Nucleotide sequences of the retroviral long terminal repeats and their adjacent regions.

The nucleotide sequences of the LTRs and their adjacent regions from 19 type C and one type B retrovirus were compared. Salient features are: (a) The R regions in the genomes of most of the type C retroviruses begin with GC and end with CA. (b) The mammalian type C retroviruses have a polyadenylation signal "AATAAA" in the R region, and most have a "CAT" box and a "TATA" box in the U3 region. (c) The avian type C retroviruses have an AATAAA sequence, and some also have "CAT-like" and "TATA-like" boxes, in the U3 region. (d) As with many transposable elements, the IR regions of the proviruses begin with TG and end with CA, and the DR sequences in the host genomes flanking the proviruses are different from one another. Although SNV is an avian retrovirus, the nucleotide sequences in the R, U5, TBS, and PU region are more similar to the mammalian type C than to the avian type C retroviruses.     

The effects of acridine orange on deoxyribonucleic acid in Escherichia coli.

1. Acridine Orange inhibits growth of Escherichia coli K12 when incubated at pH 7.9, but not at pH 7.4.2. At a non-permissive temperature for DNA polymerase I, Acridine Orange inhibits growth of a temperature-sensitive strain and also increases the rate of elimination of the F'-Lac plasmid. 3. DNA isolated from cells treated with Acridine Orange under conditions that inhibit growth contains material of low molecular weight, which is absent from DNA isolated from cells treated under conditions in which growth is not impaired. 4. Cells incubated with Acridine Orange at both pH 7.4 and 7.9 suffer degradation of DNA, as shown by loss of labelled DNA from the acid-insoluble fraction, which is not observed with untreated cells at either pH. 5. The results suggest that elimination of the F'-Lac plasmid by Acridine Orange requires inactivation of repair processes.     

Japanese Hollies: Intolerant Hosts of Meloidogyne arenaria in Microplots

Japanese hollies were itttolerant of Meloidogyne arenaria in field microplot experiments. Ilex crenata var. rotundifolia was relatively more tolerant than I. crenata var. convexa or I. crenata var. helleri. When M. arenaria was added at various itfitial population densities to soil containing plants of "Helleri," "Convexa," and "Rotundifolia," respectively, 91, 75, and 25% were killed by the end of the third growing season. No control plants died during the same period. Initial numbers of M. arenaria larvae and eggs were the only population densities that were correlated (negatively), regardless of cultivar, with plant growth over the three growing seasons. A linear relation was found for initial density of M. arenaria and growth of I. crenata rotundifolia. Increasing nematode density by 10-fold suppressed the growth of this cultivar by 23%.     

Application of living immobilized cells to the acceleration of the continuous conversions of ethanol (wort) to acetic acid (vinegar)—Hydrous titanium(IV) oxide-immobilized Acetobacter species

Various strains of Acetobacter species have been immobilized on hydrous titanium(IV) oxide or hydrous titanium(IV) chelated cellulose and used in the continuous conversion of a dilute aqueous alcoholic solution (in the form of‘charging wort’) into acetic acid (in the form of vinegar) in tower fermenter-type reactors. A strain of Acetobacter species producing extracellular polysaccharide aggregated in the presence of hydrous titanium(IV) oxide thereby enabling higher medium flow rates and an increased acetic acid output to be achieved. A strain of Acetobacter species not producing polysaccharide showed no effect with hydrous titanium(IV) oxide but did produce more acetic acid when a titanium(IV)-cellulose chelate was added to the fermentation, although aggregation was not observed. Mechanisms, which appear to conform to established results, are proposed for the aggregation of both strains of bacteria. Apparently, these water-insoluble titanium compounds can interact with the bacterial cells, increasing their density and thus making them more resistant to ‘wash out’ by increasing the rate at which they sediment in the fermenter. This enables a greater cell mass per unit volume to be achieved which in turn leads to an increase in conversion rate in the reactor.     

The fate of norleucine as a replacement for methionine in protein synthesis.

In vivo synthesised protein with norleucine occupying one half of the normal methionine loci was prepared using a methionine auxotroph of Escherichia coli K12. The extent of charging of the analogue onto both tRNA_met species and subsequent incorporation into soluble protein was monitored with a double-labelling system comprising [G-³H]norleucine and [³⁵S]methionine. Further experiments established that norleucine can be formylated in vivo once charged onto the initiator tRNA^f_met. An N-terminal analysis of the crude soluble protein revealed that formylnorleucyl-tRNA^f_met can initiate protein synthesis and that the formyl group is then removed from the nascent polypeptide. We were also led to conclude that the N-terminal methionine-amino peptidase does not recognise the analogue in this position. Slow growth rates on the methionine analogue have been partly attributed to limiting levels of charged tRNA^m_met, resulting in turn from the inefficiency of norleucine charging by methionyl-tRNA synthetase. Finally no evidence has been found for the production of aberrant protein as a result of norleucine incorporation, implying that limited growth on the analogue is due to its inability to replace methionine as the precursor of S-adenosyl methionine.