{"id":2245,"date":"2025-01-22T10:00:42","date_gmt":"2025-01-22T10:00:42","guid":{"rendered":"https:\/\/research.reading.ac.uk\/lemontree\/?p=2245"},"modified":"2025-02-06T15:48:42","modified_gmt":"2025-02-06T15:48:42","slug":"life-in-the-shadows-new-research-on-shade-plant-photosynthesis","status":"publish","type":"post","link":"https:\/\/research.reading.ac.uk\/lemontree\/life-in-the-shadows-new-research-on-shade-plant-photosynthesis\/","title":{"rendered":"Life in the shadows: New research on shade plant photosynthesis"},"content":{"rendered":"

Recent research from Utrecht University and Wageningen University & Research (WUR) has discovered that plants growing in the shade receive more light than previously understood. This discovery, detailed in the journal Plant Cell & Environment<\/em><\/a>, deepens our understanding of photosynthesis under low-light conditions.<\/p>\n

LEMONTREE’s Dr. Hugo de Boer,<\/a> an experimental scientist at Utrecht University, explains that plants shaded by others receive a higher proportion of green and far-red light. While traditional models posited that plants primarily utilize visible light (400 to 700 nm) for photosynthesis, this study reveals that the far-red spectrum (700 to 750 nm) significantly contributes to the process when combined with visible light.<\/p>\n

PhD candidate Tinko Jans<\/a> from WUR notes that previous experiments with monochromatic light underestimated the role of far-red light in photosynthesis. The team’s innovative method for measuring and modelling this contribution challenges longstanding assumptions and opens new avenues for optimiing plant growth in shaded environments.<\/p>\n

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Enhancing the FvCB Model<\/h3>\n

At the heart of the study is the adaptation of the Farquhar, von Caemmerer and Berry (FvCB) model\u2014a cornerstone in photosynthesis research. Originally designed to predict carbon assimilation based on factors like temperature, CO\u2082 and O\u2082 partial pressures, and light intensity, this model was expanded to incorporate the impact of far-red light. This enhancement offers a more accurate representation of photosynthesis in shaded environments where far-red light often dominates.<\/p>\n

Methodology and Key Findings<\/h3>\n

The research team combined experimental and computational methods to quantify the effects of far-red light on photosynthesis. They measured gas exchange parameters and light spectra in three plant species:<\/p>\n