Ultraviolet light-induced recombination

Stimulation of transduction in $\text{Escherichia coli}$ by ultraviolet irradiation of the transducing phage P1 requires the $\text{uvrA-uvrB}$ nuclease but not the $\text{uvrC}$ product or DNA polymerase I. It is hypothesized that the first step in “normal” recombination can be bypassed by any procedure generating single-stranded ends of DNA (as, for example, by $\text{uvra-uvrB}$ nuclease activity).     

Ultraviolet light-induced crosslinking of mRNA to proteins.

Irradiation of intact or EDTA-dissociated L-cell polyribosomes with 254 nm UV light at doses of 1-2 x 10(5) ergs/mm2 extensively crosslinks mRNA to proteins. The crosslinked mRNA-protein complexes can be isolated on the basis of buoyant density in urea-containing CS2SO4 gradients that dissociate non-covalent complexes. Crosslinking of mRNA can also be assayed by phenolchloroform extraction. mRNA recovered from the crosslinked complexes by digestion with proteinase K has the same electrophoretic mobility in polyacrylamide gels as unirradiated mRNA. Therefore, irradiation does not either crosslink RNA molecules to RNA molecules or break phosphodiester bonds. With these methods it has been found that more than 70% of high molecular weight polydisperse mRNA, but only 25-40% of histone mRNA, can be crosslinked to protein. On the basis of buoyant density the histone mRNA-protein complex had a protein content of 26%, whereas the mean protein content of most non-histone mRNA-protein complexes was 65%. It is concluded that most mRNA in polyribosomes is in close contact with proteins, and that histone mRNA can be crosslinked to many fewer proteins that most other mRNAs.     

Ultraviolet light-induced changes in ribonuclease conformation

Ultraviolet light-induced inactivation of RNase A is accompanied by a decrease in the circular dichroism (CD) at the extrema observed at 239 nm and 275 nm. As inactivation progresses a new CD band centered near 325 nm also develops. For RNase maintaining up to one half of its original activity an isoelliptic point may be noted near 257 nm. These findings are consistent with initial normalization of a “buried” tyrosyl residue followed by chemical modification of the protein. Further chemical change and extensive conformational reorganization of the protein appear to accompany advanced inactivation.     

Ultraviolet light-induced mutation of diploid human lymphoblasts

Ultraviolet irradiation (254 nm) of immortal diploid human lymphoblasts killed cells, caused mutation at three genetic loci studied, and transiently inhibited ³H-TdR uptake into DNA. A shoulder of about 6 J/m² and a D₀ of 6 J/m² was observed for survival. Mutation rose in a monotonic non-linear fashion through 6 J/m²; above 6 J/m², complex behavior approximating a plateau in induced mutation was observed. Irradiation at 4.4 J/m² caused a transient increase in the number of cells synthesizing DNA and a decrease in the rate of DNA synthesis relative to mock-irradiated controls. The parameter of rate of DNA synthesis per cell in DNA synthetic phase showed a rapid recovery toward control values between 2 and 4 h after irradiation and a slower recovery to control values by 22 h post-irradiation.Fractionated dose schedules were used to measure the effects of allowing a time interval between doses at nontoxic fluences (2.2 j/m²), moderately toxic fluences (8.8 J/m²) and toxic fluences (17.6 J/m²). These measurements indicate that in the non-toxic range of fluences common to human exposure, mutational response is mediated by a post-irradiation process which seems to show to shkow enchanced ability to protect against mutation induced by subsequent irradiation. However, at moderately toxic fluences there was little effect of dose fractionation, and at toxic fluences, a time-dependent increase in mutation fraction was observed at separation times greater than 7 h. We suggest that these latter observations arise primarily from cell cycle heterogeneity with regard to sensitivity to UV killing and mutation.     

Ultraviolet light-induced inhibition of small nuclear RNA synthesis

Two apparently distinct types of inhibition of the synthesis of U1, U2, U3, U4, and U5 small nuclear RNA, induced by ultraviolet (UV) radiation, have been described before: immediate and delayed. Our present observation can be summarized as follows: a) neither the immediate nor the delayed inhibition appear to be mediated by the formation of cyclobutane pyrimidine dimers, since they were not prevented by photoreactivating light, in ICR 2A frog cells; b) the inhibition of U1 RNA synthesis, monitored in HeLA cells within the first few minutes after irradiation, extrapolated to a substantial suppression at time zero of postirradiation cell incubation, providing further support for the proposal that the immediate inhibition is a reaction separate from the delayed UV light-induced inhibition of U1 RNA synthesis; c) the transition from the pattern of the immediate inhibition to that of the delayed inhibition (disappearance of the UV-resistant fraction of U1 RNA synthesis and increased rate of inhibition) occurred gradually, without an apparent threshold, within the first 2 hr of incubation after irradiation; and d) the incident UV dose that resulted in a 37% level of residual U1 RNA synthesis (D37) during the delayed inhibition was about 7 J/m2, with an apparent UV dose threshold, and was about 60 J/m2 for the immediate inhibition.     

