Post by skyship on Jan 9, 2010 17:31:50 GMT -5
How it began with true alterations in the human gene pool!
Of Mice and Men!
Found the code, hid it, read it, reconfigured it, produce alternatives to the code, insert, without our consent or knowledge until we reach
the End zone! No warning! No Informing the Public! Total theft, deletion, and insertions at the whim of the Human foundations
aiming for perfect human beings, discarding the message codes
in those genes that adapted to so-called errors. Were they
in our genes or in someone's mind!
"Reading the Human Blueprint:
The Human Genome Project
"All human disease is genetic in origin,'' Nobel laureate Paul Berg of Stanford University told a cancer symposium a few years ago.
Berg was exaggerating, but only slightly. It has become increasingly evident that virtually all human afflictions, from cancer to psychiatric disorders and susceptibility to infection, are rooted in our genes. "What we need to do now is find those genes," says James Watson, who shared a Nobel Prize for deciphering the structure of DNA.
Mapping the human genome actually began in 1911, when the gene responsible for red-green color blindness was assigned to the X chromosome. This flowed from the observation that color blindness was passed on to sons by mothers who saw colors normally. Females, who have two X chromosomes, are protected from this disorder by a normal copy of the gene on their second X chromosome—unlike males, who have one X and one Y chromosome.
Some other disorders that affect only males were likewise mapped to the X chromosome, but the other 22 pairs of chromosomes remained virtually uncharted until the late 1960s. At that time, biologists fused human and mouse cells to create hybrid cells and found that these uneasy hybrids cast off their human chromosomes until only one or a few of the human chromosomes remained. Any recognizable human proteins found in such cells would therefore have to be produced by genes located on the remaining human chromosomes. Narrowing down the number of chromosomes in this fashion allowed scientists to assign about 100 genes to specific chromosomes. ".......
www.hhmi.org/genetictrail/c100.html
============================
Note the names.
=====================
Albert Lasker
Basic Medical Research Award
Award Description
Paul Berg
Herbert Boyer
Stanley Cohen
A. Dale Kaiser
Paul Berg
For his key, historic achievements which made recombinant DNA a brilliant reality, and inaugurated a new age of biomedical promise.
Paul Berg brilliantly envisioned how a portion of a DNA molecule from one cell could be woven artificially into the DNA of another, and devised a fundamental technique which has helped to make recombinant DNA a practical reality.
In 1970, Dr. Berg began research to find a method for introducing additional DNA into the DNA of a living cell. Two years later, Dr. Berg and his co-workers showed that the well-known SV40 virus could be used as a carrier, or "vector," for DNA fragments. Dr. Berg used enzymes to cut a hole in the viral DNA and substitute a piece of bacterial DNA.
In 1976, Dr. Berg and his student, Stephen Goff, constructed a new kind of recombinant DNA, reintroducing it into the nucleus of a cultured animal cell, where it multiplied and functioned as a viral gene. In subsequent experiments, with his student Richard Mulligan, Dr. Berg introduced a new gene into the chromosomes of cultured animal cells, where the new gene functioned as if it were part of the cellular chromosomes, showing that artificially reconstructed DNA can cause changes in the biological activity of an animal cell.
Recombinant DNA will shape many vital industrial processes, from the preparation of vaccines to the creation of new sources of energy. It has already been used to establish new supplies of medically important natural substances such as human hormones and interferons.
Even more exciting, scientifically, is the prospect of learning, through recombinant DNA methodology, how human chromosomes are structured, and how genes really work. Dr. Berg's discoveries are helping scientists to clarify our understanding of development and differentiation of all living things. Recombinant DNA may reveal how the incalculable latent powers of human genes can be activated to maintain an individual's health and well-being.
To Dr. Berg, for his theoretical and technological discoveries, which have made recombinant DNA a brilliant reality and inaugurated a new, promising age of biomedical achievements, this 1980 Albert Lasker Basic Medical Research Award is given.
Herbert Boyer
For his brilliant contributions to recombinant DNA methodology, particularly in enzymology, plasmids, and in application of synthetic DNA.
Dr. Boyer was the first to show how restriction enzymes could be used to separate and rearrange segments of the DNA molecule. Using this expertise, he reconstructed bacterial plasmids, thereby making the technology of recombinant DNA straightforward and readily accessible. Dr. Boyer went on to show that synthetic DNA could be used to build plasmids as effectively as DNA from natural sources.
The restriction enzyme, EcoRI endonuclease, was discovered in Dr. Boyer's laboratory in 1968 and quickly became an indispensable tool in early recombinant DNA research. Dr. Boyer supplied this enzyme to Dr. Paul Berg and others in 1971 for recombinant DNA studies. In 1973, he entered an historic collaboration with Dr. Stanley Cohen, who was working with bacterial plasmids.
Dr. Boyer used enzymes to dissect and recombine the DNA of plasmids supplied by Dr. Cohen, who inserted the reconstructed plasmids into E. coli bacteria. The two investigators jointly analyzed the resulting clones of cells to detect the presence of the reconstructed plasmids. The critical moment came in 1974 when a plasmodium containing DNA from the South African toad replicated successfully in the bacteria—the first transplantation of genes between species.
