Proposed guidelines to evaluate scientific validity and evidence for genotype-based dietary advice

Nutrigenetic research examines the effects of inter-individual differences in genotype on responses to nutrients and other food components, in the context of health and of nutrient requirements. A practical application of nutrigenetics is the use of personal genetic information to guide recommendations for dietary choices that are more efficacious at the individual or genetic subgroup level relative to generic dietary advice. Nutrigenetics is unregulated, with no defined standards, beyond some commercially adopted codes of practice. Only a few official nutrition-related professional bodies have embraced the subject, and, consequently, there is a lack of educational resources or guidance for implementation of the outcomes of nutrigenetic research. To avoid misuse and to protect the public, personalised nutrigenetic advice and information should be based on clear evidence of validity grounded in a careful and defensible interpretation of outcomes from nutrigenetic research studies. Evidence requirements are clearly stated and assessed within the context of state-of-the-art ‘evidence-based nutrition’. We have developed and present here a draft framework that can be used to assess the strength of the evidence for scientific validity of nutrigenetic knowledge and whether ‘actionable’. In addition, we propose that this framework be used as the basis for developing transparent and scientifically sound advice to the public based on nutrigenetic tests. We feel that although this area is still in its infancy, minimal guidelines are required. Though these guidelines are based on semi-quantitative data, they should stimulate debate on their utility. This framework will be revised biennially, as knowledge on the subject increases.     

The efficient physiological strategy of a novel tomato genotype to adapt to chronic combined water and heat stress

• Climate change is increasing the frequency of high temperature shocks and water shortages, pointing to the need to develop novel tolerant varieties and to understand the mechanisms employed to withstand combined abiotic stresses.
• Two tomato genotypes, a heat-tolerant Solanum lycopersicum accession (LA3120) and a novel genotype (E42), previously selected as a stable yielding genotype under high temperatures, were exposed to single and combined water and heat stress. Plant functional traits, pollen viability and physiological (leaf gas exchange and chlorophyll a fluorescence emission measurements) and biochemical (antioxidant content and antioxidant enzyme activity) measurements were carried out. A Reduced Representation Sequencing approach allowed exploration of the genetic variability of both genotypes to identify candidate genes that could regulate stress responses.
• Both abiotic stresses had a severe impact on plant growth parameters and on the reproductive phase of development. Growth parameters and leaf gas exchange measurements revealed that the two genotypes used different physiological strategies to overcome individual and combined stresses, with E42 having a more efficient capacity to utilize the limiting water resources. Activation of antioxidant defence mechanisms seemed to be critical for both genotypes to counteract combined abiotic stresses. Candidate genes were identified that could explain the different physiological responses to stress observed in E42 compared with LA3120.
• Results here obtained have shown how new tomato genetic resources can be a valuable source of traits for adaptation to combined abiotic stresses and should be used in breeding programmes to improve stress tolerance in commercial varieties.

     

Multitraits evaluation of a Solanum pennellii introgression tomato line challenged by combined abiotic stress

• Rising daily temperatures and water shortage are two of the major concerns in agriculture.
• In this work, we analysed the tolerance traits in a tomato line carrying a small region of the Solanum pennellii wild genome (IL12-4-SL) when grown under prolonged conditions of single and combined high temperature and water stress.
• When exposed to stress, IL12-4-SL showed higher heat tolerance than the cultivated line M82 at morphological, physiological, and biochemical levels. Moreover, under stress IL12-4-SL produced more flowers than M82, also characterized by higher pollen viability. In both lines, water stress negatively affected photosynthesis more than heat alone, whereas the combined stress did not further exacerbate the negative impacts of drought on this trait. Despite an observed decrease in carbon fixation, the quantum yield of PSII linear electron transport in IL12-4-SL was not affected by stress, thereby indicating that photochemical processes other than CO₂ fixation acted to maintain the electron chain in oxidized state and prevent photodamage. The ability of IL12-4-SL to tolerate abiotic stress was also related to the intrinsic ability of this line to accumulate ascorbic acid.
• The data collected in this study clearly indicate improved tolerance to single and combined abiotic stress for IL12-4-SL, making this line a promising one for cultivation in a climate scenario characterized by frequent and long-lasting heatwaves and low rainfall.

     

Birth Control in Nineteenth-Century America: A View from Three Contemporaries

Social, philosophical and technical aspects of birth control in nineteenth-century America are examined through the lives and thoughts of three men who lived and worked at that time: John Humphrey Noyes, Anthony Comstock and Edward Bliss Foote.     

Uptake and phosphorylation of 2-deoxy-D-glucose by wild-type and single-kinase strains of Saccharomyces cerevisiae

The role of phosphorylation in sugar transport in baker's yeast was studied using 2-deoxy-D-glucose. In wild-type baker's yeast, 2-deoxy-D-glucose is accumulated as a mixture of the free sugar and several derivatives. Pool labeling experiments, designed to determine the temporal order of appearance of labeled 2-deoxy-D-glucose in the intracellular pools, have confirmed previous reports that 2-deoxy-D-glucose first appears in the sugar phosphate pool. Such results are consistent with a transport associated phosphorylation mechanism. Since wild-type yeasts contain three enzymes which could participate in such a process, hexokinase isozymes PI and PII and glucokinase, pool labeling experiments were carried out with single-kinase mutant strains containing only one of these enzymes. Results similar to those for wild-type strains were obtained for all three single-kinase strains, suggesting that if transport associated phosphorylation does occur in baker's yeast, it is not a function of the specific kinase present in the cell. While the results of the pool labeling experiments are consistent with a transport associated phosphorylation mechanism for 2-deoxy-D-glucose, caution is urged in interpreting the results of experiments with whole cells where problems of compartmentation and multiple pools are difficult to assess.     

Glucose transport activity in isolated plasma membrane vesicles from Saccharomyces cerevisiae

Purified plasma membranes prepared from yeast cells by mechanical agitation with glass beads exhibit no detectable sugar transport activity. However, the addition of phospholipid (asolectin) liposomes to the purified plasma membranes followed by freezing, thawing, and brief sonication produces membrane vesicles which exhibit D-glucose-specific transport activity. The characteristics of zero trans, equilibrium exchange, and influx counterflow exhibited by the membrane vesicles are similar to those of intact cells.