Lan Liu-Gitz scite author profile

A substantial number of studies have been conducted over the last several decades to assess the potential impacts of long-term increases in ultraviolet-B radiation (UV-B between 280 and 320 nm) that will result from continued depletion of stratospheric ozone. However, seasonal changes, tropospheric chemistry and cloudiness are the dominant factors controlling ambient UV-B levels on a short-term or daily basis. The effects of short-term changes in UV-B on plant growth, phytochemistry and physiological processes have received relatively little attention. The USDA UV-B Monitoring and Research Program provides an excellent network of stations that provide an opportunity to monitor long-term changes in solar UV-B radiation and evaluate the responses of plants to short-term variation in UV-B levels on a near-real-time basis. In this study barley (Hordeum vulgare L.) and soybean (Glycine max [L] Merr.) were used as model systems. Emerging seedlings of these species were grown under either near-ambient levels of UV-B or under reduced levels (ca 90% reduction) in the field. Periodic measurements of foliar UV-screening compounds were made on separate groups of seedlings planted at intervals over the growing season during contrasting periods of ambient levels of UV radiation. The levels of UV-screening compounds correlated with UV-B levels in both species and with UV-A in soybean but the sensitivity of the response differed between the two species and among the soybean cultivars. Response differences among species may be related to unique secondary chemistry of each species, so one response estimate or action spectrum may not be appropriate for all species.

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How do UV Photomorphogenic Responses Confer Water Stress Tolerance?¶†

Gitz¹,

Liu-Gitz²

2003

Photochem Photobiol

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Although ultraviolet-B (UV-B) radiation is potentially harmful, it is an important component of terrestrial radiation to which plants have been exposed since invading land. Since then, plants have evolved mechanisms to avoid and repair UV radiation damage; therefore, it is not surprising that photomorphogenic responses to UV-B are often assumed to be adaptations to harmful radiation. This presupposes that the function of the observed responses is to prevent UV damage. It has been hypothesized that, as with blue light, UV-B provides a signal important for normal plant development and might be perceived within developing plants through nondestructive processes, perhaps through UV-specific signal perception mechanisms. UV signal perception can lead to photomorphogenic responses that may confer adaptive advantages under conditions associated with high-light environments, such as water stress. Plant responses to UV radiation in this regard include changes in leaf area, leaf thickness, stomatal density, photosynthetic pigment production and altered stem elongation and branching patterns. Such responses may lead to altered transpiration rates and water-use efficiencies. For example, we found that the cumulative effect of ambient UV-B radiation upon stomatal density and conductance can lead to altered water-use efficiencies. In field settings, UV might more properly be viewed as a photomorphogenic signal than as a stressor. Hence, it might be insufficient to attempt to fully evaluate the adaptive roles of plant responses to UV-B cues upon stress tolerance by the simultaneous application of UV and drought stress during development. We propose that rather than examining a plant's response to combinations of stressors one might also examine how a plant's response to UV induces tolerance to subsequently applied stresses.

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Blue light inhibits stomatal development in soybean isolines containing kaempferol‐3‐O‐2^G‐glycosyl‐gentiobioside (K9), a unique flavonoid glycoside

Liu-Gitz

Britz

Wergin³

2000

Plant Cell & Environment

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Lan Liu-Gitz

Ultraviolet-B effects on stomatal density, water-use efficiency, and stable carbon isotope discrimination in four glasshouse-grown soybean () cultivars

Coupling Short‐Term Changes in Ambient UV‐B levels with Induction of UV‐Screening Compounds^†

How do UV Photomorphogenic Responses Confer Water Stress Tolerance?¶†

Blue light inhibits stomatal development in soybean isolines containing kaempferol‐3‐O‐2^G‐glycosyl‐gentiobioside (K9), a unique flavonoid glycoside

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Lan Liu-Gitz

Ultraviolet-B effects on stomatal density, water-use efficiency, and stable carbon isotope discrimination in four glasshouse-grown soybean () cultivars

Coupling Short‐Term Changes in Ambient UV‐B levels with Induction of UV‐Screening Compounds†

How do UV Photomorphogenic Responses Confer Water Stress Tolerance?¶†

Blue light inhibits stomatal development in soybean isolines containing kaempferol‐3‐O‐2G‐glycosyl‐gentiobioside (K9), a unique flavonoid glycoside

Contact Info

Product

Resources

About

Coupling Short‐Term Changes in Ambient UV‐B levels with Induction of UV‐Screening Compounds^†

Blue light inhibits stomatal development in soybean isolines containing kaempferol‐3‐O‐2^G‐glycosyl‐gentiobioside (K9), a unique flavonoid glycoside