Aspekte der Siebröhren-Differenzierung bei Monocotylen

Zusammenfassung Ausgehend vom nachmeristematischen Zustand einer prospektiven Siebröhre machen Kern, Tonoplast, ER, Dictyosomen und Ribosomen wÄhrend der Zelldifferenzierung folgende Umwandlungen durch:DerKern erfÄhrt in seiner Matrix eine zunehmende Substanzverarmung, an deren Ende seine vollstÄndige Auflösung steht. In der Kernmembran sind lokale Erweiterungen des intrazisternalen Raumes charakteristisch für den Beginn der degenerativen VerÄnderungen. Stets bleibt die Kernhülle jedoch in lockerem Kontakt mit dem ER; vermutlich geht sie zum Abschlu\ der Kernauflösung in das Membransystem des ER ein.In AbhÄngigkeit von der Rückbildung des Zellsaftraums zerfÄllt derTonoplast zunÄchst in zisternenartige Abschnitte, um spÄter in der ausdifferenzierten Siebröhre ganz zu verschwinden. Wie an verschiedenen Beispielen abzulesen ist, werden diese VerÄnderungen offensichtlich auf dem Höhepunkt der protoplasmatischen Differenzierung eingeleitet.Das gleichmÄ\ig granulÄr-zisternaleEndomembransystem junger Siebelemente — hÄufig charakterisiert durch spiralig aufgereihte Ribosomen — wandelt sich mit zunehmender Hydratisierung des Protoplasten in tubulÄre bis vesikulÄre Elemente um und geht zum anderen über verschiedene Zwischenstufen in gitterartige Membranstrukturen ein.Die in der jungen Siebröhre zahlreichen, polar gebautenDictyosomen tragen mit der Produktion von Golgi-Vesikeln zum Wandaufbau bei. Im Laufe der Zelldifferenzierung werden in steigendem Ma\e auch coated vesicles abgegeben, deren Bedeutung noch unklar ist. In der ausdifferenzierten Siebröhre sind weder Dictyosomen noch die von ihnen abgegebenen Vesikel nachzuweisen. Dieses Schicksal teilen sie mit denRibosomen, die gleichfalls nur in jungen Siebelementen anzutreffen sind und dort zu Polysomen vereint, hÄufig in spiraliger oder helixförmiger Anordnung vorkommen.

---

Aspects of sieve-tube differentiation in monocotyledons

Summary Subsequent to the postmeristematic state of a future sieve-tube its nucleus, tonoplast, endoplasmic reticulum, dictyosomes, and ribosomes undergo the following transformations:Thenucleus shows a gradually declining ground substance until at last it entirely disintegrates. Local enlargements of the intracisternal space of the nuclear membrane indicate the beginning of the degenerative phase. During all these alterations as well as in the meristematic state the nuclear envelope is in loose contact with the endoplasmic reticulum. We suppose that it finally becomes part of a complex ER system. Subject to the disorganization of the central cell-sap room thetonoplast initially removing from the parietal protoplast later on completely disappears. According to our results these transformations are obviously introduced at the climax of protoplasmatic differentiations.The uniform rough surfaced cisternal ER of young sieve elements—often characterized by spirally arranged ribosomes—changes during sieve-tube ontogeny to tubular or vesicular elements and partly fuses to lattice-like membrane structures passing several other stages of membrane condensation.Polardictyosomes that are numerous in young sieve-tubes produce coated vesicles besides smooth golgi-vesicles.Ribosomes are abundant in young elements, too, they are often found as polysomes of helical or spiral arrangement. Neither dictyosomes nor ribosomes have been seen in differentiated sieve-tubes.

---

---

Teil einer Habilitationsschrift der Math.-Naturw. FakultÄt Bonn.     

Geschlechtliche organisation,fortpflanzungsverhalten und ursachen der sexuellen vermehrung von Stenostomum sthenum nov. spec. (Turbellaria,Catenulida)

Certain temperatures and H-Ion concentrations are necessary for the development of male and female reproductive organs. The differentiation of the reproductive system from undifferentiated cells conforms precisely with data on other species of Stenostomum.

