How plants decide when to flower

Researchers at Michigan State University have uncovered the molecular mechanism that allows plants to sense phosphorus deficiency and delay flowering, a survival strategy that could inspire new ways to breed crops for low-fertility soils.
The discovery reveals a phosphorus-dependent switch inside plant cells that reprograms their development when nutrients are scarce, allowing them to invest in survival rather than reproduction under low-phosphorus conditions.
A key protein called β-GLUCOSIDASE 25 (bGLU25) acts as a signal, relaying information about the plant’s nutrient environment and triggering the delay in flowering when phosphorus is scarce.
The mechanism involves the movement of bGLU25 from one cellular compartment to another, which changes its interactions with other proteins and ultimately delays flowering by boosting the activity of a gene known as FLOWERING LOCUS C (FLC).
The discovery has exciting possibilities for improving agricultural resilience in phosphorus-deficient regions and could lead to the development of “nutrient-smart” crops that require less fertilizer while maintaining yields, helping to make agriculture more sustainable.

A group of pink and yellow flowers on a white background.

New research digs into how plants decide when to flower.

Phosphorus, a key ingredient in fertilizers, is running out. The world’s food systems depend on phosphorus mined from limited reserves, yet much of what is applied to fields washes away, leaving soils increasingly depleted.

As phosphorus becomes scarcer, crops struggle to grow and reproduce, threatening yields and global food security.

But while humans search for ways to use phosphorus more efficiently, plants have been managing this challenge for millions of years. When phosphorus runs low, they adjust their growth, slow their flowering, and wait for better conditions. Until now, the method plants use to make this developmental shift was a mystery to scientists.

Researchers at Michigan State University’s Plant Resilience Institute have uncovered the molecular mechanism that allows plants to sense phosphorus deficiency and delay flowering, a survival strategy that could inspire new ways to breed crops for low-fertility soils. The research in Developmental Cell reveals a phosphorus-dependent “switch” inside plant cells that reprograms their development when nutrients are scarce.

“This is the first time we have seen such a direct link between nutrient status, protein movement inside the cell, and control of flowering time,” says Associate Professor Hatem Rouached, senior author and faculty member in MSU’s plant, soil, and Mmicrobial sciences department.

“This discovery helps explain how plants translate nutrient stress into developmental timing. By understanding that mechanism, we can begin designing crops that flower and yield optimally even in nutrient-poor environments.”

The research, led by Hui-Kyong Cho, a postdoctoral fellow in the Rouached lab, began with a simple observation: plants grown in phosphorus-poor conditions consistently flower later than those with sufficient phosphorus. Using genome-wide association mapping in Arabidopsis, Cho and her colleagues searched for the molecular basis that explains this phenomenon.

Their search led to an unexpected candidate; a protein called β-GLUCOSIDASE 25 (bGLU25). Although bGLU25 belongs to a family of enzymes that typically break down carbohydrates, the team found that it is catalytically inactive. Instead, it acts as a signal, relaying information about the plant’s nutrient environment.

Under phosphorus-rich conditions, the bGLU25 protein resides quietly in the endoplasmic reticulum, the cellular compartment that helps process proteins. When phosphorus runs low, bGLU25 is cut by another protein, SCPL50, and released into the cytosol, the cell’s fluid interior.

“That movement, from one compartment to another, is the plant’s way of flipping a molecular switch,” says Cho. “It changes what bGLU25 can interact with, and that changes how the plant decides when to flower.”

Once in the cytosol, bGLU25 binds to another protein called AtJAC1, which then traps a third protein, GRP7, preventing it from entering the cell’s nucleus. GRP7 normally regulates a gene known as FLOWERING LOCUS C (FLC), a master repressor that keeps plants from flowering too soon.

By keeping GRP7 in the cytosol, bGLU25 indirectly boosts FLC activity, delaying flowering when phosphorus is scarce. The result is a finely tuned response: under low phosphorus, the plant invests in survival rather than reproduction.

“It is an elegant example of how plants integrate environmental signals into developmental choices,” Rouached says.

Phosphorus is essential for plant metabolism. It forms part of DNA, membranes, and energy molecules such as ATP. But phosphorus-rich soils are rare, and phosphate fertilizer supplies depend on limited global reserves. Understanding how plants naturally cope with scarcity could help scientists breed nutrient-efficient crops that require less fertilizer while maintaining yields.

“This mechanism is not just an Arabidopsis curiosity,” says Rouached. “We have already seen evidence that a similar process operates in rice and other crop species. That opens exciting possibilities for improving agricultural resilience in phosphorus-deficient regions.”

By decoding how plants sense and respond to phosphorus stress, Rouached and Cho hope to lay the foundation for a new generation of “nutrient-smart” crops.

“If we can help plants make better decisions about when to flower and how to use their resources, we can help agriculture become more sustainable,” Rouached says. “This discovery gives us a blueprint for that future.”

Source: Michigan State University

The post How plants decide when to flower appeared first on Futurity.

link

Q. What is phosphorus running out of, and how does it affect crops?

A. Phosphorus is a key ingredient in fertilizers that is running out, and its scarcity affects crops by making them struggle to grow and reproduce.

Q. How do plants decide when to flower, and what happens if they don’t have enough phosphorus?

A. Plants adjust their growth, slow their flowering, and wait for better conditions when phosphorus runs low, as a survival strategy that could inspire new ways to breed crops for low-fertility soils.

Q. What is the molecular mechanism that allows plants to sense phosphorus deficiency and delay flowering?

A. Researchers have uncovered a phosphorus-dependent switch inside plant cells that reprograms their development when nutrients are scarce.

Q. Who led the research on this topic, and what was the initial observation that sparked the investigation?

A. The research was led by Hui-Kyong Cho, a postdoctoral fellow in the Rouached lab, who observed that plants grown in phosphorus-poor conditions consistently flower later than those with sufficient phosphorus.

Q. What is the role of the protein β-GLUCOSIDASE 25 (bGLU25) in this process?

A. bGLU25 acts as a signal, relaying information about the plant’s nutrient environment, and its movement from one compartment to another is the plant’s way of flipping a molecular switch.

Q. How does bGLU25 interact with other proteins to delay flowering when phosphorus is scarce?

A. Once in the cytosol, bGLU25 binds to AtJAC1, which then traps GRP7, preventing it from entering the cell’s nucleus and regulating the gene FLOWERING LOCUS C (FLC).

Q. What is the master repressor that keeps plants from flowering too soon?

A. The gene FLOWERING LOCUS C (FLC) is a master repressor that keeps plants from flowering too soon.

Q. How does this discovery help explain how plants translate nutrient stress into developmental timing?

A. By understanding the molecular mechanism, scientists can begin designing crops that flower and yield optimally even in nutrient-poor environments.

Q. What are the potential implications of this discovery for agriculture and food security?

A. The discovery could lead to breeding nutrient-efficient crops that require less fertilizer while maintaining yields, helping agriculture become more sustainable and improving global food security.