Interaction of the exr and lon Genes in Escherichia coli

Strains of Escherichia coli carrying the gene lon typically produced excess capsular polysaccharide, and were sensitive to ultraviolet light (UV) irradiation, thymine starvation, and nalidixic acid, forming long filaments after these treatments. Sensitivity was reduced by a number of posttreatments. In the presence of a second UV sensitivity gene, exr, some of these properties were suppressed: long filaments were not formed, the effect of lon on UV and nalidixic acid sensitivity was greatly reduced, and irradiation posttreatments gave an enhancement of survival characteristic of exr rather than lon strains. Production of capsular polysaccharide was not affected by the exr gene.     

A comparison of light-dependent RNA metabolism in wild-type Euglena with that of mutants impaired for chloroplast development

Summary The possibility that ³²PO ₄ ^3- (³²P_i) labeling of both chloroplast and non-chloroplast RNAs during light-induced chloroplast development in Euglena is due, in part, to the break-down of existing RNAs and their resynthesis into labeled RNAs has been examined by comparing the RNA content of dark-grown, non-dividing cells after completion of light-induced chloroplast development with that of identical cells maintained in darkness for the same period of time. The involvement of the photo-conversion of protochlorophyll to chlorophyll and other photoreceptor systems in the labeling of RNA during chloroplast development has been considered by comparing the labeling pattern obtained with wild-type cells with the patterns obtained with mutants of Euglena which either lack detectable amounts of protochlorophyll and chlorophyll or form only rudimentary chloroplasts upon light induction.No significant difference in RNA content between dark-grown, non-dividing cells containing fully developed chloroplasts and the same cells maintained in darkness for the development period can be detected. This observation is interpreted to mean that in non-dividing cells precursors for chloroplast-associated RNAs are derived from pools and pre-existing RNAs, including non-chloroplast RNAs, and that the matebolic entrapment of ³²P_i involves a light-dependent turnover and DNA-directed RNA synthesis in wild-type cells.The RNA profiles on sucrose gradients of mutants of Euglena show no remarkable deviation from the profile established for wild-type cells. The labeling patterns obtained after 24 hours of incubation in light and in darkness differ from that obtained for wild-type cells in that all mutants show less of a light-minus-dark difference than wild-type and that mutants lacking plastid-associated DNA and detectable amounts of chlorophyll incorporate considerably more ³²P_i into RNA in darkness than wild-type. One such mutant shows no significant difference in its light-dark labeling pattern.These observations indicate that cells possessing normal proplastids capable of forming functional chloroplasts regulate metabolism of RNA in darkness in a different manner than with either rudimentary chloroplasts or containing no detectable plastids structures. The possible involvement of more than one photoreceptor system in metabolic control is discussed.Supported by a grant from the National Institutes of Health, GM 14595     

Homoaconitic Acid Accumulation by a Lysine-Requiring Yeast Mutant

Homoaconitic acid, the second intermediate of the proposed pathway for lysine biosynthesis in yeast, is accumulated in the growth medium of a lysine-requiring mutant. This acid has been identified on paper and column chromatography by comparing it with authentic cis-homoaconitic acid. The infrared spectrum of the isolated material was identical with that of synthetic cis-homoaconitic acid. In addition, the chemical structure of the enzymatic product has been verified by degradation to glyoxylic and α-ketoglutaric acids after treatment with KMnO₄ and HIO₄ and by catalytic reduction to the saturated acid 1,2,4-butanetricarboxylic acid. The isolated homoaconitic acid was also identified as a substrate for a purified enzyme preparation of homoaconitase.     

Ultraviolet Sensitivity of the Biological Activity of ΦX174 Virus, Single-Stranded DNA, and RF DNA

Action spectra for inactivation of varphiX virus, free varphiX single-stranded DNA, and double-stranded varphiX DNA (RF) have been measured using light of wavelength 225-302 mmu. The sensitivity of RF has been determined using bacterial hosts both capable and incapable of reactivation of UV damage. The inactivation of varphiX virus is due, at all wavelengths, to damage to its DNA; it appears that, below 240 mmu, energy absorbed by viral structural protein may inactivate the viral DNA. The variation of the probability of inactivation by an absorbed quantum (quantum yield) with wavelength, in the case of free-single-stranded varphiX DNA, suggests that energy absorbed by pyrimidine residues is more likely to yield inactivation than absorption by purines. This implies that energy transfer is not so extensive as to make all absorbed energy available to pyrimidines.     

Patterns of puffing activity in the salivary gland chromosomes of Drosophila

The patterns of puffing activity have been studied during the late larval and prepupal stages of Drosophila melanogaster. On the major salivary gland autosomes (chromosomes 2 and 3) 108 loci form puffs at some time during these developmental stages. The timing and pattern of activity of 83 of these puffs is found to be strictly dependent upon the age of the animals. Two major peaks in puffing activity occur. The first of these is at the time of puparium formation and the second in 8 hr. old prepupae. Both of these puffing peaks precede a moult by 4 hrs. 30 puffs are active before or at the time of both of these two moults. However, the sequence of appearance and regression of many of this group of puffs is different at the prepupal moult than at the pupal moult. 12 puffs occur only before or at the time of the prepupal moult and 13 puffs only before or at the time of the pupal moult. The functional significance of these periods of puffing activity is discussed and it is concluded that one function of this genetic activity in the salivary glands of metamorphosing Drosophila is the production of substances to be utilised during the histogenesis of the adult tissues.     

Derepression of Phosphomannose Isomerase by Regulator Gene Mutations Involved in Capsular Polysaccharide Synthesis in Escherichia coli K-12

A regulator gene mutation (capR) that causes increased synthesis of capsular polysaccharide and derepressed synthesis of several enzymes involved in polysaccharide synthesis also derepresses phosphomannose isomerase (PMI) synthesis. In contrast, a second mutation (capS, which maps separately from capR) that causes increased production of the same polysaccharide does not lead to increased synthesis of PMI (nor of several of the other enzymes involved in polysaccharide synthesis). Introduction of the capR9 allele by transduction or mutation of capR(+) to capR can change the phenotype of a mannose-negative nonmucoid strain to a mannose-positive mucoid phenotype. Thus, genotype capR(+)man-2 is mannose-negative and nonmucoid, but genotype capR9 man-2 is mannose positive and mucoid. Other interactions between these alleles in the synthesis of capsular polysaccharide are recorded.