---

Abkürzungen in den Abbildungen b Bindegewebszelle - c Cilien - cy Cytoplasma - d Darm - de Ductus ejaculatorius - dl Darmlumen - do Dotter - dr Drüsenzellen - lr Lÿckenraum - m Mundöffnung - n Nucleolus - np Nephroporus - o Ovar - p männlicher Genitalporus - pa parenchymatischer Raum - pf periembryonale Flüssigkeit - dse dorsale Epidermis - e dorsolaterale Epidermis - ed extraembryonaler Dotter - ee Epidermiseinstülpung - eh Epidermis +Hautmuskelschlauch - em Embryo - ex Exkretvakuole - f Freßzelle - g Gehirn - ga Gehirnanlagen - gr Granula - h Hautmuskelschlauch - hz Hüzllzelle - kl Versehlußkegel/Klebkegel - in indifferente Zelle - k Kern - kdr Klebdrüsenzelle(n) - kk kollabierter Kanal - kö Körnerkolbenzelle - kp Kopulationsorgan - ku Kufen - kw Körperwand - l Lichtsinnesorgan - li Linsenkörper - lk lichtbrechende Konkremente im Darmgewebe - ph Pharynx - phr Pharynxregion - pr Zentralkanal des Protonephridialsystems - ps Präspermatide - pu Punktfeld - q Zellquartett - r Riechgruben - rh Rhombuszellenband - rhb Rhabditen - rm Radiärmuskelzelle - rhs Rhabditenschleim - rs resorbierende Darmzelle(n) - s Schale - sc Spermatocyten - se Sekretgang - t Tastborste - ta Auflösungsprodukte des Hodens - te Hoden - to Terminalorgane(e) - tz Teilungszone - v Vakuole - w vermutliches Rudiment des weiblichen Genitalporus     

Feinstrukturen der Mikrokörper (Microbodies) des proximalen Nierentubulus

Zusammenfassung Die Feinstrukturen der Mikrokörper des Nierenepithels werden beschrieben und mit denjenigen der Leber-Mikrokörper verglichen. Als besondere Charakteristika der Nieren-Mikrokörper sind eine (nicht kristalline) nucleoide Verdichtung und eigentümliche stabförmige Ausstülpungen (Stäbe) anzusehen. Die Stäbe stellen unterschiedlich lange Zylinder mit einem Durchmesser von 100 nm dar. Im Inneren findet sich eine unmittelbar der Membran anliegende, ring- oder spiralförmig angeordnete, granuläre Struktur (Granula-Durchmesser 50 Å), die in Stablängsschnitten eine Querstreifung vortäuscht. Es wird eine in Phasen ablaufende Bildung der Mikrokörper-Stäbe angenommen: ein in der Matrix entstandener Granula-Zylinder hebt sich aus dem Mikrokörper heraus, wobei die Mikrokörper-Membran entsprechend vorgebuchtet wird, und wächst schließlich zu einem eigenständigen, allseits membranumzogenen Stab aus. Die Möglichkeit, daß die Stäbe von Mikrokörpern abgestoßen werden, wird diskutiert. — Die Segregation von Mikrokörpern in Vakuolen wird nicht als aktive Beteiligung an lytischen Prozessen, sondern als autophagischer Vorgang gedeutet.

---

Fine structure of microbodies in proximal tubular epithelium of the kidney

Summary Ultrastructural observations on microbodies in normal proximal tubule cells of the rat kidney are described and compared with microbodies of hepatic parenchymal cells. After fixation in osmium tetroxide with phosphate buffer the special features of the renal microbodies are the non-crystalline nucleoid and protrusions (rods) extending from the main body. These rods are cylindrical in shape having a diameter about 100 nm and are of varying lengths. Inside the limiting membrane are ring- or spiral-like ordered profiles consisting of granules (about 50 Å in diameter) which often appeared as a row of parallel linear densities arranged at approximately right angles to the long axis of the rod. It can be demonstrated that the parallel linear pattern depends on the projection of the granules in the photographic plane. — The findings suggest that the cylindrical structures of granules are formed in the peripheral matrix of microbodies; in a second phase they are lifted outside, in part enveloped with the membrane of the microbody; in this situation, the protrusions are formed. This form of creation would explain the characteristic excentrical (tangential) relation between protrusions and the main body. The observation that rods are often seen apparently isolated in the cytoplasm without visible connection with a microbody is only discussed hypothetically, because of the plane of sectioning. — Microbodies and rods can be identified in cytosegresomes. These investigations were interpreted as an autophagic degradation and not as an active role of the enzymes of microbodies in digestive mechanisms.

---

---

Herrn Prof. Dr. Helmut Ruska zum 60. Geburtstag gewidmet.

---

Mit Unterstützung durch die Deutsche Forschungsgemeinschaft.

