2011 Group Project 3

From Embryology
Revision as of 12:23, 1 October 2011 by Z3289066 (talk | contribs)
Note - This page is an undergraduate science embryology student group project 2011.
2011 Projects: Turner Syndrome | DiGeorge Syndrome | Klinefelter's Syndrome | Huntington's Disease | Fragile X Syndrome | Tetralogy of Fallot | Angelman Syndrome | Friedreich's Ataxia | Williams-Beuren Syndrome | Duchenne Muscular Dystrolphy | Cleft Palate and Lip


Klinefelter's Syndrome

--Mark Hill 14:36, 8 September 2011 (EST) Good sub-heading structure and overall draft text layout. Some sections very content poor, who was working on Diagnosis and Current Research? In particular where are all the figures???

  • Introduction- you have the content there, but it reads very poorly in structure. You should try and fix this. Remember the introduction is the first thing that people will read. Also good to have some figure to interest the reader. There are also lots of clinical terms that may not be understood by the average undergraduate student.
  • History - There are only 3 worthy features in the history of this disease? You have not done the work here. This should perhaps also be structured as a timeline, bullets date first in bold.
  • Epidemiology - read the first sentence, its not English. The next section also is not very clear. I think this whole section should be looked at again in terms of structure and clarity.
  • Signs and Symptoms - this should illustrate some of these Signs and Symptoms, not the genital features please.
  • Diagnosis - OK this is sort of a description for Karyotyping, but it is not complete or accurate description of the method. Look it up please and fix this.
  • Etiology - this is not a description of non-disjunction, which is what this section should be about.
  • Pathogenesis - first sentence is repetition of previous sections, this should have been fixed by now so that the same content does not appear in multiple sub-headings.
  • Case Study- I don't think you need this section.
  • Other Similar Defects -first identify why they are similar, then explain how you will describe in a table.
  • Current Research - very poor. Who in the group should have done this section?


Introduction

Klinefelter's syndrome, first described in 1942 by Harry F. Klinefelter[1], is caused by the addition of one or more X chromosome(s) in affected males . He depicted a disorder characterised by gynecomastia and a very specific type of hypogonadism, as well as an absence of spermatogenesis.

It is still largely associated with these defects, the most common including reduced fertility and hypogonadism. A high proportion of affected men may remain asymptomatic their whole lives, this is because the severity of the disorder differs greatly from person to person[2].

The extra chromosome present is largely due to a genetic abnormality known as non-disjunction that can occur during either mitosis or [[#Glossary | meiosis], this is described in detail below. It has also been suggested to be the most common disorder associated with non-disjunction [2].

There are a number of diagnostic techniques currently used to determine accurate and early identification of the syndrome. This is particularly useful to encourage the implementation of the best treatment plan to manage the symptoms of the syndrome[3]. The phenotype of the syndrome differs significantly through the different stages of life, and a particular stage will correspond to the best management protocol for that point.


History

Klinefelter syndrome was first described by Harry F. Klinefelter and his colleagues in 1942. Their observations of nine patients where characterised by a number of peculiar symptoms; [[#Glossary | gynecomastia, azoospermia, hyalinised and small testes, absent spermatogenesis, elevated levels of follicle-stimulating hormone (FSH) and hypogonadism. [4] [2].

In 1949, Murray L. Barr and Ewart G. Bertram discovered that patients with Klinefelter’s syndrome had positive sex chromatin material in their epithelial cells, this is normal for females but not in males. [5] It was a dense chromatin mass which they later termed, Barr body. This discovery led to the use of smears of stained buccal mucosal cells which determined whether the infant’s genetic sex matched the phenotypic sex.

The late 1950’s led to a breakthrough in understanding Klinefelter’s syndrome. In 1956, investigations described 7 patients with Klinefelter’s syndrome as a result of the buccal smears that demonstrated Barr bodies. However, the cause of the syndrome remained unknown until 1959, when Jacobs and Strong discovered that a patient with KS had 47 chromosomes, including an extra X chromosome in the karotype of the patient[4]. This discovery confirmed that the Barr body seen in patients with KS corresponds to an extra X chromosome[6]. Harry F. Klinefelter in 1966, reported that the extra X chromosome results from either meiotic non-disjunction or anaphase lag. Anaphase lag describes a chromosome which is not incorporated into the new cell in the second stage of mitosis(anaphase) due to it ‘lagging’, resulting in gametes lacking a sex chromosome[7]. Subsequent studies have shown other aberrations of the X chromosome in KS, these include 48,XXXY and mosaicism.


