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Plants as sessile organisms have evolved fascinating capacities to adapt to changes in their natural environment. Arguably, light is by far the most important and variable environmental factor. The quality, quantity, direction and duration of light is monitored by a series of photoreceptors covering spectral information from UVB to near infrared. The response of the plants to light is called photomorphogenesis and it is regulated by the concerted action of photoreceptors. The combined techniques of action spectroscopy and biochemistry allowed one of the important photoreceptors – phytochrome – to be identified in the middle of the last century. An enormous number of physiological studies published in the last century describe the properties of phytochrome and its function and also the physiology of blue and UV-B photoreceptors, unidentified at the time. This knowledge was summarized in the advanced textbook “Photomorphogenesis in Plants” (Kendrick and Kronenberg, eds., 1986, 1994). With the advent of molecular biology, genetics and new molecular, cellular techniques, our knowledge in the field of photomorphogenesis has dramatically increased over the last 15 years.

Plants --- Bacteria --- Plant cellular signal transduction. --- Photomorphogenesis. --- Effect of light on. --- Cellular signal transduction --- Plant cellular control mechanisms --- Germs --- Microbes --- Prokaryotes --- Photomorphogenesis, Plant --- Photomorphosis, Plant --- Plant photomorphogenesis --- Plant photomorphosis --- Growth (Plants) --- Plant morphogenesis --- Plant physiology --- Phytochrome --- Effect of light on --- Botany. --- Plant physiology. --- Plant genetics. --- Plant anatomy. --- Plant Ecology. --- Plant Sciences. --- Plant Physiology. --- Plant Genetics and Genomics. --- Plant Anatomy/Development. --- Botany --- Ecology --- Plant structure --- Structural botany --- Vegetable anatomy --- Anatomy --- Genetics --- Physiology --- Botanical science --- Phytobiology --- Phytography --- Phytology --- Plant biology --- Plant science --- Biology --- Natural history --- Structure --- Phytoecology --- Vegetation ecology --- Plant science. --- Plant development. --- Plant ecology. --- Development of plants --- Plant development --- Developmental biology --- Ontogeny --- Floristic botany --- Floristic ecology

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Plants as sessile organisms have evolved fascinating capacities to adapt to changes in their natural environment. Arguably, light is by far the most important and variable environmental factor. The quality, quantity, direction and duration of light is monitored by a series of photoreceptors covering spectral information from UVB to near infrared. The response of the plants to light is called photomorphogenesis and it is regulated by the concerted action of photoreceptors. The combined techniques of action spectroscopy and biochemistry allowed one of the important photoreceptors - phytochrome - to be identified in the middle of the last century. An enormous number of physiological studies published in the last century describe the properties of phytochrome and its function and also the physiology of blue and UV-B photoreceptors, unidentified at the time. This knowledge was summarized in the advanced textbook Photomorphogenesis in Plants  (Kendrick and Kronenberg, eds., 1986, 1994). With the advent of molecular biology, genetics and new molecular, cellular techniques, our knowledge in the field of photomorphogenesis has dramatically increased over the last 15 years.