Topography of carpal bone - An experimental model for carpal tunnel syndrome

By preparing a new experimental model for the carpal tunnel syndrome, the authors evaluated the differences of the human and rabbit carpal tunnels using a comparative anatomical study. A nearly identical situation-regarding the osseous and connective tissue formations in the carpal channel--was found. Therefore, the carpal tunnel of the rabbit is recommended for a model of chronic nerve compression, which is now planned by the authors.     

Preferential expression of cellular retinoic acid binding protein in a subpopulation of neural cells in the developing mouse embryo

The cellular retinoic acid binding protein is thought to be involved in the retinoic-acid-mediated signal transduction pathway. We have isolated the mouse cellular retinoic acid binding protein cDNA from an embryonal-carcinoma-derived cell line by using differential cDNA cloning strategies. In situ hybridization on sections of mouse embryos of various developmental stages indicated that the cellular retinoic acid binding protein gene, which we localized on mouse chromosome 9, is preferentially expressed in a subpopulation of neurectodermal cells. This restricted expression pattern suggests an important role for cellular retinoic acid binding protein in murine neurogenesis.     

Recovery of plastids from photooxidative damage: Significance of a plastidic factor

Glyoxysomal citrate synthase (gCS) was purified from crude extracts of watermelon (Citrullus vulgaris Schrad.) cotyledons, yielding a homogenous protein with a subunit MW of 48 kDa. The enzyme was selectively inhibited by 5,5-dithiobis-(2-nitrobenzoic acid), allowing quantification in the presence of the mitochondrial isoenzyme (mCS). Differences were also observed with respect to inhibition by ATP (k _i=2.6 mmol · l^-1 for gCS, k _i=0.33 mmol · l^-1 for mCS). The antibodies prepared against gCS did not cross-react with mCS. The immunocytochemical localization of gCS by the indirect protein A-gold procedure was restricted to the glyoxysomal membrane or the peripheral matrix of glyoxysomes. Other compartments, e.g. the endoplasmic reticulum, were not labeled. Xenopus oocytes were used for the translation of watermelon polyadenylated RNA (poly(A)⁺RNA). A translation product with a MW of 51 kDa was immunoprecipitated by the anti-gCS antibodies. It was absent in controls without poly(A)⁺RNA or with preimmune serum. A similar translation product was also immunoprecipitated after cell-free synthesis of watermelon poly(A)⁺RNA in a reticulocyte system, in contrast to the in-vivo labeled gCS (48 kDa). It was concluded that gCS is synthesized as a higher-molecular-weight precursor.Abbreviations DTNB 5,5-dithiobis-(2-nitrobenzoic acid) - gCS glyoxysomal citrate synthase - gMDH glyoxysomal malate dehydrogenase - k _i inhibitor constant - mCS mitochondrial citrate synthase - OAA oxaloacetate - poly(A)⁺RNA polyadenylated RNA - SDS-PAGE sodium dodecyl sulfate-polyacrylamide gel electrophoresis     

Phytochrom-induzierte Enzymbildung (Phenylalanindesaminase), ein schnell ablaufender Prozeß

Zusammenfassung Bei Erstbelichtung des Senfkeimlings mit Dauer-Dunkelrot tritt der P₇₃₀-abhängige Anstieg der Phenylalanindesaminase-Aktivität erst mit einer lag-Phase von 1,5 Std ein (Abb. 3, 4 unten). Bei einer Zweitbelichtung (Programm: Erstbelichtung — längere Dunkelperiode — Zweitbelichtung) fehlt die lag-Phase (Abb. 4, oben). Die Enzymaktivität steigt sofort linear an. Da der Anstieg der Enzymaktivität wahrscheinlich auf eine de novo Synthese von RNS und Enzymprotein zurückzuführen ist (Tabelle), so erscheint der Schluß berechtigt, daß P₇₃₀ sehr rasch eine differentielle Genaktivierung mit anschließender Enzymsynthese bewirken kann, falls die Gene der Aktivierung durch P₇₃₀ zugänglich sind. Die relativ lange lag-Phase nach Einsetzen der Erstbelichtung benötigt das P₇₃₀ offenbar dazu, die potentiell aktiven Gene (P₇₃₀) für das P₇₃₀ zugänglich zu machen. Das Problem der primären lag-Phase ist in einer vorangegangenen Arbeit zur P₇₃₀-abhängigen Anthocyansynthese ausführlich diskutiert worden (vgl. Lange, Bienger und Mohr, 1967).

