Temperature dependence of the gel electrophoretic mobility of superhelical DNA.

We have determined the gel electrophoretic behavior of closed circular plasmid pSM1 DNA (5420 bp) as a function of both temperature and of linking number (Lk). At temperatures below 37 degrees, the electrophoretic mobility first increases, then becomes constant as Lk is decreased below that of the relaxed closed DNA. As the temperature is increased above 37 degrees the electrophoretic mobility first increases as Lk decreases and then varies in a cyclic manner with further decreases in Lk. As the temperature is increased over the range 37 degrees - 65 degrees the cyclic behavior is manifested at progressively smaller decreases in Lk and the amplitude of the cycles increases. We interpret the results in terms of the early melting of superhelical DNA, in which the free energy associated with superhelix formation is progressively transferred to local denaturation. Using a two state approximation, we estimate the free energy change in the first cyclic transition to be 35 Kcal/mole DNA at 37 degrees and to decrease linearly with temperature. The free energy becomes equal to zero at a temperature of 71.6 degrees, which lies within 3 degrees of the melting temperature for the corresponding nicked circular DNA. From the slope of this relationship we estimate the apparent entropy and enthalpy of the first mobility transition to be 6.0 Kcal/mole base pair and 17.3 cal/mole base pair/degree, values consistent with duplex melting.     

Site-dependent cleavage of pBR322 DNA by restriction endonuclease HinfI.

Cleavage of pBR322 DNA I by the restriction endonuclease HinfI is preferentially inhibited at specific HinfI cleavage sites. These sites in pBR322 DNA I have been identified and ordered with respect to the frequency with which they are cleaved. The HinfI site most resistant to cleavage in pBR322 DNA I is unique in that runs of G-C base pairs are immediately adjacent on both sites. Two differently permuted linear (DNA III) species were produced by cleavage with two different restriction endonucleases, PstI and AvaI. Only one of these linear molecules, that produced by PstI, exhibits the same preferential cleavage pattern as DNA I. The second linear species, that arising from AvaI digestion, shows pronounced relative inhibition of cleavage at the HinfI sites nearest the ends of the molecule (100 to 120 base pairs away, respectively). This result suggest that proximity to the termini of a linear DNA molecule might also influence preferential cleavage. The possibility of formation of stem-loop structures does not appear to influence preferential cleavage by HinfI.     

Ultrastructural localization of cell wall teichoic acids in Streptococcus faecalis by means of concanavalin A

Some teichoic acids are known to be partially substituted by α-D-glucopyranosyl residues such as the teichoic acids of Streptococcus faecalis NCIB 8191. They will, therefore, bind specifically the phytohemagglutinin concanavalin A. Concanavalin A labelled with mercury or colloidal gold coated with concanavalin A has been used to mark isolated cell walls in order to localize the teichoic acids at the ultrastructural level. Besides these two direct marking techniques, the indirect concanavalin A-peroxidase technique (localization of peroxidase by the diaminobenzidine method followed by postosmication) has been applied to thin sections of premarked cells. All three methods gave almost identical results, namely, a dense and homogeneous distribution of the cell wall teichoic acids. In control experiments total inhibition was achieved in the presence of methyl-α-D-mannopyranoside. After trichloroacetic acid or alkali extraction of the teichoic acids from isolated walls no marking could be detected.     

Ploidy effect on the radiation reaction of mammalian cells

Summary The variation of X-ray sensitivity was investigated during the cell cycle. The cells were most sensitive during the S phase and less sensitive during the G₂- and G₁ phase. Furthermore, the repair of X-ray damage was investigated in stationary (plateau phase) cells. The cells of both lines were able to repair damage to nearly the same extent.

---

Zusammenfassung Die Variation der Strahlensensibilität während des Zellcyclus wurde untersucht. Die Zellen reagierten am sensibelsten in der S-Phase, weniger sensibel in der G₂-und G₁-Phase. Weiterhin wurde die Reparation von Strahlenschäden bei stationären (Plateauphase-)Zellen untersucht. Die Zellen beider Linien sind in etwa gleichem Maße reparationsfähig.

