Varieties of RNA

Ribosomal RNA
Ribosomal RNA (rRNA) is, as its name suggests, the RNA that plays a crucial role in the creation of ribosomes. This kind of RNA is transcribed in the nucleolus (all other types are not) from DNA segments that are looped into structures called nucleolar organizer regions. Because rRNA is often in high demand in a cell, the data necessary for their creation is often repeated a number of times on the DNA strand. This repetition allows thousands of identical molecules to be transcribed simultaneously.

Once transcribed, rRNA can then go to work in the construction of ribosomes. In a cell, ribosomes are the only places where proteins can be synthesized. These are the structures that allow tRNA, mRNA, and amino acids to create polypeptide chains.

Messenger RNA
Messenger RNA (mRNA) is the structure that carries the genetic code instructions for how to create new proteins and enzymes. The major function of the DNA is to allow a cell to synthesize proteins, and it is the mRNA that provides the physical link between the DNA blueprints and the actual polypeptide chains themselves- the finished product.

Proteins are, in essence, a linear series of amino acids arranged in a particular order. There are twenty different amino acids, and from them an almost infinite number of different proteins can be created. To describe these proteins mRNA uses the genetic code. Every three nitrogenous bases in the molecule makes up a unit in this code called a codon, and each codon, then, represents a specific amino acid. Because there are four different nitrogenous bases and three bases to a codon, there are 64 (4x4x4=64) possible units in the genetic code system. With only twenty amino acids, then, many acids can be represented by more than one possible codon. These are called synonymous codons. For example, GGU, GGC, GGA, and GGG all represent the amino acid glycine.

mRNA Codon - Amino Acid Table - a chart of the 64 codons and what they stand for.

In addition to the codons representing amino acids, there are 3 that are reserved as stop codons. UAA, UAG, and UGA all signify the end of a complete gene. There is also a start codon, AUG. This unit, though, doubles as the code for methionine, depending upon its position in the strand. If the codon is found in the leading end of an mRNA strand it signals its start. Otherwise, it adds another amino acid to the chain being generated.

In eukaryotes mRNA is not created ready to go to work. Instead, it must first go through "posttranscriptional modification" to purify its information. Directly after being synthesized from a DNA strand, mRNA contains many noncoding sequences called introns that must be removed by enzymes. Once the introns have been removed, only the relevant portions (called exons) remain. The final mRNA is arranged as follows: First, there is a leading segment, called the "cap." After the cap comes the actual gene, or cistron. Finally, the end of the molecule is attached to many adenine bases. This is sometimes called the poly-A tail.

In prokaryotes mRNA is transcribed from the DNA in its finished form- no posttranscriptional modification is necessary. Also, prokaryotic mRNA lacks a cap and a poly-A tail. Finally, many of these strands contain more than one gene. This polycistronic mRNA allows for many different proteins to be created within the same small area, which is sometimes convenient for certain cellular processes.

Transfer RNA
Though ribosomes can be created with the help of rRNA, and mRNA can bring data to these structures concerning what proteins need to be created, ribosomes themselves cannot decode the genetic messages into polypeptide chains. For this task, a third type of ribonucleic acid is required, tRNA.

Each strand of tRNA is able to decode a specific portion of the mRNA code in the ribosome because of its three major qualities:

1. It connects to a specific amino acid through a charging enzyme
2. It binds to ribosomes
3. Finally, tRNA has an anticodon that allows it to connect to a specific codon in mRNA through Watson-Crick binding

As each of the codons in the mRNA strand being processed binds to a tRNA molecule, the amino acids connected to the transfer RNA are lined up and combined to form the final product: a protein molecule.

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REPLACEMENT OF DNA CELLS

Introduction

The possibility of human cloning, raised when Scottish scientists at Roslin Institute created the much-celebrated sheep "Dolly" (Nature 385, 810-13, 1997), aroused worldwide interest and concern because of its scientific and ethical implications. The feat, cited by Science magazine as the breakthrough of 1997, also generated uncertainty over the meaning of "cloning" --an umbrella term traditionally used by scientists to describe different processes for duplicating biological material.