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Phytochrome-mediated enzyme formation (Phenylalanine deaminase) as a rapid process

Summary In previous papers we have reported (Mohr and Durst, 1966a, b) that synthesis of phenylalanine deaminase (EC 4.3.1.5), an important enzyme of phenolic metabolism, can be stimulated by the physiologically active phytochrome (=P₇₃₀) in the mustard seedling. The data of the present paper suggest that induction of this enzyme is a rapid process if the gene in question is easily accessible for the activating action of P₇₃₀.The seedlings were irradiated with continuous standard far-red light. Longtime irradiation with far-red will maintain a low but virtually constant level of P₇₃₀ in the seedling over an extended period of time. At the moment when the far-red light is turned off the action of P₇₃₀ will virtually cease. — Fig. 3 and Fig. 4, lower part, show the kinetics of enzyme induction by P₇₃₀ in an etiolated seedling. The initial (or primary) lag-phase after the onset of far-red is 1.5 hours. If, however, a seedling which has been pre-irradiated with 12 hours of far-red is kept in darkness for 6 hours and is then re-irradiated with far-red no lag-phase for the action of the second irradiation can be found. Enzyme activity increases immediately after the onset of far-red. Since the action of the second irradiation as measured by increase of enzyme activity can be inhibited by relatively low doses of Puromycin and Cycloheximide (table) we conclude that the re-appearance of P₇₃₀ leads to de novo synthesis of enzyme protein. — Application of Actinomycin D (10 g/ml) only partially inhibits the action of the second irradiation as measured by increase of enzyme activity. This finding was to be expected. In preceding papers (e.g. Mohr and Bienger, 1967) it has been concluded that genes which have once been activated by P₇₃₀ remain less sensitive towards Actinomycin D even when P₇₃₀ has disappeared. Taking into account all available data the conclusion seems to be justified that the induction of enzyme synthesis by P₇₃₀ (i.e. differential gene activation followed by enzyme synthesis) is a rapid process if the genes are accessible for the action of P₇₃₀. The relatively long initial lag-phase (1.5 hours) is needed to make the potentially active genes (P₇₃₀) accessible for the action of P₇₃₀. The problem of how the initial lag-phase can be understood has been dealt with more in detail in a previous paper on phytochrome-mediated anthocyanin synthesis (Lange, Bienger and Mohr, 1967).

     

Protein- und RNS-Gehalt des Hypokotyls beim stationären Wachstum im Dunkeln und unter dem Einfluß von Phytochrom (Keimlinge von Sinapis alba L.)

Zusammenfassung Das Wachstum des Hypokotyls wurde an Restkeimlingen ohne Kotyledonen (Abb. 1) untersucht. Die Wachstumsgeschwindigkeit ist in dem von uns untersuchten Zeitraum sowohl im Dunkeln als auch unter dem Einfluß von P₇₃₀ (Dauer-Dunkelrot) praktisch konstant. Obgleich sich die Wachstumsgeschwindigkeiten im Dunkeln und im Dauer-Dunkelrot um den Faktor 4 unterscheiden, hat das Dunkelrot keinen signifikanten Einfluß auf den Gesamt-Proteingehalt des Hypokotyls (bzw. der durchschnittlichen Hypokotylzelle). Der Proteingehalt nimmt im Dunkeln und im Licht kontinuierlich ab. Auch der Gesamt-RNS-Gehalt zeigt innerhalb des Versuchszeitraums eine Abnahme, die unter dem Einfluß von Dunkelrot früher einsetzt als im Dunkeln. — Man kann aus den Daten der vorliegenden Arbeit schließen, daß nur ein kleiner Teil des Gesamt-Proteins und der Gesamt-RNS einer Zelle mit dem Zellwachstum unmittelbar in Verbindung gebracht werden kann.

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Protein and RNA contents of the hypocotyl during steady state growth lengthening in the dark and under the influence of phytochrome (seedlings of sinapis alba L.)

Summary Inhibition of hypocotyl lengthening by phytochrome can be regarded as a prototype of a negative photoresponse. The hypothesis has been advanced (Schopfer, 1967) that negative photoresponses are the consequence of a differential gene repression which is exerted by P₇₃₀, the active phytochrome. This hypothesis is mainly based on experiments with specific inhibitors of RNA- and protein synthesis. —The present paper is part of an experimental program which has been designed to check this hypothesis.—Continuous irradiation with standard far-red has been used to establish a virtually stationary concentration of P₇₃₀ over the whole period of experimentation (36–60 hours after sowing). To correlate more strictly the growth response of the hypocotyl with molecular changes in this organ the axis system without cotyledons has been used (Fig. 1). Even under these conditions the growth rate of the hypocotyl is nearly constant in light (continuous far-red) and dark during the whole period of experimentation (36–60 hours after sowing) (Fig. 2, 3). It is known from earlier experiments that cell division in the hypocotyl are very rare during this period and that there is virtually no increase in the DNA contents of the organ during the period of our experimentation (Weidner, 1967). Obviously the number of cells per hypocotyl is virtually constant between 36 and 60 hours after sowing. Organ (i.e. hypocotyl) lengthening is nearly exclusively due to cellular lengthening.—If we follow the protein contents of the hypocotyl we find (Fig. 4) that the total protein of the organ decreases steadily in spite of the fact that the organ grows at a constant rate. There is no significant difference in protein contents between dark-grown and far-red grown systems although the growth rates differ by a factor of 4 (Fig. 2, 3).—The situation is some-what different with respect to total RNA (Fig. 5). The RNA contents eventually decrease in far-red as well as in dark-grown systems but the decrease is significantly faster in the far-red treated systems than in the dark controls.—It is concluded that only a very small part of the total RNA and total protein of a cell can be related to the control of cellular growth. Changes in bulk RNA and bulk protein obviously do not necessarily reflect changes in the growth rate or growth capacity of an organ or a cell.