Tryptophan Metabolism of Rats Fed on an Amino Acid Diet Devoid of One Branched Chain Amino Acid

In an attempt to study on metabolic changes in rats fed on an amino acid diet devoid of one branched chain amino acid and of niacin, rats were force-fed a leucine-free, isoleucine-free, valine-free or complete amino acid diet for 3 or 4 days and killed 3 hr after the feeding on day 4 or 5 to observe the body weight changes, the urinary nitrogen and N¹-methylnicotinamide (MNA), and liver tryptophanpyrrolase (TPase) and tyrosine-α-keto-glutarate transaminase (TKase) activities.

The excretion of the urinary nitrogen and MNA, TPase and TKase activities, and fat content of livers of rats force-fed these amino acid deficient diets were higher than those fed the complete amino acid diet. It was further confirmed in the present study that changes in TPase activity of rats given diets devoid of one essential amino acid were in the same direction with changes in urinary MNA which was observed in the previous studies on rats given threonine-free, tryptophan-free, methionine-free, lysine-free and complete amino acid diets. However, such metabolic changes in rats fed the leucine-free diet were not so remarkable, compared with those of rats fed the other amino acid deficient diets.     

Geminin escapes degradation in G1 of mouse pluripotent cells and mediates the expression of Oct4, Sox2, and Nanog

Geminin is an essential cell-cycle protein that is only present from S phase to early mitosis in metazoan somatic cells. Genetic ablation of geminin in the mouse results in preimplantation embryonic lethality because pluripotent cells fail to form and all cells differentiate to trophoblast. Here we show that geminin is present in G1 phase of mouse pluripotent cells in contrast to somatic cells, where anaphase-promoting complex/cyclosome (APC/C)-mediated proteasomal destruction removes geminin in G1. Silencing geminin directly or by depleting the APC/C inhibitor Emi1 causes loss of stem cell identity and trophoblast differentiation of mouse embryonal carcinoma and embryonic stem cells. Depletion of cyclins A2 or B1 does not induce this effect, even though both of these APC/C substrates are also present during G1 of pluripotent cells. Crucially, geminin antagonizes the chromatin-remodeling protein Brg1 to maintain expression of Oct4, Sox2, and Nanog. Our results define a pluripotency pathway by which suppressed APC/C activity protects geminin from degradation in G1, allowing sustained expression of core pluripotency factors. Collectively, these findings link the cell cycle to the pluripotent state but also raise an unexplained paradox: How is cell-cycle progression possible in pluripotent cells when oscillations of key regulatory proteins are lost?     

A mechanism of cohesin‐dependent loop extrusion organizes zygotic genome architecture

Fertilization triggers assembly of higher‐order chromatin structure from a condensed maternal and a naïve paternal genome to generate a totipotent embryo. Chromatin loops and domains have been detected in mouse zygotes by single‐nucleus Hi‐C (snHi‐C), but not bulk Hi‐C. It is therefore unclear when and how embryonic chromatin conformations are assembled. Here, we investigated whether a mechanism of cohesin‐dependent loop extrusion generates higher‐order chromatin structures within the one‐cell embryo. Using snHi‐C of mouse knockout embryos, we demonstrate that the zygotic genome folds into loops and domains that critically depend on Scc1‐cohesin and that are regulated in size and linear density by Wapl. Remarkably, we discovered distinct effects on maternal and paternal chromatin loop sizes, likely reflecting differences in loop extrusion dynamics and epigenetic reprogramming. Dynamic polymer models of chromosomes reproduce changes in snHi‐C, suggesting a mechanism where cohesin locally compacts chromatin by active loop extrusion, whose processivity is controlled by Wapl. Our simulations and experimental data provide evidence that cohesin‐dependent loop extrusion organizes mammalian genomes over multiple scales from the one‐cell embryo onward.     

Antioxidant and Antihemolytic Activity of a New Isoflavone, “Factor 2” Isolated from Tempeh

A new isoflavone assigned the trivial name “Factor 2” which was first isolated from tempeh, fermented soybean product, and identified as 6,7,4′-trihydroxyisoflavone was chemically synthesized and tested for antioxidant activity by several methods. Factor 2 was proved to be a potent antioxidant in aqueous solution at pH 7.4. However it was not effective in preventing autoxidation of soybean oil and soybean powder. Factor 2 given orally to rats fed vitamin E-deficient diet was also negative in hemolysis preventing activity. Biological activity of tempeh and the isolated Factor 2 to prevent hemolysis of red blood cells of rats fed vitamin E-deficient diet was discussed.     

Studies on the Nutritional Value of Tempeh

1. The nutritional value of tempeh in comparison with that of unfermented soybeans was studied in rat feeding experiment. It was observed that the PER value of tempeh (fresh or stored) was not significantly different from that of the unfermented soybeans (fresh or stored).

2. The peroxide value of the oil of stored tempeh powder was only 10% of that of stored soybean powder. Red blood cells of rats receiving tempeh were less than 20% in hemolysis by dialuric acid whereas hemolysis was 100% for the rats receiving the unfermented soybeans. Serum tocopherol was 0.14±0.05 mg/dl in the former group, but 0.07±0.05 mg/dl in the latter. Liver TBA values were 0.20±0.05 O. D./g and 0.65±0.13 O. D./g in the tempeh and the unfermented soybeans group, respectively.