What is cloning? Are there different types of cloning?

When the media report on cloning in the news, they are usually talking about only one type called reproductive cloning. There are different types of cloning however, and cloning technologies can be used for other purposes besides producing the genetic twin of another organism. A basic understanding of the different types of cloning is key to taking an informed stance on current public policy issues and making the best possible personal decisions. The following three types of cloning technologies will be discussed: (1) recombinant DNA technology or DNA cloning, (2) reproductive cloning, and (3) therapeutic cloning.

Recombinant DNA Technology or DNA Cloning

The terms "recombinant DNA technology," "DNA cloning," "molecular cloning," and "gene cloning" all refer to the same process: the transfer of a DNA fragment of interest from one organism to a self-replicating genetic element such as a bacterial plasmid. The DNA of interest can then be propagated in a foreign host cell. This technology has been around since the 1970s, and it has become a common practice in molecular biology labs today.

Scientists studying a particular gene often use bacterial plasmids to generate multiple copies of the same gene. Plasmids are self-replicating extra-chromosomal circular DNA molecules, distinct from the normal bacterial genome (see image to the right). Plasmids and other types of cloning vectors were used by Human Genome Project researchers to copy genes and other pieces of chromosomes to generate enough identical material for further study.

To "clone a gene," a DNA fragment containing the gene of interest is isolated from chromosomal DNA using restriction enzymes and then united with a plasmid that has been cut with the same restriction enzymes. When the fragment of chromosomal DNA is joined with its cloning vector in the lab, it is called a "recombinant DNA molecule." Following introduction into suitable host cells, the recombinant DNA can then be reproduced along with the host cell DNA. See a diagram depicting this process.

Plasmids can carry up to 20,000 bp of foreign DNA. Besides bacterial plasmids, some other cloning vectors include viruses, bacteria artificial chromosomes (BACs), and yeast artificial chromosomes (YACs). Cosmids are artificially constructed cloning vectors that carry up to 45 kb of foreign DNA and can be packaged in lambda phage particles for infection into E. coli cells. BACs utilize the naturally occurring F-factor plasmid found in E. coli to carry 100- to 300-kb DNA inserts. A YAC is a functional chromosome derived from yeast that can carry up to 1 MB of foreign DNA. Bacteria are most often used as the host cells for recombinant DNA molecules, but yeast and mammalian cells also are used.

Reproductive Cloning

Celebrity Sheep Died at Age 6 Dolly, the first mammal to be cloned from adult DNA, was put down by lethal injection Feb. 14, 2003. Prior to her death, Dolly had been suffering from lung cancer and crippling arthritis. Although most Finn Dorset sheep live to be 11 to 12 years of age, postmortem examination of Dolly seemed to indicate that, other than her cancer and arthritis, she appeared to be quite normal. The unnamed sheep from which Dolly was cloned had died several years prior to her creation. Dolly was a mother to six lambs, bred the old-fashioned way. Image credit: Roslin Institute Image Library

Reproductive cloning is a technology used to generate an animal that has the same nuclear DNA as another currently or previously existing animal. Dolly was created by reproductive cloning technology. In a process called "somatic cell nuclear transfer" (SCNT), scientists transfer genetic material from the nucleus of a donor adult cell to an egg whose nucleus, and thus its genetic material, has been removed. The reconstructed egg containing the DNA from a donor cell must be treated with chemicals or electric current in order to stimulate cell division. Once the cloned embryo reaches a suitable stage, it is transferred to the uterus of a female host where it continues to develop until birth.

