Alan M. Kinnersley scite author profile

Wild-carrot (Daucus carota L.) cell cultures were screened to yield small (less than 63 μm) or large (greater than 170 μm) cell aggregates which were then subcultured. Cultures of the small-size class had a higher, those of the large-size class a lower anthocyanin yield than the unscreened culture. This relationship became accentuated with an increasing number of passages with screening prior to subculture. At the end of six months (12 passages), the pigment yield of the small-size class was triple that of the unscreened cells. Following this selection period, the tendency of the small-size fraction to increase in clump size when subcultured without screening was much less than that of freshly isolated cell aggregates of the same size. These observations may be explainable on the basis of a differential distribution of cytokinin between aggregates of different sizes. High levels of cytokinin inhibit anthocyanin accumulation and inhibit cell separation; these effects result in large cell aggregates having low levels of anthocyanin. In support of this hypothesis, it is shown that addition of kinetin to cultures of small cell aggregates causes an increase in the size of cell aggregates and a parallel decrease in anthocyanin yield.

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Corn starch as an alternative gelling agent for plant tissue culture

Henderson¹,

Kinnersley²

1988

Plant Cell Tiss Organ Cult

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Growth and differentiation of plant cell cultures was increased when media were gelled with corn starch instead of agar. Dry weight of tobacco and wild carrot cell cultures on media gelled with starch was more than three times that of cultures on media gelled with agar. Higher yield of anthocyanin and dry weight of embryos were found in wild carrot cultures grown on media gelled with corn starch. The starch-mediated increase in growth and differentiation of wild carrot ceils was accompanied by an increase in density of the cultures shown by higher dry weight/fresh weight ratios.

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The role of phytochelates in plant growth and productivity

Kinnersley¹

1993

Plant Growth Regul

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Plants require minimal amounts of certain metals (Zn,Fe,Cu,etc) for optimal growth and productivity, but excess of these metals leads to cell death. When growth is limited by metal excess or metal deficiency plants respond by synthesizing nonproteinogenic chelating substances. Phytosiderophores are secreted by roots of iron deficient grasses and are important in providing sufficient Fe for normal growth. In response to growth-inhibitory levels of heavy metals plants synthesize metal-binding phytochelatins which detoxify excess metals. Biostimulants such as humic substances and oligomers of lactic acid have properties in common with both phytosiderophores and phytochelatins. The word phytochelates is proposed as a generic term to cover substances that affect plant growth by acting as chelating agents. Introduction and overview

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