Ultraviolet reactivation of the single stranded DNA phage phiX 174.

Summary When UV-irradiated X174 was grown in pre-irradiated host cells of various strains, ultraviolet reactivation (UVR) was observed only in recombination proficient strains such as E. coli C (uvrA ⁺ recA ⁺) and HF4704 (uvrA ^- recA ⁺), but not in the recombination deficient strain HF4712 (uvrA ⁺ recA ^-). By increasing the multiplicity of infection, no rise in the amount of such reactivation was observed. From the study of the neutral and alkaline sucrose gradient sedimentation patterns of DNA samples extracted from unirradiated cells infected with unirradiated phage, it appears that after the conversion of the viral single stranded (SS) DNA to the double stranded form (DS), nicks or scissions were produced on it within all three strains, which were ultimately sealed up in the recA ⁺ but persisted within the recA ^- host cells. When UV-irradiated phage infected unirradiated host cells, such nicking of the DS DNA appeared to be much more extensive in uvrA ⁺ recA ⁺, but slightly reduced in uvrA ⁺ recA ^- and severely suppressed in uvrA ^- recA ⁺ strains. When the host cells were also UV-irradiated, the conversion of the infecting viral SS DNA to DS DNA as well as its subsequent nicking were reduced in all the three strains to a much greater extent. Although nicking of the DS DNA molecule is an essential step even in the normal intracellular replication of X DNA, the production and the sealing up of such nicks appear not to have any positive correlation with UVR of these phages. A drastic reduction in nicking due te pre-irradiation of the host cells might, however, mean slowing down of the replication of the damaged parental RF molecules which would facilitate their repair perhaps through recombination with the homologous parts of the host genome.     

In vitro reactivation of spindle elongation in fission yeast nuc2 mutant cells

To investigate the mechanisms of spindle elongation and chromosome separation in the fission yeast Schizosaccharomyces pombe, we have developed an in vitro assay using a temperature-sensitive mutant strain, nuc2. At the restrictive temperature, nuc2 cells are arrested at a metaphase-like stage with short spindles and condensed chromosomes. After permeabilization of spheroplasts of the arrested cells, spindle elongation was reactivated by addition of ATP and neurotubulin both at the restrictive and the permissive temperatures, but chromosome separation was not. This suggests that the nuc2 cells are impaired in function at a stage before sister chromatid disjunction. Spindle elongation required both ATP and exogenous tubulin and was inhibited by adenylyl imidodiphosphate (AMPPNP) or vanadate. The ends of yeast half-spindle microtubules pulse-labeled with biotinylated tubulin moved past each other during spindle elongation and a gap formed between the original half-spindles. These results suggest that the primary mechanochemical event responsible for spindle elongation is the sliding apart of antiparallel microtubules of the two half-spindles.     

Ultraviolet light-induced crosslinking of HnRNA to informofer proteins in vitro

RNA-protein interaction in the 30S subunits of rat liver hnRNP has been studied by crosslinking of informofer proteins to hnRNA induced by UV irradiation.Irradiation of 30S particles with 254 nm UV light in doses of 1×10⁵ erg/mm² leads to the extensive crosslinking hnRNA to informofer proteins. The crosslinked material was analyzed either by resedimentation in a 15–30% sucrose gradient in the presence of 3 M guanidine-HCl and 1 M NaCl or by centrifugation in a Cs₂SO₄ density gradient containing guanidine-HCl and sarkosyl. The crosslinked complexes sedimented at about 25S in the sucrose gradient and proved to be heterogeneous in isopycnic centrifugation experiments. The proteins of the crosslinked complexes were analyzed by polyacrylamide gel electrophoresis. Proteins with M_r values of 70 000, 58 000, 43 000 and 40 000 appeared to be crosslinked with hnRNAs of the 30S particles.In the unirradiated 30S particles after centrifugation in the Cs₂SO₄ density gradient containing guanidine-HCl and sarkosyl two minor proteins were observed with M_r values of 70 000 and 58 000, banded in density zones characteristic for free RNA.     

New photo-induced effects of reactivation and protection of yeast cells under lethal UVB radiation

Brief exposure of yeasts to low-intensity monochromatic light (400–730 nm) has revealed the effects of photoreactivation and photoprotection of the cells inactivated by medium wave UVB radiation (290–320 nm). The red spectral region with a maximum at 680 nm has been found to be the most active in the initiation of photoreactivation and photoprotection. It has been noted that, according to the regularities investigated, these processes differ fundamentally from the known processes of enzymatic photoreactivation and photoprotection, which have a spectral response limited by, respectively, blue (<450 nm) and near (<380 nm) UV light. The data obtained make possible to consider the observed effects of photoreactivation and photo-protection as the manifestation of functioning of some light-dependent defense system capable of increasing the resistance of cells to UVB radiation.