Studies on inmates in prisons and institutions for mental health revealed an increased risk of psychiatric disorders, mental retardations and criminal behaviour in patients with Klinefelter’s syndrome, these findings were reported by Maclean and Mitchell in 1962[4]. Since the 1960’s, a number of studies have revealed more of Klinefelter syndrome, including the chromosome survey’s that identified unselected newborn babies with sex-chromosome aberrations. These individuals were followed up throughout the 1970s and 1980s, and focused on the development of affected individuals throughout infancy, childhood and adolescence.

The ‘prototypic’ man with KS was initially described as tall, with narrow shoulders, broad hips, sparse body hair, gynecomastia, small testes, androgen deficiency and reduced intelligence[4]. However, a few years after the syndrome was described Heller and Nelson reported that the gynacomastia was not a necessary part of the syndrome, even though it occurred in about 75% of the patients which they observed. The hallmarks of the syndrome were then thought small testes, sterility and increased excretion of follicle stimulating hormone[7]. Extensive studies of these patients during their adolescence illustrated the various personality traits, which can be handled by proper counselling. Similar to today, Harry Klinefelter reported that most patients with this condition were not diagnosed until early adult life, when counselling is may be less rewarding. By the 1960s, there was no treatment for sterility and the treatment for gynecomastia was excision of the tissue with preservation of the nipple[7]. They also treated hypogonadism with injected testosterone, and thought this also aided personality abnormalities in adolescent patients[7].


Below is a timeline highlighting all the major advancements and developments in Klinefelter’s Syndrome.

Timeline

Year
1942 Dr. Harry Klinefelter and his co-workers at Massachusetts General Hospital in Boston published a report on 9 men describing the signs and symptoms of Klinefelter’s Syndrome.
1949 Barr and Bertram noticed positive chromatin material in KS patients.
1956 The discovery of Barr bodies as a result of the new development of Buccal smears
1959 Jacobs and Strong discovered that it was a chromosomal disorder, with the appearance of an extra X chromosome.
1966 Dr. Harry Klinefelter discerns that it is caused from non-disjunction' or an anaphase lag.
1970s A number of centres began screening newborns for sex chromatin abnormalities.


Epidemiology

Figure 2. The emotional response and comprehension of men with Klinefelter’s Syndrome differs from that of normal men

One of the most common disorders of sex chromosomes in humans is Klinefelter’s syndrome, otherwise known as 47,XXY gene mutations. This is prevalent in around 1 in 500 males[8]. There can also be variations of this genetic condition, and these variations are referred to as chromosomal aneuploidies.

The chromosomal variations are present within 1 in 50 000 male births, so are much rarer than 47,XXY mutations. It is said that males born with Klinefelter’s syndrome often go through life without being karyotyped, meaning that they are left undiagnosed[9]. Males born with Klinefelter syndrome often fail to produce sperm, and have very low testosterone levels due to largely to them having small testes. They have increased susceptibility to diabetes, cardiovascular disease and cancer, although it is still unclear why.

In around 80% of cases, the karyotype for Klinefelter’s syndrome is shown in every cell of the body. The age of the mother and father at the time of conceiving a child has no relation at all to whether a child will be born with the condition. The appearance or phenotype of Klinefelter syndrome often becomes evident after puberty. Prior to puberty, the pituitary gland and gonad function is relatively normal in sufferers[2]. Males with Klinefelter’s syndrome generally have IQs which are 10-15 points lower than the general population. Interestingly, these differences in IQ levels were only minor. There is also a decreased head circumference found in XXY males as opposed to normal karyotype males. As well, males with Klinefelter’s syndrome generally have delayed speech development[10]. There is also a higher chance that those affected will experience behavioural problems, possibly due to lower IQ levels.

