Phytochrome Quantitation in Crude Extracts of Avena by Enzyme-linked Immunosorbent Assay with Monoclonal Antibodies

Overview

Journal Planta

Specialty Biology

Date 2013 Nov 22

PMID 24258330

Citations 9

Authors

Y Shimazaki

M M Cordonnier

L H Pratt

Affiliations

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Abstract

An enzyme-linked immunosorbent assay (ELISA), which uses both rabbit polyclonal and mouse monoclonal antibodies to phytochrome, has been adapted for quantitation of phytochrome in crude plant extracts. The assay has a detection limit of about 100 pg phytochrome (<1 fmol of monomer) and can be completed within 10 h. Nonspecific interference by crude plant extracts was detected and corrected for. Quantitation of phytochrome in crude extracts of etiolated oat (Avena sativa L.) seedlings by ELISA gave values that agreed well with those obtained by spectrophotometric assay. When etiolated oat seedlings were irradiated continuously for 24 h, the amount of phytochrome detected by ELISA and by spectrophotometric assay in crude extracts of these seedlings decreased by more than 1000-fold and about 100-fold, respectively. This discrepancy indicates that phytochrome in light-treated plants may be antigenically distinct from that found in fully etiolated plants. Both a decrease in the light and an increase in the dark of phytochrome content was observed in crude extracts of light-grown oat shoots, both green and Norflurazon-bleached, in response to a 12:12-h light-dark cycle. When these light-grown oat seedlings were kept in darkness for 48 h, phytochrome content detected by ELISA increased by 50-fold in crude extracts of green oat shoots, but only about 12-fold in extracts of herbicide-treated oat shoots. Phytochrome reaccumulation in green oat shoots was initially more rapid in the more mature cells of the primary leaf tip than near the basal part of the shoot. The inhibitory effect of Norflurazon on phytochrome accumulation was much more evident near the leaf tip than the shoot base. A 5-min red irradiation of oat seedlings at the end of a 48-h dark period resulted in a subsequent, massive decrease in phytochrome content in crude extracts from both green and Norflurazon-bleached oat shoots. These observations eliminate the possibility that substantial accumulation of chromophore-free phytochrome was being detected and indicate that Norflurazon has a substantial effect on phytochrome accumulation during a prolonged dark period.

Citing Articles

Immunochemical detection with rabbit polyclonal and mouse monoclonal antibodies of different pools of phytochrome from etiolated and green Avena shoots.

Shimazaki Y, Pratt L Planta. 2013; 164(3):333-44.

PMID: 24249602 DOI: 10.1007/BF00402944.

Phytochrome in green tissue: Spectral and immunochemical evidence for two distinct molecular species of phytochrome in light-grown Avena sativa L.

Tokuhisa J, Daniels S, Quail P Planta. 2013; 164(3):321-32.

PMID: 24249601 DOI: 10.1007/BF00402943.

Immunological assay of phytochrome in small sections of roots and other organs of maize (Zea mays L.) seedlings.

Schwarz H, Schneider H Planta. 2013; 170(2):152-60.

PMID: 24232873 DOI: 10.1007/BF00397883.

The levels of two distinct species of phytochrome are regulated differently during germination in Avena sativa L.

Tokuhisa J, Quail P Planta. 2013; 172(3):371-7.

PMID: 24225921 DOI: 10.1007/BF00398666.

Avena sativa L. contains three phytochromes, only one of which is abundant in etiolated tissue.

Wang Y, Stewart S, Cordonnier M, Pratt L Planta. 2013; 184(1):96-104.

PMID: 24193935 DOI: 10.1007/BF00208242.

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