Optically detected magnetic resonance studies of porcine pancreatic phospholipase A2 binding to a negatively charged substrate analogue

The direct binding of porcine pancreatic phospholipase A2 and its zymogen to 1,2-bis(heptanylcarbamoyl)-rac-glycerol 3-sulfate was studied by optical detection of triplet-state magnetic resonance spectroscopy in zero applied magnetic field. The zero-field splittings of the single Trp3 residue undergo significant changes upon binding of phospholipase A2 to lipid. Shifts in zero-field splittings, characterized mainly by a reduction of the E parameter from 1.215 to 1.144 GHz, point to large changes in the Trp3 local environment which accompany the complexing of phospholipase A2 with lipid. This may be attributed to Stark effects caused by the binding of a charged group near Trp3 in the enzyme-lipid complex. The cofactor, Ca2+, which is strongly bound to the enzyme active site, has an influence on the bonding, as reflected by smaller zero-field splitting shifts. A relatively small change in the Trp environment was observed for the interaction of the zymogen with lipid.     

Phosphorylation of Chromosomal Proteins in Resting and Wounded Potato Tuber Tissues

Wounding of quiescent white potato tuber tissue enhances chromatin-boundprotein phosphokinase activity, which exhibits two distinctphases during wound-healing. A moderate activation of the enzymesup to 20 hr after injury is followed by a dramatic increasein activity with a peak at 50 hr. This time-course resemblesthat of chromatinbound DNA-dependent RNA polymerase with a peakin activity at about 48 hr after wounding. The kinases phosphorylateendogenous proteins as well as added histones, phosvitin andcasein. The incorporated phosphate is stable under standardassay conditions, indicating the absence of protein phosphatases.Sensitivity of the incorporated phosphate toward trypsin andalkali, but not DNase, RNase, hydroxylamine or succinic acidpoints to seryl- and threonyl-bonds and proteins as acceptormolecules. Kinases from resting tissues are only weakly stimulatedeven by 100 mM MgCl₂, those from wounded tissues exhibit pronouncedMg^$$-optima at 5–10 mM with endogenous proteins, phosvitinand casein and 50 mM MgCl₂ with histones. Wounding also increasesthe sensitivity of the kinases toward p-hydroxymercuribenzoate. Chromatin preparations from both resting and wounded tissuescontain about 40 protein bands after polyacrylamide disc gelelectrophoresis. In vitro phosphorylation of these proteinsin chromatin from quiescent tissues is comparably low and uniform.Wounding induces changes in the protein and phosphorylationpattern with a general enhancement of phosphorylative capacityand preferential phosphorylation of low molecular weight proteins. (Received August 10, 1981; Accepted November 18, 1981)     

Integration of replication-defective R68.45-like plasmids into the Pseudomonas aeruginosa chromosome

R68.45 and other similar broad-host-range (IncP) plasmids carrying a tandem repeat of the 2.1 kb insertion element IS21 mobilize the chromosome of many different Gram-negative bacteria. To analyse the structure of R68.45-chromosome cointegrates, whose involvement in the mobilization process had been postulated previously, we selected for the stable integration of R68.45-like plasmids into the Pseudomonas aeruginosa chromosome. Two plasmids were chosen: pME28, a transfer-deficient, mobilizable RP1 derivative with an inactive replication control (trfA) gene, and pME487, an R68.45 derivative with a trfA(ts) mutation causing temperature-sensitive replication. Chromosomally integrated pME28 and pME487 were found to be flanked by single IS21 elements. This structure is in agreement with a 'cut-and-paste' mode of R68.45 transposition. pME28 and pME487 showed a low specificity of insertion but rarely (less than 0.1%) induced auxotrophic mutations. Hfr (high-frequency-of-recombination) donors of P. aeruginosa could be obtained by chromosomal integration of pME487 or pME28; in the latter case, the transfer functions lacking from pME28 had to be provided in trans on an autonomous plasmid. Hfr donors gave higher conjugational linkage and transferred longer stretches of the P. aeruginosa chromosome than did R68.45 donors. This suggests that the integration of R68.45 into the donor chromosome is short-lived in P. aeruginosa.     