Figure 3. The average intellect of boys with Klinefelter's Syndrome differs from that of normal males

The vast majority of males are not diagnosed prenatally with Klinefelter’s syndrome. A typical male suffering from Klinefelter’s is characterized by abnormally long legs and arm span, feminine-like distribution of adipose tissue including a condition known as gynecomastia, absent or decreased facial and pubic hair as well as small hyalinized testes and a small penis [11]. There has also been an association hypothesized between tooth size and Klinefelter's syndrome[12]. This could be attributed to a growth gene which may be found in the Y chromosome, as opposed to the X chromosome since females have a smaller crown size than males. Since 47,XXY males have a taller body stature than normal males, it is not a surprise that Klinefelter sufferers have larger tooth sizes.

Seizures can typically occur, and when seizures occur in males with Klinefelter's syndrome, it usually happens between 3 months and 3 years of age. Neuro-imaging tests have failed to identify the cause of the seizures[13]. It is very difficult to diagnose a child with Klinefelter's syndrome immediately, since many of the symptoms that are exhibited in childhood may be due to other factors, such as shyness, stress, and social phobia. Across are two graphs adapted from recent studies which demonstrate both the emotional response to stimuli of men with Klinefelter's syndrome, and the intelligence of males with Klinefelter's syndrome compared to normal males.

Aetiology

Chromosome abnormalities have a high incidence in humans. The most common type is aneuploidy, which is the loss (monosomy) or gain (trisomy) of an entire chromosome [14]. Aneuploidy’s occur in approximately 5% of pregnancies which survive long enough to be seen and approximately 10-25% of all fertilised human oocytes are either monosomic or trisomic [14]. Trisomies are incapable of normal development, the consequences are less severe for the sex chromosomes than the autosomes, leading to enhanced sex chromosomes among live-borns in comparison with autosomal trisomies. Therefore, the 47,XXY condition, termed Klinefelter’s Syndrome (KS) is identified in almost 1 of every 1000 male births, causing it to be one of the most commonly identified chromosome abnormality among live-born individuals.

Non-disjunction

Non-disjunction is the failure of chromosome pairs to separate during the first and second meiotic divisions. Maternal XXY can be caused by non-disjunction during the first and second meiotic divisions, however, XXY of paternal origin can only occur during the first meiotic division. In the great majority of trisomies the additional chromosome is of maternal origin and results from an error during the first meiotic division as seen in figure 1. However, the 47,XXY has been extensively studied and around one half of all cases are paternally derived. The nature of the errors by which maternal and paternal XXYs can arise are extremely diverse. The process of meiosis serves to generate haploid gametes through a specialised cell division process, consisting of two stages of cell division, MI and MII. During prophase of MI the pairs of homologous chromosomes synapse and undergo recombination, with chiasmata being formed at the sites of exchange. Their purpose is to link together the homologues and therefore play a crucial role in the proper disjunction of chromosomes in the first meiotic division[14].

Animation Meiotic Non-disjunction - Meiosis I

Animation Meiotic Non-disjunction - Meiosis II

Genetics

Although many other genes are important for proper sexual development of the male foetus, the SRY (sex-determining region of Y chromosome) gene located on the Y chromosome directs the development of the foetal gonads into testes. Typically, when two or more X chromosomes are present in a cell, as in healthy females or sex chromosome disorders like 47,XXY, only one is active. The additional X chromosome is mostly inactive and the X chromatin is perceived as a Barr body in the periphery of the cell nucleus[15]. In addition to specific regions, both sex chromosomes carry short regions of homology termed pseudoautosomal regions (PAR) [16] which remain active in men and woman [17]. They behave as an autosome and function to allow X and Y chromosomes to pair and properly segregate during meiosis in males. Some genes in the X chromosome which are not homologous to the Y chromosome can escape inactivation and are functionally duplicated in KS males[17].


Pathogenesis

Abnormal chromosome distribution, which leads to Klinefelter’s syndrome, is the result of one of two mechanisms. These are anaphase lagging and non-disjunction. The latter of the two, non-disjunction, takes place more often.[18]

Anaphase Lagging

In the anaphase phase of cell division, spindle fibers attach to sister chromatids and separate them. However, in the abnormal event of anaphase lagging, some spindle fibers are missing. Because of this, sister chromatid will not be successfully separated but together will be incorporated into a single daughter nucleus. As a result, the daughter cell will have a supernumerary chromosome.