Dolly or any other animal created using nuclear transfer technology is not truly an identical clone of the donor animal. Only the clone's chromosomal or nuclear DNA is the same as the donor. Some of the clone's genetic materials come from the mitochondria in the cytoplasm of the enucleated egg. Mitochondria, which are organelles that serve as power sources to the cell, contain their own short segments of DNA. Acquired mutations in mitochondrial DNA are believed to play an important role in the aging process.

Dolly's success is truly remarkable because it proved that the genetic material from a specialized adult cell, such as an udder cell programmed to express only those genes needed by udder cells, could be reprogrammed to generate an entire new organism. Before this demonstration, scientists believed that once a cell became specialized as a liver, heart, udder, bone, or any other type of cell, the change was permanent and other unneeded genes in the cell would become inactive. Some scientists believe that errors or incompleteness in the reprogramming process cause the high rates of death, deformity, and disability observed among animal clones.

Therapeutic Cloning

Therapeutic cloning, also called "embryo cloning," is the production of human embryos for use in research. The goal of this process is not to create cloned human beings, but rather to harvest stem cells that can be used to study human development and to treat disease. Stem cells are important to biomedical researchers because they can be used to generate virtually any type of specialized cell in the human body. Stem cells are extracted from the egg after it has divided for 5 days. The egg at this stage of development is called a blastocyst. The extraction process destroys the embryo, which raises a variety of ethical concerns. Many researchers hope that one day stem cells can be used to serve as replacement cells to treat heart disease, Alzheimer's, cancer, and other diseases. See more on the potential use of cloning in organ transplants.

In November 2001, scientists from Advanced Cell Technologies (ACT), a biotechnology company in Massachusetts, announced that they had cloned the first human embryos for the purpose of advancing therapeutic research. To do this, they collected eggs from women's ovaries and then removed the genetic material from these eggs with a needle less than 2/10,000th of an inch wide. A skin cell was inserted inside the enucleated egg to serve as a new nucleus. The egg began to divide after it was stimulated with a chemical called ionomycin. The results were limited in success. Although this process was carried out with eight eggs, only three began dividing, and only one was able to divide into six cells before stopping.

How can cloning technologies be used?

Recombinant DNA technology is important for learning about other related technologies, such as gene therapy, genetic engineering of organisms, and sequencing genomes. Gene therapy can be used to treat certain genetic conditions by introducing virus vectors that carry corrected copies of faulty genes into the cells of a host organism. Genes from different organisms that improve taste and nutritional value or provide resistance to particular types of disease can be used to genetically engineer food crops. See Genetically Modified Foods and Organisms for more information. With genome sequencing, fragments of chromosomal DNA must be inserted into different cloning vectors to generate fragments of an appropriate size for sequencing. See a diagram on constructing clones for sequencing.

If the low success rates can be improved (Dolly was only one success out of 276 tries), reproductive cloning can be used to develop efficient ways to reliably reproduce animals with special qualities. For example, drug-producing animals or animals that have been genetically altered to serve as models for studying human disease could be mass produced.

Reproductive cloning also could be used to repopulate endangered animals or animals that are difficult to breed. In 2001, the first clone of an endangered wild animal was born, a wild ox called a gaur. The young gaur died from an infection about 48 hours after its birth. In 2001, scientists in Italy reported the successful cloning of a healthy baby mouflon, an endangered wild sheep. The cloned mouflon is living at a wildlife center in Sardinia. Other endangered species that are potential candidates for cloning include the African bongo antelope, the Sumatran tiger, and the giant panda. Cloning extinct animals presents a much greater challenge to scientists because the egg and the surrogate needed to create the cloned embryo would be of a species different from the clone.

Therapeutic cloning technology may some day be used in humans to produce whole organs from single cells or to produce healthy cells that can replace damaged cells in degenerative diseases such as Alzheimer's or Parkinson's. Much work still needs to be done before therapeutic cloning can become a realistic option for the treatment of disorders.

What animals have been cloned?

