From Wikipedia,
the free encyclopedia
The C-value enigma is a
term used to describe the complex
puzzle surrounding the extensive
variation in nuclear
genome size among
eukaryotic species. At the
center of the C-value enigma is
the observation that genome size
does not correlate with organismal
complexity. For example, many
plant species and some
single-celled
protists, have genomes much
larger than
humans.
Origin
The term "C-value enigma"
represents an update of the more
common but outdated term "C-value
paradox" (Thomas 1971), being
ultimately derived from the term "C-value"
(Swift 1950) in reference to
haploid
nuclear
DNA contents. The term was
coined by Canadian biologist
Dr. T. Ryan Gregory of the
University of Guelph in
2000/2001. In general terms, the
C-value enigma relates to the
issue of variation in the amount
of
non-coding DNA found within
the
genomes of different
eukaryotes.
The C-value enigma, unlike the
older C-value paradox, is
explictly defined as a series of
independent but equally important
component questions, including:
1) What types of
non-coding DNA are found in
different eukaryotic genomes, and
in what proportions?
2) From where does this
non-coding DNA come, and how is it
spread and/or lost from genomes
over time?
3) What effects, or
perhaps even functions, does this
non-coding DNA have for
chromosomes,
nuclei,
cells, and
organisms?
4) Why do some species
exhibit remarkably streamlined
chromosomes, while others possess
massive amounts of non-coding DNA?
Puzzle versus paradox
Although it refers to a
different problem (which has since
been solved), the term "C-value
paradox" is still commonly
used in reference to one or more
of the component questions of the
C-value enigma. The term C-value
enigma is preferred because it
explicitly includes all of the
questions that will need to be
answered if a complete
understanding of
genome size
evolution is to be achieved
(Gregory 2005). Moreover, the term
paradox implies a lack of
understanding of one of the most
basic features of eukaryotic
genomes: namely that they are
composed primarily of
non-coding DNA. It also has
the unfortunate tendency to lead
authors to seek simple
one-dimensional solutions to what
is, in actuality, a multi-faceted
puzzle. For these reasons, in 2003
the term "C-value enigma" was
endorsed in preference to "C-value
paradox" at the
Second Plant Genome Size
Discussion Meeting and Workshop
at the
Royal Botanic Gardens, Kew,
UK, and an increasing number
of authors have begun adopting the
more accurate term.
References
Gregory, T.R. 2000. Nucleotypic
effects without nuclei: genome
size and erythrocyte size in
mammals. Genome 43:
895-901.
Gregory, T.R. 2001.
Coincidence, coevolution, or
causation? DNA content, cell size,
and the C-value enigma.
Biological Reviews 76: 65-101.
Gregory, T.R. 2005. Genome size
evolution in animals. In
The Evolution of the Genome
(ed. T.R. Gregory), pp. 3-87.
Elsevier, San Diego.
Swift, H. 1950. The constancy
of desoxyribose nucleic acid in
plant nuclei. Proceedings of
the National Academy of Sciences
of the USA 36: 643-654.
Thomas, C.A. 1971. The genetic
organization of chromosomes.
Annual Review of Genetics 5:
237-256.