Non-disjunction

This more common aberrant cell division takes place during gametogenesis. More specifically, it is the event of the homologous chromosome or sister chromatid failing to separate normally. So like anaphase lagging, the distribution of genetic content in the daughter cells is uneven. Non-disjunction can take place in the first or the second meiotic division. In addition, it can also occur in both of the meiotic division, leading to variants of Klinefelter’s syndrome with a greater number of X chromosomes. Some examples of these variants are 48,XXXY and 48,XXXXY. Furthermore, non-disjunction can also take place in postzygotic division. [19]

As depicted in Figure 5, when non-disjunction takes place in the first meiotic division, a homologous pair of chromosomes is not separated in the anaphase 1. The result is one daughter cell having three chromosomes while the other has only one by the end of meiosis -1. The daughter cell with one chromosome is not viable. When the daughter cell with three chromosomes is followed through meiosis two, its own progeny can be seen to include either a parental and maternal X chromosome or two copies of the maternal X chromosome.

However, if non-disjunction occurs in the second meiotic division, then the abnormal separation of genetic material takes place in anaphase 2. This is seen in Figure 6. By the end of the second meiosis one daughter cell contains both sister chromatids of the maternal X chromosome, while the other daughter cell does not contain that maternal genetic material.

The consequence of non-disjunction is that an XX ovum or a XY sperm will be produced. This gamete will then go on to be fertilised by a normal Y sperm or an X ovum respectively and conclusively produce a XXY zygote, which is the hallmark of Klinefelter’s syndrome.


Signs and Symptoms

Symptoms may differ slightly depending on the stage of development. Screening is recommended when a combination of the following signs of Klinefelter’s syndrome are observed.

Age Signs and Symptoms Image
Birth
  • Cryptorchidism (1 or 2 testes have not dropped into the scrotum from the abdominal cavity)
  • Small penis
  • Hypotonia (reduced muscle tone)
  • Scrotum Bifidus
  • Inguinal Hernia
  • Cleft Palate[20]
Comparing age and intellect of a Klinefelter group and a non-clinical control group
Infancy
  • Learning difficulties (severity is proportional to number of extra X chromosomes)
  • Delayed speech and language deficits
  • Motor delay or dysfunction
  • Attention deficits
  • Small penis and testes
  • Long limbs[21]
Childhood
  • Small, firm testicles
  • Verbal cognitive deficits
  • Speech difficulties
  • Trouble with spelling, reading and mathematics
  • Mood and Behavioral problems
  • Difficulty expressing feelings and socializing[22]
Puberty
  • gynecomastia (enlarged breasts)
  • Long limbs but short trunk
  • Above average, accelerated height
  • Reduced muscle bulk
  • Scarce facial and body hair
  • Delayed or incomplete pubertal development
  • Low energy levels
File:Pubertal gynecomastia.jpg
Pubertal gynecomastia
Adulthood
  • Other mental difficulties (eg. unable to make plans or solve problems)
  • Osteoporosis (due to decreased bone mineral density) [23]
  • Low testosterone levels
  • Infertility due to a lack of sperm
  • Under average testicular volume
  • Problem with penile erection
  • Decreased Libido (sexual desire)


Diagnosis

Karyotype

Karyotyping is a process where the number of chromosomes and their structures are observed for any abnormalities. In a healthy male subject, the karyotype analysis will show 46,XY. But in a Klinefelter's syndrome patient, the karyotype is often observed to be 47,XXY. The featured image is an example of a typical karyotype of a Klinefelter's syndrome patient.