Das Bewegungsverhalten der Coelomzellen vonPsammechinus miliaris bei der Wundheilung (Echinodermata)

Zusammenfassung 1. Das Bewegungsverhalten der Coelomzellen des EchinoidenPsammechinus miliaris Gmel. wird an kleinen von Stacheln, Füßchen und Pedicellarien befreiten Stellen der Skelettoberfläche in Periproctnähe untersucht.2. Aus dem freiliegenden Bälkchenwerk treten Coelomzellen aus, von denen nur die rotbraunen Amoebocyten auf dem hellen Kalkuntergrund im Auflicht (Ultropak;E. Leitz) sichtbar sind.3. Nach einigen Stunden ist die Wundfläche mit einer dicken rötlichen Zellmasse bedeckt, dem primären Wundverschluß. Außer den Coelomzellen enthält der Wundverschluß noch verschieden große Kalkpartikel, die vom Abschleifen der Versuchsstelle herrühren.4. Bei direkter Beobachtung ist weder an den rotbraunen Amoebocyten noch am Wundverschluß die geringste Bewegung zu erkennen.5. Zeittransformation (Zeitraffung [Z.R.] auf 1/240 und 1/480) zeigt die mit erheblicher Ortsverlagerung und Metabolie verbundene Bewegung der allein wahrehmbaren rotbraunen Amoebocyten auf der Wundfläche. Im scheinbar in Ruhe befindlichen Wundverschluß findet eine ständig hin- und herwogende Bewegung der Zell-Kalkamsse statt.6. Bereits nach 6 bis 7 Stunden ist das Operationsfeld völlig geglättet; die Lücken im Kalkskelett sind kaum noch zu erkennen infolge der neu eingebauten Kalkelemente. Die eigentlichen Heilungsvorgänge (Wiederherstellung der Feinstruktur des Kalkskelettes) erfolgen unterhalb des primären Wundverschlusses, sind also nicht der Beobachtung zugängig.7. Wird der primäre Wundverschluß im ganzen vorsichtig abgehoben und zerzupft, so kann das Bewegungsverhalten der entstandenen kleinen und großen Aggregate im Durchlicht unter Z.R. untersucht werden.8. Die im zerriebenen Explantat erhaltenen Coelomzell-Aggregate aller Größen weisen erhebliche Ortsveränderungen auf; oft breiten sie sich langsam aus unter Auswanderung zehlreicher randlich liegender Zellen. An den Außenzonen mittlerer und großer Aggregate werden plasmatische Netze sichtbar, die ständig ihre Gestalt und Maschenweite ändern.9. Diese Plasma-Netze bilden die Grundlage der Aggregate; ihre Kontraktionen und Dilatationen bewirken die Ortsverlagerungen der Aggregate (Netzbildende Coelomzellen;Kuhl 1937).10. Wenigzellige Aggregate vereinigen sich in den allermeisten Fällen, sobald ein gewisser Abstand überbrückt ist. Mittlere und große Aggregate gehen häufig eine Verbindung ein; meist werden vorher lockere Coelomzell-Brücken hergestellt. In manchen Fällen gleiten die Aggregate aneinander vorbei.11. Im polarisierten Licht lassen sich bei gekreuzten Nicols die ersten kleinen neugebildeten Kalkkristalle in den skelettbildenden Coelomzellen (= netzbildenden Zellen) nachweisen.12. Der Verschluß kleiner Kratzwunden im noch dünnen primären Wundverschluß (die Kratzer dringen bis zur abgeschliffenen Skelettoberfläche vor) wird unter Z.R. im Ultropak-Auflicht untersucht. Die Ergebnisse am explantierten Wundverschluß im Durchlicht führen zum Verständnis der Bewegungsvorgänge im ungewohnten Auflicht.13. Im zunächst verwirrenden Bewegungsgeschehen (die auffälligen rotbraunen Amoebocyten haben bei der Wundheilung keine Funktion) fallen die durch die Operationsnadel herausgerissenen kleinen Kalktrümmer auf; sie werden passiv durch die Plasmanetze bewegt, gelangen auch zufällig in die Kratzer und werden an den Rändern durch neugebildetes Kalkmaterial festgelegt oder eingebaut. Aus der Tiefe der Kratzer können lose Kalkpartikel heraufbefördert werden; auch diese werden häufig eingebaut. Die entstehenden Kalkbrücken werden schließlich untereinander verbunden und dadurch die kleine Wunde verschlossen. Das eingebaute Kalkmaterial zeigt auch unter starker Z.R. keine passive Bewegung mehr.14. In seltenen Fällen kann der Vorgang des schubweisen Aufsteigens der skelettbildenden Zellen aus dem Panzer und ihre Zusammenballung im Z.R.-Laufbild beobachtet werden.15. Ob der Einbau von herausgerissenem Kalkmaterial temporär oder dauernd ist, muß noch geprüft werden.

