Peter M. Hirst scite author profile

Multi-scale models can facilitate whole plant simulations by linking gene networks, protein synthesis, metabolic pathways, physiology, and growth. Whole plant models can be further integrated with ecosystem, weather, and climate models to predict how various interactions respond to environmental perturbations. These models have the potential to fill in missing mechanistic details and generate new hypotheses to prioritize directed engineering efforts. Outcomes will potentially accelerate improvement of crop yield, sustainability, and increase future food security. It is time for a paradigm shift in plant modeling, from largely isolated efforts to a connected community that takes advantage of advances in high performance computing and mechanistic understanding of plant processes. Tools for guiding future crop breeding and engineering, understanding the implications of discoveries at the molecular level for whole plant behavior, and improved prediction of plant and ecosystem responses to the environment are urgently needed. The purpose of this perspective is to introduce Crops in silico (cropsinsilico.org), an integrative and multi-scale modeling platform, as one solution that combines isolated modeling efforts toward the generation of virtual crops, which is open and accessible to the entire plant biology community. The major challenges involved both in the development and deployment of a shared, multi-scale modeling platform, which are summarized in this prospectus, were recently identified during the first Crops in silico Symposium and Workshop.

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Increase in fruit size of a spontaneous mutant of ‘Gala’ apple (Malus×domestica Borkh.) is facilitated by altered cell production and enhanced cell size

Malladi

Hirst

2010

101

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Fruit size regulation was studied in the apple cultivar ‘Gala’ and a large fruit size spontaneous mutant of ‘Gala’, ‘Grand Gala’ (GG). GG fruits were 15% larger in diameter and 38% heavier than ‘Gala’ fruits, largely due to an increase in size of the fruit cortex. The mutation in GG altered growth prior to fruit set and during fruit development. Prior to fruit set, the carpel/floral-tube size was enhanced in GG and was associated with higher cell number, larger cell size, and increased ploidy through endoreduplication, an altered form of the cell cycle normally absent in apple. The data suggest that the mutation in GG promotes either cell production or endoreduplication in the carpel/floral-tube cells depending on their competence for division. Ploidy was not altered in GG leaves. During fruit growth, GG fruit cells exited cell production earlier, and with a DNA content of 4C suggesting G2 arrest. Cell size was higher in GG fruits during exit from cell production and at later stages of fruit growth. Final cell diameter in GG fruit cortex cells was 15% higher than that in ‘Gala’ indicating that enhanced fruit size in GG was facilitated by increased cell size. The normal progression of cell expansion in cells arrested in G2 may account for the increase in cell size. Quantitative RT-PCR analysis indicated higher MdCDKA1 expression and reduced MdCYCA2 expression during early fruit development in GG fruits. Together, the data indicate an important role for cell expansion in regulating apple fruit size.

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Rootstock Effects on the Flowering of `Delicious' Apple. I. Bud Development

Hirst¹,

Ferree²

1995

jashs

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Floral development was studied in buds of `Starkspur Supreme Delicious' apple trees growing on B.9, M.26 EMLA, M.7 EMLA, P.18, and seedling rootstocks. In each of 3 years, buds were sampled from the previous years growth at intervals throughout the growing season and dissected to determine whether the apex was domed, indicating the start of floral development. Number of bud scales and true leaves increased during the early part of the growing season, but remained fairly constant beyond 70 days after full bloom. The type of rootstock did not affect the number of bud scales or transition leaves, and effects on true leaf numbers were small and inconsistent. Final bract number per floral bud was similarly unaffected by rootstock. The proportion of buds in which flowers were formed was influenced by rootstock in only one year of the study, which was characterized by high temperatures and low rainfall over the period of flower formation. Bracts were observed only in floral buds, and became visible after doming of bud apices had occurred. Flowers were formed during the first 20 days in August, regardless of rootstock or year. The appendage number of vegetative buds was constant from 70 days after full bloom until the end of the growing season, but the number of appendages in floral buds increased due to the continued production of bracts. The critical bud appendage number for `Starkspur Supreme Delicious' before flower formation was 20, and was stable among rootstocks and years. Buds with diameters above 3.1 mm were generally floral, but on this basis only 65% of buds could be correctly classified. Spur leaf number, spur leaf area, and spur leaf dry weight were not good predictors of floral formation within the spur bud.

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Optimizing Microwave‐Assisted Extraction of Phenolic Antioxidants from Red Delicious and Jonathan Apple Pomace

Chandrasekar

Martín-González

Hirst

et al. 2015

J Food Process Engineering

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Microwave-assisted extraction (MAE) of phenolic antioxidants from the pomace of Red Delicious and Jonathan apple varieties was optimized using response surface methodology. Optimization parameters included solvent type, microwave power, solvent volume to sample ratio and extraction time. Optimum conditions were based on the total polyphenol content (TPC) of extracts. Antioxidant activities of optimized extracts were also measured by inhibition percentage (IP) of the DPPH (2,2-diphenyl-1-picrylhydrazyl) free radical. High-performance liquid chromatography was used to identify and quantify some of the major phenolics extracted. Red Delicious pomace had the highest TPC (15.8 mg GAE/g) obtained under the optimum extraction conditions of 735 W power and 149 s extraction time with 10.3 mL of ethanol per gram dry sample. The DPPH IP of this extract was 77.1%. Phloridzin, caffeic acid, chlorogenic acid and quercetrin were some of the major polyphenols identified in the extracts. MAE was found to be an effective method of extracting antioxidant compounds from apple pomace. PRACTICAL APPLICATIONSExtraction of phenolics from apple pomace using microwave-assisted extraction (MAE) has significant potential compared with traditional extraction methods, as it significantly reduces extraction time and solvent consumption while generating higher extraction yields. The optimized extraction conditions obtained in this study resulted in extracts with high concentrations of polyphenols and high DPPH (2,2-diphenyl-1-picrylhydrazyl) radical-scavenging activity. Optimized extraction conditions were found to be independent of apple variety and therefore can be extended to extraction of phenolics from the pomace of other apple cultivars. This work opens the door for further research on the feasibility of an industrial-scale continuous MAE process for the recovery of these valuable compounds from apple pomace. In addition, there is promise for these value-added extracts to be used in a number of applications, including the extension of product shelf life (as an alternative to synthetic antioxidants), functional food ingredients and dietary supplements.

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Light Transmission, Yield Distribution, and Fruit Quality in Six Tree Canopy Forms of 'Granny Smith' Apple

Warrington

Stanley

Tustin

et al. 1996

Journal of Tree Fruit Production

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Peter M. Hirst

Crops In Silico: Generating Virtual Crops Using an Integrative and Multi-scale Modeling Platform

Increase in fruit size of a spontaneous mutant of ‘Gala’ apple (Malus×domestica Borkh.) is facilitated by altered cell production and enhanced cell size

Rootstock Effects on the Flowering of `Delicious' Apple. I. Bud Development

Optimizing Microwave‐Assisted Extraction of Phenolic Antioxidants from Red Delicious and Jonathan Apple Pomace

Light Transmission, Yield Distribution, and Fruit Quality in Six Tree Canopy Forms of 'Granny Smith' Apple

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