Scientists have been cloning animals for many years. In 1952, the first animal, a tadpole, was cloned. Before the creation of Dolly, the first mammal cloned from the cell of an adult animal, clones were created from embryonic cells. Since Dolly, researchers have cloned a number of large and small animals including sheep, goats, cows, mice, pigs, cats, rabbits, and a gaur. See Cloned Animals below. All these clones were created using nuclear transfer technology.

Hundreds of cloned animals exist today, but the number of different species is limited. Attempts at cloning certain species have been unsuccessful. Some species may be more resistant to somatic cell nuclear transfer than others. The process of stripping the nucleus from an egg cell and replacing it with the nucleus of a donor cell is a traumatic one, and improvements in cloning technologies may be needed before many species can be cloned successfully.

Can organs be cloned for use in transplants?

Scientists hope that one day therapeutic cloning can be used to generate tissues and organs for transplants. To do this, DNA would be extracted from the person in need of a transplant and inserted into an enucleated egg. After the egg containing the patient's DNA starts to divide, embryonic stem cells that can be transformed into any type of tissue would be harvested. The stem cells would be used to generate an organ or tissue that is a genetic match to the recipient. In theory, the cloned organ could then be transplanted into the patient without the risk of tissue rejection. If organs could be generated from cloned human embryos, the need for organ donation could be significantly reduced.

Many challenges must be overcome before "cloned organ" transplants become reality. More effective technologies for creating human embryos, harvesting stem cells, and producing organs from stem cells would have to be developed. In 2001, scientists with the biotechnology company Advanced Cell Technology (ACT) reported that they had cloned the first human embryos; however, the only embryo to survive the cloning process stopped developing after dividing into six cells. In February 2002, scientists with the same biotech company reported that they had successfully transplanted kidney-like organs into cows. The team of researchers created a cloned cow embryo by removing the DNA from an egg cell and then injecting the DNA from the skin cell of the donor cow's ear. Since little is known about manipulating embryonic stem cells from cows, the scientists let the cloned embryos develop into fetuses. The scientists then harvested fetal tissue from the clones and transplanted it into the donor cow. In the three months of observation following the transplant, no sign of immune rejection was observed in the transplant recipient.

Another potential application of cloning to organ transplants is the creation of genetically modified pigs from which organs suitable for human transplants could be harvested . The transplant of organs and tissues from animals to humans is called xenotransplantation.

Why pigs? Primates would be a closer match genetically to humans, but they are more difficult to clone and have a much lower rate of reproduction. Of the animal species that have been cloned successfully, pig tissues and organs are more similar to those of humans. To create a "knock-out" pig, scientists must inactivate the genes that cause the human immune system to reject an implanted pig organ. The genes are knocked out in individual cells, which are then used to create clones from which organs can be harvested. In 2002, a British biotechnology company reported that it was the first to produce "double knock-out" pigs that have been genetically engineered to lack both copies of a gene involved in transplant rejection. More research is needed to study the transplantation of organs from "knock-out" pigs to other animals.

What are the risks of cloning?

Reproductive cloning is expensive and highly inefficient. More than 90% of cloning attempts fail to produce viable offspring. More than 100 nuclear transfer procedures could be required to produce one viable clone. In addition to low success rates, cloned animals tend to have more compromised immune function and higher rates of infection, tumor growth, and other disorders. Japanese studies have shown that cloned mice live in poor health and die early. About a third of the cloned calves born alive have died young, and many of them were abnormally large. Many cloned animals have not lived long enough to generate good data about how clones age. Appearing healthy at a young age unfortunately is not a good indicator of long-term survival. Clones have been known to die mysteriously. For example, Australia's first cloned sheep appeared healthy and energetic on the day she died, and the results from her autopsy failed to determine a cause of death.

In 2002, researchers at the Whitehead Institute for Biomedical Research in Cambridge, Massachusetts, reported that the genomes of cloned mice are compromised. In analyzing more than 10,000 liver and placenta cells of cloned mice, they discovered that about 4% of genes function abnormally. The abnormalities do not arise from mutations in the genes but from changes in the normal activation or expression of certain genes.