In 1977, with Drs. Keiichi Itakura and Arthur Riggs, Dr. Boyer constructed a synthetic duplicate for the gene for the human brain hormone somatostatin. Placed in a plasmid and transplanted to E. coli, the gene functioned as if it were a bacterial gene, and the bacteria produced the hormone. This was the first time that bacteria produced a non-bacterial substance.
For his brilliant investigations of restriction and modification enzymes, for his central role in constructing plasmids with recombinant DNA and for his continuing studies in molecular genetics employing the recombinant DNA methodology which he was instrumental in creating, this 1980 Albert Lasker Basic Medical Research Award is given.
Stanley Cohen
For his splendid contributions to recombinant DNA methodology, and for accomplishing the first transplantation of genes between cells.
Stanley Cohen is honored for his imaginative and persevering studies of bacterial plasmids, for discovering new opportunities for manipulating and investigating the genetics of cells, and for establishing the biological promise of recombinant DNA methodology.
In 1968, Dr. Cohen began to focus his attention on the extrachromosomal elements of DNA known as plasmids, particularly those coding for resistance to antibiotics. He studied how plasmids replicate, the ways in which their DNA is organized, and the effects of transposing segments of the DNA within them. In 1972, he and his co-workers showed that purified plasmids can be introduced into the bacterium E. coli. This new genetic material can alter the biological activity of the bacterial cell. These transformed cells, Dr. Cohen showed, give rise to daughter cells which carry the progeny of the plasmids introduced into their progenitors.
Working with Dr. Herbert Boyer, Dr. Cohen began, in 1973, a stunning series of experiments which demonstrated that the genetics of cells could be manipulated in a variety of inventive ways. With the restriction enzyme EcoRI, an entirely new plasmid was constructed in vitro, and cloned in E. coli. Soon afterward, Dr. Cohen transplanted into E. coli genes from an unrelated bacterium and from an animal species. In both experiments, the transplanted genes were expressed in the new clones of cells.
With these techniques, scientists can now modify the genetics of cells to create results which were unimaginable before the work of Dr. Cohen. It is now possible to use the chemical-synthesizing apparatus of one cell to produce substances from the genetic blueprints of a totally unrelated cell.
For Dr. Cohen's splendid contributions to recombinant DNA methodology, which launched a new era in biological research technology, and for accomplishing the first transplantation of genes between cells, this 1980 Albert Lasker Basic Medical Research Award is given.
A. Dale Kaiser
For his crucial role in creating recombinant DNA methodology through his pathbreaking studies of cohesive single-stranded DNA.
A. Dale Kaiser is honored for his fundamental studies of the virus bacteriophage lambda and his invention of a method to render the ends of DNA fragments cohesive, thus placing in the hands of his fellow scientists both the concept of genetic engineering and an approach to recombining DNA.
In 1957, Dr. Kaiser set out to explore how DNA governs the biological activity of a cell. He reasoned that if DNA were removed from a cell, altered, and introduced into another, identical cell, the second cell would reflect, through differences in its biological activity, the changes in the transplanted DNA. To test this hypothesis, he undertook a series of strikingly original studies of the bacillus E. coli and the bacteriophage lambda.
Dr. Kaiser made the immensely significant discovery that the ends of the viral DNA molecule were single stranded and had a base-pair structure complementary to each other. Thus the ends of the molecule could join together to form a ring-shaped structure. He then devised a method of employing enzymes to create similar cohesiveness at the ends of any fragment of DNA, permitting them to join with each other.
This process, known as "tailing," makes it possible to join together any arbitrary pair of DNA fragments and thus to recombine DNA. Dr. Kaiser's discovery has become one of the basic tools in the field of recombinant DNA.
For his crucial role in creating the methodology of recombinant DNA, through his pathbreaking studies of the single-stranded cohesive ends of the DNA molecule, this 1980 Albert Lasker Basic Medical Research Award is given.
© LASKER FOUNDATION, 2009
www.laskerfoundation.org/awards/1980_b_description.htm
Epigenetics next.
skyship
Of Mice and Men!
Found the code, hid it, read it, reconfigured it, produce alternatives to the code, insert, without our consent or knowledge until we reach
the End zone! No warning! No Informing the Public! Total theft, deletion, and insertions at the whim of the Human foundations
aiming for perfect human beings, discarding the message codes
in those genes that adapted to so-called errors. Were they
in our genes or in someone's mind!
"Reading the Human Blueprint:
The Human Genome Project
"All human disease is genetic in origin,'' Nobel laureate Paul Berg of Stanford University told a cancer symposium a few years ago.
Berg was exaggerating, but only slightly. It has become increasingly evident that virtually all human afflictions, from cancer to psychiatric disorders and susceptibility to infection, are rooted in our genes. "What we need to do now is find those genes," says James Watson, who shared a Nobel Prize for deciphering the structure of DNA.
