Although the
replication and
transcription of
DNA is highly standardized in
eukaryotes, the same cannot be said for their karyotypes, which are highly variable. There is variation between species in chromosome number, and in detailed organization, despite their construction from the same
macromolecules. This variation provides the basis for a range of studies in evolutionary
cytology. In some cases there is even significant variation within species. In a review, Godfrey and Masters conclude: Although much is known about karyotypes at the descriptive level, and it is clear that changes in karyotype organization has had effects on the evolutionary course of many species, it is quite unclear what the general significance might be.
Changes during development Instead of the usual gene repression, some organisms go in for large-scale elimination of
heterochromatin, or other kinds of visible adjustment to the karyotype. • Chromosome elimination. In some species, as in many
sciarid flies, entire chromosomes are eliminated during development. • Chromatin diminution (founding father:
Theodor Boveri). In this process, found in some
copepods and
roundworms such as
Ascaris suum, portions of the chromosomes are cast away in particular cells. This process is a carefully organised genome rearrangement where new telomeres are constructed and certain heterochromatin regions are lost. In
A. suum, all the somatic cell precursors undergo chromatin diminution. •
X-inactivation. The inactivation of one X chromosome takes place during the early development of mammals (see
Barr body and
dosage compensation). In
placental mammals, the inactivation is random as between the two Xs; thus the mammalian female is a mosaic in respect of her X chromosomes. In
marsupials it is always the paternal X which is inactivated. In human females some 15% of somatic cells escape inactivation, and the number of genes affected on the inactivated X chromosome varies between cells: in
fibroblast cells up about 25% of genes on the Barr body escape inactivation.
Number of chromosomes in a set A spectacular example of variability between closely related species is the
muntjac, which was investigated by
Kurt Benirschke and
Doris Wurster. The diploid number of the Chinese muntjac,
Muntiacus reevesi, was found to be 46, all
telocentric. When they looked at the karyotype of the closely related Indian muntjac,
Muntiacus muntjak, they were astonished to find it had female = 6, male = 7 chromosomes. The number of chromosomes in the karyotype between (relatively) unrelated species is hugely variable. The low record is held by the
nematode Parascaris univalens, where the
haploid n = 1; and an ant:
Myrmecia pilosula. The high record would be somewhere amongst the
ferns, with the adder's tongue fern
Ophioglossum ahead with an average of 1262 chromosomes. Top score for animals might be the
shortnose sturgeon Acipenser brevirostrum at 372 chromosomes. The existence of supernumerary or
B chromosomes means that chromosome number can vary even within one interbreeding population; and
aneuploids are another example, though in this case they would not be regarded as normal members of the population.
Fundamental number The fundamental number,
FN, of a karyotype is the number of visible major chromosomal arms per set of chromosomes. Thus, FN ≤ 2 × 2n, the difference depending on the number of chromosomes considered single-armed (
acrocentric or
telocentric) present. Humans have FN = 82, due to the presence of five acrocentric chromosome pairs:
13,
14,
15,
21, and
22 (the human
Y chromosome is also acrocentric). The fundamental autosomal number or autosomal fundamental number,
FNa or
AN, of a karyotype is the number of visible major chromosomal arms per set of
autosomes (non-
sex-linked chromosomes).
Ploidy Ploidy is the number of complete sets of chromosomes in a cell. •
Polyploidy, where there are more than two sets of homologous chromosomes in the cells, occurs mainly in plants. It has been of major significance in plant evolution according to
Stebbins. The proportion of flowering plants which are polyploid was estimated by Stebbins to be 30–35%, but in grasses the average is much higher, about 70%. Polyploidy in lower plants (
ferns,
horsetails and
psilotales) is also common, and some species of ferns have reached levels of polyploidy far in excess of the highest levels known in flowering plants. Polyploidy in animals is much less common, but it has been significant in some groups.Polyploid series in related species which consist entirely of multiples of a single basic number are known as
euploid. •
Haplo-diploidy, where one sex is
diploid, and the other
haploid. It is a common arrangement in the
Hymenoptera, and in some other groups. •
Endopolyploidy occurs when in adult
differentiated tissues the cells have ceased to divide by
mitosis, but the
nuclei contain more than the original
somatic number of
chromosomes. In the
endocycle (
endomitosis or
endoreduplication) chromosomes in a 'resting' nucleus undergo
reduplication, the daughter chromosomes separating from each other inside an
intact nuclear membrane.In many instances, endopolyploid nuclei contain tens of thousands of chromosomes (which cannot be exactly counted). The cells do not always contain exact multiples (powers of two), which is why the simple definition 'an increase in the number of chromosome sets caused by replication without cell division' is not quite accurate.This process (especially studied in insects and some higher plants such as maize) may be a developmental strategy for increasing the productivity of tissues which are highly active in biosynthesis.The phenomenon occurs sporadically throughout the
eukaryote kingdom from
protozoa to humans; it is diverse and complex, and serves
differentiation and
morphogenesis in many ways.