Problems also may result from programming errors in the genetic material from a donor cell. When an embryo is created from the union of a sperm and an egg, the embryo receives copies of most genes from both parents. A process called "imprinting" chemically marks the DNA from the mother and father so that only one copy of a gene (either the maternal or paternal gene) is turned on. Defects in the genetic imprint of DNA from a single donor cell may lead to some of the developmental abnormalities of cloned embryos.

For more details on the risks associated with cloning, see the Cloning Problems links below.

Should humans be cloned?

Physicians from the American Medical Association and scientists with the American Association for the Advancement of Science have issued formal public statements advising against human reproductive cloning. The U.S. Congress has considered the passage of legislation that could ban human cloning. See the Policy and Legislation links below.

Due to the inefficiency of animal cloning (only about 1 or 2 viable offspring for every 100 experiments) and the lack of understanding about reproductive cloning, many scientists and physicians strongly believe that it would be unethical to attempt to clone humans. Not only do most attempts to clone mammals fail, about 30% of clones born alive are affected with "large-offspring syndrome" and other debilitating conditions. Several cloned animals have died prematurely from infections and other complications. The same problems would be expected in human cloning. In addition, scientists do not know how cloning could impact mental development. While factors such as intellect and mood may not be as important for a cow or a mouse, they are crucial for the development of healthy humans. With so many unknowns concerning reproductive cloning, the attempt to clone humans at this time is considered potentially dangerous and ethically irresponsible. See the Cloning Ethics links below for more information about the human cloning debate.

---

Related Links
(most resources focus on reproductive cloning)

General Information Cloning in the News Cloning Ethics Policy and Legislation
Cloning Problems Cloned Animals Cloning for Organs More Information

General Information

• Cloning - A collection of resources from MEDLINEplus, a service of the U.S. National Library of Medicine and the National Institutes of Health.
• Cloning In Focus - An excellent introduction to cloning from the Genetic Science Learning Center. Teacher resources covering cloning and other genetics topics also are available.
• Cloning: How It Works - An interactive guide to cloning with graphics and animations provided by Guardian Unlimited.
• Creating a Cloned Sheep Named Dolly - General information on cloning from the National Institutes of Health Office of Science Education. For grades 9-12.
• How Cloning Works - from the How Stuff Works Web site.
• How Human Cloning Will Work - from the How Stuff Works Web site
• Weblog Special: Human Cloning
• Cloning - Introduction to cloning and stem cells. An issue brief from the Genetics & Public Policy Center.

Cloning in the News

• The Real Face of Cloning - From USA Today (January 17, 2003)
• The History of Cloning - From MSNBC News. A timeline outlining a brief history of cloning.

Cloning Ethics

• The Politics of Human Biotechnology: Overview - Center for Genetics and Society.
• Primer on Ethics and Human Cloning - A 2001 actionbioscience.org original article by Glenn McGee, Ph.D.
• Beyond Dolly the Human Cloning Dilemma - From MSNBC.
• Human Cloning and Human Dignity: An Ethical Inquiry - 2002 human cloning report published by The President's Council on Bioethics. Includes ethical discussions and policy recommendations.
• Sex and Cloning - From NewScientist.com (requires subscription).
• National Information Resource on Ethics & Human Genetics - Includes GenETHX, the genetics and ethics database.
• Cat Cloning is Wrong-Headed States The Humane Society of the United States - Press release (2002) from the Humane Society of the United States advising against the cloning of cats and other pets.