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The locomotory behaviour of coelom cells ofPsammechinus miliaris (Echinodermata) during wound-healing

In the sea urchinP. miliaris application of time lapse photography allows a study of the very slow movements of coelom cells during the healing process of small wounds on the surface of the calcareous skeleton near the periproct. For observation and time lapse photography LEITZ-Ultropak objectives were used (incident light). Ambulacral feet, spines and pedicellaria were removed, and the animal was fixed in three places in a ring of plexiglass by means of three little screws, which touched the equator of skeleton. The rate of time transformation was 1/240 to 1/480. The film reveals the behaviour of coelom cells, which move out the skeleton to the surface of the small experimental region. Within several hours the white polished surface is covered with hundreds of red-brown amoebocytes; only these are visible on the white lime-ground; they have no function in the healing process, which takes place below the surface of the primäre Wundverschluß and therefore cannot be observed. There are three main types of coelom cells: red-brown amoebocytes, körnchenführende Zellen (white amoebocytes) and leucocytes (netzbildende or skelettbildende Zellen); the flagellated cells may be neglected here. In order to be able to study the behavior of the three main types of coelom cells, the primäre Wundverschluß, i. e. the total cell-covering of the wound, is removed and torn into microscopic fragments. These are studied (time lapse) under normal optical conditions (transmitted light). The slides show many aggregates of different sizes, single cells and little calcareous concrements torn off the skeleton. The aggregates, even the big ones, exhibit slow locomotion and change their positions considerably. If the distance of two aggregates becomes small enough, they fuse. In these cases a loose cell bridge between the two aggregates is formed. Sometimes no union occurs, although the distance is very small. Even big aggregates suddenly show considerable contractions if spreading has preceded. All movements and place changing of cell-aggregates are caused by contractions and dilatations of the plasmatic network which forms the cellular basis. Little wounds in the newly built Wundverschluß scratched with a lancet, heal within several hours. Time lapse shows passive movements of small calcareous fragments, which by chance sometimes enter the small wounds, where they help and accelerate the closing of the injury. The fragments are fixed on the edge of the wound by newly produced lime. Skeleton building coelom cells (netzbildende Coelomzellen) come up in batches from the depth of the sea urchin's skeleton; each cell contains lime crystals.

     

Insulin-like growth factor-I supports proliferation of autocrine thymic lymphoma cells with a pre-T cell phenotype

We have studied the phenotypic characteristics and growth properties of murine T lymphoma cell lines derived from primary x-ray-induced thymic lymphomas at the earliest stage at which they can be detected, and well before spreading to other organs has occurred. These cell lines serve as model systems for the earliest events in T cell lymphoma induction, before tumor cell progression and spreading to other organs. We find that primary x-ray-induced T cell lymphoma lines have phenotypic characteristics of thymic pre-T cells and show no proliferative response to any of the IL tested nor to other hematopoietic growth factors. However, they do proliferate in response to insulin-like growth factor I (IGF-I) and to a small autocrine peptide distinct from IGF-I, which we term lymphoma growth factor. One of the earliest lesions in T cell lymphoma induction may therefore be an inhibition of differentiation at one of several specific points. In its early stages, T lymphoma cell growth may be restricted to an environment where local concentrations of specific growth factors such as IGF-I or lymphoma growth factor are sufficiently high.