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X-inactivation
- antisense
- autosome
- autosomes
- Barr body
- BioEssays
- blastocyst
- cell cycle
- cell nucleus
- DAPI
- DNA
- DNA methylation
- DNA replication
- dosage compensation
- embryo
- epigenetics
- Ernest Beutler
- euchromatin
- eutheria
- female
- gene
- gene expression
- gene product
- gene silencing
- genotype
- germline
- H2AFY
- heterochromatin
- heterozygous
- histone
- histone acetylation
- histone H3
- histone methylation
- human
- Klinefelter syndrome
- long non-coding RNA
- male
- mammal
- marsupial
- Mary F. Lyon
- mosaic (genetics)
- mouse
- Nature (journal)
- NcRNA
- NEJM
- nucleosome
- oocyte
- placenta
- regulatory protein
- RNA
- sex linkage
- Susumu Ohno
- tortoiseshell cat
- Turner syndrome
- X chromosome
- X-linked
- Xist
- Y chromosome
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Biology: X Inactivation in Humans
- Order: Reorder
- Duration: 3:34
- Published: 14 Sep 2010
- Uploaded: 23 Jul 2011
- Author: Mindbitesdotcom
www.mindbites.com for full video
http://wn.com/Biology_X_Inactivation_in_Humans
Calico X Inactivation (random deactivation of an X chromosome)
For those that have been asking...
http://wn.com/Calico_X_Inactivation_random_deactivation_of_an_X_chromosome
Mary Lyon and X-Inactivation
- Order: Reorder
- Duration: 2:54
- Published: 25 Aug 2010
- Uploaded: 20 Nov 2010
- Author: lamusica164
A project done in PAA Biology Senior year about x-inactivation, and the Mary Lyon, the lady who discovered it. Super duper interesting.
http://wn.com/Mary_Lyon_and_X-Inactivation
Circle of Angels Research Fund - Rett Syndrome / Part 2.
- Order: Reorder
- Duration: 5:17
- Published: 03 Mar 2008
- Uploaded: 12 Apr 2011
- Author: SzChristie
Most individuals with Rett syndrome are female. One explanation given for this was that the genetic defect that caused Rett syndrome in females caused embryonic lethality in males (that is, males with disease-causing MECP2 mutations died before they were born). While a plausible hypothesis, more recent research has contradicted this explanation. The incidence of Rett in males is unknown. The severity of Rett syndrome in females can vary depending on the type and position of the MECP2 mutation and the pattern of X-chromosome inactivation. It is generally assumed that 50% of a female's cells use the maternal X chromosome while the other 50% uses the paternal X chromosome (see X-inactivation). However, if most cells in the brain activate the X chromosome with the functional MECP2 allele, the individual will have very mild Rett syndrome; likewise, if most neurons activate the X chromosome with the mutated MECP2 allele, the individual will have very severe Rett syndrome just as males with MECP2 mutations do (as they only have one X chromosome).
http://wn.com/Circle_of_Angels_Research_Fund__Rett_Syndrome_/_Part_2
Nondisjunction, mitochondrial, and Y-linked inheritance
- Order: Reorder
- Duration: 9:46
- Published: 15 Feb 2011
- Uploaded: 27 May 2011
- Author: MurrysPottery
YOU ARE HERE This video discusses nondisjunction, mitochondrial inheritance, X-chromosome inactivation, and Y-linked inheritance.
http://wn.com/Nondisjunction,_mitochondrial,_and_Y-linked_inheritance
ASHG 2010 Mtg.: "DNA Methylation and Evolution of Gene Regulation in Primates" (Athma Pai)
- Order: Reorder
- Duration: 10:40
- Published: 31 Mar 2011
- Uploaded: 20 Apr 2011
- Author: HumanGeneticsSociety
TO VIEW THE FULL WEBCAST OF THIS SESSION, GO TO: www.ashg.org ASHG 2010 Annual Meeting Plenary Session: "DNA Methylation and the Evolution of Gene Regulation in Primates" Speaker: Athma A. Pai, University of Chicago November 3, 2010 (Washington, DC) DESCRIPTION: Modification of DNA by methylation is an important epigenetic mechanism that affects the spatial and temporal regulation of gene expression. While methylation patterns have been described in many contexts within species (for example, across different tissues), the extent to which these signatures are conserved across species has not been well characterized. To this end, we assayed genome-wide DNA methylation patterns in six livers, six hearts, and six kidneys from multiple humans and chimpanzees, using tissue samples for which genome-wide gene expression data are also available. Using the multi-species gene expression and methylation data for over 7000 genes, we were able to study the evolution of gene regulation in the context of conservation or changes in DNA methylation patterns across tissues and species. Overall, we found that inter-tissue methylation patterns are largely conserved between humans and chimpanzees, and we confirmed that hyper-methylation is correlated with decreased gene expression levels regardless of tissues or species. We identified a large number of genes that show differences in expression levels between tissues or across species, which can be explained, at least in part, by corresponding <b>...</b>
http://wn.com/ASHG_2010_Mtg_DNA_Methylation_and_Evolution_of_Gene_Regulation_in_Primates_Athma_Pai
Who the Hell is Michael Noble?