Policy and Legislation (focus on U.S. policy)

• Federal Policies on Cloning - A summary of U.S. efforts (1991 to 2003) to pass cloning legislation from the Center for Genetics and Society.
• State Human Cloning Laws - An overview from the National Conference of State Legislatures.
• Hot Topic: Cloning - A collection of legislative and other cloning resources. Provided by the National Conference of State Legislatures.
• Database of Global Policies on Human Cloning and Germ-line Engineering - A database of cloning legislation from around the world. Provided by the Global Lawyers and Physicians, a non-profit organization working on health and human rights issues.
• Policy Brief: Human Cloning - From the American Association for the Advancement of Science
• Why We Should Not Clone Humans - From the American Medical Association.
• Bills Introduced to Congress
  • H.R.2560 - Human Cloning Prohibition Act of 2007
  • H.R.2564 - Human Cloning Prohibition Act of 2007
  • S. 812 - Human Cloning Ban and Stem Cell Research Protection Act of 2007

Cloning Problems

• TIME Collection: Cloning - Archive of articles from Time Magazine
• Cloned Mice Have Genomic Flaws - Article from the Genome News Network (September 2002).
• Tears of a Clone - Article from The Guardian (April 19, 2002).
• Cloned Monkey Embryos Are a "Gallery of Horrors" - Article from NewScientist.com (December 12, 2001).
• Imprinting Marks Clones for Death: Unstable Genes Make Normal Clones Unlikely - Article from Nature News Service (July 6, 2001).
• Clones Contain Hidden DNA Damage - Article from NewScientist.com (July 6, 2001).

Cloned Animals

• TIME Collection: Cloning - Archive of articles from Time Magazine
• Cloned Rabbits Produced by Nuclear Transfer from Adult Somatic Cells - Article from the April 2002 issue of Nature Biotechnology.
• Endangered wild sheep clone reported to be healthy - Article from the Genome News Network (October 12, 2001).
• First Cloned Mouse Dies Of Old Age - Report from CBSNEWS.com (May 10, 2000).
• Pigs Cloned for First Time - Article from the April 2000 issue of Nature Biotechnology.
• Cloning Noah's Ark - Article on cloning endangered species from the November 2000 issue of Scientific American (requires subscription).
• First Male Clone - Article from Nature News Service about the first successfully cloned male animal, a mouse (1999).
• A Clone in Sheep's Clothing - Article in Scientific American reporting the cloning of Dolly (March 3, 1997).

Cloning for Organs

• Cloned Pigs Raise Transplant Hopes - Article from the August 22, 2002, issue of BBC News.
• Building Brand New Kidneys - Article from the February 13, 2002, issue of The Scientist (requires subscription).
• Scientists Produce Five Pig Clones - Article from the March 14, 2000, issue of BBC News.

More Information

• Roslin Institute - Learn more about Dolly's home.
• Hello Dolly: A WebQuest -Web-based curriculium for teaching cloning.
• Cloning: From DNA Molecules to Dolly - Human Genome News article (January 1998).
• Genome Audio Files - Page down for several real audio interviews on cloning.

Molecular cloning

Molecular cloning refers to the process of making multiple copies of a defined DNA sequence. Cloning is frequently used to amplify DNA fragments containing whole genes, but it can also be used to amplify any DNA sequence such as promoters, non-coding sequences and randomly fragmented DNA. It is used in a wide array of biological experiments and practical applications ranging from genetic fingerprinting to large scale protein production. Occasionally, the term cloning is misleadingly used to refer to the identification of the chromosomalpositional cloning. In practice, localization of the gene to a chromosome or genomic region does not necessarily enable one to isolate or amplify the relevant genomic sequence. To amplify any DNA sequence in a living organism, that sequence must be linked to an origin of replication, which is a sequence of DNA capable of directing the propagation of itself and any linked sequence. However, a number of other features are needed and a variety of specialised cloning vectorsprotein expression, tagging, single stranded RNA and DNA production and a host of other manipulations. location of a gene associated with a particular phenotype of interest, such as in (small piece of DNA into which a foreign DNA fragment can be inserted) exist that allow

Cloning of any DNA fragment essentially involves four steps ^[1]

1. fragmentation - breaking apart a strand of DNA
2. ligation - gluing together pieces of DNA in a desired sequence
3. transfection - inserting the newly formed pieces of DNA into cells
4. screening/selection - selecting out the cells that were successfully transfected with the new DNA

Although these steps are invariable among cloning procedures a number of alternative routes can be selected, these are summarized as a 'cloning strategy'.