Movie on the process of karyotyping

Statistics

The chances of diagnosing KS are, unfortunately, very low. In one study, only 36% of KS patients are diagnosed, of which 10% of the KS patients being diagnosed prenatally and 26% post natally. This shows that diagnosis methods are not easily accessed and performed. [24]

Prenatal Diagnosis methods

Prenatal diagnosis is most common achieved by two methods, either by amniocentesis or chorionic villus sampling (CVS). As both are invasive procedures, they have considerable risks. Most often these diagnosis methods are performed because other genetic defects are suspected, such as Down ’s syndrome, because of an advanced maternal age. Therefore, the diagnosis of KS is often considered a chance finding.

Amniocentesis can be done from approximately 14 weeks gestation, it involves the sampling of amniotic fluid. The amniotic fluid contains fetal DNA and cells, proving very useful for such testing.

Karyotype of Klinefelter's Syndrome

A needle is passed into the mother’s abdomen and into the amniotic cavity. This process is always used in conjunction with an ultrasound, to ensure the best conditions are available, ie fetal position in womb. [25]

For CVS, a catheter is passed through the mother’s vagina and into the uterus using ultrasound imaging. From here, cells from the chorionic placenta can be sampled for future testing. This can be carried out in the first trimester of pregnancy, a significant benefit over amniocentesis. However, there is a risk of miscarriage with this test, especially when compared to the process amniocentesis. [26]

The cells from both samples are then cultured until there are sufficient numbers of cells. An enzyme is then added that halts proliferation at a point when the chromosomes are condensed. These chromosomes are then stained and, using a light microscope, any abnormalities can be identified. [27]

Diagnosis at birth

Although this rarely takes place, some clinical features may make physicians suspect and ask for a karyotype analysis. Some abnormalities include:

• genital abnormalities (eg. cryptorchidism, small penis, scrotum bifidus and hypospadias)

• fifth finger clinodactyly

• cleft palate

• inguinal hernia [28]

Postnatal Diagnosis Methods

FISH showing the number of X chromosomes within a nuclei

Postnatal diagnositic test for Klinefelter’s syndrome are often performed because physicians may suspect it because of clinical findings. As described in the ‘Signs and Symptoms’ section, some clinical findings may include patients suffering from infertility, learning disabilities and osteoporosis. Furthermore, a blood test of a Klinefelter’s syndrome patient may show high levels of follicle stimulating hormone, luteinizing hormone and low levels of testosterone. [29]

Postnatal karyotyping is a process where a blood sample is analysed. Leukocytes from the patient’s blood sample are separated and then cultured. They are halted in the cell cycle when the chromosomes are condensed and can be stained. A photograph is taken of the chromosomes from one cell. Then they are organized according to size, number and structure and then observed for abnormalities.[30][31]

Management

Androgen Therapy

Androgen therapy involves the replacement of testosterone. This is primarily given to stimulate the onset of puberty in affected males. Ideally, testosterone is given from the age that puberty usually occurs, in order to encourage normal development. In addition to this, it assists in treating or preventing some of the more typical clinical presentations of this disorder. Testosterone replacement encourages secondary sexual attributes, and helps ensure standard bone and muscle mass[32].

Samango-Sprouse et al found that the initiation of androgen therapy early in life was highly associated with improvments in speech and cognition, and other neurogical development. This research was based around children with severe Klinefelter's syndrome - 49,XXXXY. This gives much hope to the prospect of early treatment resulting in normal development of those afflicted with Klinefelter's syndrome. [33]

Action of Inhibitors on the Conversion of Testosterone to Estradiol

However, it has also been associated with a decrease in fertility, especially if given early in life. Premature treatment has been suggested to result in delayed puberty and abnormal physical development during this period[34]. It is also recommended to stop testosterone replacement a few months prior to the administration of infertility treatment[34].

Fertility

Aromatase inhibitors can be administered to men, in order to lower intratesticular estradiol levels. This is thought to encourage the production of testosterone and activate spermatogenesis[35]. There are two main methods used to treat non-obstructive azoospermia, microdissection testicular sperm extraction (TESE) and conventional TESE. These are methods of extracting what sperm is present in the testes for use in in vitro fertilisation (IVF). It has been shown that microdissection TESE has a higher rate of extraction, and allows for minial testicular damage[36], and so conventional TESE is slowly being replaced by microdissection TESE. The most common IVF technique used in these situations is intracytoplasmic sperm injection, where a single sperm is injected into a single oocyte. This means that for the highest chance of success, the extraction of both the sperm and the egg need to be well timed[37]. Before surgery, men are usually administered aromatase inhibitors for a few months. This is to restore the ratio of testoserone to esradiol back to normal levels, and to encourage the amount of viable sperm present[35][38].


