Exploring trajectories in dietary adequacy of the B vitamins folate, riboflavin, vitamins B6 and B12, with advancing older age: a systematic review.

Maintaining nutritional adequacy contributes to successful ageing. B vitamins involved in one-carbon metabolism regulation (folate, riboflavin, vitamins B6 and B12) are critical nutrients contributing to homocysteine and epigenetic regulation. Although cross-sectional B vitamin intake in ageing populations is characterised, longitudinal changes are infrequently reported. This systematic review explores age-related changes in dietary adequacy of folate, riboflavin, vitamins B6 and B12 in community-dwelling older adults (≥65 years at follow-up). Following Preferred Reporting Items for Systematic Reviews and Meta-Analyses guidelines, databases (MEDLINE, Embase, BIOSIS, CINAHL) were systematically screened, yielding 1579 records; eight studies were included (n 3119 participants, 2­25 years of follow-up). Quality assessment (modified Newcastle­Ottawa quality scale) rated all of moderate­high quality. The estimated average requirement cut-point method estimated the baseline and follow-up population prevalence of dietary inadequacy. Riboflavin (seven studies, n 1953) inadequacy progressively increased with age; the prevalence of inadequacy increased from baseline by up to 22·6 and 9·3 % in males and females, respectively. Dietary folate adequacy (three studies, n 2321) improved in two studies (by up to 22·4 %), but the third showed increasing (8·1 %) inadequacy. Evidence was similarly limited (two studies, respectively) and inconsistent for vitamins B6 (n 559; −9·9 to 47·9 %) and B12 (n 1410; −4·6 to 7·2 %). This review emphasises the scarcity of evidence regarding micronutrient intake changes with age, highlighting the demand for improved reporting of longitudinal changes in nutrient intake that can better direct micronutrient recommendations for older adults. This review was registered with PROSPERO (CRD42018104364).

Further evidence for double-strand breaks originating from a paired radical precursor from studies of oxygen fixation processes.

By using a fast reaction technique which employs H2S gas as a fast-reacting chemical repair agent, it is possible to measure the competition kinetics between chemical repair reactions and oxygen fixation reactions in model DNA and cellular systems. In plasmid pBR322 DNA irradiated with electrons, we have compared the oxygen fixation reactions of the free radical precursors that lead to the production of single-strand (SSBs) and double-strand breaks (DSBs). For the oxygen-dependent fixation of radical damage leading to SSBs, a second-order rate constant of 2.3 x 10(8) dm3 mol(-1) s(-1) was obtained compared to 8.9 x 10(7) dm3 mol(-1) s(-1) for DSBs. The difference is in general agreement with predictions from a multiple-radical model where the precursor of a DSB originates from two radicals. The fixation of this precursor by oxygen will require both radicals to be fixed for the DSB to be formed, which will have slower kinetics than that of single free-radical precursors of SSBs.

Evidence for a hypoxic fixation reaction leading to the induction of ssb and dsb in irradiated DNA.

PURPOSE: To measure hypoxic chemical fixation processes of radiation damage in both isolated plasmid DNA and in GSH-depleted E. coli cells. MATERIALS AND METHODS: Plasmid pBR322 DNA was irradiated with a single 5 ns pulse of 400 keV electrons under hypoxic conditions. At pre-set times, immediately before or after the electron pulse, the chamber containing the DNA was exposed to a high-pressure shot of hydrogen sulphide (H2S) gas. RESULTS: DNA irradiated before contact with the H2S pulse was more sensitive to the production of both single strand breaks (ssb) and double strand breaks (dsb) than DNA irradiated after the addition of H2S. The post-irradiation protection of DNA by H2S was time-dependent, having first-order rate constants of 21 s(-1) for ssb and 10 s(-1) for dsb. CONCLUSIONS: This is the first direct kinetic evidence for the involvement of a hypoxic fixation reaction in the production of DNA damage by ionizing radiation. It indicates that long-lived radical damage is induced in DNA which, even at times of 20-50ms after irradiation, can be chemically repaired, or rescued, by the addition of a thiol agent. This reaction may partially explain the predicted decrease in oxygen enhancement ratio (OER) with linear energy transfer (LET) on the basis of the increased clustering of radicals produced on the DNA by tracks of ionizing radiation. As radical multiplicity increases with LET there is a greater chance that some of the radicals will become fixed in the absence of oxygen leading to an increased probability of damage under hypoxia and a reduction in the OER.

Role of charge in the radioprotection of E. coli by thiols.

