortisol up to 3 × 10^?8 M with insulin and prolactin did not further increase the level of α-lactalbumin; in fact, at concentrations above 3 × 10^?7 M the steroid caused progressive inhibition of the accumulation of this protein in cultured explants. Studies of the appearance of casein and α-lactalbumin in incubation medium during organ culture revealed the presence of substantial amounts of these milk proteins. During the first 2 days of culture with insulin, prolactin and 3 × 10^?6 M cortisol, the amount of α-lactalbumin in culture medium was almost equal to the level found in tissue, whereas in the presence of 3 × 10^?8 M cortisol, or in the absence of exogenous steroid, over 70% of total α-lactalbumin was retained in tissue. The observed difference in the amount of α-lactalbumin in culture medium can, however, only partially account for the inhibitory effect of high doses of cortisol on the accumulation of α-lactalbumin in cultured mammary explants. In contrast to α-lactalbumin, the relative amount of casein in culture medium containing insulin and prolactin was smaller—19% of total casein synthesized—and was further reduced to 16% and 11% of the total in the presence of 3 × 10^?8 M and 3 × 10^?6 M cortisol, respectively. The above results indicate that cortisol exerts dose-dependent differential actions on the accumulation of casein and α-lactalbumin in mouse mammary epithelium in vitro.     

The cytoplasmic domain of MUC1 induces hyperplasia in the mammary gland and correlates with nuclear accumulation of β-catenin

MUC1 is an oncoprotein that is overexpressed in up to 90% of breast carcinomas. A previous in vitro study by our group demonstrated that the cytoplasmic domain of MUC1 (MUC1-CD), the minimal functional unit of MUC1, contributes to the malignant phenotype in cells by binding directly to β-catenin and protecting β-catenin from GSK3β-induced degradation. To understand the in vivo role of MUC1-CD in breast development, we generated a MUC1-CD transgenic mouse model under the control of the MMTV promoter in a C57BL/6J background, which is more resistant to breast tumor. We show that the expression of MUC1-CD in luminal epithelial cells of the mammary gland induced a hyperplasia phenotype characterized by the development of hyper-branching and extensive lobuloalveoli in transgenic mice. In addition to this hyperplasia, there was a marked increase in cellular proliferation in the mouse mammary gland. We further show that MUC1-CD induces nuclear localization of β-catenin, which is associated with a significant increase of β-catenin activity, as shown by the elevated expression of cyclin D1 and c-Myc in MMTV-MUC1-CD mice. Consistent with this finding, we observed that overexpression of MUC1-C is associated with β-catenin nuclear localization in tumor tissues and increased expression of Cyclin D1 and c-Myc in breast carcinoma specimens. Collectively, our data indicate a critical role for MUC1-CD in the development of mammary gland preneoplasia and tumorigenesis, suggesting MUC1-CD as a potential target for the diagnosis and chemoprevention of human breast cancer.     

The mammary gland response to estradiol: monotonic at the cellular level, non-monotonic at the tissue-level of organization?

The role of hormones in mammary gland development has been studied in detail using surgical and genetic models. These studies have indicated roles for estrogen in ductal elongation and terminal end bud formation. However, no comprehensive study has quantified how different doses of estrogen affect morphological parameters of mammary gland development. Additionally, comparisons between the estrogen-responsiveness of the mammary gland and uterus, the model organ for estrogen action are incomplete. In this study, immature mice were ovariectomized and implanted with osmotic pumps releasing one of eight doses of 17β-estradiol for 10 days. As expected from the classical uterotrophic assay, the uterus showed a monotonic dose–response curve for all measured endpoints. In contrast, the mammary gland showed a non-monotonic, inverted-U shaped response to estrogen with regard to morphometric parameters, and a monotonic response with regard to gene expression parameters. These results indicate that estrogen has opposing effects in mammary gland morphogenesis depending on estrogen dose, i.e. low to moderate doses induce terminal end bud formation and ductal elongation while higher doses inhibit these processes. This non-monotonic dose–response in the mammary gland may reflect complex interactions, where estrogen can act on multiple targets either as an agonist or antagonist.     