Other Similar Defects

Abnormality Description Similarities Differences Image
Turner Syndrome (XO) This is a condition where a female only has one sex chromosome (45,XO). Girls with Turner syndrome lack certain characteristics, such as full grown ovaries, metabolic problems, short stature and decreased life expectancy [39].

In embryology, the embryo may present with a web-like neck, low birth length and lymphedema of the dorsum of hands and feet. There may also be a delay in puberty because of gonadal dysgenesis. As well as all this, there may also be congenital defects of the heart, kidney and autoimmune system [40].

  • Abnormal karyotype
  • People are also generally infertile
  • The phenotype of is very variable, in that girls may present with the standard symptoms from it as aforementioned, or they may be asymptomatic and blend in with the rest of the population
  • People with Klinefelter’s and Turners may both have learning difficulties, and difficulties with social interaction [41]
  • Results from the loss of a chromosome, as opposed to the addition of a chromosome
  • Many females with Turner’s syndrome have normal intelligence, whereas males with Klinefelter’s syndrome tend to have slightly below average intelligence
Immunoglobulin levels in 15 Turner girls. The shaded boxes indicate the 95% confidence interval for the 5–20 years age group. Girls with recurrent otitis media are illustrated with open symbols (n = 8) and those who are otitis free with filled symbols (n = 7)
47,XYY This is a condition where a male inherits an extra Y chromosome. The additional Y chromosome is from the father (paternal origin) and there is existing evidence that spermatocytes with additional Y chromosomes are selected against during gametogenesis [42]. This condition only affects males.

This condition is not usually passed on from parents to offspring, and it has been shown that the sperm of 47,XYY males has the normal karyotype [43].

  • Results from the addition of a chromosome
  • Boys have an increased risk of having learning difficulties which could begin in their early childhood
  • Boys with 47,XYY may have a slightly lower IQ than their peers
  • The condition is completely asymptomatic in most cases, this is the reason for the debate regarding whether it should be termed a ‘syndrome’
  • Boys with 47,XYY Syndrome are fertile and produce normal testosterone levels
  • Boys with 47,XYY syndrome tend to have some impairment in language development, albeit minor, whereas boys with Klinefelter’s syndrome have some form of motor impairment function [44]
Karyogram of male with 47,XYY Syndrome
48,XXYY 48,XXYY, frequently referred to as another variant of Klinefelter’s syndrome, is an anomaly whereby males have an extra X and Y chromosome. Sometimes, renal clearance can be affected by this condition. This is caused by low levels of serum urate in conjunction with high levels of renal urate clearance [45].
  • The physical phenotype of the condition is very similar to Klinefelter’s Syndrome, since males have a tall stature, have learning disabilities and are infertile [46]
  • In some cases, signs of acromegaly have been seen in some patients with this variant, as demonstrated in a study of a 24 year old male living in Japan [47]
Male with 48,XXYY Syndrome


Current Research

Neural systems for social cognition in Klinefelter syndrome (47,XXY): evidence from fMRI; 2011

It is suggested that the addition of an X chromosome has a significant impact on neural systems. The X chromosome contains a large number of genes responsible for neural system development, and so Klinefelter's syndrome was the ideal model for the observation of neural development abnormalities. van Rijn et al used fMRI (functional magnetic resonance imaging) to observe the activity in specfic parts of the brain. People with Klinefelter's syndrome are generally socially disadvantaged, and so a link was investigated between neural activity and social cues.

It was found that Klinefelter's syndrome can be associated with decreased activity in specific neural systems. This also advocates the possibility of using Klinefelter's syndrome as a model for further study of the X chromosome. [48]


Insights into the pathogenesis of XXY phenotype from comparison of the clinical syndrome with an experimental XXY mouse model; 2010

Even after all we now know about Klinefelter's syndrome, a lot still remains a mystery. This is particularly due to the absence of a commonly used animal model. Lue et al investigated the ultimate similarities of a mouse 41,XXY model (as opposed to the human 47,XXY), and it's use in further research. It is important to have an animal model that largely resembles the human syndrome or disease. Lue et al used this model to compare phenotypic similaries between the two, in regards to hormonal imbalances and effect of additional X chromosome genes.