The role of net charge (zeta) of thiols in their ability to radioprotect cells has been investigated in a glutathione (GSH)-deficient strain of E. coli. This strain, 7, is deficient in the enzyme gamma-glutamylcysteine synthetase and allows the effects of added low molecular weight thiols to be studied. Using the gas explosion system it is possible to measure the chemical repair of the free-radical precursors of lethal lesions by thiols in intact cells. The first-order chemical repair rate in strain 7 is 280 s-1 in comparison with 1100 s-1 in the wild-type strain 1157. From the measured difference in the intracellular concentration of GSH between the wild-type and the mutant, this gives a second-order repair rate, kr, of 1.23 +/- 0.3 x 10(5) dm3mol-1s-1. Measurement of intracellular thiol levels after addition of various low molecular weight thiols showed that uptake was rapid, leading to stable thiol levels within 1 min. The ratios of the intracellular to extracellular concentrations (Cin/Cout) were 0.74 for 3-mercaptopropionic acid (zeta = -1), 0.56 for 2-mercaptoethanol (zeta = 0), 1.47 for cysteamine (zeta = +1) and 1.04 for WR1065 (zeta = +2). The kr's for these thiols were 1.3 +/- 0.5 x 10(5) dm3mol-1s-1 for 30-mercaptopropionic acid, 3.3 +/- 1.6 x 10(5) dm3mol-1s-1 for 2-mercaptoethanol, 3.9 +/- 1.1 x 10(5) dm3mol-1s-1 for cysteamine and 2.7 +/- 1.1 x 10(6) dm3mol-1s-1 for WR1065. These are lower and increase less with charge than previously published values for chemical repair in isolated pBR322 DNA, probably because of the association of nucleoproteins and polyamines with the cellular DNA of E. coli. However, the approximate three-fold increase in kr per unit increase in zeta shows that the counter-ion condensation and co-ion depletion are important in determining the effectiveness of charged thiols in the radioprotection of E. coli.

Recombinant human interferon alpha-2b enhances the radiosensitivity of small cell lung cancer in vitro.

We have studied the effects of human recombinant interferon alpha on the radiobiological response and the cell cycle distribution of human small cell lung cancer cell lines. In two small cell lung cancer cell lines tested so far, pretreatment with interferon alpha was found to increase the radiation sensitivity without altering the distribution of cells in the cell cycle.

Detoxification of DNA hydroperoxide by glutathione transferases and the purification and characterization of glutathione transferases of the rat liver nucleus.

DNA peroxidized by exposure to ionizing radiation in the presence of oxygen is a substrate for the Se-independent GSH peroxidase activity of several GSH transferases, GSH transferases 5-5, 3-3 and 4-4 being the most active in the rat liver soluble supernatant fraction (500, 35 and 20 nmol/min per mg of protein respectively) and GSH transferases mu and pi the most active, so far found, in the human liver soluble supernatant fraction (80 and 10 nmol/min per mg respectively). Although the GSH transferase content of the rat nucleus was found to be much lower than that of the soluble supernatant, nuclear GSH transferases are likely to be more important in the detoxification of DNA hydroperoxide produced in vivo. Two nuclear fractions were studied, one extracted with 0.075 M-saline/0.025 M-EDTA, pH 8.0, and the other extracted from the residue with 8.5 M-urea. The saline/EDTA fraction contained subunits 1, 2, 3, 4 and a novel subunit, similar but not identical to 5, provisionally referred to as 5*, in the proportions 40:25:5:5:25 respectively. The 8.5 M-urea-extracted fraction contained principally subunit 5* together with a small amount of subunit 6 in the proportion 95:5 respectively. GSH transferase 5*-5* purified from the 8.5 M-urea extract has the highest activity towards DNA hydroperoxide of any GSH transferase so far studied (1.5 mumol/min per mg). A Se-dependent GSH peroxidase fraction from rat liver was also active towards DNA hydroperoxide; however, since this enzyme accounts for only 14% of the GSH peroxidase activity detectable in the nucleus, GSH transferases may be the more important source of this activity. The possible role of GSH transferases, in particular GSH transferase 5*-5*, in DNA repair is discussed.

Constants of the Alper and Howard-Flanders oxygen equation for damage to bacterial membrane, deduced from observations on the radiation-induced penicillin-sensitive lesion.

