Creatine Monohydrate Supplementation, but not Creatyl-L-Leucine, Increased Muscle Creatine Content in Healthy Young Adults: A Double-Blind Randomized Controlled Trial.

Creatine (Cr) supplementation is a well-established strategy to enhance gains in strength, lean body mass, and power from a period of resistance training. However, the effectiveness of creatyl-L-leucine (CLL), a purported Cr amide, is unknown. Therefore, the purpose of this study was to assess the effects of CLL on muscle Cr content. Twenty-nine healthy men (n = 17) and women (n = 12) consumed 5 g/day of either Cr monohydrate (n = 8; 28.5 ± 7.3 years, 172.1 ± 11.0 cm, 76.6 ± 10.7 kg), CLL (n = 11; 29.2 ± 9.3 years, 170.3 ± 10.5 cm, 71.9 ± 14.5 kg), or placebo (n = 10; 30.3 ± 6.9 years, 167.8 ± 9.9 cm, 69.9 ± 11.1 kg) for 14 days in a randomized, double-blind design. Participants completed three bouts of supervised resistance exercise per week. Muscle biopsies were collected before and after the intervention for quantification of muscle Cr. Cr monohydrate supplementation which significantly increased muscle Cr content with 14 days of supplementation. No changes in muscle Cr were observed for the placebo or CLL groups. Cr monohydrate supplementation is an effective strategy to augment muscle Cr content while CLL is not.

Potato ingestion is as effective as carbohydrate gels to support prolonged cycling performance.

Carbohydrate (CHO) ingestion is an established strategy to improve endurance performance. Race fuels should not only sustain performance but also be readily digested and absorbed. Potatoes are a whole-food-based option that fulfills these criteria, yet their impact on performance remains unexamined. We investigated the effects of potato purée ingestion during prolonged cycling on subsequent performance vs. commercial CHO gel or a water-only condition. Twelve cyclists (70.7 ± 7.7 kg, 173 ± 8 cm, 31 ± 9 yr, 22 ± 5.1% body fat; means ± SD) with average peak oxygen consumption (V̇o2peak) of 60.7 ± 9.0 mL·kg-1·min-1 performed a 2-h cycling challenge (60-85% V̇o2peak) followed by a time trial (TT; 6 kJ/kg body mass) while consuming potato, gel, or water in a randomized-crossover design. The race fuels were administered with [U-13C6]glucose for an indirect estimate of gastric emptying rate. Blood samples were collected throughout the trials. Blood glucose concentrations were higher (P < 0.001) in potato and gel conditions compared with water condition. Blood lactate concentrations were higher (P = 0.001) after the TT completion in both CHO conditions compared with water condition. TT performance was improved (P = 0.032) in both potato (33.0 ± 4.5 min) and gel (33.0 ± 4.2 min) conditions compared with water condition (39.5 ± 7.9 min). Moreover, no difference was observed in TT performance between CHO conditions (P = 1.00). In conclusion, potato and gel ingestion equally sustained blood glucose concentrations and TT performance. Our results support the effective use of potatoes to support race performance for trained cyclists.NEW & NOTEWORTHY The ingestion of concentrated carbohydrate gels during prolonged exercise has been shown to promote carbohydrate availability and improve exercise performance. Our study aim was to expand and diversify race fueling menus for athletes by providing an evidence-based whole-food alternative to the routine ingestion of gels during training and competition. Our work shows that russet potato ingestion during prolonged cycling is as effective as carbohydrate gels to support exercise performance in trained athletes.

Polyethylene glycol treatment promotes metabolic events associated with maize callus morphogenic competence.