Influence of lβ-, dα- and dβ-Asp isomers of the Asp-76 residue on the properties of αA-crystallin 70–88 peptide

Proteins have been considered to consist exclusively of l-amino acids in living tissues. However, our previous studies showed that two specific aspartyl (Asp) residues in αA- and αB-crystallins from human eye lenses invert to the d-isomers to a high degree during aging. The reaction is also accompanied by isomerization into a form containing β-Asp (isoaspartate) residues. The appearance of d- and β-Asp in a protein potentially induces large changes to the higher order structure of the protein as well as to its function. However, it remains unclear whether the formation of the Asp isomer is the direct trigger of the change to the higher order structure and function. In this study, in order to clarify the effect of the inversion to d-isomers in a protein, we synthesized peptides corresponding to the 70–88 (KFVIFLDVKHFSPEDLTVK) fragment of human αA-crystallin and its corresponding diastereoisomers in which lα-Asp was replaced with lβ-Asp, dα-Asp, and dβ-Asp at position 76 and compared their biochemical properties with that of normal peptide. The peptides containing abnormal isomers (lβ-Asp, dα-Asp, and dβ-Asp residues, respectively) were more hydrophilic than the normal peptide (containing lα-Asp), lost β-sheet structure and changed to random structures. The normal peptide promoted the aggregation of insulin while the other three isomers suppressed the aggregation of insulin. This is the first evidence that a single substitution of an Asp isomer in a peptide induces a large change to the properties of the peptide.     

The role of oxygen limitation in the formation of poly-β-hydroxybutyrate during batch and continuous culture of Azotobacter beijerinckii

Azotobacter beijerinckii was grown in ammonia-free glucose-mineral salts media in batch culture and in chemostat cultures limited by the supply of glucose, oxygen or molecular nitrogen. In batch culture poly-beta-hydroxybutyrate was formed towards the end of exponential growth and accumulated to about 74% of the cell dry weight. In chemostat cultures little poly-beta-hydroxybutyrate accumulated in organisms that were nitrogen-limited, but when oxygen limited a much increased yield of cells per mol of glucose was observed, and the organisms contained up to 50% of their dry weight of poly-beta-hydroxybutyrate. In carbon-limited cultures (D, the dilution rate,=0.035-0.240h(-1)), the growth yield ranged from 13.1 to 19.8g/mol of glucose and the poly-beta-hydroxybutyrate content did not exceed 3.0% of the dry weight. In oxygen-limited cultures (D=0.049-0.252h(-1)) the growth yield ranged from 48.4 to 70.1g/mol of glucose and the poly-beta-hydroxybutyrate content was between 19.6 and 44.6% of dry weight. In nitrogen-limited cultures (D=0.053-0.255h(-1)) the growth yield ranged from 7.45 to 19.9g/mol of glucose and the poly-beta-hydroxybutyrate content was less than 1.5% of dry weight. The sudden imposition of oxygen limitation on a nitrogen-limited chemostat culture produced a rapid increase in poly-beta-hydroxybutyrate content and cell yield. Determinations on chemostat cultures revealed that during oxygen-limited steady states (D=0.1h(-1)) the oxygen uptake decreased to 100mul h(-1) per mg dry wt. compared with 675 for a glucose-limited culture (D=0.1h(-1)). Nitrogen-limited cultures had CO(2) production values in situ ranging from 660 to 1055mul h(-1) per mg dry wt. at growth rates of 0.053-0.234h(-1) and carbon-limited cultures exhibited a variation of CO(2) production between 185 and 1328mul h(-1) per mg dry wt. at growth rates between 0.035 and 0.240h(-1). These findings are discussed in relation to poly-beta-hydroxybutyrate formation, growth efficiency and growth yield during growth on glucose. We suggest that poly-beta-hydroxybutyrate is produced in response to oxygen limitation and represents not only a store of carbon and energy but also an electron sink into which excess of reducing power can be channelled.     

The Neurospora crassa dfg5 and dcw1 genes encode α-1,6-mannanases that function in the incorporation of glycoproteins into the cell wall

The covalent cross-linking of cell wall proteins into the cell wall glucan/chitin matrix is an important step in the biogenesis of the fungal cell wall. We demonstrate that the Neurospora crassa DFG5 (NCU03770) and DCW1 (NCU08127) enzymes function in vivo to cross-link glycoproteins into the cell wall. Mutants lacking DFG5 or DCW1 release slightly elevated levels of cell wall proteins into their growth medium. Mutants lacking both DFG5 and DCW1 have substantially reduced levels of cell wall proteins in their cell walls and release large amounts of known cell wall proteins into the medium. DFG5 and DCW1 are members of the GH76 family of glycosyl hydrolases, which have specificity to recognize and cleave α-1,6-mannans. A model for incorporation of glycoproteins into the cell wall through the α-1,6-mannan core of the N-linked galactomannan is presented. In this model, DFG5 and DCW1 recognize the N-linked galactomannan present on glycoproteins and cross-link it into the cell wall glucan/chitin matrix.     

