Sex chromosome


A sex chromosome, is a chromosome that differs from an ordinary autosome in form, size, and behavior. The human sex chromosomes, a typical pair of mammal allosomes, determine the sex of an individual created in sexual reproduction. Autosomes differ from allosomes because autosomes appear in pairs whose members have the same form but differ from other pairs in a diploid cell, whereas members of an allosome pair may differ from one another and thereby determine sex.
Nettie Stevens and Edmund Beecher Wilson both independently discovered sex chromosomes in 1905. However, Stevens is credited for discovering them earlier than Wilson.

Differentiation

In humans, each cell nucleus contains 23 pairs of chromosomes, a total of 46 chromosomes. The first 22 pairs are called autosomes. Autosomes are homologous chromosomes i.e. chromosomes which contain the same genes in the same order along their chromosomal arms. The chromosomes of the 23rd pair are called allosomes consisting of two X chromosomes in most females, and an X chromosome and a Y chromosome in most males. Females therefore have 23 homologous chromosome pairs, while males have 22. The X and Y chromosomes have small regions of homology called pseudoautosomal regions.
The X chromosome is always present as the 23rd chromosome in the ovum, while either an X or a Y chromosome can be present in an individual sperm. Early in female embryonic development, in cells other than egg cells, one of the X chromosomes is randomly and permanently partially deactivated: In some cells the X chromosome inherited from the mother is deactivated, while in others the X chromosome from the father is deactivated. This ensures that both sexes always have exactly one functional copy of the X chromosome in each body cell. The deactivated X-chromosome is silenced by repressive heterochromatin that compacts the DNA and prevents expression of most genes. This compaction is regulated by PRC2.

Sex determination

All diploid organisms with allosome-determined sex get half of their allosomes from each of their parents. In mammals, females are XX, they can pass along either of their X's, and since the males are XY they can pass along either an X or a Y. For a mammal to be female, the individual must receive an X chromosome from both parents, whereas to be male, the individual must receive a X chromosome from their mother and a Y chromosome from their father. It is thus the male's sperm that determines the sex of each offspring in mammals.
However, a small percentage of humans have a divergent sexual development, known as intersex. This can result from allosomes that are neither XX nor XY. It can also occur when two fertilized embryo fuse, producing a chimera that might contain two different sets of DNA one XX and the other XY. It could also result from exposure, often in utero, to chemicals that disrupt the normal conversion of the allosomes into sex hormones and further into the development of either ambiguous outer genitalia or internal organs.

Previous theories on Sex Determination

Ever since the discovery of X-inactivation through research into Calico cats, it has been postulated that X-inactivation plays a role in genetic sex determination in humans. Initially, there were many theories as to how exactly X-inactivation influences sex. To understand one such theory, you can take the following scenario into consideration: a DNA sequence that is concerned with the creation of a male-trait is regulated by a regulatory DNA sequence. If the regulatory DNA sequence allows the main sequence to be expressed, the male-trait will appear in the phenotype, otherwise not. An explanation for this theory is that the X-chromosome simply inactivates in the presence of another X-chromosome; this causes XX-chromosome humans to have a lower frequency of the regulatory gene and so the expression of the male trait is prevented from appearing in the phenotype.

Sex Determination as understood today

Theories like the one above have become redundant now, however. In the past, there wasn't much evidence supporting the idea that X-chromosome inactivation occurred due to dosage compensation. At present, it is believed that one X-chromosome in female humans is inactivated. This leaves only one functioning X-chromosome in both male and female humans, thereby equalizing “dosage.”
But dosage regulation isn't all there is to genetic sex determination. There is a gene in the Y-chromosome that has regulatory sequences that control genes that code for maleness. This gene is called the SRY gene. The SRY sequence's prominence in sex determination was discovered when the genetics of sex-reversed XX men were studied. After examination, it was discovered that the difference between a typical XX individual and a sex-reversed XX man was that the typical individuals lacked the SRY gene. It is theorized that in sex-reversed XX men, the SRY mistakenly gets translocated to an X-chromosome in the XX pair during meiosis. Any how, this experimentation had proved the SRY gene's role in genetic sex determination.

Other vertebrates

It is argued that humans have developed a complex system of genetic sex determination due to their status as highly complex chordates. Lower chordates, such as fish, amphibians and reptiles, have systems that are influenced by the environment. Fish and amphibians, for example, have genetic sex determination but their sex can also be influenced by externally available steroids and incubation temperature of eggs. In reptiles, only incubation temperature determines sex.
Many scientists argue that Sex Determination in flowering plants is more complex than that in humans. This is because even the flowering plant subset has a variety of mating systems. Their Sex Determination is primarily regulated by MADS-box genes. These genes code for proteins that form the sex organs in flowers.
Understanding Sex Determination in other taxonomic groups allows us to understand human Sex Determination better, as well as place humans in the phylogenetic tree more accurately.

