1. LON-CAPA Logo
  2. Help
  3. Log In
 

C-Fern Logo  C-Fern
C O N T E N T S
C-Fern Home
Web Manual
  Introduction
  C-Fern Nutrient Medium
  Culture Conditions
  Gametophyte Culture
  Gametophyte Observations
  Sporophyte Culture
  Spore Mutagenesis
  Bibliography

Other Resources

  Light Stand
  Growth Pod
  DNA Extraction
  C-Fern T-shirt
  Who's Who
  Selection and mutants
  Media formulation error
  Image gallery
Web Journal
Educational Resources
  National Science Standards
  Gametophyte development
  Student research questions
  Research in the classroom
  Research with C-Fern
  Brief description of C-Fern
  C-Fern manipulation
  Root tropism?
Frequently Asked Questions
Workshop and Exhibit Schedule
 Educational Materials
  Investigations
  Mutant & wild type spores
  Manual & Culture Instructions
  Supplies - Domes, media
Have questions?
Contact the C-Fern Project
cfern@utk.edu
 Supported, in part, by the National Science Foundation - Division of Undergraduate Education
Development of C-Fern is supported
by the National Science Foundation (NSF-DUE)
Copyright © 1997-2000
Thomas R. Warne and
Leslie G. Hickok.
All rights reserved.
 Why C-Fern (Ceratopteris)?

  Hermaphroditic and male C-Fern gametophytes
Why would you want to use a fern? The advantages of Ceratopteris as a model plant system derive from the unique features of its life cycle: both haploid and diploid phases exist independently, studies can be undertaken at both the whole plant and cellular level without artificial manipulations of the life cycle, reproduction by means of single celled haploid spores allows for the study/screening of extremely large numbers of individuals in a small space, the haploid/diploid genetic system is very simple and the life cycle (spore-to-spore) takes less than 120 days. Ceratopteris combines the features of both 'higher' and 'lower' plant systems. The developmental simplicity and haploid condition of the gametophyte phase provides opportunities that are not available in angiosperm models. At the same time, the ability to also study any genotype or process within the complex vascular sporophyte phase allows direct comparisons with higher plant systems (e.g., Arabidopsis) that are not possible with developmentally simpler systems such as mosses (e.g., Physcomitrella) or algae.

As an homosporous fern, Ceratopteris has two independent, autotrophic phases: a developmentally simple haploid gametophyte and a vascular diploid sporophyte. The gametophyte phase, which develops after germination of the single-celled spore, can be cultured axenically on a simple inorganic nutrient medium. Development of this haploid phase is very rapid. Germination occurs at three days from inoculation and full sexual maturity is attained within six days from germination.. At maturity, the gametophyte consists of a small (<2 mm), simple two dimensional thallus with rhizoids, vegetative cells and sexual organs (archegonia and antheridia). Sexual differentiation is under the control of a pheromone, ACe (biosynthetically related to GA) and two sexual types exist. In the absence of ACe, gametophytes develop initially as females with archegonia and subsequently as hermaphrodites with both archegonia and antheridia. A meristem region is present and growth is indeterminate until fertilization of an egg occurs via swimming sperm that are released from antheridia in the presence of water. In contrast to females/hermaphrodites, gametophytes developing in the presence of Ace develop into small, determinate males that lack a meristem and produce large numbers of antheridia. The vascular sporophyte stage consists of 5 - 20 cm plants composed of a short upright stem (rhizome) with roots and leaves. In contrast to many ferns, the Ceratopteris sporophyte is not woody and grows rapidly as an annual. Spore production via meiosis occurs within sporangia that are located on the margins of fertile leaves. Upon maturity spore production is continuous and unlimited in number. Because individual haploid gametophytes can be self-fertilized, sporophytes completely homozygous across all genetic loci can be produced in one generation of selfing. Such sporophytes produce an unlimited number of genetically identical spores. Spores remain viable for many years and can be stored at room temperature. Further details about the life cycle and culture of Ceratopteris can be found in the Ceratopteris Bibliography (e.g., Hickok, Warne and Slocum, 1987; Hickok, Warne and Fribourg, 1995).