By the comparison of the animal model and human representative, they found that clinical symptoms and phenotype typical in Klinefelter's syndrome are likely due to an avoidance of the inactivation of the X chromosome. [49]


Expression of selected genes escaping from X inactivation in the 41, XXY* mouse model for Klinefelter’s syndrome; 2010

It still remains a debate as to the exact molecular and genetic actions that result in the presentation of Klinefelter's syndrome. It has been suggested that some of the genes on the X chromosome escape inactivation and so result in the clinical symptoms of Klinefelter's syndrome. Werler et al explored this theory using two mouse models (41,XXY and 41,XXY*) and epigenetics. Out of the genes that were obseved in this study, they all seemed to undergo escape from X chromosome inactivation similarly to female mice.

There were also noticable tissue differences, wherein gene expression in the brain was significantly different to that of the liver and kidney. In the brain there was substantial upregulation of these "X-linked excapee genes". This is suggested to directly affect the phenotypic presentation of 47,XXY syndrome. [50]

Glossary

--Mark Hill 07:50, 15 September 2011 (EST) Try bullet listing your glossary it looks neater and maybe remove the letter sub-headings it is too spread out on the project page, up to you.


  • Acromegaly - This is a condition caused by abnormal hormone production from the pituitary gland, resulting in altered growth of hands, feet, and face
  • Androgen - A male sex hormone, ie testosterone
  • Aneuploidy - Abnormal number of chromosomes
  • Azoospermia - Occurs when males have little to no motile sperm in the semen
  • Barr bodies - Inactivated X chromosome in females due to sex being determined by W or Y chromosomes instead of XY
  • Buccal mucosal cells - Cells of the oral cavity that secrete mucus
  • Chromatin - The genetic material that forms chromosomes, it is also composed of DNA
  • Dysgenesis - Defective or abnormal development of an organ, especially of the gonads
  • Gametogenesis - Biological process by which haploid or diploid cells undergo division and/or differentiation to form mature haploid gametes.
  • Gonadotropin - Protein hormones secreted by gonadotrope cells of the pituitary gland.
  • Gynecomastia - Is the abnormal development of large mammary glands in males which give large breasts.
  • Hyalinised - The state of something being hyaline (clear and translucent)
  • Hypogonadism - Occurs when the sex glands produce little to no hormones.
  • In vitro fertilisation - The process of fertilising an oocyte by sperm outside the womb.
  • Karyotype - Number and/or appearances of chromosomes in a eukaryotic cell nucleus
  • Leukocytes - White blood cells which are cells of the immune system
  • Meiosis - The process of cell division of germ (sex) cells resulting in 4 daughter cells.
  • Mosaicism - The presence of two or more genetically different cells in one organism
  • Non-disjunction - The failure of chromosomes to separate properly during cell division. This results in abnormal chromosome number in daughter cells.
  • Pituitary gland - Endocrine gland that secretes hormones that regulate homeostasis.
  • Post zygotic non-disjunction - This occurs when chromosomes do not separate during mitosis, and the cells are not removed by the usual 'proof-reading' mechanisms.
  • Seminiferous tubule - Long, thread like tubes found in the testes and are the specific location of meiosis in the body.
  • Sertoli cells - Cell of the testes that is part of the seminiferous tubule. It is activated by Follicle Stimulating Hormone
  • Spermatogenesis - Process by which male germ cells undergo division and produce a number of cells referred to as spermatogonia, through which spermatocytes are derived from.


References

--Mark Hill 00:25, 15 September 2011 (EST) You need to fix your referencing so that multiple entries for the same reference are not listed here (see ref 18 which I have amended in the text).

