Summer food science
This is a story about the biochemistry of some of the foods that make summer delicious--most of which are fruits and vegetables. For those of you bound for a summertime holiday weekend, we dug into recent research into the yummy foods you might serve at a socially distant picnic.
Fruits and veggies in general
It’s in the bag: The plant hormone ethylene is key to fruit ripening. You’ve probably heard that you can make fruit ripen faster by placing it in a paper bag, raising the concentration of ethylene. in the Journal of Biological Chemistry covers what we know about how cells sense and respond to the hormone and how it might be harnessed for agriculture.
Oh, I see! No discussion of the biochemistry of fruits and vegetables would be complete without a nod to the fluorescent protein family named for produce that includes , , and ! Click through for a look at just a few of the many ways these fluorescent proteins are used to understand biochemistry.
Corn
From tropical crop to temperate staple: Once upon a time, corn was a tropical crop, hailing from the Central Balsas River Valley of southern Mexico before humans domesticated it around 9,000 years ago. Part of that domestication was an adaptation to more temperate climates that entailed change in the expression of protein and mRNA. To get a full picture of how domestication altered maize genetics, researchers at the National Maize Improvement Center of China conducted an integrative analysis of proteomic and transcriptomic changes in a maize association panel. Their , published in the journal Molecular & Cellular Proteomics, suggest that the proteome evolved under a greater evolutionary constraint than the transcriptome did while maize was adapting from tropical to temperate regions.
Corn rinds in dry times: Maize being the staple that it is, researchers at France’s UMR de Génétique Végétale examined how the plant’s phosphoproteome responds to drought events. By combining a physiological approach and a quantitative phosphoproteomic analysis, , published in the journal Molecular & Cellular Proteomics, provides new insights into the in-vivo early phosphorylation events triggered by rapid changes in plant water status and their possible involvement in plant growth-related processes.
Strawberries
AsESing the defensive secrets of a strawberry fungus: Anthracnose, a type of fungal rot, can devastate strawberry yields. By ramping up the plant’s defensive activity, however, scientists may be able to induce broad resistance against a range of fungal pathogens in the bright berries. In this published in the Journal of Biological Chemistry, researchers in Argentina purified and characterized a pathogen protein called AsES, which elicits a defensive immune response in the berries. Their findings may contribute to developing disease biocontrol strategies that use strawberries’ innate immunity.
Use a straw: Perhaps you like your strawberries in smoothie form? in the Journal of Lipid Research, by researchers at the Mayo Clinic, participants consumed almost three-quarters of their daily calories in strawberry smoothie form. Mmmmm.
Cantaloupe
Here’s the scoop: Orange melons, better known in the U.S. as cantaloupes, are rich in β-carotene that can be metabolized into vitamin A. in the Journal of Lipid Research, scientists investigated how intestinal cells take up metabolites of β-carotene.
Tomatoes
High-stakes structure: Tomatoes, like many other plants, use photoreceptors called phytochromes to sense far-red light and respond to temperature. In a structural biophysics , researchers reported the crystal structure of an enzyme that converts a precursor molecule used for photosynthesis into phytochrome pigments.
Hardy heirloom: How do tomato seedlings survive an early-season cold snap? It’s a trick question; a gardener could tell you that most don’t. But among strains that can tolerate some cold, it’s thanks to major changes to signaling. compared the cold-responsive phosphoproteome in an heirloom varietal called the greengage tomato to more wimpy strains to understand what makes the greengage so hardy.
Fresh herbs
From the ground up: If your summer would be incomplete without a big batch of pesto made from fresh basil and plenty of olive oil, you might be interested in the lipophilic, or oil-soluble, compounds produced in the basil leaves. In in the Journal of Biological Chemistry, researchers put mortar and pestle to a different use, grinding up leaves to carry out a detailed biochemical analysis of a certain type of flavone and pinpoint the enzyme responsible for synthesizing it.
Special sprigs: Why do basil, peppermint and marjoram all taste differently? Leaves from all three plant species, which belong to the mint family, have plenty in common but produce distinct sets of diterpenes, diverse 20-carbon molecules that impart flavor and aroma. In in the Journal of Biological Chemistry, researchers searched the genomes of 48 mint family species to find new diterpene synthase enzymes that help explain their unique flavor profiles.
Sweet(s)
And sweat: The insulin-responsive glucose transporter type 4 (GLUT4) protein was discovered in 1988. covers three decades of research made possible by the discovery, which clarified how insulin and exercise regulate glucose transport into muscle and fat cells.
Sip it for science: Milkshakes are a favorite research tool over at the Journal of Lipid Research. that introduced dietary fat with a milkshake in order to determine how genetic variation affects people’s metabolism.
Enjoy reading 91ÑÇÉ«´«Ã½ Today?
Become a member to receive the print edition four times a year and the digital edition weekly.
Learn moreGet the latest from 91ÑÇÉ«´«Ã½ Today
Enter your email address, and we’ll send you a weekly email with recent articles, interviews and more.
Latest in Science
Science highlights or most popular articles
An inclusive solar eclipse — with outreach
Traveling more than 150 miles with a group of neurodivergent students to have them witness a rare orbital alignment. and also teach the public about it, requires some strategic planning.
Predicting fatty liver disease from a tiny blood sample
Obesity and being overweight aren't the only factors that contribute to liver disease. New tests can help identify who is at risk or already has the disease, even in people who are lean or have a normal weight.
An ancient animal helps scientists improve modern technology
The same molecules that help tardigrades survive extreme weather can improve cryo-EM images of cellular structures and proteins, a team led by University of Wisconsin–Madison researcher Ci Ji Lim reports.
New structure gives insight into mRNA export and cancers
Yi Ren’s lab at Vanderbilt has described the structure of a protein complex that sheds light on the underlying molecular mechanism of mRNA export.
Analyzing triglycerides in Americans of African ancestry
Using the All of Us database, researchers at Vanderbilt sought a genetic reason why some patients, often underrepresented in research, could have varying levels of fat in the bloodstream.
Of yeasts and men: One-hour proteomes, 10 years apart
To profile the human genome within an hour, the researchers used a new mass spectrometer and packed their liquid chromatography columns with very high pressure.