---

---

Supported (I-IV) by the Deutsche Forschungsgemeinschaft (Mi/100, 1-7).     

Ribonuclease H activity present in purified DNA polymerase from avian myeloblastosis virus

The presence of ribonuclease H activity in the purified complex of DNA polymerase from avian myeloblastosis virus is described. Evidence includes co-chromatography of the two activities during all purification steps; the presence of ribonuclease H activity in the purified two-polypeptide complex of DNA polymerase; ion requirements for optimal activity of purified ribonuclease H are identical to those for the purified DNA polymerase; and monospecific antiserum against purified DNA polymerase neutralizes the ribonuclease H activity.     

Cross-reactions between human and animal plasma proteins

Summary Cross-reactions between human plasma proteins and their homologues in primate blood were investigated systematically. From the three groups of proteins distinguished earlier [2] two have been especially examined; these findings are reported and discussed in the present communication. The Immunological Evolution Group (IEG) I, comprising IgA (-chain), IgD (-chain) and inter--trypsininhibitor, cross-reacts with pongid plasma only, IEG IIa, i.e. IgM (-chain), ₂-glycoproteins II and III and cholinesterase, does so with the pongid and cercopithecoid plasmas tested; IEG IIb, including acid _l-glycoprotein, _2HS-glycoprotein, _l-trypsininhibitor, haptoglobin and hemopexin, cross-reacts with pongid, cercopithecoid and cebus (platyrrhinian) plasma and finally IEG IIc, consisting of transferrin and Gc-globulin, does so with all primate plasmas tested, including prosimians. All the proteins named do not cross-react however with non-primate proteins as do those of IEG III. It is concluded, that the determinants reacting in the primate proteins increase in their evolutionary ages from IEG I over IEG IIa, IIb to IIc in the same way as the last common ancestors of man and the crossreacting species increase.

---

Zusammenfassung Die Kreuzreaktionen zwischen menschlichen Plasmaeiweißen und ihren Homologen im Blut von subhumanen Primaten wurden systematisch untersucht. Von den drei früher voneinander abgetrennten Gruppen [2] wurden zwei für die vorliegende Versuchsreihe herausgegriffen; eine von ihnen konnte weiter unterteilt werden. Die erhobenen Befunde werden berichtet und diskutiert. Die Immunologische Evolutions-Gruppe (IEG) I, die IgA (-Kette), IgD (-Kette) und den Inter--Trypsininhibitor umfaßt, zeight Kreuzreaktionen nur mit den Plasmen von Pongiden. Die IEG IIa, zu der IgM (-Kette), die ₂ II und III und Cholinesterase gehören, kreuzreagiert mit den entsprechenden Plasmaproteinen der geprüften Pongiden und Cercopithecoidea, die IEG IIb—das sind saueres _l-Glycoprotein, _2HS-Glycoprotein, _l-Trypsininhibitor, Haptoglobin und Haemopexin — mit Pongiden, Cercopithecoidea und Cebus (Platyrrhini) und endlich die IEG IIc, die sich aus Transferrin und dem Gc-Globulin zusammensetzt, mit allen geprüften Primatenplasmen einschließlich denen von Prosimiern. Alle hier genannten Plasmaeiweiße zeigen jedoch keine Kreuzreaktionen mit Proteinen von Nichtprimaten, wie dies bei der IEG III der Fall ist.Aus den vorliegenden Befunden wird der Schluß gezogen, daß die Determinanten der Primatenproteine, die jeweils reagieren, in ihrem phylogenetischen Alter von IEG Iüber IEG IIa, IIb, IIc im gleichen Maße ansteigen, wie die letzten gemeinsamen Vorfahren von Mensch und den kreuzreagierenden Arten.

---

---

(Chief: Prof. Dr. E. Krah)