  1. Klinefelter HF, Reifenstein EC & Albright F. Syndrome characterized by gynecomastia, aspermatogenesis without a-Leydigism, and increased excretion of follicle-stimulating hormone. American Journal of Clinical Dermatology 1942; 2: 615–627.
  2. 2.0 2.1 2.2 2.3 <pubmed>21397196</pubmed>
  3. <pubmed>20392711</pubmed>
  4. 4.0 4.1 4.2 4.3 <pubmed>17415352</pubmed>
  5. <pubmed>15729733</pubmed>
  6. <pubmed> 13632697</pubmed>
  7. 7.0 7.1 7.2 7.3 <pubmed>3529433</pubmed>
  8. <pubmed>17062147</pubmed>
  9. <pubmed>9160389</pubmed>
  10. <pubmed>7065696</pubmed>
  11. <pubmed>12574191</pubmed>
  12. <pubmed>1686171</pubmed>
  13. <pubmed>20438626</pubmed>
  14. 14.0 14.1 14.2 <pubmed>12926525</pubmed>
  15. 21521364</pubmed>
  16. <pubmed> 20228051</pubmed>
  17. 17.0 17.1 <pubmed>21521364</pubmed>
  18. Cynthia M. Smyth, William J. B. Klinefelter Syndrome Arch Intern Med. 1998;158:1309-1314
  19. Bandmann, H. J., Breit, R., & Perwein, E., (1984). Genetics and Cytogenetics of Klinefelter's Syndrome: Karyotype of Klinefelter's Syndrome and Its Variants. In H. J. Bandmann, B. Reinhardt, & E. Perwein, Klinefelter's Syndrome (1, pp. 1-229). New York, America: Springer-Verlag.
  20. http://www.genome.gov/19519068
  21. http://emedicine.medscape.com/article/945649-clinical#a0217
  22. Schlatt S, Hillier SG &Foresta C, Klinefelter’s syndrome: from chromosome to clinic Molecular Human Reproduction 2010;16: 373– 374
  23. Daniel JW, MAJ, MC, USAF, and Maximilian M, M.D. Klinefelter Syndrome Am Fam Physician. 2005 Dec 1;72(11):2259-2262.
  24. Abramsky L, Chapple J. 47,XXY (Klinefelter syndrome) and 47,XYY: estimated rates of and indication for postnatal diagnosis with implications for prenatal counselling. Prenat Diagn 1997;17:363 – 368
  25. <pubmed>15758614</pubmed>
  26. <pubmed>21413037</pubmed>
  27. <pubmed>135003</pubmed>
  28. Lee YS, Wai Fun Cheng A, Ahmed SF, Shaw JN, Hughes AI. Genital anomalies in Klinefelter’s Syndrome. Horm Res 2007;68:150 – 155.
  29. http://tidsskriftet.no/article/1695231 Week. 11 - 29 May 2008 Journal of Medical Unite 2008: 128:1281-3
  30. <pubmed>15183749</pubmed>
  31. http://www.genome.gov/19519068
  32. <pubmed>20482304</pubmed>
  33. <pubmed>21362043</pubmed>
  34. 34.0 34.1 <pubmed>18832949</pubmed>
  35. 35.0 35.1 <pubmed>11792932</pubmed>
  36. <pubmed>21811543</pubmed>
  37. <pubmed>21716935</pubmed>
  38. <pubmed>19616796</pubmed>
  39. <pubmed>21454226</pubmed>
  40. <pubmed>21271130</pubmed>
  41. <pubmed>21818630</pubmed>
  42. <pubmed>10545600</pubmed>
  43. <pubmed>18037669</pubmed>
  44. <pubmed>20014371</pubmed>
  45. <pubmed>3714610</pubmed>
  46. <pubmed>18481271</pubmed>
  47. <pubmed>8389624</pubmed>
  48. <pubmed>21737434</pubmed>
  49. <pubmed>21217605</pubmed>
  50. <pubmed>21241365</pubmed>

2011 Projects: Turner Syndrome | DiGeorge Syndrome | Klinefelter's Syndrome | Huntington's Disease | Fragile X Syndrome | Tetralogy of Fallot | Angelman Syndrome | Friedreich's Ataxia | Williams-Beuren Syndrome | Duchenne Muscular Dystrolphy | Cleft Palate and Lip