The post-exercise glycogen recovery in tissues of trained rats.

The post-exercise glycogen recovery in myocardium, liver, diaphragm muscle and musculus biceps femoris was compared in untrained and trained rats. The glycogen level in myocardium of the trained rats was significantly higher than that in the untrained ones only immediately after the exercise-test and on the second day after the exercise. The liver glycogen levels on each of the examined post-exercise days were similar in both groups and did not differ from the control values. The post-exercise glycogen recovery in the diapraghm muscle of the untrained rats was also similar to that in the trained animals. In musculus bicpes femoris similar post-exercise supercompensation was found in both groups except on the second day when the glycogen level in the trained animals was significantly higher than that in the untrained ones. The results suggest that it is necessary to separate the effects of training from those of the last bout of exercise in the training program when the effect of training is examined.     

Ultrastructure and cytochemistry of cardiac intramitochondrial glycogen.

Authors have observed abnormalities of glycogen localization in cardiac muscle, after normothermic cardiac arrest. The identification of these intramitrochondrial particles as glycogen was confirmed by selective staining with periodic acid-lead citrat, periodic acid-thiosemicarbazide protein methods and by their selective removal from tissue sections by alfa-amylase. The intramitochondrial glycogen particles were of beta-type. Some intramitochondrial particles were surrounded by paired membranes which resulted from protrusion of parts of mitochondrial membrane.     

Diadenosine triphosphate splitting by rat liver extracts.

A splitting activity on diadenosine triphosphate has been found in rat liver. One of the products of the cleavage is ADP. A Km of 10 μM has been found. This activity on diadenosine triphosphate seems to be specific as diadenosine tetraphosphate, a nucleotide previously described by others to occur in rat liver at very low concentration, is not a substrate of the reaction. The occurrence of diadenosine triphosphate in rat liver has not been so far reported, but a dinucleoside triphosphate structure has been described at the 5′ end of certain mRNAs. The possibility that this enzymatic activity may be involved in the hydrolysis of diadenosine triphosphate or in the processing of mRNAs is suggested.     

Neutral currents in weak interactions and molecular asymmetry

Weak interactions are parity violating forces, i.e. they differentiate between mirror images. Therefore it is a very attractive hypothesis to invoke weak interactions in explaining the origin of molecular asymmetry. It is, however, not clear whether weak interactions may operate between electrons and/or between electrons and protons? For these types of interactions so called neutral currents are needed. Recent experiments with muon neutrinos at CERN gave some evidence for the existence of neutral currents. Thus we may suppose that parity violating forces are active in molecules. In the first part of this paper a very elementary theory of weak interactions is outlined with special reference to the discovery of neutral currents. In the second part we show how weak interactions may differentiate between mirror image molecules. The asymmetrically distributed static charges in chiral molecules represent a helical potential field. This potential field may exert an effect on the orbital electrons and therefore coupling of spins and momenta occurs. Thus the enantiomers are parity transformed images not only as geometrical bodies, but their orbital electrons are parity transformed too as "a helical electron gas". Weak interactions will differentiate between L and D forms because their orbital electrons have a nonzero spin polarization with respect to their velocity.     

Uric acid as electronic acceptor of chicken liver's XDH (author's transl)]

Uric acid seems to act as an electronic acceptor in the dehydrogenation of hypoxanthine catalyzed by chicken liver's xanthinedehydrogenase (XDH). Oxidation was observed in crude homogenates under anaerobic conditions, although dialyzed homogenates or purified hepatic XDH also induce a similar action either in aerobic or anaerobic conditions. The reaction pH optimum is about 6.0. Xanthine appears to be the only inhibited product of the reaction when its concentration is greater than 1 X 10(-4) M. When hypoxanthine and uric acid concentrations exceed 2 X 10(-3) M and 1 X 10(-4) M, respectively, they induce inhibition by substrate. Purine is a fairly good substrate of XDH when uric acid acts as acceptor. Allopurinol inhibits hypoxanthine oxidation by uric acid in the presence of XDH. XDH also catalyzes the dismutation of xanthine to hypoxanthine and uric acid.     

Cyclization of 13beta-ethyl-3-methoxy-17beta-ol-8,14-seco-1,3,5(10),9-gonatetraen-14-one and its 17 acetate derivative.

13beta-Ethyl-3-methoxy-17beta-ol-8,14-seco-1,3,5(10),8-gonatetraen-14-one (IIIa) was isolated and its participation in the well-known acidic cyclization process was established.     

Histochemical localization of capillary enzyme activities in brain smears.

Since the regulation of the vascular permeability in the CNS is dependent partly on the enzymes associated with the wall of brain capillaries, the histochemical demonstration of these enzymes may furnish further data on the function of the blood brain barrier (BBB), a new methodological approach, using brain smears was developed for the histochemical demonstration of several enzymes participating in the function of the BBB. The method presented renders possible also the subsequent demonstration of monoamines and the activity of different enzymes in the same tissue preparation. The usefulness of this simple technique in the study of brain capillary functions is discussed.