Energy deposited in the bacterial envelope of E. coli B/r induces lesions which are lethally attacked by penicillin in concentration insufficient to affect unirradiated bacteria. The critical lesions are probably in the membrane moiety. Bacteria were irradiated in the presence of 100 per cent oxygen, oxygen-free nitrogen and mixtures of 1.01, 0.59, 0.3, 0.1 and 0.06 per cent oxygen in nitrogen. Changes in sensitivity with pO2 conformed with the Alper and Howard-Flanders equation, for bacteria treated after irradiation by penicillin as well as for the untreated ones. The values of m were respectively 4.8 and 3.3; the values of K were identical, within experimental error, i.e. 4.4 mmHg. Sensitivity to induction of the penicillin-sensitive lesion was calculated from the difference in the reciprocals of D0 values proper to untreated and treated bacteria, for every gas used. The value of m could not be directly calculated because the effect of penicillin on anoxically irradiated bacteria was not detectable. For that reason, a transformation of the oxygen equation was used which allowed estimates to be made of both m and K, provided the results conformed with the equation. Within experimental error they did so conform. The calculated values of m and K for induction of the penicillin-sensitive lesion were respectively 8 and 5.9 mmHg, but it is shown that the oxygen enhancement ratio was probably underestimated and the K value overestimated. On the assumptions that these values of m and K are specific for radiation damage to bacterial membrane, and that radiation-induced killing is attributable to lethal lesions in the membrane as well as the DNA, the results demonstrate that any interaction of oxygen with sites of energy deposition in the DNA must play a very much smaller role in radiosensitization than does interaction with sites of energy deposition in the membrane.

Repair of membrane damage in X-irradiated E. coli.

When E. coli B/r or E. coli K12 AB1157 were X-irradiated in the presence of oxygen and incubated immediately after irradiation in broth containing penicillin in concentration that on its own was not lethal to unirradiated bacteria, substantial additional killing was caused. When treatment with penicillin was delayed for increasing times after irradiation the additional killing became progressively less. These results were interpreted as demonstrating the repair or removal of oxygen-dependent radiation-induced lesions in the bacterial membranes. Removal of these lesions was inhibited by incubation of the irradiated bacteria at low temperature before treatment with penicillin or by exposing the cells to a non-lethal concentration of toluene before irradiation. These observations suggest that an enzymatic repair process may be involved in the removal of the membrane lesions. The fatty acid mutant E. coli K 1060 proved exceptional in that some additional killing by penicillin was detectable after anaerobic as well as aerobic irradiation. This points to the importance of membrane composition in the development of those radiation lesions that are brought to light by penicillin treatment.

The lethal interaction of X ray and penicillin induced lesions following X-irradiation of Escherichia coli B/R in the presence of hypoxic cell sensitizers.

When Escherichia coli B/r were x-irradiated under anoxia in the presence of different electron-affinic sensitizers and then incubated in broth containing penicillin (at a concentration that did not kill unirradiated cells) additional killing of the bacteria occurred provided the sensitizers were of relatively high lipophilicity. The overall effect was to increase the efficiency of these sensitizers. It is concluded that sensitizer-dependent latent radiation lesions(s) are produced in membrane components of the cell envelope that interact with damage caused by penicillin in the peptidoglycan layer and this causes the additional lethality.

An oxygen dependent X-ray lesion in Escherichia coli strain B/r detected by penicillin.

Enhancement of lethal damage to E. coli B/r by penicillin was observed after X-irradiation under aerobic conditions but not after exposure to X-rays under anoxia or after U.V. (260 nm). No enhancement of damage occurred when incubation with penicillin was delayed for 2 hours after aerobic X-irradiation. This enhancing effect was only detected in this strain and not in the filamentous strain E. coli B. It is concluded that an X-ray induced lesion, sensitive to the presence of oxygen at the time of irradiation and probably located in the cell envelope, initiates filamentation in E. coli B/r, which results in lethal damage in this strain.

Radiation-induced chromosomal aberrations in human lymphocytes after partial-body exposure to 60Co gamma-irradiation and in vitro exposure to 230 kV X-irradiation.

Small yields of chromosome aberrations were present in lymphocytes from 12 patients observed at first metaphase in culbure. Blood samples were obtained at various times, up to three days, after single partial-body therapeutic exposure ranging from 75 to 400 rads of 60Co gamma-irradiation. When all patients were considered there was no correlation between treatment dose and aberration frequency, but on subdivision into two groups on the basis of whether the reticuloendothelial system was involved in the cancer, linear regression analysis could be fitted to the data for each group. An in vitro dose response curve for dicentrics induced by 230 kV X rays at a dose rate of 23.3 rads per minute was constructed for use as a standard calibration curve for 48 hour cultures. The yield of dicentric aberrations was best fitted by a power law model, Y = kDn in which k = (1.59 +/- 0.66) 10(-4) and n= 1.49 +/- 0.08, (P =0.96).