---

Herrn Doz. Dr. W. Thoenes danke ich für wertvolle Hinweise und für die kritische Durchsicht des Manuskriptes.     

Biosynthesis of digalactosyldiacylglycerol in plastids from 16:3 and 18:3 plants

Intact chloroplasts isolated from leaves of eight species of 16:3 and 18:3 plants and chromoplasts isolated from Narcissus pseudonarcissus L. flowers synthesize galactose-labeled mono-, di-, and trigalactosyldiacylglycerol (MGDG, DGDG, and TGDG) when incubated with UDP-[6-³H]galactose. In all plastids, galactolipid synthesis, and especially synthesis of DGDG and TGDG, is reduced by treatment of the organelles with the nonpenetrating protease thermolysin. Envelope membranes isolated from thermolysin-treated chloroplasts of Spinacia oleracea L. (16:3 plant) and Pisum sativum L. (18:3 plant) or membranes isolated from thermolysin-treated chromoplasts are strongly reduced in galactolipid:galactolipid galactosyltransferase activity, but not with regard to UDP-Gal:diacylglycerol galactosyltransferase. For the intact plastids, this indicates that thermolysin treatment specifically blocks DGDG (and TGDG) synthesis, whereas MGDG synthesis is not affected. Neither in chloroplast nor in chromoplast membranes is DGDG synthesis stimulated by UDP-Gal. DGDG synthesis in S. oleracea chloroplasts is not stimulated by nucleoside 5′-diphospho digalactosides. Therefore, galactolipid:galactolipid galactosyltransferase is so far the only detectable enzyme synthesizing DGDG. These results conclusively suggest that the latter enzyme is located in the outer envelope membrane of different types of plastids and has a general function in DGDG synthesis, both in 16:3 and 18:3 plants.     

Ichnology and sedimentology of the early Permian deep-water deposits from the Lercara-Roccapalumba area (Western Sicily,Italy)

Summary Diverse and abundant trace fossils of the deep-waterNereites ichnofacies have been found in well-dated Early Permian deep-water turbidites (Lercara Formation) of western Sicily (Italy). Conodonts indicate a latest Artinskian to Cathedralian (late Early Permian) age. Microfossils (pelagic conodonts, albaillellid Radiolaria, paleopsychrospheric ostracods, foraminiferal associations dominated byBathysiphon), trace fossils (deep-bathyal to abyssalNereites ichnofacies) and sedimentologic data collectively indicate a deep-water environment for the Early Permian turbidites of the Lercara Formation. The dominance ofAgrichnium and of thePaleodictyon subichnogeneraSquamodictyon andMegadictyon suggests that this icnofauna is closely related in ichnotaxonomic composition to other late Paleozoic deep-water ichnofaunas. The occurrence ofAcanthorhaphe. Dendrotichnium andHelicoraphe, to date only reported from Cretaceous or Tertiary flysch deposits, suggests that the entire ichnofauna corresponds well to previously documented Silurian-Tertiary flysch ichnofaunas. Eight new ichnospecies and a new ichnosubgenus,Megadictyon, are described.     

Functional cis-element sequence requirements for suppression of gene expression by the TNPA protein of the Zea mays transposon En/Spm

TNPA, one of the two transposition proteins encoded by the En/Spm transposable elements of Zea mays, suppresses the expression of genes that contain an appropriate cis element. Suppression can be monitored in tobacco protoplasts in a transient expression assay as follows. The plant promoter-driven expression of the Escherichia coli-glucuronidase (GUS)-encoding gene, uidA, is repressed in the presence of TNPA if the GUS gene contains a functional cis element in the untranslated RNA leader sequence. Earlier, we found that the minimal cis element is composed of two 12 by sequences in a tail-to-tail inverted orientation. Each 12 by sequence is sufficient to bind TNPA in vitro and can be thought of as a half-site in the cis element. Here, we investigated the sequence requirements of the minimal cis element. Our observations support our expectations that a functional cis element must provide a template to which two TNPA molecules can bind in the correct orientation. Sequences within the half-sites can be altered as long as the eight bases that make up the consensus binding sites are not changed. However, we found the following unexpected sequence specificities. Firstly, some changes to the consensus binding sequence can be tolerated in one half-site, as long as the other site matches the consensus. Secondly, although the region between the half-sites can vary in sequence and in length between two and four bases, a thymidine residue is not tolerated directly 5′ preceding the second half-site. Since many variants of the cis element sequence remain functional, the suppressor response element provides a flexible tool for artificially manipulating the expression of genes.