- Order: Reorder
- Duration: 9:38
- Published: 08 Apr 2011
- Uploaded: 22 Jul 2011
- Author: XXYforLIFE
Representations of Klinefelter Syndrome: oiiaustralia.com XXY Phenotypic female: www.annclinlabsci.org OII Says: Quotes from OII Australia: "INTERSEX is not a part of Transgender because intersex is not about gender. Intersex is about anatomical differences in sex." "INTERSEX is not a sexual orientation." "INTERSEX is not a gender nor a gender identity." "INTERSEX is not a medical condition or a disorder or a disability or a pathology or a condition of any sort." X Inactivation, what happens to additional X's in those with them: www.genetics.com.au
http://wn.com/Who_the_Hell_is_Michael_Noble?
Baby X
- Order: Reorder
- Duration: 0:52
- Published: 17 Oct 2009
- Uploaded: 14 Aug 2010
- Author: ChadMiddletonFilms
X inactivation dooms an X chromosome . Hand drawn animation with sharpie marker on index cards. Filmed on Super 8.
http://wn.com/Baby_X
Ernest Beutler Receives Wallace H. Coulter Award for Lifetime Achievement in Hematology
- Order: Reorder
- Duration: 5:25
- Published: 14 Apr 2009
- Uploaded: 30 Nov 2010
- Author: ASHWebmaster
Dr. Ernest Beutler was honored with the Wallace H. Coulter Award for Lifetime Achievement in Hematology at the 2007 American Society of Hematology Annual Meeting. He was a physician-scientist whose career has spanned more than half a century. This is his acceptance speech. Among his many accomplishments, Dr. Beutler made significant contributions to the understanding of the biochemical and genetic causes underlying disorders of the red blood cell, originated the concept of X-chromosome inactivation in human females independently of mouse geneticist Mary Lyon, and provided the first formal proof of this phenomenon, an insight that has become one of the cornerstones of mammalian genetics. He also developed screening tests for the genetic disorders galactosemia and Gaucher disease. Learn more about the life of Dr. Beutler by visiting his Legends in Hematology profile at www.hematology.org
http://wn.com/Ernest_Beutler_Receives_Wallace_H_Coulter_Award_for_Lifetime_Achievement_in_Hematology
Te Kaha Rapata-Apiata - MECP2 DUPLICATION SYNDROME
This video was created based on a child who has MECP2 DUPLICATION SYNDROME. He is only three years old and has alot of difficuties. Now the queastion is... WHAT IS MECP2 DUPLICATION SYNDROME??? The syndrome was first discovered in 2005. The MECP2 Duplication Syndrome is usually caused by duplication of DNA on the Xq28 region of the chromosome. Most reported duplications are sub-microscopic (cannot be seen with a microscope by standard chromosome analysis) and span 0.3 to 4 megabases of DNA in size. Many cases of "functional disomy" of the Xq28 region (meaning an extra copy of the Xq28 region that occurs somewhere other than directly at Xq28) due to chromosome Xq-Yq translocation, chromosome Xq-Xp rearrangements, and chromosome X-autosomal chromosome translocations have also been reported. Many of these cases were reported before the name "MECP2 Duplication Syndrome" was assigned. MECP2 Duplication Syndrome is most commonly inherited in an X-linked manner. Most affected males have inherited the MeCP2 duplication from a carrier mother, however, spontaneous (also known as de novo) duplications have been reported. If the mother has a MECP2 duplication, the chance of transmitting it in each pregnancy is 50%. In the case of de novo duplications, the possibility exists that the mother can have mosaicism and therefore only carry the duplicated X chromosome in her ova or egg cells (or only in some of these cells). Because ova or germ-line mosaicism cannot be ruled out in de novo <b>...