Initially, the DNA of interest needs to be isolated to provide a DNA segment of suitable size. Subsequently, a ligation procedure is used where the amplified fragment is inserted into a vector (piece of DNA). The vector (which is frequently circular) is linearised using restriction enzymes, and incubated with the fragment of interest under appropriate conditions with an enzyme called DNA ligase. Following ligation the vector with the insert of interest is transfected into cells. A number of alternative techniques are available, such as chemical sensitivation of cells, electroporation, optical injection and biolistics. Finally, the transfected cells are cultured. As the aforementioned procedures are of particularly low efficiency, there is a need to identify the cells that have been successfully transfected with the vector construct containing the desired insertion sequence in the required orientation. Modern cloning vectors include selectable antibioticX-gal medium. Nevertheless, these selection steps do not absolutely guarantee that the DNA insert is present in the cells obtained. Further investigation of the resulting colonies must be required to confirm that cloning was successful. This may be accomplished by means of PCR, restriction fragment analysis and/or DNA sequencing. resistance markers, which allow only cells in which the vector has been transfected, to grow. Additionally, the cloning vectors may contain colour selection markers, which provide blue/white screening (α-factor complementation) on

Unicellular organisms

Cloning cell-line colonies using cloning rings

Cloning a cell means to derive a population of cells from a single cell. In the case of unicellular organisms such as bacteria and yeast, this process is remarkably simple and essentially only requires the inoculation of the appropriate medium. However, in the case of cell cultures from multi-cellular organisms, cell cloning is an arduous task as these cells will not readily grow in standard media.

A useful tissue culture technique used to clone distinct lineages of cell lines involves the use of cloning rings (cylinders)^[2]. According to this technique, a single-cell suspension of cells that have been exposed to a mutagenic agent or drug used to drive selection is plated at high dilution to create isolated colonies; each arising from a single and potentially clonally distinct cell. At an early growth stage when colonies consist of only a few of cells, sterile polystyrene rings (cloning rings), which have been dipped in grease are placed over an individual colony and a small amount of trypsin is added. Cloned cells are collected from inside the ring and transferred to a new vessel for further growth.

[edit] Cloning in stem cell research

Main article: Somatic cell nuclear transfer

Somatic cell nuclear transfer, known as SCNT, can also be used to create embryos for research or therapeutic purposes. The most likely purpose for this is to produce embryos for use in stem cell research. This process is also called "research cloning" or "therapeutic cloning." The goal is not to create cloned human beings (called "reproductive cloning"), but rather to harvest stem cells that can be used to study human development and to potentially treat disease. While a clonal human blastocyst has been created, stem cell lines are yet to be isolated from a clonal source.^[3]

[edit] Organism cloning

This article needs reorganization to meet Wikipedia's quality standards. There is good information here, but it is poorly organized; editors are encouraged to be bold and make changes to the overall structure to improve this article. (February 2007)

Further information: Asexual reproduction

Organism cloning (also called reproductive cloning) refers to the procedure of creating a new multicellular organism, genetically identical to another. In essence this form of cloning is an asexual method of reproduction, where fertilization or inter-gamete contact does not take place. Asexual reproduction is a naturally occurring phenomenon in many species, including most plants (see vegetative reproduction) and some insects. Scientists have made some major achievements with cloning, including the asexual reproduction of sheep and cows. There is a lot of ethical debate over whether or not cloning should be used. However cloning, or asexual propagation,[2] has been common practice in the horticultural world for hundreds of years.

