Research Proposal for Aspects of Arabidopsis thaliana Introduction The mouse ear cress Arabidopsis thaliana is a member of the Brassica eae that lends itself well to genetic study in that it has only a small quantity of DNA. The plant itself has little commercial value aside from that as a research tool, and it has no aesthetic horticultural value at all. It is a small plant that can be grown by the hundreds in cells on a laboratory bench, and its small quantity of DNA makes it useful in identifying genes of other organisms (Wheeler, 1994).
Normal flower color varies between solid white petals to green petals only tinged with white. Manipulation of flower color is of interest not because of any potential ornamental value, but because of the mechanisms of gene expression in the visible appearance of the yellow pigment anthocyanin.
In like manner, information regarding cold tolerance and the biochemical changes that occur within the plant in response to cold are not of interest primarily for culture of the plant itself except as it applies to cultural conditions that need to be maintained for optimum life cycle completion time. Rather, Arabidopsis response to cold stress is of interest because facts learned from it can be applied to investigations in human systems (Stock inger, Gilmour and Thomas how, 1997).
This investigation seeks to determine if enough anthocyanin can be concentrated in petal cells so that they express a visible yellow color, and if cold stress has any effect on visible levels of anthocyanin concentrations in petal cells. Literature Review Arabidopsis naturally contains anthocyanin, and Lloyd, Wal bot and Davis (1992) were able to cause anthocyanin “pathway-specific transcriptional activators R an C 1 from the monocot maize were expressed in two dicots, Arabidopsis thaliana and Nicotiana taba cum.
The Essay on Plant Pigment Chromatography
1. Describe what each of your chromatography strips looked like. Specifically, identify the pigments on each strip and compare their positions to one another. Plants have four types of pigments, namely chlorophyll, carotenoids, anthocyanins, and xanthophylls. These pigments have different polarities and chemical properties. In paper chromatography, the pigments will separate based on their ...
Expression of R caused augmented anthocyanin pigmentation in both plant species and augmented trichome (hair) production in Arabidopsis” (p. 1773), but C 1 had no effect alone. Expression of both in Arabidopsis resulted in expression of anthocyanins in tissues that normally contain none, such as root, petal and stamen tissues. In more recent research, Walker, Davison, Bolognese-Winfield, James, Srinivasan, Blundell, Esch, Marks and Gray (1999), the researchers isolated by positional cloning the transparent testa gla bra 1 (TTG 1) locus they had previously determined as regulating development of anthocyanins in Arabidopsis.