The expression of β-1,3 galactosyltransferase and β-1,4 galactosyltransferase enzymatic activities in the mammary gland of the tammar wallaby (Macropus eugenii) during early lactation

The regulation of β-1,3 galactosyltransferase (3βGalT) and β-1,4 galactosyltransferase enzymatic (4βGalT) activities in the mammary gland of the tammar wallaby (Macropus eugenii) have been characterised. These two β-galactosyltransferases are active at different times during the lactation cycle and play a central role in regulating the carbohydrate composition in tammar milk, which changes progressively throughout lactation to assist the physiological development of the altrical young. The 4βGalT activity was present at parturition and increased 3-fold by day 10 of lactation (d10L), whereas 3βGalT activity was barely detectable at day d5L and then increased 6-fold by d10L. This increase in activity of both enzymes was sucking dependent. While 3βGalT activity was not observed in the mammary gland prior to d7L, this activity was found in mammary explants from late pregnant tammar cultured with insulin, hydrocortisone and prolactin (IFP) and was further stimulated by the addition of tri-iodothyronine (T) and 17β-oestradiol (E). The activity of 4βGalT in these explants was stimulated maximally with IFP. These data suggest the temporal activity of both 3βGalT and 4βGalT is most likely regulated by both endocrine stimuli and factors intrinsic to the mammary gland.     

The Structure- and Metal-dependent Activity of Escherichia coli PgaB Provides Insight into the Partial De-N-acetylation of Poly-β-1,6-N-acetyl-D-glucosamine

Exopolysaccharides are required for the development and integrity of biofilms produced by a wide variety of bacteria. In Escherichia coli, partial de-N-acetylation of the exopolysaccharide poly-β-1,6-N-acetyl-d-glucosamine (PNAG) by the periplasmic protein PgaB is required for polysaccharide intercellular adhesin-dependent biofilm formation. To understand the molecular basis for PNAG de-N-acetylation, the structure of PgaB in complex with Ni²⁺ and Fe³⁺ have been determined to 1.9 and 2.1 Å resolution, respectively, and its activity on β-1,6-GlcNAc oligomers has been characterized. The structure of PgaB reveals two (β/α)_x barrel domains: a metal-binding de-N-acetylase that is a member of the family 4 carbohydrate esterases (CE4s) and a domain structurally similar to glycoside hydrolases. PgaB displays de-N-acetylase activity on β-1,6-GlcNAc oligomers but not on the β-1,4-(GlcNAc)₄ oligomer chitotetraose and is the first CE4 member to exhibit this substrate specificity. De-N-acetylation occurs in a length-dependent manor, and specificity is observed for the position of de-N-acetylation. A key aspartic acid involved in de-N-acetylation, normally seen in other CE4s, is missing in PgaB, suggesting that the activity of PgaB is attenuated to maintain the low levels of de-N-acetylation of PNAG observed in vivo. The metal dependence of PgaB is different from most CE4s, because PgaB shows increased rates of de-N-acetylation with Co²⁺ and Ni²⁺ under aerobic conditions, and Co²⁺, Ni²⁺ and Fe²⁺ under anaerobic conditions, but decreased activity with Zn²⁺. The work presented herein will guide inhibitor design to combat biofilm formation by E. coli and potentially a wide range of medically relevant bacteria producing polysaccharide intercellular adhesin-dependent biofilms.     

The impact of testosterone,tibolone and black cohosh on purified mammary and placental 17β-hydroxysteroid dehydrogenase type 1

Abstract

Context: Mammary and placental 17β-hydroxysteroid dehydrogenase type 1 (17βHSD1).

Objective: To assess the impact of testosterone, tibolone, and black cohosh on purified mammary and placental 17βHSD1.

Materials and methods: 17βHSD1 was purified from human mammary gland and placenta by column chromatography, its activity was monitored by a radioactive activity assay, and the degree of purification was determined by gel electrophoresis. Photometric cofactor transformation analysis was performed to assess 17βHSD1 activity without or in presence of testosterone, tibolone and black cohosh.

Results: 17βHSD1 from both sources displayed a comparable basal activity. Testosterone and tibolone metabolites inhibited purified mammary and placental 17βHSD1 activity to a different extent, whereas black cohosh had no impact.

Discussion: Studies on purified enzymes reveal the individual action of drugs on local regulatory mechanisms thus helping to develop more targeted therapeutic intervention.

Conclusion: Testosterone, tibolone and black cohosh display a beneficial effect on local mammary estrogen metabolism by not affecting or decreasing local estradiol exposure.     

Microbial metabolism of C1 and C2 compounds. The role of acetate during growth of Pseudomonas AM1 on C1 compounds, ethanol and β-hydroxybutyrate

Pseudomonas AM1 grows on beta-hydroxybutyrate and methanol at similar rates. beta-Hydroxybutyrate is not metabolized by way of the glyoxylate bypass, but is assimilated by the novel route (with acetate as an intermediate) that operates during growth of this organism on ethanol. Evidence from short-term labelling experiments indicates that acetate, which is a possible intermediate in the assimilation of C(1) compounds, is rapidly metabolized to glycine during growth of Pseudomonas AM1 on methanol.