3. Subsitution of whole egg for tempeh to supply 30% of protein in the diet improved the quality of the protein as measured by the protein efficiency ratio. An equal improvement was accomplished by supplementation of tempeh with lysine, methionine, and threonine in such amounts as the level of these amino acids equal to that in the tempeh-egg diet.     

Protein-Vitamin E Relation and the Hemolysis Test

The blood cells of vitamin E deficient rats are hemolyzed by dialuric acid. The percent of hemolysis in the dialuric acid test was higher in rats fed a 5% casein diet than in pair-fed animals receiving 10 or 20% casein diet when a suboptimal amount of α-tocopherol (7 ~ 32 µg per day) was administered. With 1 mg per day of α-tocopherol there was no hemolysis at any protein level. The significance of the results is discussed.     

Distinct activities of the anaphase-promoting complex/cyclosome (APC/C) in mouse embryonic cells

The first differentiation event in mammalian development gives rise to the blastocyst, consisting of two cell lineages that have also segregated in how the cell cycle is structured. Pluripotent cells of the inner cell mass divide mitotically to retain a diploid DNA content, but the outer trophoblast cells can amplify their genomes more than 500-fold by undergoing multiple rounds of DNA replication, completely bypassing mitosis. Central to this striking divergence in cell cycle control is the E3 ubiquitin-ligase activity of the anaphase-promoting complex or cyclosome (APC/C). Extended suppression of APC/C activity during interphase of mouse pluripotent cells promotes rapid cell cycle progression by allowing stabilization of cyclins, whereas unopposed APC/C activity during S phase of mouse trophoblast cells triggers proteasomal-mediated degradation of geminin and giant cell formation. While differential APC/C activity might govern the atypical cell cycles observed in pre-implantation mouse embryos, geminin is a critical APC/C substrate that: (1) escapes degradation in pluripotent cells to maintain expression of Oct4, Sox2 and Nanog and (2) mediates specification and endoreduplication when targeted for ectopic destruction in trophoblast. Thus, in contrast to trophoblast giant cells that lack geminin, geminin is preserved in both mouse pluripotent cells and non-endoreduplicating human cytotrophoblast cells.Key words: APC/C, geminin, Emi1, cell cycle, pluripotency, trophoblast, endoreduplication, DNA damage     

Comparison of the Activity of the Tryptophan-NAD Pathway between Rats Fed a Fat-free Diet and a Fat Diet

The effect of dietary fat on tryptophan-NAD metabolism was investigated. Weanling male rats of the Sprague Dawley strain were fed a 40% casein diet (nicotinic acid-free) with or without 20% fat for 13 days. Although the food intake in 13 days was significantly higher in the fat-free group than in the fat group, the gains in body weight in the two groups were almost the same, because of the same energy intakes. The urinary excretion of tryptophan metabolites such as quinolinic acid, niacin and N¹-methylnicotinamide was greatly increased in the fat group in comparison with that in the fat-free group. The urinary excretion of xanthurenic acid was almost the same in the two groups. The blood NAD level of the fat group was significantly increased. The activities of liver amino-carboxymuconate-semialdehyde decarboxylase and liver nicotinamide methyltransferase in the fat group were significantly reduced, and that of liver NMN adenylyltransferase was significantly increased. The changes of these three enzymes could be advantageous for the increased formation of NAD from tryptophan. As a result, the feeding of a high fat diet to rats increased the formation of niacin and niacin-related compounds.     

BIOCHEMICAL CHANGES IN THE BRAIN IN RATS POISONED WITH AN ALKYLMERCURY COMPOUND, WITH SPECIAL REFERENCE TO THE INHIBITION OF PROTEIN SYNTHESIS IN BRAIN CORTEX SLICES

The incorporation of [U-¹⁴C]leucine into the protein of brain cortex slices from rats poisoned with methylmercury thioacetamide was markedly inhibited before the development of neurological symptoms and when the oxygen consumption, aerobic and anaerobic glycolysis and sulphydryl enzyme activities were unchanged. After the appearance of neurological symptoms, the oxygen consumption decreased significantly, while lactic acid formation did not change under anaerobic conditions, but slightly decreased under aerobic conditions. The activities of the three sulphydryl enzymes (Mg-activated ATPase, fructose- diphosphate aldolase and succinate dehydrogenase) were almost the same in visual cortex, motor cortex, cerebellum and caudate nucleus, while the activities of Mg-activated ATPase and succinate dehydrogenase in the white matter were lower than that in the grey matter. There was no difference in the activity of fructosediphosphate aldolase in grey and white matter. The activities of all three enzymes did not show any change in the earlier stage of poisoning when the animal remained free from neurological symptoms. At the more advanced stage, when neurological symptoms were present, only the activity of the succinate dehydrogenase decreased significantly, while the activities of the other two enzymes remained unchanged. The selective inhibition of protein synthesis may have a direct bearing on the poisoning by the alkylmercury compound.