[edit] Horticultural

The term clone is used in horticulture to mean all descendants of a single plant, produced by vegetative reproduction or apomixis. Many horticultural plant cultivars are clones, having been derived from a single individual, multiplied by some process other than sexual reproduction. As an example, some European cultivars of grapes represent clones that have been propagated for over two millennia. Other examples are potato and banana. Grafting can be regarded as cloning, since all the shoots and branches coming from the graft are genetically a clone of a single individual, but this particular kind of cloning has not come under ethical scrutiny and is generally treated as an entirely different kind of operation.

Many trees, shrubs, vines, ferns and other herbaceous perennials form clonal colonies. Parts of a large clonal colony often become detached from the parent, termed fragmentation, to form separate individuals. Some plants also form seedsdandelion. asexually, termed apomixis, e.g.

[edit] Parthenogenesis

Clonal derivation exists in nature in some animal species and is referred to as parthenogenesis (reproduction of an organism by itself without a mate). This is an asexual form of reproduction that is only found in females of some insects, crustaceans and lizards. The growth and development occurs without fertilization by a male. In plants, parthenogenesis means the development of an embryo from an unfertilized egg cell, and is a component process of apomixis. In species that use the XY sex-determination system, the offspring will always be female. An example is the "Little Fire Ant" (Wasmannia auropunctata), which is native to Central and South America but has spread throughout many tropical environments.

[edit] Artificial cloning of organisms

Artificial cloning of organisms may also be called reproductive cloning.

[edit] Methods

Reproductive cloning generally uses "somatic cell nuclear transfer" (SCNT) to create animals that are genetically identical. This process entails the transfer of a nucleus from a donor adult cell (somatic cell) to an egg that has no nucleus. If the egg begins to divide normally it is transferred into the uterus of the surrogate mother. Such clones are not strictly identical since the somatic cells may contain mutations in their nuclear DNA. Additionally, the mitochondria in the cytoplasmmitochondrial genome is not the same as that of the nucleus donor cell from which it was produced. This may have important implications for cross-species nuclear transfer in which nuclear-mitochondrial incompatibilities may lead to death. also contains DNA and during SCNT this DNA is wholly from the donor egg, thus the

Artificial embryo splitting or embryo twinning may also be used as a method of cloning, where an embryo is split in the maturation before embryo transfer. It is optimally performed at the 6- to 8-cell stage, where it can be used as an expansion of IVF to increase the number of available embryos.^[4] If both embryos are successful, it gives rise to monozygotic (identical) twins.

[edit] Dolly the Sheep

Main article: Dolly the Sheep

Dolly, a Finn Dorsett ewe, was the first mammal to have been successfully cloned from an adult cell. She was cloned at the Roslin Institute in Scotland and lived there from her birth in 1996 until her death in 2003 when she was six. Her stuffed remains were placed at Edinburgh's Royal Museum, part of the National Museums of Scotland.

Dolly was publicly significant because the effort showed that the genetic material from a specific adult cell, programmed to express only a distinct subset of its genes, can be reprogrammed to grow an entire new organism. Before this demonstration, there was no proof for the widely spread hypothesis that differentiated animal cells can give rise to entire new organisms.

Cloning Dolly the sheep had a low success rate per fertilized egg; she was born after 237 eggs were used to create 29 embryos, which only produced three lambs at birth, only one of which lived. Seventy calves have been created from 9,000 attempts and one third of them died young; Prometea took 328 attempts. Notably, although the first clones were frogs, no adult cloned frog has yet been produced from a somatic adult nucleus donor cell.

There were early claims that Dolly the Sheep had pathologies resembling accelerated aging. Scientists speculated that Dolly's death in 2003 was related to the shortening of telomeres, DNA-protein complexes that protect the end of linear chromosomes. However, other researchers, including Ian Wilmut who led the team that successfully cloned Dolly, argue that Dolly's early death due to respiratory infection was unrelated to deficiencies with the cloning process.

Though Dolly was the first cloned mammal, the first vertebrate to be cloned was a tadpole in 1952