</b>
http://wn.com/Te_Kaha_Rapata-Apiata__MECP2_DUPLICATION_SYNDROME
90 07 家國論壇高國清:基因染色體與遺傳病
- Order: Reorder
- Duration: 10:48
- Published: 22 Oct 2009
- Uploaded: 31 Jan 2010
- Author: MeiFengNorway
基因、染色體與遺傳病高國清現任:中國都會網路報業有限公司社長台灣省堪輿地理命理協會榮譽理事長中國全球地理協會榮譽理事長中華民國周易應用文化院總幹事中國共產聯盟常務理事學歷:陽明大學生化暨生物研究所碩士、博士經歷:報社主筆、電視台主播、股市名嘴聯絡:高國清kaokuo7327@yahoo.com.tw 886-937851006 基因X 染色體是許多動物決定性別的染色體。它出現在X0 和XY 性別決定系統中。對一般人類來說,女性有兩條X 染色體,男性X、Y 染色體各有一條。X 染色體是許多動物決定性別的染色體。它出現在X0 和XY 性別決定系統中。對一般人類來說,女性有兩條X 染色體,男性X、Y 染色體各有一條一、人類在人類約兩萬至兩萬五千個基因之中,X染色體約有九百至一千兩百個基因。 一般女性雖然都有兩條X 染色體,但事實上有一條會惰性化,變成巴爾體(Barr body),這個作用稱為X去活性(X inactivation)或里昂化作用(lyonization,以發現者Mary F. Lyon 命名)。(參見:三色貓) 二、疾病有些人的性染色體數目可能異常: ◎ X-三體:女性有三條X 染色體。她們發展較遲緩(但可由後天多加培養而糾正),平均智力為九十,較正常的一百為低。她們能正常生育。較罕見的情況如XXXX 或XXXXX 都有。 ◎ XXY 三體:男性有兩條X 染色體。他們的睪酮水平可能較低,胸部發育接近女性。較罕見的情況如XXXY 或XXXXY 都有。 ◎ 透納氏症(Turner syndrome):女性只有一條X 染色體。她們身材較矮小,性功能不能正常發展。 三、遺傳病X 性聯隱性遺傳病是指只有一個人所有的X 染色體都有帶病基因時才會發生的疾病。男性患上這些疾病的機會都比女性高,因為男性只有一個X 染色體,而女性有兩條。若女性其中一條有帶病基因,另一條可以發揮作用,但可能也會有較輕微的症狀出現,因為在每個細胞內去活性化的X 染色體都是隨機決定 <b>...</b>
http://wn.com/90_07_家國論壇高國清:基因染色體與遺傳病
90 08 家國論壇高國清:基因染色體與遺傳病
- Order: Reorder
- Duration: 10:43
- Published: 22 Oct 2009
- Uploaded: 12 Aug 2010
- Author: MeiFengNorway
基因、染色體與遺傳病高國清現任:中國都會網路報業有限公司社長台灣省堪輿地理命理協會榮譽理事長中國全球地理協會榮譽理事長中華民國周易應用文化院總幹事中國共產聯盟常務理事學歷:陽明大學生化暨生物研究所碩士、博士經歷:報社主筆、電視台主播、股市名嘴聯絡:高國清kaokuo7327@yahoo.com.tw 886-937851006 基因X 染色體是許多動物決定性別的染色體。它出現在X0 和XY 性別決定系統中。對一般人類來說,女性有兩條X 染色體,男性X、Y 染色體各有一條。X 染色體是許多動物決定性別的染色體。它出現在X0 和XY 性別決定系統中。對一般人類來說,女性有兩條X 染色體,男性X、Y 染色體各有一條一、人類在人類約兩萬至兩萬五千個基因之中,X染色體約有九百至一千兩百個基因。 一般女性雖然都有兩條X 染色體,但事實上有一條會惰性化,變成巴爾體(Barr body),這個作用稱為X去活性(X inactivation)或里昂化作用(lyonization,以發現者Mary F. Lyon 命名)。(參見:三色貓) 二、疾病有些人的性染色體數目可能異常: ◎ X-三體:女性有三條X 染色體。她們發展較遲緩(但可由後天多加培養而糾正),平均智力為九十,較正常的一百為低。她們能正常生育。較罕見的情況如XXXX 或XXXXX 都有。 ◎ XXY 三體:男性有兩條X 染色體。他們的睪酮水平可能較低,胸部發育接近女性。較罕見的情況如XXXY 或XXXXY 都有。 ◎ 透納氏症(Turner syndrome):女性只有一條X 染色體。她們身材較矮小,性功能不能正常發展。 三、遺傳病X 性聯隱性遺傳病是指只有一個人所有的X 染色體都有帶病基因時才會發生的疾病。男性患上這些疾病的機會都比女性高,因為男性只有一個X 染色體,而女性有兩條。若女性其中一條有帶病基因,另一條可以發揮作用,但可能也會有較輕微的症狀出現,因為在每個細胞內去活性化的X 染色體都是隨機決定 <b>...</b>
http://wn.com/90_08_家國論壇高國清:基因染色體與遺傳病
90 12 家國論壇高國清:基因染色體與遺傳病
- Order: Reorder
- Duration: 8:55
- Published: 22 Oct 2009
- Uploaded: 15 Jul 2010
- Author: MeiFengNorway
基因、染色體與遺傳病高國清現任:中國都會網路報業有限公司社長台灣省堪輿地理命理協會榮譽理事長中國全球地理協會榮譽理事長中華民國周易應用文化院總幹事中國共產聯盟常務理事學歷:陽明大學生化暨生物研究所碩士、博士經歷:報社主筆、電視台主播、股市名嘴聯絡:高國清kaokuo7327@yahoo.com.tw 886-937851006 基因X 染色體是許多動物決定性別的染色體。它出現在X0 和XY 性別決定系統中。對一般人類來說,女性有兩條X 染色體,男性X、Y 染色體各有一條。X 染色體是許多動物決定性別的染色體。它出現在X0 和XY 性別決定系統中。對一般人類來說,女性有兩條X 染色體,男性X、Y 染色體各有一條一、人類在人類約兩萬至兩萬五千個基因之中,X染色體約有九百至一千兩百個基因。 一般女性雖然都有兩條X 染色體,但事實上有一條會惰性化,變成巴爾體(Barr body),這個作用稱為X去活性(X inactivation)或里昂化作用(lyonization,以發現者Mary F. Lyon 命名)。(參見:三色貓) 二、疾病有些人的性染色體數目可能異常: ◎ X-三體:女性有三條X 染色體。她們發展較遲緩(但可由後天多加培養而糾正),平均智力為九十,較正常的一百為低。她們能正常生育。較罕見的情況如XXXX 或XXXXX 都有。 ◎ XXY 三體:男性有兩條X 染色體。他們的睪酮水平可能較低,胸部發育接近女性。較罕見的情況如XXXY 或XXXXY 都有。 ◎ 透納氏症(Turner syndrome):女性只有一條X 染色體。她們身材較矮小,性功能不能正常發展。 三、遺傳病X 性聯隱性遺傳病是指只有一個人所有的X 染色體都有帶病基因時才會發生的疾病。男性患上這些疾病的機會都比女性高,因為男性只有一個X 染色體,而女性有兩條。若女性其中一條有帶病基因,另一條可以發揮作用,但可能也會有較輕微的症狀出現,因為在每個細胞內去活性化的X 染色體都是隨機決定 <b>...</b>