Metabolic changes were studied, which accompanied the conversion of 6month old HiII maize non-regenerable (NR) calli into regenerable (R) calli when cultured for 63days with 10% polyethylene glycol (PEG) (3350MW) in culture medium. The conversion of 6month old NR to R callus morphotype caused by PEG application decreased cell wall contents in callus dry mass and changed cell wall phenolics making their profile similar to that of R callus by reduction of lignin and ester- and ether-bound phenolic concentrations, including p-coumaric acid and ester- and ether-bound diferulates and by increase of the ratios of ester- and ether-bound ferulic acid/coumaric acid and ferulic acid/diferulic acid in cell walls of NR callus. Some similar changes of cell wall phenolics caused by PEG application were also found in 48month old NR callus, that changed the morphology, but did not regenerate plants. However, there were no changes in the old callus in levels of total ester and ether-bound cell wall phenolics and substantially smaller decreases were found in ratios of ester- and ether-bound ferulic acid/coumaric acid and ferulic acid/diferulic acid, as well as in diferulate concentrations compared to young NR callus cultured with PEG. Remarkably, application of PEG also changed the primary metabolism of young NR callus tissues, so that they acquired metabolic features of highly regenerable callus. These data clearly suggest that PEG alters metabolism of NR calli, so they acquire biochemical characteristics of R calli, and that adaptive osmotic adjustments vary in different types of callus tissues.

Physiological and molecular adaptations to drought in Andean potato genotypes.

The drought stress tolerance of two Solanum tuberosum subsp. andigena landraces, one hybrid (adgxtbr) and Atlantic (S. tuberosum subsp. tuberosum) has been evaluated. Photosynthesis in the Andigena landraces during prolonged drought was maintained significantly longer than in the Tuberosum (Atlantic) line. Among the Andigena landraces, 'Sullu' (SUL) was more drought resistant than 'Negra Ojosa' (NOJ). Microarray analysis and metabolite data from leaf samples taken at the point of maximum stress suggested higher mitochondrial metabolic activity in SUL than in NOJ. A greater induction of chloroplast-localized antioxidant and chaperone genes in SUL compared with NOJ was evident. ABA-responsive TFs were more induced in NOJ compared with SUL, including WRKY1, mediating a response in SA signalling that may give rise to increased ROS. NOJ may be experiencing higher ROS levels than SUL. Metabolite profiles of NOJ were characterized by compounds indicative of stress, for example, proline, trehalose, and GABA, which accumulated to a higher degree than in SUL. The differences between the Andigena lines were not explained by protective roles of compatible solutes; hexoses and complex sugars were similar in both landraces. Instead, lower levels of ROS accumulation, greater mitochondrial activity and active chloroplast defences contributed to a lower stress load in SUL than in NOJ during drought.

Genetic and transgenic perturbations of carbon reserve production in Arabidopsis seeds reveal metabolic interactions of biochemical pathways.

The biosynthesis of seed oil and starch both depend on the supply of carbon from the maternal plant. The biochemical interactions between these two pathways are not fully understood. In the Arabidopsis mutant shrunken seed 1 (sse1)/pex16, a reduced rate of fatty acid synthesis leads to starch accumulation. To further understand the metabolic impact of the decrease in oil synthesis, we compared soluble metabolites in sse1 and wild type (WT) seeds. Sugars, sugar phosphates, alcohols, pyruvate, and many other organic acids accumulated in sse1 seeds as a likely consequence of the reduced carbon demand for lipid synthesis. The enlarged pool size of hexose-P, the metabolites at the crossroad of sugar metabolism, glycolysis, and starch synthesis, was likely a direct cause of the increased flow into starch. Downstream of glycolysis, more carbon entered the TCA cycle as an alternative to the fatty acid pathway, causing the total amount of TCA cycle intermediates to rise while moving the steady state of the cycle away from fumarate. To convert the excess carbon metabolites into starch, we introduced the Escherichia coli starch synthetic enzyme ADP-glucose pyrophosphorylase (AGPase) into sse1 seeds. Expression of AGPase enhanced net starch biosynthesis in the mutant, resulting in starch levels that reached 37% of seed weight. However, further increases above this level were not achieved and most of the carbon intermediates remained high in comparison with the WT, indicating that additional mechanisms limit starch deposition in Arabidopsis seeds.