Aneuploidy Aneuploidy is the condition in which the chromosome number in the cells is not the typical number for the species. This would give rise to a
chromosome abnormality such as an extra chromosome or one or more chromosomes lost. Abnormalities in chromosome number usually cause a defect in development.
Down syndrome and
Turner syndrome are examples of this. Aneuploidy may also occur within a group of closely related species. Classic examples in plants are the genus
Crepis, where the gametic (= haploid) numbers form the series x = 3, 4, 5, 6, and 7; and
Crocus, where every number from x = 3 to x = 15 is represented by at least one species. Evidence of various kinds shows that trends of evolution have gone in different directions in different groups. In primates, the
great apes have 24x2 chromosomes whereas humans have 23x2.
Human chromosome 2 was formed by a merger of ancestral chromosomes, reducing the number.
Chromosomal polymorphism Some species are
polymorphic for different chromosome structural forms. The structural variation may be associated with different numbers of chromosomes in different individuals, which occurs in the ladybird beetle
Chilocorus stigma, some
mantids of the genus
Ameles, the European shrew
Sorex araneus. There is some evidence from the case of the
mollusc Thais lapillus (the
dog whelk) on the
Brittany coast, that the two chromosome morphs are
adapted to different habitats.
Species trees The detailed study of chromosome banding in insects with
polytene chromosomes can reveal relationships between closely related species: the classic example is the study of chromosome banding in
Hawaiian drosophilids by
Hampton L. Carson. In about , the
Hawaiian Islands have the most diverse collection of drosophilid flies in the world, living from
rainforests to
subalpine meadows. These roughly 800 Hawaiian drosophilid species are usually assigned to two genera,
Drosophila and
Scaptomyza, in the family
Drosophilidae. The polytene banding of the 'picture wing' group, the best-studied group of Hawaiian drosophilids, enabled Carson to work out the evolutionary tree long before genome analysis was practicable. In a sense, gene arrangements are visible in the banding patterns of each chromosome. Chromosome rearrangements, especially
inversions, make it possible to see which species are closely related. The results are clear. The inversions, when plotted in tree form (and independent of all other information), show a clear "flow" of species from older to newer islands. There are also cases of colonization back to older islands, and skipping of islands, but these are much less frequent. Using
K-Ar dating, the present islands date from 0.4 million years ago (mya) (
Mauna Kea) to 10mya (
Necker). The oldest member of the Hawaiian archipelago still above the sea is
Kure Atoll, which can be dated to 30 mya. The archipelago itself (produced by the
Pacific Plate moving over a
hot spot) has existed for far longer, at least into the
Cretaceous. Previous islands now beneath the sea (
guyots) form the
Emperor Seamount Chain. All of the native
Drosophila and
Scaptomyza species in Hawaii have apparently descended from a single ancestral species that colonized the islands, probably 20 million years ago. The subsequent
adaptive radiation was spurred by a lack of
competition and a wide variety of
niches. Although it would be possible for a single
gravid female to colonise an island, it is more likely to have been a group from the same species. There are other animals and plants on the Hawaiian archipelago which have undergone similar, if less spectacular, adaptive radiations.
Chromosome banding Chromosomes display a banded pattern when treated with some stains. Bands are alternating light and dark stripes that appear along the lengths of chromosomes. Unique banding patterns are used to identify chromosomes and to diagnose chromosomal aberrations, including chromosome breakage, loss, duplication, translocation or inverted segments. A range of different chromosome treatments produce a range of banding patterns: G-bands, R-bands, C-bands, Q-bands, T-bands and NOR-bands. == Depiction of karyotypes ==