http://wn.com/90_12_家國論壇高國清:基因染色體與遺傳病
90 09 家國論壇高國清:基因染色體與遺傳病
- Order: Reorder
- Duration: 10:42
- Published: 22 Oct 2009
- Uploaded: 05 Nov 2009
- Author: MeiFengNorway
基因、染色體與遺傳病高國清現任:中國都會網路報業有限公司社長台灣省堪輿地理命理協會榮譽理事長中國全球地理協會榮譽理事長中華民國周易應用文化院總幹事中國共產聯盟常務理事學歷:陽明大學生化暨生物研究所碩士、博士經歷:報社主筆、電視台主播、股市名嘴聯絡:高國清kaokuo7327@yahoo.com.tw 886-937851006 基因X 染色體是許多動物決定性別的染色體。它出現在X0 和XY 性別決定系統中。對一般人類來說,女性有兩條X 染色體,男性X、Y 染色體各有一條。X 染色體是許多動物決定性別的染色體。它出現在X0 和XY 性別決定系統中。對一般人類來說,女性有兩條X 染色體,男性X、Y 染色體各有一條一、人類在人類約兩萬至兩萬五千個基因之中,X染色體約有九百至一千兩百個基因。 一般女性雖然都有兩條X 染色體,但事實上有一條會惰性化,變成巴爾體(Barr body),這個作用稱為X去活性(X inactivation)或里昂化作用(lyonization,以發現者Mary F. Lyon 命名)。(參見:三色貓) 二、疾病有些人的性染色體數目可能異常: ◎ X-三體:女性有三條X 染色體。她們發展較遲緩(但可由後天多加培養而糾正),平均智力為九十,較正常的一百為低。她們能正常生育。較罕見的情況如XXXX 或XXXXX 都有。 ◎ XXY 三體:男性有兩條X 染色體。他們的睪酮水平可能較低,胸部發育接近女性。較罕見的情況如XXXY 或XXXXY 都有。 ◎ 透納氏症(Turner syndrome):女性只有一條X 染色體。她們身材較矮小,性功能不能正常發展。 三、遺傳病X 性聯隱性遺傳病是指只有一個人所有的X 染色體都有帶病基因時才會發生的疾病。男性患上這些疾病的機會都比女性高,因為男性只有一個X 染色體,而女性有兩條。若女性其中一條有帶病基因,另一條可以發揮作用,但可能也會有較輕微的症狀出現,因為在每個細胞內去活性化的X 染色體都是隨機決定 <b>...</b>
http://wn.com/90_09_家國論壇高國清:基因染色體與遺傳病
90 10 家國論壇高國清:基因染色體與遺傳病
- Order: Reorder
- Duration: 10:42
- Published: 22 Oct 2009
- Uploaded: 10 May 2010
- Author: MeiFengNorway
基因、染色體與遺傳病高國清現任:中國都會網路報業有限公司社長台灣省堪輿地理命理協會榮譽理事長中國全球地理協會榮譽理事長中華民國周易應用文化院總幹事中國共產聯盟常務理事學歷:陽明大學生化暨生物研究所碩士、博士經歷:報社主筆、電視台主播、股市名嘴聯絡:高國清kaokuo7327@yahoo.com.tw 886-937851006 基因X 染色體是許多動物決定性別的染色體。它出現在X0 和XY 性別決定系統中。對一般人類來說,女性有兩條X 染色體,男性X、Y 染色體各有一條。X 染色體是許多動物決定性別的染色體。它出現在X0 和XY 性別決定系統中。對一般人類來說,女性有兩條X 染色體,男性X、Y 染色體各有一條一、人類在人類約兩萬至兩萬五千個基因之中,X染色體約有九百至一千兩百個基因。 一般女性雖然都有兩條X 染色體,但事實上有一條會惰性化,變成巴爾體(Barr body),這個作用稱為X去活性(X inactivation)或里昂化作用(lyonization,以發現者Mary F. Lyon 命名)。(參見:三色貓) 二、疾病有些人的性染色體數目可能異常: ◎ X-三體:女性有三條X 染色體。她們發展較遲緩(但可由後天多加培養而糾正),平均智力為九十,較正常的一百為低。她們能正常生育。較罕見的情況如XXXX 或XXXXX 都有。 ◎ XXY 三體:男性有兩條X 染色體。他們的睪酮水平可能較低,胸部發育接近女性。較罕見的情況如XXXY 或XXXXY 都有。 ◎ 透納氏症(Turner syndrome):女性只有一條X 染色體。她們身材較矮小,性功能不能正常發展。 三、遺傳病X 性聯隱性遺傳病是指只有一個人所有的X 染色體都有帶病基因時才會發生的疾病。男性患上這些疾病的機會都比女性高,因為男性只有一個X 染色體,而女性有兩條。若女性其中一條有帶病基因,另一條可以發揮作用,但可能也會有較輕微的症狀出現,因為在每個細胞內去活性化的X 染色體都是隨機決定 <b>...</b>
http://wn.com/90_10_家國論壇高國清:基因染色體與遺傳病
90 11 家國論壇高國清:基因染色體與遺傳病
- Order: Reorder
- Duration: 10:41
- Published: 22 Oct 2009
- Uploaded: 16 Apr 2010
- Author: MeiFengNorway
基因、染色體與遺傳病高國清現任:中國都會網路報業有限公司社長台灣省堪輿地理命理協會榮譽理事長中國全球地理協會榮譽理事長中華民國周易應用文化院總幹事中國共產聯盟常務理事學歷:陽明大學生化暨生物研究所碩士、博士經歷:報社主筆、電視台主播、股市名嘴聯絡:高國清kaokuo7327@yahoo.com.tw 886-937851006 基因X 染色體是許多動物決定性別的染色體。它出現在X0 和XY 性別決定系統中。對一般人類來說,女性有兩條X 染色體,男性X、Y 染色體各有一條。X 染色體是許多動物決定性別的染色體。它出現在X0 和XY 性別決定系統中。對一般人類來說,女性有兩條X 染色體,男性X、Y 染色體各有一條一、人類在人類約兩萬至兩萬五千個基因之中,X染色體約有九百至一千兩百個基因。 一般女性雖然都有兩條X 染色體,但事實上有一條會惰性化,變成巴爾體(Barr body),這個作用稱為X去活性(X inactivation)或里昂化作用(lyonization,以發現者Mary F. Lyon 命名)。(參見:三色貓) 二、疾病有些人的性染色體數目可能異常: ◎ X-三體:女性有三條X 染色體。她們發展較遲緩(但可由後天多加培養而糾正),平均智力為九十,較正常的一百為低。她們能正常生育。較罕見的情況如XXXX 或XXXXX 都有。 ◎ XXY 三體:男性有兩條X 染色體。他們的睪酮水平可能較低,胸部發育接近女性。較罕見的情況如XXXY 或XXXXY 都有。 ◎ 透納氏症(Turner syndrome):女性只有一條X 染色體。她們身材較矮小,性功能不能正常發展。 三、遺傳病X 性聯隱性遺傳病是指只有一個人所有的X 染色體都有帶病基因時才會發生的疾病。男性患上這些疾病的機會都比女性高,因為男性只有一個X 染色體,而女性有兩條。若女性其中一條有帶病基因,另一條可以發揮作用,但可能也會有較輕微的症狀出現,因為在每個細胞內去活性化的X 染色體都是隨機決定 <b>...</b>
http://wn.com/90_11_家國論壇高國清:基因染色體與遺傳病
Regulatory and Epigenetic Landscapes of Mammalian Genomes
February 23, 2010. Laura Elnitski, Ph.D. Current Topics in Genome Analysis 2010 Handout: www.genome.gov More: www.genome.gov
http://wn.com/Regulatory_and_Epigenetic_Landscapes_of_Mammalian_Genomes
Neurobiology of Rett Syndrome and Related Disorders
Air date: Wednesday, June 17, 2009, 3:00:00 PM Timedisplayed is Eastern Time, Washington DC Local Category: Wednesday Afternoon Lectures Description: Rett syndrome is a postnatal developmental disorder characterized by stagnation of normal development and loss of acquired skills by 12-18 months of age. Although Rett syndrome is sporadic in over 99% of the cases, it is a genetic disorder caused by mutations in the X-linked gene encoding methyl-CpG-binding protein 2 (MeCP2). Loss of MeCP2 function in ~50% of neurons (due to random X chromosome inactivation [XCI]), causes classic Rett syndrome which is characterized by loss of language and social interaction skills, cognitive impairment, balance problems, seizures, tremors, stereotyped repetitive hand movements, and autonomic dysfunction. Girls with favorable XCI patterns manifest only partial features of the syndrome and may present with either classic autism or mild mental retardation with or without seizures and tremors. Doubling of MeCP2 levels also causes a progressive neurological syndrome that shows overlapping features with Rett syndrome. The use of accurate genetic models of Rett and the duplication syndrome is providing insight about the pathogenic effects of MeCP2 dysfunction. Data demonstrating the mechanism underlying the duplication phenotype, the role of MeCP2 in specific neurons, and the transcriptional alterations resulting from MeCP2 dysfunction will be presented The NIH Director's Wednesday Afternoon <b>...</b>
http://wn.com/Neurobiology_of_Rett_Syndrome_and_Related_Disorders
Cupcakes as educational aid!
Leilani, Erin, Neena and Britney use cupcakes to explain the role of Jpx in X chromosome inactivation -- cupcakes were then eaten by all!
http://wn.com/Cupcakes_as_educational_aid!
MDS 3.0 Sections X and Z
Please review the RAI Manual for updated requirements for completing an inactivation request. We would like to hear from you. Please send all comments to MDS30Comments@cms.hhs.gov. Thank you for your time.
http://wn.com/MDS_30_Sections_X_and_Z
HHMI - Sexual Evolution: From X to Y (3/6)
- Order: Reorder
- Duration: 9:57
- Published: 07 Nov 2007
- Uploaded: 19 Dec 2010
- Author: BonoboBill
This lecture is one among many provided by the Howard Hughes Medical Institute completely FREE of charge. catalog.hhmi.org The process of becoming a male or a female is complex and intricate. Researchers are gaining intriguing insights into how chromosomes, genes, and molecules are involved in sex determination. Dr. David C. Page explains the role of the human sex chromosomes, describing the evolution of the Y chromosome and the problems that arise in males when portions of the chromosome are deleted.
http://wn.com/HHMI__Sexual_Evolution_From_X_to_Y_3/6
Enzymes III
- Order: Reorder
- Duration: 38:54
- Published: 20 Oct 2010
- Uploaded: 12 Aug 2011
- Author: OregonStateUniv
This course is part of a series taught by Kevin Ahern at Oregon State University on General Biochemistry. For more information about online courses go to ecampus.oregonstate.edu 1. "Perfect" enzymes are enzymes that have evolved to the point where any additional mutation will reduce their ability to catalyze reactions. They are not common. Perfect enzymes have a very high ratio of Kcat/Km and are such that the only thing that inhibits their ability to function more efficiently is the rate of diffusion of substrate in water. 2. Substrate binding to enzymes is relevant to catalysis that we will consider. The first is the category of Sequential Displacement. It has two subsets. a. Random binding - the order of binding multiple substrates is not rigidly set. b. Ordered binding - Simple ordered binding - one substrate binds first followed by another followed by release of product. 3. Note that the models of substrate binding above are all non-covalent. 4. Allosterism is a phenomenon in which a small molecule interacts with a protein and affects the proteins activity. Such an enzyme is an allosteric enzyme. I pointed out the similarity between the kinetics of allosterically acting enzymes and the coopertivity of binding of oxygen by hemoglobin. 5. Lineweaver-Burk plots are alternative plots of V vs S data obtained by taking the inverse of each and plotting it, thus making a 1/V vs 1/[S] plot (also called a double reciprocal plot). 6. On a Lineweaver-Burk plot, the Y intercept <b>...</b>
http://wn.com/Enzymes_III
Bite-Sized Biochemistry #11: Enzymes II
Lecture by Kevin Ahern of Oregon State University discussing Biochemistry Basics in BB 450. See the full course at oregonstate.edu This course can be taken for credit (wherever you live) via OSU's ecampus. For details, see ecampus.oregonstate.edu Download Metabolic Melodies at www.davincipress.com Related courses include BB 350 - oregonstate.edu BB 451 - oregonstate.edu BB 100 - oregonstate.edu Highlights of Enzymes III Lecture 1. "Perfect" enzymes are enzymes that have evolved to the point where any additional mutation will reduce their ability to catalyze reactions. They are not common. Perfect enzymes have a very high ratio of Kcat/Km and are such that the only thing that inhibits their ability to function more efficiently is the rate of diffusion of substrate in water. 2. Substrate binding to enzymes is relevant to catalysis that we will consider. The first is the category of Sequential Displacement. It has two subsets. a. Random binding - the order of binding multiple substrates is not rigidly set. b. Ordered binding - Simple ordered binding - one substrate binds first followed by another followed by release of product. 3. Note that the models of substrate binding above are all non-covalent. 4. Allosterism is a phenomenon in which a small molecule interacts with a protein and affects the proteins activity. Such an enzyme is an allosteric enzyme. I pointed out the similarity between the kinetics of allosterically acting enzymes and the coopertivity of binding of <b>...</b>
http://wn.com/Bite-Sized_Biochemistry_#11_Enzymes_II
photo: US Navy / Bill Black
Rear Adm. Joseph F. Campbell accepts authority of USS Philadelphia (SSN 690) for completion of the final stages of its availability during its inactivation ceremony at Norfolk Naval Shipyard.
photo: US Navy / Photographer's Mate 3rd Class Timothy F. Sosa
The crew of the Los Angeles-class fast attack submarine USS Salt Lake City (SSN 716) stand in ranks during the boats inactivation ceremony.
photo: US Navy / Mass Communication Specialist Seaman Kelvin Edwards
The Los Angeles-class fast attack submarine USS Minneapolis-St. Paul (SSN 708), returns from her final six-month deployment before inactivation.
photo: GFDL / Bios
Medicine
photo: army.mil
1-1 Cav. Cases Colors
photo: GFDL /
GlaxoSmithKline
photo: US Navy / Mass Communication Specialist 3rd Class Kelvin Edwards
Eleven of 12 former commanding officers of the Los Angeles-class fast-attack submarine USS Minneapolis-St. Paul (SSN 708) pose with the submarines current Commanding Officer Cmdr. Woods R. Brown II, right, following an inactivation ceremony.
photo: army.mil
'Blackhawk' Squadron Battles Grafenwoehr's Ranges for Last Time
photo: US AF
End of an era (US AF) KLeo
photo: army.mil
'Blackhawk' Squadron Battles Grafenwoehr's Ranges for Last Time
photo: US Navy / John Narewski
Naval Submarine School Silver Dolphins parade the colors.
photo: US Navy / John Narewski
USS Memphis (SSN 691) transits the Thames River for the final time.
photo: US Navy / John Narewski
USS Memphis (SSN 691) departs Submarine Base New London for the final time.
photo: Creative Commons / Mats Halldin
Navy and Air Force servicemen make early morning security rounds by the radomes at the Misawa Security Operations Cent
photo: US Navy / Mass Communication Specialist 3rd Class Kelvin Edwards
The nuclear-powered attack submarine USS Augusta (SSN 710) arrives at Naval Station Norfolk.
photo: US Navy / John Narewski
Adm. Jonathan W. Greenert compares the advantages of serving on NR-1 to learning to like Lean Cuisine.
photo: US Navy / U.S. Navy photo by John Narewski
The Los Angeles-class attack submarine USS Philadelphia (SSN 690) pulls into Submarine Base New London after returning from her final deployment.
photo: US Navy / U.S. Navy photo by John Narewski
The Los Angeles-class attack submarine USS Philadelphia (SSN 690) pulls into Submarine Base New London after returning from her final deployment.
photo: US Navy / U.S. Navy photo by John Narewski
he Los Angeles-class attack submarine USS Philadelphia (SSN 690) pulls into Submarine Base New London after returning from her final deployment.
photo: US Navy / John Narewski
SS Memphis (SSN 691) passes the Ledge Light lighthouse at the mouth of the Thames River for the final time.
photo: US Navy / Mass Communication Specialist 1st Class Steven Myers
The Los Angeles-class attack submarine USS Philadelphia (SSN 690) transits the Thames River to start her final deployment.
photo: US Navy / Journalist 2nd Class Corwin Colbert
The Los Angeles-class fast attack submarine USS Honolulu (SSN 718) prepares to get underway for its final deployment to the Western Pacific.
photo: US Navy / Mass Communication Specialist 1st Class Cynthia Clark (RELEASED)
USS Minneapolis-St. Paul (SSN 708) returns to Pearl Harbor for the final time.
photo: US Navy / U.S. Navy photo by John Narewski
Sailors aboard the Los Angeles-class attack submarine USS Philadelphia (SSN 690) stand topside as she pulls into Submarine Base New London, returning from her final deployment.
photo: US Navy / Electrician's Mate 2nd Class Xander Gamble
Los Angeles class attack submarine USS Augusta (SSN 710) render honors as the national Ensign is raised as the submarine arrives at Naval Station Norfolk.
photo: Creative Commons / Bwmoll3
Minot Air Force Base
photo: US Navy / Electrician's Mate 2nd Class Xander Gamble
Crew members aboard the Los Angeles class attack submarine USS Augusta (SSN 710) tend the mooring lines as the ship arrives at Naval Station Norfolk.
photo: US Navy / U.S. Navy photo by John Narewski
Machinist's Mate 2nd Class Trevor Fredrick hugs his girlfriend moments after the Los Angeles-class attack submarine USS Philadelphia (SSN 690) pulls into Submarine Base New London.
photo: US Navy / Photographer's Mate 3rd Class Timothy F. Sosa
Electronics Technician 2nd Class Brian Condon hauls down the commissioning pennant for the Los Angeles-class fast attack submarine .
photo: US Navy / U.S. Navy photo by Mass Communication 1st Class Elizabeth Thompson
Cmdr. Steven Harrison addresses spectators and current and former Los Angeles crew members during the boat's decommissioning ceremony.
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X-inactivation
s is a visible manifestation of X-inactivation. The black and orange alleles of a fur coloration gene reside on the X chromosome. For any given patch of fur, the inactivation of an X chromosome that carries one gene results in the fur color of the other, active gene.]] . Bottom: The same nucleus stained with a DNA stain (DAPI). The Barr body is indicated by the arrow, it identifies the inactive X (Xi).]] ) in cell nucleus(left), and to the corresponding X chromatin (right).Left: DNA (DAPI)-stained nucleus. Arrow indicates the location of Barr body(Xi). Right: DNA associated histones protein detected]] images from a combined RNA-DNA FISH experiment for Xist in fibroblast cells from adult female mouse, demonstrating that Xist RNA is coating only one of the X-chromosomes. RNA FISH signals from Xist RNA are shown in red color, marking the inactive X-chromosome (Xi). DNA FISH signals from Xist loci are shown in yellow color, marking both active and inactive X-chromosomes (Xa, Xi). The nucleus (DAPI-stained) is shown in blue color. The figure is adapted from: .]]
X-inactivation (also called lyonization) is a process by which one of the two copies of the X chromosome present in female mammals is inactivated. The inactive X chromosome is silenced by packaging into transcriptionally inactive heterochromatin. X-inactivation occurs so that the female, with two X chromosomes, does not have twice as many X chromosome gene products as the male, which only possess a single copy of the X chromosome (see dosage compensation). The choice of which X chromosome will be inactivated is random in placental mammals such as mice and humans, but once an X chromosome is inactivated it will remain inactive throughout the lifetime of the cell and its descendants in the organism. Unlike the random X-inactivation in placental mammals, inactivation in marsupials applies exclusively to the paternally derived X chromosome.
History
In 1959 Susumu Ohno showed that the two X-chromosomes of mammals were different: one appeared like the autosomes; the other was condensed and heterochromatic. This finding suggested, independently to two groups of investigators, that one of the X-chromosomes underwent inactivation. In 1961, Mary Lyon proposed the random inactivation of one female X chromosome to explain the mottled phenotype of female mice heterozygous for coat color genes. The Lyon hypothesis also accounted for the findings that one copy of the X chromosome in female cells was highly condensed, and that mice with only one copy of the X chromosome developed as infertile females. This suggested to Ernest Beutler, studying heterozygous females for Glucose-6-phosphate dehydrogenase (G6PD) deficiency, that there were two red cell populations of erythrocytes in such heterozygotes: deficient cells and normal cells, depending on whether the inactivated X chromosome contains the normal or defective G6PD allele.
Mechanism
Timing
All mouse cells undergo an early, imprinted inactivation of the paternally-derived X chromosome in two-cell or four-cell stage embryos. The extraembryonic tissues (which give rise to the placenta and other tissues supporting the embryo) retain this early imprinted inactivation, and thus only the maternal X chromosome is active in these tissues.In the early blastocyst, this initial, imprinted X-inactivation is reversed in the cells of the inner cell mass (which give rise to the embryo), and in these cells both X chromosomes become active again. Each of these cells then independently and randomly inactivates one copy of the X chromosome.
X-inactivation is reversed in the female germline, so that all oocytes contain an active X chromosome.
Selection of one active X chromosome
Normal females possess two X chromosomes, and in any given cell one chromosome will be active (designated as Xa) and one will be inactive (Xi). However, studies of individuals with extra copies of the X chromosome show that in cells with more than two X chromosomes there is still only one Xa, and all the remaining X chromosomes are inactivated. This indicates that the default state of the X chromosome in females is inactivation, but one X chromosome is always selected to remain active.It is hypothesized that there is an autosomally-encoded 'blocking factor' which binds to the X chromosome and prevents its inactivation. The model postulates that there is a limiting blocking factor, so once the available blocking factor molecule binds to one X chromosome the remaining X chromosome(s) are not protected from inactivation. This model is supported by the existence of a single Xa in cells with many X chromosomes and by the existence of two active X chromosomes in cell lines with twice the normal number of autosomes.
Sequences at the X inactivation center (XIC), present on the X chromosome, control the silencing of the X chromosome. The hypothetical blocking factor is predicted to bind to sequences within the XIC.
Chromosomal component
The X-inactivation center (XIC) on the X chromosome is necessary and sufficient to cause X-inactivation. Chromosomal translocations which place the XIC on an autosome lead to inactivation of the autosome, and X chromosomes lacking the XIC are not inactivated.The XIC contains four non-translated RNA genes, Xist, Tsix, Jpx and Ftx, which are involved in X-inactivation. The XIC also contains binding sites for both known and unknown regulatory proteins.
Xist and Tsix RNAs
The X-inactive specific transcript (Xist) gene encodes a large non-coding RNA that is responsible for mediating the specific silencing of the X chromosome from which it is transcribed. The inactive X chromosome is coated by Xist RNA, whereas the Xa is not (See Figure to the right). The Xist gene is the only gene which is expressed from the Xi but not from the Xa. X chromosomes which lack the Xist gene cannot be inactivated. Artificially placing and expressing the Xist gene on another chromosome leads to silencing of that chromosome.Prior to inactivation, both X chromosomes weakly express Xist RNA from the Xist gene. During the inactivation process, the future Xa ceases to express Xist, whereas the future Xi dramatically increases Xist RNA production. On the future Xi, the Xist RNA progressively coats the chromosome, spreading out from the XIC Tsix is a negative regulator of Xist; X chromosomes lacking Tsix expression (and thus having high levels of Xist transcription) are inactivated much more frequently than normal chromosomes.
Like Xist, prior to inactivation, both X chromosomes weakly express Tsix RNA from the Tsix gene. Upon the onset of X-inactivation, the future Xi ceases to express Tsix RNA (and increases Xist expression), whereas Xa continues to express Tsix for several days.
Silencing
The inactive X chromosome does not express the majority of its genes, unlike the active X chromosome. This is due to the silencing of the Xi by repressive heterochromatin, which compacts the Xi DNA and prevents the expression of most genes.Compared to the Xa, the Xi has high levels of DNA methylation, low levels of histone acetylation, low levels of histone H3 lysine-4 methylation, and high levels of histone H3 lysine-9 methylation, all of which are associated with gene silencing. Additionally, a histone variant called macroH2A (H2AFY) is exclusively found on nucleosomes along the Xi.
Barr bodies
DNA packaged in heterochromatin, such as the Xi, is more condensed than DNA packaged in euchromatin, such as the Xa. The inactive X forms a discrete body within the nucleus called a Barr body. The Barr body is generally located on the periphery of the nucleus, is late replicating within the cell cycle, and, as it contains the Xi, contains heterochromatin modifications and the Xist RNA.
Expressed genes on the inactive X chromosome
A fraction of the genes along the X chromosome escape inactivation on the Xi. The Xist gene is expressed at high levels on the Xi and is not expressed on the Xa. Other genes are expressed equally from the Xa and Xi; mice contain few genes which escape silencing whereas up to a quarter of human X chromosome genes are expressed from the Xi. Many of these genes occur in clusters.Many of the genes which escape inactivation are present along regions of the X chromosome which, unlike the majority of the X chromosome, contain genes also present on the Y chromosome. These regions are termed pseudoautosomal regions, as individuals of either sex will receive two copies of every gene in these regions (like an autosome), unlike the majority of genes along the sex chromosomes. Since individuals of either sex will receive two copies of every gene in a pseudoautosomal region, no dosage compensation is needed for females, so it is postulated that these regions of DNA have evolved mechanisms to escape X-inactivation. The genes of pseudoautosomal regions of the Xi do not have the typical modifications of the Xi and have little Xist RNA bound.
The existence of genes along the inactive X which are not silenced explains the defects in humans with abnormal numbers of the X chromosome, such as Turner syndrome (X0) or Klinefelter syndrome (XXY). Theoretically, X-inactivation should eliminate the differences in gene dosage between affected individuals and individuals with a normal chromosome complement, but in affected individuals the dosage of these non-silenced genes will differ as they escape X-inactivation.
The precise mechanisms that control escape from X-inactivation are not known, but silenced and escape regions have been shown to have distinct chromatin marks. It has been suggested that escape from X-inactivation might be mediated by expression of long non-coding RNA (lncRNA) within the escaping chromosomal domains.
Uses in experimental biology
Stanley Michael Gartler used X chromosome inactivation to demonstrate the clonal origin of cancers. Examining normal tissues and tumors from females heterozygous for isoenzymes of the sex-linked G6PD gene demonstrated that tumor cells from such individuals express only one form of G6PD, whereas normal tissues are composed of a nearly equal mixture of cells expressing the two different phenotypes. This pattern suggests that a single cell, and not a population, grows into a cancer.
See also
References
Further reading
Review ArticleCategory:Molecular genetics Category:Genetics Category:Epigenetics Category:Gender
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