The effect of reversal of Na and K electrochemical potential gradients on the active transport of amino acids in Ehrlich ascites tumor cells

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1. The net uptake of α-aminoisobutyric acid (AIB) in Ehrlich ascites tumor cells has been studied under a variety of transmembrane concentration gradients of Na⁺, K⁺ and AIB itself.     

Temperature-sensitive initiation of DNA replication in a mutant of Escherichia coli K12

Summary A mutant of E. coli K12 appears to be temperature-sensitive in the process of initiation of DNA replication. After a temperature shift from 33 to 42°C, the amount of residual DNA synthesis (Fig. 1) and the number of residual cell divisions (Figs. 2,4) indicate that rounds of DNA replication in process are completed, but new rounds cannot be initiated. Following the alignment of chromosomal DNA by amino acid starvation at 33° C no residual DNA synthesis at 42°C takes place (Fig. 5). When the temperature is lowered to 33°C after a period of inhibition at 42°C, the following observations are made: 1. DNA replication resumes and proceeds synchroneously, (Figs. 7, 8a), 2. cells start to divide again only after a lag period of about 1 hour 3. a temporary increase in cell volume is correlated with the frequency of initiation of DNA synthesis (Fig. 8a, b). In a lysogenic mutant strain prophage is inducible; with all bacteriophages tested, replication of phage DNA is not inhibited at 42°C.     

The fate of newly made DNA in Escherichia coli mutants thermosensitive in DNA synthesis

Summary E. coli mutants exist in which DNA synthesis is thermosensitive. In one class of these mutants DNA synthesis stops immediately if a critical temperature (42°C) is reached. When DNA replication in such mutants is followed by ³H thymidine incorporation at 33°C, it is found that 1. only the newly made DNA is degraded at 42°C, 2. the discontinuously replicated DNA is lost predominantly at 42°C, 3. 1–3% of the chromosomal DNA is rendered acid soluble at 42°C without concomitant loss of viability of the cells at 33°C.Replication of phage DNA is inhibited in the same mutant at 42°C. However, when DNA synthesis is followed in infected cells at 33°C it is found that 1. no degradation of specific DNA seems to occur at 42°C in the early phase of infection, 2. replicating DNA molecules in the late phase of infection are completed at 42°C before DNA synthesis comes to a halt.     

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.     

Determination of Melting Sequences in DNA and DNA-Protein Complexes by Difference Spectra

A graphical formula is presented for determining the base ratio of melted DNA. By use of this formula, the composition of sequences which melt in different portions of the melting curves of Clostridium DNA, Escherichia coli DNA, and mouse DNA were determined. As the DNA melts, the per cent of adenine and thymine (AT) in the melted sequences decreases linearly with temperature. The average composition of sequences which melt in a given part of the melting curve is proportional to the base ratio of the DNA. The concentration and average composition of sequences were determined for three parts of the melting curves of the DNA samples, and a frequency distribution curve was constructed. The curve is symmetrical and has a maximum at about 56% AT. The distribution of GC-rich sequences on the E. coli chromosome was estimated by shearing, partially melting, and fractionating the DNA on hydroxylapatite. GC-rich sequences appear to occur every thousand base pairs, and have a maximum length of about 180 base pairs. The graphical formula was applied to the determination of the composition of sequences which melt in different parts of the melting curve of chromatin. Throughout the melting curve, the composition of the melting sequences is about 60% AT, which appears to suggest that relatively long sequences are melting simultaneously. Their melting temperature may be a function of the composition of the protein on different parts of the DNA. The problem of light scattering in DNA-protein and DNA was also investigated. A formula is presented which corrects for light scattering by relating the intensity of the scattered light to the rate of change of absorbance of DNA with wavelength.