Plants

Sex chromosomes are most common in bryophytes, relatively common in vascular plants and unknown in ferns and lycophytes. The diversity of plants is reflected in their sex-determination systems, which include XY and UV systems as well as many variants. Sex chromosomes have evolved independently across many plant groups. Recombination of chromosomes may lead to heterogamety before the development of sex chromosomes, or recombination may be reduced after sex chromosomes develop. Only a few pseudoautosomal regions normally remain once sex chromosomes are fully differentiated. When chromosomes do not recombine, neutral sequence divergences begin to accumulate, which has been used to estimate the age of sex chromosomes in various plant lineages. Even the oldest estimated divergence, in the liverwort Marchantia polymorpha, is more recent than mammal or bird divergence. Due to this recency, most plant sex chromosomes also have relatively small sex-linked regions. Current evidence does not support the existence of plant sex chromosomes more ancient than those of M. polymorpha.
The high prevalence of autopolyploidy in plants also impacts the structure of their sex chromosomes. Polyploidization can occur before and after the development of sex chromsomes. If it occurs after sex chromosomes are established, dosage should stay consistent between the sex chromosomes and autosomes, with minimal impact on sex differentiation. If it occurs before sex chromosomes become heteromorphic, as is likely in the octoploid red sorrel Rumex acetosella, sex is determined in a single XY system. In a more complicated system, the sandalwood species Viscum fischeri has X1X1X2X2 chromosomes in females, and X1X2Y chromosomes in males.
Non-vascular plants
Ferns and lycophytes have bisexual gametophytes and so there is no evidence for sex chromosomes. In the bryophytes, including liverworts, hornworts and mosses, sex chromosomes are common. The sex chromosomes in bryophetes affect what type of gamete is produced by the gametophyte, and there is wide diversity in gametophyte type. Unlike seed plants, where gametophytes are always unisexual, in bryophytes they may produce male, female, or both types of gamete.
Bryophytes most commonly employ a UV sex-determination system, where U produces female gametophytes and V produces male gametophytes. The U and V chromosomes are heteromorphic with U larger than V, and are frequently both larger than the autosomes. There is variation even within this system, including UU/V and U/VV chromosome arrangements. In some bryophytes, microchromosomes have been found to co-occur with sex chromosomes and likely impact sex determination.
Gymnosperms
Dioecy is common among gymnosperms, found in an estimated 36% of species. However, heteromorphic sex chromosomes are relatively rare, with only 5 species known as of 2014. Five of these use an XY system, and one uses a WZ system. Some gymnosperms, such as Johann’s Pine, have homomorphic sex chromosomes that are almost indistinguishable through karyotyping.
Angiosperms
Cosexual angiosperms with either monoecious or hermaphroditic flowers do not have sex chromosomes. Angiosperms with separate sexes may use sex chromosomes or environmental flowers for sex determination. Cytogenetic data from about 100 angiosperm species showed heteromorphic sex chromosomes in approximately half, mostly taking the form of XY sex-determination systems. Their Y is typically larger, unlike in humans; however there is diversity among angiosperms. In the Poplar genus some species have male heterogamety while others have female heterogamety. Sex chromosomes have arisen independently multiple times in angiosperms, from the monoecious ancestral condition. The move from a monoecious to dioecious system requires both male and female sterility mutations to be present in the population. Male sterility likely arises first as an adaptation to prevent selfing. Once male sterility has reached a certain prevalence, then female sterility may have a chance to arise and spread.
In the domesticated papaya, three sex chromosomes are present, denoted as X, Y and Yh. This corresponds with three sexes: females with XX chromosomes, males with XY, and hermaphrodites with XYh. The hermaphrodite sex is estimated to have arisen only 4000 years ago, post-domestication of the plant. The genetic architecture suggests that either the Y chromosome has an X-inactivating gene, or that the Yh chromosome has an X-activating gene.

Medical applications

Allosomes not only carry the genes that determine male and female traits, but also those for some other characteristics as well. Genes that are carried by either sex chromosome are said to be sex linked. Sex linked diseases are passed down through families through one of the X or Y chromosomes. Since usually men inherit Y chromosomes, they are the only ones to inherit Y-linked traits. Men and women can get the X-linked ones since both inherit X chromosomes.
An allele is either said to be dominant or recessive. Dominant inheritance occurs when an abnormal gene from one parent causes disease even though the matching gene from the other parent is normal. The abnormal allele dominates. Recessive inheritance is when both matching genes must be abnormal to cause disease. If only one gene in the pair is abnormal, the disease does not occur, or is mild. Someone who has one abnormal gene is called a carrier. A carrier can pass this abnormal gene to his or her children. X chromosome carry about 1500 genes, more than any other chromosome in the human body. Most of them code for something other than female anatomical traits. Many of the non-sex determining X-linked genes are responsible for abnormal conditions. The Y chromosome carries about 78 genes. Most of the Y chromosome genes are involved with essential cell house-keeping activities and sperm production. Only one of the Y chromosome genes, the SRY gene, is responsible for male anatomical traits. When any of the 9 genes involved in sperm production are missing or defective the result is usually very low sperm counts and infertility. Examples of mutations on the X chromosome include more common diseases such as color blindness, hemophilia, and fragile-X syndrome.
Other complications include: