Gregor Mendel
Gregor Johann Mendel (July 20, 1822 – January 6, 1884) was an Augustinian monk and scientist, who gained posthumous fame as the figurehead of the new science of genetics for his study of the inheritance of certain traits in pea plants. Mendel showed that the inheritance of these traits follows particular laws, which were later named after him. The significance of Mendel's work was not recognized until the turn of the 20th century. The independent rediscovery of these laws formed the foundation of the modern science of genetics.
http://wn.com/Gregor_Mendel
Richard Goldschmidt
Richard Benedict Goldschmidt (April 12, 1878 – April 24, 1958) was a German-born American geneticist. He is considered the first to integrate genetics, development, and evolution. He pioneered understanding of reaction norms, genetic assimilation, dynamical genetics, sex determination, and heterochrony. Controversially, Goldschmidt advanced a model of macroevolution through macromutations that is popularly known as the "Hopeful Monster" hypothesis.
http://wn.com/Richard_Goldschmidt
Theophilus Painter
Theophilus Shickel Painter (August 22, 1889 – October 5, 1969) was an American zoologist known for his work in identifying genes in fruit flies (Drosophila). He did so by applying the incredible detail that had just been discovered to be visible in the giant polytene chromosomes in the salivary glands of Drosophila and other Dipteran larvae.
http://wn.com/Theophilus_Painter
Walter Sutton
Walter Stanborough Sutton (April 5, 1877 - November 10, 1916) was an American geneticist and physician whose most significant contribution to present-day biology was his theory that the Mendelian laws of inheritance could be applied to chromosomes at the cellular level of living organisms. This is now known as the Boveri-Sutton chromosome theory.
http://wn.com/Walter_Sutton
Wilhelm Johannsen
Wilhelm Johannsen (3 February 1857 - 11 November 1927) was a Danish botanist, plant physiologist and geneticist. He was born in Copenhagen. While very young, he was apprenticed to a pharmacist and worked in Denmark and Germany beginning in 1872 until passing his pharmacist's exam in 1879. In 1881, he became assistant in the chemistry department at the Carlsberg Laboratory under the chemist Johan Kjeldahl. Johannsen studied the metabolism of dormancy and germination in seeds, tubers and buds. He showed that dormancy could be broken by various anesthetic compounds, such as diethyl ether and chloroform.
http://wn.com/Wilhelm_Johannsen
Y-chromosomal Aaron
Y-chromosomal Aaron is the name given to the hypothesised most recent common ancestor of many of the patrilineal Jewish priestly caste known as Kohanim (singular "Kohen", "Cohen", or Kohane). In the Torah this ancestor is identified as Aaron, the brother of Moses. The hypothetical most recent common ancestor was therefore jocularly dubbed "Y-chromosomal Aaron", in analogy to Y-chromosomal Adam.
http://wn.com/Y-chromosomal_Aaron
Chromosomes Chromosomes contain the genetic material deoxyribonucleic acid or DNA. In association with proteins, the twisted strands of DNA become coiled and folded to give chromosomes a beaded appearance. Each bead represents a gene-a length of DNA coding for the synthesis of one or more proteins. There are thought to be more than five hundred genes on each of the cell's forty-six chromosomes. Here a progression is shown from a chromosome, as it appears under the microscope, to the molecular architecture of DNA, shown diagrammatically to illustrate the double helix. The chromosome content of every cell in the body consists of forty-six individual chromosomes, except for the sperm and ova, which have only twenty-three. Highly magnified, this chromosome set shows the X (red) and the Y (blue) sex chromosomes. A combination of X and Y denotes male characteristics, while an XX pair results in the birth of a girl. Since sperm contain either X or the Y chromosome and the ova only the X, sex is governed by the sperm.
A chromosome is a long strand of DNA that contains the information that makes individuals unique. Find out how many chromosomes people have with information from a science teacher in this free video on physiology and the human body. Expert: Janice Creneti Bio: Janice Creneti has a BS in secondary science education and a BA in biology from Boston University. Filmmaker: Christopher Rokosz
EDIT: Lyrics can be found below. This is 'Chromosome', the educational parody of Lady Gaga's 'Telephone' music video. It is a project that I directed this summer in the hopes of making science fun and interesting for students. Thank you to all of my talented friends for helping make this video possible! I hope you enjoy it and remember everyone, science is fun! Lyrics: Hello? Hello? Baby, you called. I can't hear a thing. I have got not service in the laboratory. I have got no time for talking. Baby, can't you see? I am trying to study some biochemistry. When the chromosomes condense then we call it prophase. And when they line up then it is called metaphase. When they pull apart then we call it anaphase. And when they divide into two cells that is telophase. Stop calling. Stop calling. I don't wanna talk anymore. I have a test that I am studying for. GTACCCGTAGT Neucleotides are CATGGGATCA They go TACATGTCT Neucleotides are ACTTCGGAATA DNA wrapped around histones. It's all in the chromosome. Everything in your genome: It's all in the chromosome. And when those cells explode they call it apoptosis. Different than necrosis. Not caused by osmosis. It's dangerous when the cell begin undergoing anoikis. Then there's metastasis. Cell death is so tasteless. DNA is simple if at first you only think, That you have a purine paired with a pyrimidine. The sugar-phosphate backbone holds all the bases Which is twisted around like a spiral staircase. Copying, copying like in vivo but <b>...</b>
Each chromosome consists of one continuous thread-like molecule of DNA coiled tightly around proteins, and contains a portion of the 6400000000 basepairs (DNA building blocks) that make up your DNA. Originally created for DNA Interactive ( www.dnai.org ). TRANSCRIPT In this animation we'll see the remarkable way our DNA is tightly packed up to fit into the nucleus of every cell. The process starts with assembly of a nucleosome, which is formed when eight separate histone protein subunits attach to the DNA molecule. The combined tight loop of DNA and protein is the nucleosome. Six nucleosomes are coiled together and these then stack on top of each other. The end result is a fiber of packed nucleosomes known as chromatin. This structure, is then looped and further packaged using other proteins (which are not shown here) to give the final "chromosomal" shapes. It is this remarkable multiple folding which allows six feet of DNA to fit into the nucleus of each cell in our body. And a typical cell nucleus is so small that ten thousand could fit on the tip of a needle. It is important to realize that chromosomes are not always present, they form only when cells are dividing. At other times, as we can see here at the end of cell division, our DNA becomes less highly organized.)
A 3D animation showing the structure of chromosomes and the relationship of chromosomes to DNA Learn more at CancerQuest; cancerquest.org .También disponible en español.
Dr. Ken Miller talks about the relationship between Homo sapiens and the other primates. He discusses a recent finding of the Human Genome Project which identifies the exact point of fusion of two primate chromosomes that resulted in human chromosome #2.
The phases through which chromosomes replicate, divide, shuffle, and recombine are imperfect, as DNA is subject to random mutations. Mutations do not always produce harmful outcomes. In fact, many mutations are thought to be neutral, and some even give rise to beneficial traits. To corroborate Darwin's theory, scientists would need to find a valid explanation for why a chromosome pair is missing in humans that is present in apes.
Opening DNA wrapping sequence provided by The Walter and Eliza Hall Institute of Medical Research www.wehi.edu.au Donations: www.wehi.edu.au Works Cited: Hillier, Ladeana W. "Generation and Annotation of the DNA Sequences of Human Chromosomes 2 and 4." Nature 434 (2005): 724-731. 28 Oct. 2007 www.nature.com Ijdo, JW "Origin of Human Chromosome 2: an Ancestral." Genetics 88 (1991): 9051-9055. www.pnas.org Spencer, Geoff. "Scientists Analyze Chromosomes 2 and 4." National Institutes of Health. 6 Apr. 2005. National Human Genome Research Institute. 28 Oct. 2007 www.genome.gov Video. www.youtube.com This video assumes the viewer has a basic understanding of biology, as well as a basic understanding of the structure of chromosomes.
Human cells have 46 chromosomes that are placed into 23 pairs, with one chromosome of each pair coming from the father and mother separately. Discover what an extra or missing chromosome causes with information from a science teacher in this free video on physiology and the human body. Expert: Janice Creneti Bio: Janice Creneti has a BS in secondary science education and a BA in biology from Boston University. Filmmaker: Christopher Rokosz
DNA packaging. Each chromosome consists of one continuous thread-like molecule of DNA coiled tightly around proteins, and contains a portion of the 6400000000 basepairs (DNA building blocks) that make up your DNA. The way DNA is packaged into chromatin is a factor in how protein production is controlled. Originally created for DNA Interactive ( www.dnai.org ). TRANSCRIPT In this animation we'll see the remarkable way our DNA is tightly packed up so that six feet of this long molecule fits into the microscopic nucleus of every cell. The process starts when DNA is wrapped around special protein molecules called histones. The combined loop of DNA and protein is called a nucleosome. Next the nucleosomes are packaged into a thread, which is sometimes described as "beads on a string". The end result is a fiber known as chromatin. Now the chromatin fiber is coiled into a structure called a "solenoid". This fiber is then looped and coiled yet again, leading finally to the familiar shapes known as chromosomes, which can be seen in the nucleus of dividing cells. Chromosomes are not always present. They form around the time cells divide when the two copies of the cell's DNA need to be separated. At other times, as we can see now after the cell has divided, our DNA is less highly organized. It is still wrapped up around the histones, but not coiled into chromosomes.
Chromosome Disorder Outreach, Inc. provides support and information to families affected by rare chromosome disorders. This video explains our mission and includes photos of some of the beautiful children of our members. We are a 501(c)(3) nonprofit corporation funded solely by donations and fundraising projects; we do not receive any government funding or grants. Please learn more at www.chromodisorder.org or donate at www.causes.com
www.FreeScienceLectures.com First the DNA Wrapping is animated. The wrapping allows 6 feet of the long DNA molecule to be densely packed into the tiny nucleus of every cell. The process starts when DNA is wrapped around special protein molecules called histones. The combined loop of DNA and protein is called a nuclei zone. Next the nuclei zones are packed into a thread. The end result is fiber known as chromatin. This fiber is looped and coiled yet again leading to the familiar shapes known as chromosomes which can be seen in the nucleus of dividing cells. Chromosomes are not always present - they form around the time cells divide when the two copies of the cell's DNA need to be separated. Using computer animation based on molecular research we are now able to see how DNA is actually copied in living cells. An assembly line of amazing biochemical machines are pulling apart the DNA double helix and cranking out a copy of each strand. This presentation was made by Drew Barry at The Walter and Eliza Hall Institute of Medical Research. --- It's Never too Late to Study www.FreeScienceLectures.com --- Notice This video is copyright by its respectful owners. The website address on the video does not mean anything. ---
I hope I've used all terms correctly, it's been a while since I've done any cytogenetics. The question today comes from user "spylab" of Athens, Greece: www.youtube.com "how did the transition from 48 chromosomes of primates to 46 of humans happen? I know that they fused but i cant understand the steps from 48 male 48 female to 46 m 46 f" It's a great question for the first episode! The short answer is probably a Robertsonian translocation. The frequency of these events in modern humans is about 1 in 1000 live births. You can start your own investigation into this phenomenon with reading the basics of translocations and the primate line chromosome fusion: 1. Robertsonian translocations: en.wikipedia.org 2. Ken Miller on the historical chromosome fusion event: www.youtube.com 3. Proc Natl Acad Sci US A. 1991 Oct 15;88(20):9051-5. Origin of human chromosome 2: an ancestral telomere-telomere fusion. www.ncbi.nlm.nih.gov 4. Origins of primate chromosomes - as delineated by Zoo-FISH and alignments of human and mouse draft genome sequences. Cytogenet Genome Res. 2005;108(1-3):122-38. content.karger.com 5. We can reconstruct a number of chromosomal rearrangements that occurred much earlier in primate evolution: Evolutionary descent of a human chromosome 6 neocentromere: a jump back to 17 million years ago. Genome Res. 2009 May;19(5):778-84. www.ncbi.nlm.nih.gov
The vocabulary of DNA: chromosomes, chromatids, chromatin, transcription, translation, and replication
1:15
Chromosomes
Chromosomes
Chromosomes Chromosomes contain the genetic material deoxyribonucleic acid or DNA. In association with proteins, the twisted strands of DNA become coiled and folded to give chromosomes a beaded appearance. Each bead represents a gene-a length of DNA coding for the synthesis of one or more proteins. There are thought to be more than five hundred genes on each of the cell's forty-six chromosomes. Here a progression is shown from a chromosome, as it appears under the microscope, to the molecular architecture of DNA, shown diagrammatically to illustrate the double helix. The chromosome content of every cell in the body consists of forty-six individual chromosomes, except for the sperm and ova, which have only twenty-three. Highly magnified, this chromosome set shows the X (red) and the Y (blue) sex chromosomes. A combination of X and Y denotes male characteristics, while an XX pair results in the birth of a girl. Since sperm contain either X or the Y chromosome and the ova only the X, sex is governed by the sperm.
1:36
Human Physiology : What Is a Chromosome?
Human Physiology : What Is a Chromosome?
A chromosome is a long strand of DNA that contains the information that makes individuals unique. Find out how many chromosomes people have with information from a science teacher in this free video on physiology and the human body. Expert: Janice Creneti Bio: Janice Creneti has a BS in secondary science education and a BA in biology from Boston University. Filmmaker: Christopher Rokosz
4:28
Chromosome (telephone parody)
Chromosome (telephone parody)
EDIT: Lyrics can be found below. This is 'Chromosome', the educational parody of Lady Gaga's 'Telephone' music video. It is a project that I directed this summer in the hopes of making science fun and interesting for students. Thank you to all of my talented friends for helping make this video possible! I hope you enjoy it and remember everyone, science is fun! Lyrics: Hello? Hello? Baby, you called. I can't hear a thing. I have got not service in the laboratory. I have got no time for talking. Baby, can't you see? I am trying to study some biochemistry. When the chromosomes condense then we call it prophase. And when they line up then it is called metaphase. When they pull apart then we call it anaphase. And when they divide into two cells that is telophase. Stop calling. Stop calling. I don't wanna talk anymore. I have a test that I am studying for. GTACCCGTAGT Neucleotides are CATGGGATCA They go TACATGTCT Neucleotides are ACTTCGGAATA DNA wrapped around histones. It's all in the chromosome. Everything in your genome: It's all in the chromosome. And when those cells explode they call it apoptosis. Different than necrosis. Not caused by osmosis. It's dangerous when the cell begin undergoing anoikis. Then there's metastasis. Cell death is so tasteless. DNA is simple if at first you only think, That you have a purine paired with a pyrimidine. The sugar-phosphate backbone holds all the bases Which is twisted around like a spiral staircase. Copying, copying like in vivo but <b>...</b>
1:43
How DNA is Packaged (Advanced)
How DNA is Packaged (Advanced)
Each chromosome consists of one continuous thread-like molecule of DNA coiled tightly around proteins, and contains a portion of the 6400000000 basepairs (DNA building blocks) that make up your DNA. Originally created for DNA Interactive ( www.dnai.org ). TRANSCRIPT In this animation we'll see the remarkable way our DNA is tightly packed up to fit into the nucleus of every cell. The process starts with assembly of a nucleosome, which is formed when eight separate histone protein subunits attach to the DNA molecule. The combined tight loop of DNA and protein is the nucleosome. Six nucleosomes are coiled together and these then stack on top of each other. The end result is a fiber of packed nucleosomes known as chromatin. This structure, is then looped and further packaged using other proteins (which are not shown here) to give the final "chromosomal" shapes. It is this remarkable multiple folding which allows six feet of DNA to fit into the nucleus of each cell in our body. And a typical cell nucleus is so small that ten thousand could fit on the tip of a needle. It is important to realize that chromosomes are not always present, they form only when cells are dividing. At other times, as we can see here at the end of cell division, our DNA becomes less highly organized.)
4:16
Chromosomes
Chromosomes
How many chromosomes do humans have?? How about a dog? Check out this video to find out MORE about chromosomes!
0:47
Chromosome to DNA
Chromosome to DNA
A 3D animation showing the structure of chromosomes and the relationship of chromosomes to DNA Learn more at CancerQuest; cancerquest.org .También disponible en español.
7:19
Chromosomes Crossing Over - Linked Genes
Chromosomes Crossing Over - Linked Genes
Free Science Help at Brightstorm! brightstorm.com The concepts of chromosome crossing over and linked genes.
1:36
Sex Chromosomes
Sex Chromosomes
Free Science Help at Brightstorm! brightstorm.com The description of sex chromosomes.
1:35
Chromosome Packaging
Chromosome Packaging
A clay mation adventure about the packaging of your chromosomes
4:22
Ken Miller on Human Evolution
Ken Miller on Human Evolution
Dr. Ken Miller talks about the relationship between Homo sapiens and the other primates. He discusses a recent finding of the Human Genome Project which identifies the exact point of fusion of two primate chromosomes that resulted in human chromosome #2.
3:28
Ken Miller Human Chromosome 2 Genome
Ken Miller Human Chromosome 2 Genome
The phases through which chromosomes replicate, divide, shuffle, and recombine are imperfect, as DNA is subject to random mutations. Mutations do not always produce harmful outcomes. In fact, many mutations are thought to be neutral, and some even give rise to beneficial traits. To corroborate Darwin's theory, scientists would need to find a valid explanation for why a chromosome pair is missing in humans that is present in apes.
8:32
Evidence of Common Ancestry: Human Chromosome 2
Evidence of Common Ancestry: Human Chromosome 2
Opening DNA wrapping sequence provided by The Walter and Eliza Hall Institute of Medical Research www.wehi.edu.au Donations: www.wehi.edu.au Works Cited: Hillier, Ladeana W. "Generation and Annotation of the DNA Sequences of Human Chromosomes 2 and 4." Nature 434 (2005): 724-731. 28 Oct. 2007 www.nature.com Ijdo, JW "Origin of Human Chromosome 2: an Ancestral." Genetics 88 (1991): 9051-9055. www.pnas.org Spencer, Geoff. "Scientists Analyze Chromosomes 2 and 4." National Institutes of Health. 6 Apr. 2005. National Human Genome Research Institute. 28 Oct. 2007 www.genome.gov Video. www.youtube.com This video assumes the viewer has a basic understanding of biology, as well as a basic understanding of the structure of chromosomes.
1:56
Rippling Y Chromosome
Rippling Y Chromosome
VOTE FOR TESSA, NAO: www.youtube.com
1:48
Human Physiology : How Many Chromosomes Does Each Human Cell Have?
Human Physiology : How Many Chromosomes Does Each Human Cell Have?
Human cells have 46 chromosomes that are placed into 23 pairs, with one chromosome of each pair coming from the father and mother separately. Discover what an extra or missing chromosome causes with information from a science teacher in this free video on physiology and the human body. Expert: Janice Creneti Bio: Janice Creneti has a BS in secondary science education and a BA in biology from Boston University. Filmmaker: Christopher Rokosz
DNA packaging. Each chromosome consists of one continuous thread-like molecule of DNA coiled tightly around proteins, and contains a portion of the 6400000000 basepairs (DNA building blocks) that make up your DNA. The way DNA is packaged into chromatin is a factor in how protein production is controlled. Originally created for DNA Interactive ( www.dnai.org ). TRANSCRIPT In this animation we'll see the remarkable way our DNA is tightly packed up so that six feet of this long molecule fits into the microscopic nucleus of every cell. The process starts when DNA is wrapped around special protein molecules called histones. The combined loop of DNA and protein is called a nucleosome. Next the nucleosomes are packaged into a thread, which is sometimes described as "beads on a string". The end result is a fiber known as chromatin. Now the chromatin fiber is coiled into a structure called a "solenoid". This fiber is then looped and coiled yet again, leading finally to the familiar shapes known as chromosomes, which can be seen in the nucleus of dividing cells. Chromosomes are not always present. They form around the time cells divide when the two copies of the cell's DNA need to be separated. At other times, as we can see now after the cell has divided, our DNA is less highly organized. It is still wrapped up around the histones, but not coiled into chromosomes.
3:58
Chromosome Disorder Outreach (CDO) YouTube Video
Chromosome Disorder Outreach (CDO) YouTube Video
Chromosome Disorder Outreach, Inc. provides support and information to families affected by rare chromosome disorders. This video explains our mission and includes photos of some of the beautiful children of our members. We are a 501(c)(3) nonprofit corporation funded solely by donations and fundraising projects; we do not receive any government funding or grants. Please learn more at www.chromodisorder.org or donate at www.causes.com
1:07
Bill Nye Genes DNA and Chromosomes
Bill Nye Genes DNA and Chromosomes
3:16
Molecular Biology Visualization of DNA
Molecular Biology Visualization of DNA
www.FreeScienceLectures.com First the DNA Wrapping is animated. The wrapping allows 6 feet of the long DNA molecule to be densely packed into the tiny nucleus of every cell. The process starts when DNA is wrapped around special protein molecules called histones. The combined loop of DNA and protein is called a nuclei zone. Next the nuclei zones are packed into a thread. The end result is fiber known as chromatin. This fiber is looped and coiled yet again leading to the familiar shapes known as chromosomes which can be seen in the nucleus of dividing cells. Chromosomes are not always present - they form around the time cells divide when the two copies of the cell's DNA need to be separated. Using computer animation based on molecular research we are now able to see how DNA is actually copied in living cells. An assembly line of amazing biochemical machines are pulling apart the DNA double helix and cranking out a copy of each strand. This presentation was made by Drew Barry at The Walter and Eliza Hall Institute of Medical Research. --- It's Never too Late to Study www.FreeScienceLectures.com --- Notice This video is copyright by its respectful owners. The website address on the video does not mean anything. ---
4:48
Episode 1: Primate chromosomes, from 48 to 46
Episode 1: Primate chromosomes, from 48 to 46
I hope I've used all terms correctly, it's been a while since I've done any cytogenetics. The question today comes from user "spylab" of Athens, Greece: www.youtube.com "how did the transition from 48 chromosomes of primates to 46 of humans happen? I know that they fused but i cant understand the steps from 48 male 48 female to 46 m 46 f" It's a great question for the first episode! The short answer is probably a Robertsonian translocation. The frequency of these events in modern humans is about 1 in 1000 live births. You can start your own investigation into this phenomenon with reading the basics of translocations and the primate line chromosome fusion: 1. Robertsonian translocations: en.wikipedia.org 2. Ken Miller on the historical chromosome fusion event: www.youtube.com 3. Proc Natl Acad Sci US A. 1991 Oct 15;88(20):9051-5. Origin of human chromosome 2: an ancestral telomere-telomere fusion. www.ncbi.nlm.nih.gov 4. Origins of primate chromosomes - as delineated by Zoo-FISH and alignments of human and mouse draft genome sequences. Cytogenet Genome Res. 2005;108(1-3):122-38. content.karger.com 5. We can reconstruct a number of chromosomal rearrangements that occurred much earlier in primate evolution: Evolutionary descent of a human chromosome 6 neocentromere: a jump back to 17 million years ago. Genome Res. 2009 May;19(5):778-84. www.ncbi.nlm.nih.gov
51:08
Biology 1A - Lecture 17: Chromosomes, Checkpoints, and Cance
Biology 1A - Lecture 17: Chromosomes, Checkpoints, and Cance
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The AustralianROCHE'S bet on gene sequencing could still be a chromosome short. The Swiss drugs group has raised its hostile bid for DNA-decoding group Illumina by 15 per cent, to around a hefty $US6.5 billion ($6.3bn). And the new $US51-a-share cash tender offer may not be the deal's final mutation. US-based...(size: 8.0Kb)
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A chromosome is an organized structure of DNA and protein found in cells. It is a single piece of coiled DNA containing many genes, regulatory elements and other nucleotide sequences. Chromosomes also contain DNA-bound proteins, which serve to package the DNA and control its functions.
Chromosomes vary widely between different organisms. The DNA molecule may be circular or linear, and can be composed of 100,000 to 10,000,000,000 nucleotides in a long chain. Typically, eukaryotic cells (cells with nuclei) have large linear chromosomes and prokaryotic cells (cells without defined nuclei) have smaller circular chromosomes, although there are many exceptions to this rule. Also, cells may contain more than one type of chromosome; for example, mitochondria in most eukaryotes and chloroplasts in plants have their own small chromosomes.
In eukaryotes, nuclear chromosomes are packaged by proteins into a condensed structure called chromatin. This allows the very long DNA molecules to fit into the cell nucleus. The structure of chromosomes and chromatin varies through the cell cycle. Chromosomes are the essential unit for cellular division and must be replicated, divided, and passed successfully to their daughter cells so as to ensure the genetic diversity and survival of their progeny. Chromosomes may exist as either duplicated or unduplicated. Unduplicated chromosomes are single linear strands, whereas duplicated chromosomes (copied during synthesis phase) contain two copies joined by a centromere.
Compaction of the duplicated chromosomes during mitosis and meiosis results in the classic four-arm structure (pictured to the right). Chromosomal recombination plays a vital role in genetic diversity. If these structures are manipulated incorrectly, through processes known as chromosomal instability and translocation, the cell may undergo mitotic catastrophe and die, or it may unexpectedly evade apoptosis leading to the progression of cancer.
In practice "chromosome" is a rather loosely defined term. In prokaryotes and viruses, the term genophore is more appropriate when no chromatin is present. However, a large body of work uses the term chromosome regardless of chromatin content. In prokaryotes, DNA is usually arranged as a circle, which is tightly coiled in on itself, sometimes accompanied by one or more smaller, circular DNA molecules called plasmids. These small circular genomes are also found in mitochondria and chloroplasts, reflecting their bacterial origins. The simplest genophores are found in viruses: these DNA or RNA molecules are short linear or circular genophores that often lack structural proteins.
The word ''chromosome'' comes from the Greek (''chroma'', colour) and (''soma'', body) due to their property of being very strongly stained by particular dyes.
History
In a series of experiments beginning in the mid-1880s, Theodor Boveri gave the definitive demonstration that chromosomes are the vectors of heredity. His two principles were the ''continuity'' of chromosomes and the ''individuality'' of chromosomes. It is the second of these principles that was so original. Wilhelm Roux suggested that each chromosome carries a different genetic load. Boveri was able to test and confirm this hypothesis. Aided by the rediscovery at the start of the 1900s of Gregor Mendel's earlier work, Boveri was able to point out the connection between the rules of inheritance and the behaviour of the chromosomes. Boveri influenced two generations of American cytologists: Edmund Beecher Wilson, Walter Sutton and Theophilus Painter were all influenced by Boveri (Wilson and Painter actually worked with him).
In his famous textbook ''The Cell in Development and Heredity'', Wilson linked together the independent work of Boveri and Sutton (both around 1902) by naming the chromosome theory of inheritance the "Sutton-Boveri Theory" (the names are sometimes reversed). Ernst Mayr remarks that the theory was hotly contested by some famous geneticists: William Bateson, Wilhelm Johannsen, Richard Goldschmidt and T.H. Morgan, all of a rather dogmatic turn-of-mind. Eventually, complete proof came from chromosome maps in Morgan's own lab.
In eukaryotes
Eukaryotes (cells with nuclei such as those found in plants, yeast, and animals) possess multiple large linear chromosomes contained in the cell's nucleus. Each chromosome has one centromere, with one or two arms projecting from the centromere, although, under most circumstances, these arms are not visible as such. In addition, most eukaryotes have a small circular mitochondrial genome, and some eukaryotes may have additional small circular or linear cytoplasmic chromosomes.
In the nuclear chromosomes of eukaryotes, the uncondensed DNA exists in a semi-ordered structure, where it is wrapped around histones (structural proteins), forming a composite material called chromatin.
Chromatin
Chromatin is the complex of DNA and protein found in the eukaryotic nucleus, which packages chromosomes. The structure of chromatin varies significantly between different stages of the cell cycle, according to the requirements of the DNA.
Interphase chromatin
During interphase (the period of the cell cycle where the cell is not dividing), two types of chromatin can be distinguished:
Euchromatin, which consists of DNA that is active, e.g., being expressed as protein.
Heterochromatin, which consists of mostly inactive DNA. It seems to serve structural purposes during the chromosomal stages. Heterochromatin can be further distinguished into two types:
* ''Constitutive heterochromatin'', which is never expressed. It is located around the centromere and usually contains repetitive sequences.
* ''Facultative heterochromatin'', which is sometimes expressed.
Individual chromosomes cannot be distinguished at this stage – they appear in the nucleus as a homogeneous tangled mix of DNA and protein.
Metaphase chromatin and division
In the early stages of mitosis or meiosis (cell division), the chromatin strands become more and more condensed. They cease to function as accessible genetic material (transcription stops) and become a compact transportable form. This compact form makes the individual chromosomes visible, and they form the classic four arm structure, a pair of sister chromatids attached to each other at the centromere. The shorter arms are called ''p arms'' (from the French ''petit'', small) and the longer arms are called ''q arms'' (''q'' follows ''p'' in the Latin alphabet; q-g "grande"). This is the only natural context in which individual chromosomes are visible with an optical microscope.
During divisions, long microtubules attach to the centromere and the two opposite ends of the cell. The microtubules then pull the chromatids apart, so that each daughter cell inherits one set of chromatids. Once the cells have divided, the chromatids are uncoiled and can function again as chromatin. In spite of their appearance, chromosomes are structurally highly condensed, which enables these giant DNA structures to be contained within a cell nucleus (Fig. 2).
The self-assembled microtubules form the spindle, which attaches to chromosomes at specialized structures called kinetochores, one of which is present on each sister chromatid. A special DNA base sequence in the region of the kinetochores provides, along with special proteins, longer-lasting attachment in this region.
In humans
Chromosomes can be divided into two types—autosomes, and sex chromosomes. Certain genetic traits are linked to a person's sex and are passed on through the sex chromosomes. The autosomes contain the rest of the genetic hereditary information. All act in the same way during cell division. Human cells have 23 pairs of large linear nuclear chromosomes (22 pairs of autosomes and one pair of sex chromosomes), giving a total of 46 per cell. In addition to these, human cells have many hundreds of copies of the mitochondrial genome. Sequencing of the human genome has provided a great deal of information about each of the chromosomes. Below is a table compiling statistics for the chromosomes, based on the Sanger Institute's human genome information in the Vertebrate Genome Annotation (VEGA) database. Number of genes is an estimate as it is in part based on gene predictions. Total chromosome length is an estimate as well, based on the estimated size of unsequenced heterochromatin regions.
Prokaryotic chromosomes have less sequence-based structure than eukaryotes. Bacteria typically have a single point (the origin of replication) from which replication starts, whereas some archaea contain multiple replication origins. The genes in prokaryotes are often organized in operons, and do not usually contain introns, unlike eukaryotes.
DNA packaging
Prokaryotes do not possess nuclei. Instead, their DNA is organized into a structure called the nucleoid. The nucleoid is a distinct structure and occupies a defined region of the bacterial cell. This structure is, however, dynamic and is maintained and remodeled by the actions of a range of histone-like proteins, which associate with the bacterial chromosome. In archaea, the DNA in chromosomes is even more organized, with the DNA packaged within structures similar to eukaryotic nucleosomes.
Bacterial chromosomes tend to be tethered to the plasma membrane of the bacteria. In molecular biology application, this allows for its isolation from plasmid DNA by centrifugation of lysed bacteria and pelleting of the membranes (and the attached DNA).
Prokaryotic chromosomes and plasmids are, like eukaryotic DNA, generally supercoiled. The DNA must first be released into its relaxed state for access for transcription, regulation, and replication.
Number of chromosomes in various organisms
Eukaryotes
These tables give the total number of chromosomes (including sex chromosomes) in a cell nucleus. For example, human cells are diploid and have 22 different types of autosome, each present as two copies, and two sex chromosomes. This gives 46 chromosomes in total. Other organisms have more than two copies of their chromosomes, such as bread wheat, which is ''hexaploid'' and has six copies of seven different chromosomes – 42 chromosomes in total.
Normal members of a particular eukaryotic species all have the same number of nuclear chromosomes (see the table). Other eukaryotic chromosomes, i.e., mitochondrial and plasmid-like small chromosomes, are much more variable in number, and there may be thousands of copies per cell.
Asexually reproducing species have one set of chromosomes, which are the same in all body cells. However, asexual species can be either haploid or diploid.
Sexually reproducing species have somatic cells (body cells), which are diploid [2n] having two sets of chromosomes, one from the mother and one from the father. Gametes, reproductive cells, are haploid [n]: They have one set of chromosomes. Gametes are produced by meiosis of a diploid germ line cell. During meiosis, the matching chromosomes of father and mother can exchange small parts of themselves (crossover), and thus create new chromosomes that are not inherited solely from either parent. When a male and a female gamete merge (fertilization), a new diploid organism is formed.
Some animal and plant species are polyploid [Xn]: They have more than two sets of homologous chromosomes. Plants important in agriculture such as tobacco or wheat are often polyploid, compared to their ancestral species. Wheat has a haploid number of seven chromosomes, still seen in some cultivars as well as the wild progenitors. The more-common pasta and bread wheats are polyploid, having 28 (tetraploid) and 42 (hexaploid) chromosomes, compared to the 14 (diploid) chromosomes in the wild wheat.
Prokaryotes
Prokaryotespecies generally have one copy of each major chromosome, but most cells can easily survive with multiple copies. For example, ''Buchnera'', a symbiont of aphids has multiple copies of its chromosome, ranging from 10–400 copies per cell. However, in some large bacteria, such as ''Epulopiscium fishelsoni'' up to 100,000 copies of the chromosome can be present. Plasmids and plasmid-like small chromosomes are, as in eukaryotes, very variable in copy number. The number of plasmids in the cell is almost entirely determined by the rate of division of the plasmid – fast division causes high copy number, and vice versa.
Karyotype
In general, the karyotype is the characteristic chromosome complement of a eukaryotespecies. The preparation and study of karyotypes is part of cytogenetics.
Although the replication and transcription of DNA is highly standardized in eukaryotes, ''the same cannot be said for their karyotypes'', which are often highly variable. There may be variation between species in chromosome number and in detailed organization.
In some cases, there is significant variation within species. Often there is:
:1. variation between the two sexes
:2. variation between the germ-line and soma (between gametes and the rest of the body)
:3. variation between members of a population, due to balanced genetic polymorphism
:4. geographical variation between races
:5. mosaics or otherwise abnormal individuals.
Also, variation in karyotype may occur during development from the fertilised egg.
The technique of determining the karyotype is usually called ''karyotyping''. Cells can be locked part-way through division (in metaphase) in vitro (in a reaction vial) with colchicine. These cells are then stained, photographed, and arranged into a ''karyogram'', with the set of chromosomes arranged, autosomes in order of length, and sex chromosomes (here X/Y) at the end: Fig. 3.
Like many sexually reproducing species, humans have special gonosomes (sex chromosomes, in contrast to autosomes). These are XX in females and XY in males.
Historical note
Investigation into the human karyotype took many years to settle the most basic question: ''How many chromosomes does a normal diploid human cell contain?'' In 1912, Hans von Winiwarter reported 47 chromosomes in spermatogonia and 48 in oogonia, concluding an XX/XOsex determination mechanism. Painter in 1922 was not certain whether the diploid number of man is 46 or 48, at first favouring 46. He revised his opinion later from 46 to 48, and he correctly insisted on humans having an XX/XY system.
New techniques were needed to definitively solve the problem:
:1. Using cells in culture
:2. Pretreating cells in a hypotonic solution, which swells them and spreads the chromosomes
:3. Arresting mitosis in metaphase by a solution of colchicine
:4. Squashing the preparation on the slide forcing the chromosomes into a single plane
:5. Cutting up a photomicrograph and arranging the result into an indisputable karyogram.
It took until 1954 before the human diploid number was confirmed as 46. Considering the techniques of Winiwarter and Painter, their results were quite remarkable. Chimpanzees (the closest living relatives to modern humans) have 48 chromosomes.
Aberrations
Chromosomal aberrations are disruptions in the normal chromosomal content of a cell and are a major cause of genetic conditions in humans, such as Down syndrome. Some chromosome abnormalities do not cause disease in carriers, such as translocations, or chromosomal inversions, although they may lead to a higher chance of birthing a child with a chromosome disorder. Abnormal numbers of chromosomes or chromosome sets, aneuploidy, may be lethal or give rise to genetic disorders. Genetic counseling is offered for families that may carry a chromosome rearrangement.
The gain or loss of DNA from chromosomes can lead to a variety of genetic disorders. Human examples include:
Cri du chat, which is caused by the deletion of part of the short arm of chromosome 5. "Cri du chat" means "cry of the cat" in French, and the condition was so-named because affected babies make high-pitched cries that sound like those of a cat. Affected individuals have wide-set eyes, a small head and jaw, moderate to severe mental health issues, and are very short.
Down syndrome, usually is caused by an extra copy of chromosome 21 (trisomy 21). Characteristics include decreased muscle tone, stockier build, asymmetrical skull, slanting eyes and mild to moderate developmental disability.
Edwards syndrome, which is the second-most-common trisomy; Down syndrome is the most common. It is a trisomy of chromosome 18. Symptoms include motor retardation, developmental disability and numerous congenital anomalies causing serious health problems. Ninety percent die in infancy; however, those that live past their first birthday usually are quite healthy thereafter. They have a characteristic clenched hands and overlapping fingers.
Idic15, abbreviation for Isodicentric 15 on chromosome 15; also called the following names due to various researches, but they all mean the same; IDIC(15), Inverted duplication 15, extra Marker, Inv dup 15, partial tetrasomy 15
Jacobsen syndrome, also called the terminal 11q deletion disorder. This is a very rare disorder. Those affected have normal intelligence or mild developmental disability, with poor expressive language skills. Most have a bleeding disorder called Paris-Trousseau syndrome.
Klinefelter's syndrome (XXY). Men with Klinefelter syndrome are usually sterile, and tend to have longer arms and legs and to be taller than their peers. Boys with the syndrome are often shy and quiet, and have a higher incidence of speech delay and dyslexia. During puberty, without testosterone treatment, some of them may develop gynecomastia.
Patau Syndrome, also called D-Syndrome or trisomy-13. Symptoms are somewhat similar to those of trisomy-18, but they do not have the characteristic hand shape.
Triple-X syndrome (XXX). XXX girls tend to be tall and thin. They have a higher incidence of dyslexia.
Turner syndrome (X instead of XX or XY). In Turner syndrome, female sexual characteristics are present but underdeveloped. People with Turner syndrome often have a short stature, low hairline, abnormal eye features and bone development and a "caved-in" appearance to the chest.
XYY syndrome. XYY boys are usually taller than their siblings. Like XXY boys and XXX girls, they are somewhat more likely to have learning difficulties.
Wolf-Hirschhorn syndrome, which is caused by partial deletion of the short arm of chromosome 4. It is characterized by severe growth retardation and severe to profound mental health issues.
Chromosomal mutations produce changes in whole chromosomes (more than one gene) or in the number of chromosomes present.
Deletion – loss of part of a chromosome
Duplication – extra copies of a part of a chromosome
Inversion – reverse the direction of a part of a chromosome
Translocation – part of a chromosome breaks off and attaches to another chromosome
Most mutations are neutral – have little or no effect. Chromosomal aberrations are the changes in the structure of chromosomes. It has a great role in evolution. A detailed graphical display of all human chromosomes and the diseases annotated at the correct spot may be found at the Oak Ridge National Laboratory.
Human Physiology : How Many Chromosomes Does Each Human Cell Have?
eHow
Human Physiology : How Many Chromosomes Does Each Human Cell Have?
Human cells have 46 chromosomes that are placed into 23 pairs, with one chromosome of each pair coming from the father and mother separately. Discover what an extra or missing chromosome causes with information from a science teacher in this free video on physiology and the human body. Expert: Janice Creneti Bio: Janice Creneti has a BS in secondary science education and a BA in biology from Boston University. Filmmaker: Christopher Rokosz
DNA packaging. Each chromosome consists of one continuous thread-like molecule of DNA coiled tightly around proteins, and contains a portion of the 6400000000 basepairs (DNA building blocks) that make up your DNA. The way DNA is packaged into chromatin is a factor in how protein production is controlled. Originally created for DNA Interactive ( www.dnai.org ). TRANSCRIPT In this animation we'll see the remarkable way our DNA is tightly packed up so that six feet of this long molecule fits into the microscopic nucleus of every cell. The process starts when DNA is wrapped around special protein molecules called histones. The combined loop of DNA and protein is called a nucleosome. Next the nucleosomes are packaged into a thread, which is sometimes described as "beads on a string". The end result is a fiber known as chromatin. Now the chromatin fiber is coiled into a structure called a "solenoid". This fiber is then looped and coiled yet again, leading finally to the familiar shapes known as chromosomes, which can be seen in the nucleus of dividing cells. Chromosomes are not always present. They form around the time cells divide when the two copies of the cell's DNA need to be separated. At other times, as we can see now after the cell has divided, our DNA is less highly organized. It is still wrapped up around the histones, but not coiled into chromosomes.
3:58
Chromosome Disorder Outreach (CDO) YouTube Video
chromodisorder
Chromosome Disorder Outreach (CDO) YouTube Video
Chromosome Disorder Outreach, Inc. provides support and information to families affected by rare chromosome disorders. This video explains our mission and includes photos of some of the beautiful children of our members. We are a 501(c)(3) nonprofit corporation funded solely by donations and fundraising projects; we do not receive any government funding or grants. Please learn more at www.chromodisorder.org or donate at www.causes.com
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Bill Nye Genes DNA and Chromosomes
HorrasTeach
Bill Nye Genes DNA and Chromosomes
3:16
Molecular Biology Visualization of DNA
FreeScienceLectures
Molecular Biology Visualization of DNA
www.FreeScienceLectures.com First the DNA Wrapping is animated. The wrapping allows 6 feet of the long DNA molecule to be densely packed into the tiny nucleus of every cell. The process starts when DNA is wrapped around special protein molecules called histones. The combined loop of DNA and protein is called a nuclei zone. Next the nuclei zones are packed into a thread. The end result is fiber known as chromatin. This fiber is looped and coiled yet again leading to the familiar shapes known as chromosomes which can be seen in the nucleus of dividing cells. Chromosomes are not always present - they form around the time cells divide when the two copies of the cell's DNA need to be separated. Using computer animation based on molecular research we are now able to see how DNA is actually copied in living cells. An assembly line of amazing biochemical machines are pulling apart the DNA double helix and cranking out a copy of each strand. This presentation was made by Drew Barry at The Walter and Eliza Hall Institute of Medical Research. --- It's Never too Late to Study www.FreeScienceLectures.com --- Notice This video is copyright by its respectful owners. The website address on the video does not mean anything. ---
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![A mule is the offspring of a male donkey and a female horse.[1] Horses and donkeys are different species, with different numbers of chromosomes.](http://web.archive.org./web/20120429114333/http://cdn8.wn.com/pd/22/28/fcfe1ea8205eeb5a93ebdabeb47c_medium.jpg "A mule is the offspring of a male donkey and a female horse.[1] Horses and donkeys are different species, with different numbers of chromosomes.")
![Genghis Khan Monument in Hohhot Zerjal et al. [2003][34] identified a Y-chromosomal lineage present in about 8% of the men in a large region of Asia (about 0.5% of the men in the world).](http://web.archive.org./web/20120429114333/http://cdn2.wn.com/pd/c9/60/4b11c1570625eea44a9dbdfd1659_medium.jpg "Genghis Khan Monument in Hohhot Zerjal et al. [2003][34] identified a Y-chromosomal lineage present in about 8% of the men in a large region of Asia (about 0.5% of the men in the world).")
