Identification of a rosette-enriched chromatin fraction from mouse fibroblast nuclei.

We have characterized two components of DNA isolated from mouse L-M cell nuclei. These components, designated as HMW (high molecular weight) and VHMW (very high molecular weight) DNA, were characterized by rate zonal sedimentation, agarose gel electrophoresis, and for protein content. Our electron micrographs revealed that HMW-DNA contained mainly linear molecules with few single rosette structures, while the VHMW-DNA was enriched in rosettes, many of which were significantly larger and linked together in multimeric structural forms. The VHMW-DNA component was also enriched for residual protein, which we believe represents the core of the rosette. The characteristics of this residual protein are consistent with reported findings of the most tightly bound proteins. The rosette conformation does not appear to be an artifact of microscopy or of an aggregate nature for several reasons: (i) rosettes are preferentially found in the VHMW-DNA component; (ii) further manipulation or purification of the DNA disrupts the rosette structure and produces linear fragments; (iii) the amount of proteinaceous material at the core of the rosette is diminished when the DNA is further purified; and (iv) treatment of intact nuclei with a novel bisamine reagent putatively crosslinks DNA in vivo and minimizes the disruption of rosettes by shear. We believe this separation of chromatin is critical to establish the architectural forms of euchromatin and heterochromatin of interphase DNA in the eucaryotic system. Once established, fractionated chromatin can be used to identify specifically expressed or repressed genes with linear form DNA and rosette form DNA. We discuss rosettes as derivatives of chromosomal domains that retain structural features because of residual peptide elements.

Biological activity of heated diphtheria toxin.

Diphtheria toxin splits into two fragments when heated at 100 C for 10 min in a phosphate buffer. The separated fragments have molecular weights of 24,000 and 39,000, respectively. These molecular weights are similar to those of the A and B fragments found in diphtheria toxin preparations after thiol reduction. Since the separation of toxin into fragments is not complete, it is likely that only nicked toxin molecules having a cleaved peptide bond are split by heating. When toxin is suspended in phosphate buffer at pH 6.4, the B-like fragment precipitates, but at pH 7.8 it does not. Heated toxin is unable to intoxicate sensitive cells or cause a necrodermal response in animals. Fragment A produced by heating is active in inhibiting cell-free protein synthesis. It is able to intoxicate both HeLa and L cells when the uptake of the fragment is facilitated by addition of polyornithine to the cultures. Fragment B produced by heating is involved with binding to the cell surface. It is able to delay the action of toxin on KB cell cultures preincubated with fragment B.

Site in cell-free protein synthesis sensitive to diphtheria toxin.

The effects of diphtheria toxin on cell-free protein synthesis in a bacterial system, and preparations obtained from animals that were sensitive and resistant to toxin were examined. In the presence of nicotinamide adenine dinucleotide (NAD), toxin inhibited the incorporation of amino acids by endogenous and synthetic polynucleotides in both rat liver and guinea pig liver cell-free systems that were exposed to 6 Lf units per ml of toxin. A cell-free system derived from Streptococcus faecalis was resistant to high concentrations of toxin. Dialyzed toxin-antitoxin floccules that are formed in the presence of NAD and the 105,000 x g supernatant fluid from rat liver contain NAD. Such floccules are also active in protein synthesis in the absence of added transferase I or II. An operational model presents the view that the intoxication complex is formed at the ribosomal level and occurs in two steps. First, the toxin molecule binds to transferase II and alters its stereospecific relationship to transferase I, but it does not result in an inactive complex. Second, the stereospecific alteration in transferase I, but it does not result in an inactive complex. Second, the stereospecific alteration in transferase II caused by the binding of diphtheria toxin allows NAD to bridge between transferase I and II, which then results in an inactivated complex. The sensitivity of the cell-free system derived from the normally resistant rat implies that in some cells the cell membrane serves as a permeability barrier to the toxin molecule. The resistance of bacterial cell-free protein synthesizing systems to diphtheria toxin may reflect basic differences between transferase enzymes from bacterial and mammalian sources.

The response of cultured mammalian cells to diphtheria toxin. I. Amino acid transport, accumulation, and incorporation in normal and intoxicated sensitive cells.

The response to diphtheria toxin of two sensitive cell lines, KB and HeLa, was investigated. Inhibition of the incorporation of radioactively labeled amino acids into protein was the earliest detectable effect of diphtheria toxin. It was observed that, during the period of intoxication, the cell membrane was morphologically intact and retained its semi-permeable character, although it was rendered fragile and more easily disrupted by mechanical manipulations than the normal cell. The transport of amino acids continued even after intoxicated cells had ceased to synthesize protein, and the levels accumulated were equal to those of control cells. It was observed that cultural conditions, age, and handling of cells affected their response to toxin. In early log phase cells subjected to a minimum of handling before application of the toxin, the normally observed latent period preceding detectable effects was reduced to 15 min for KB cells and 30 min for HeLa cells, shorter times than previously reported. The data are consistent with the hypothesis that diphtheria toxin enters susceptible cells, possibly by pinocytosis, and there acts upon cytoplasmic sites of protein synthesis.