Mapping the human genome actually began in 1911, when the gene responsible for red-green color blindness was assigned to the X chromosome. This flowed from the observation that color blindness was passed on to sons by mothers who saw colors normally. Females, who have two X chromosomes, are protected from this disorder by a normal copy of the gene on their second X chromosome—unlike males, who have one X and one Y chromosome.
Some other disorders that affect only males were likewise mapped to the X chromosome, but the other 22 pairs of chromosomes remained virtually uncharted until the late 1960s. At that time, biologists fused human and mouse cells to create hybrid cells and found that these uneasy hybrids cast off their human chromosomes until only one or a few of the human chromosomes remained. Any recognizable human proteins found in such cells would therefore have to be produced by genes located on the remaining human chromosomes. Narrowing down the number of chromosomes in this fashion allowed scientists to assign about 100 genes to specific chromosomes. ".......
www.hhmi.org/genetictrail/c100.html
============================
Note the names.
=====================
Albert Lasker
Basic Medical Research Award
Award Description
Paul Berg
Herbert Boyer
Stanley Cohen
A. Dale Kaiser
Paul Berg
For his key, historic achievements which made recombinant DNA a brilliant reality, and inaugurated a new age of biomedical promise.
Paul Berg brilliantly envisioned how a portion of a DNA molecule from one cell could be woven artificially into the DNA of another, and devised a fundamental technique which has helped to make recombinant DNA a practical reality.
In 1970, Dr. Berg began research to find a method for introducing additional DNA into the DNA of a living cell. Two years later, Dr. Berg and his co-workers showed that the well-known SV40 virus could be used as a carrier, or "vector," for DNA fragments. Dr. Berg used enzymes to cut a hole in the viral DNA and substitute a piece of bacterial DNA.
In 1976, Dr. Berg and his student, Stephen Goff, constructed a new kind of recombinant DNA, reintroducing it into the nucleus of a cultured animal cell, where it multiplied and functioned as a viral gene. In subsequent experiments, with his student Richard Mulligan, Dr. Berg introduced a new gene into the chromosomes of cultured animal cells, where the new gene functioned as if it were part of the cellular chromosomes, showing that artificially reconstructed DNA can cause changes in the biological activity of an animal cell.
Recombinant DNA will shape many vital industrial processes, from the preparation of vaccines to the creation of new sources of energy. It has already been used to establish new supplies of medically important natural substances such as human hormones and interferons.
Even more exciting, scientifically, is the prospect of learning, through recombinant DNA methodology, how human chromosomes are structured, and how genes really work. Dr. Berg's discoveries are helping scientists to clarify our understanding of development and differentiation of all living things. Recombinant DNA may reveal how the incalculable latent powers of human genes can be activated to maintain an individual's health and well-being.
To Dr. Berg, for his theoretical and technological discoveries, which have made recombinant DNA a brilliant reality and inaugurated a new, promising age of biomedical achievements, this 1980 Albert Lasker Basic Medical Research Award is given.
Herbert Boyer
For his brilliant contributions to recombinant DNA methodology, particularly in enzymology, plasmids, and in application of synthetic DNA.
Dr. Boyer was the first to show how restriction enzymes could be used to separate and rearrange segments of the DNA molecule. Using this expertise, he reconstructed bacterial plasmids, thereby making the technology of recombinant DNA straightforward and readily accessible. Dr. Boyer went on to show that synthetic DNA could be used to build plasmids as effectively as DNA from natural sources.
The restriction enzyme, EcoRI endonuclease, was discovered in Dr. Boyer's laboratory in 1968 and quickly became an indispensable tool in early recombinant DNA research. Dr. Boyer supplied this enzyme to Dr. Paul Berg and others in 1971 for recombinant DNA studies. In 1973, he entered an historic collaboration with Dr. Stanley Cohen, who was working with bacterial plasmids.
Dr. Boyer used enzymes to dissect and recombine the DNA of plasmids supplied by Dr. Cohen, who inserted the reconstructed plasmids into E. coli bacteria. The two investigators jointly analyzed the resulting clones of cells to detect the presence of the reconstructed plasmids. The critical moment came in 1974 when a plasmodium containing DNA from the South African toad replicated successfully in the bacteria—the first transplantation of genes between species.
In 1977, with Drs. Keiichi Itakura and Arthur Riggs, Dr. Boyer constructed a synthetic duplicate for the gene for the human brain hormone somatostatin. Placed in a plasmid and transplanted to E. coli, the gene functioned as if it were a bacterial gene, and the bacteria produced the hormone. This was the first time that bacteria produced a non-bacterial substance.
For his brilliant investigations of restriction and modification enzymes, for his central role in constructing plasmids with recombinant DNA and for his continuing studies in molecular genetics employing the recombinant DNA methodology which he was instrumental in creating, this 1980 Albert Lasker Basic Medical Research Award is given.
Stanley Cohen
For his splendid contributions to recombinant DNA methodology, and for accomplishing the first transplantation of genes between cells.
Stanley Cohen is honored for his imaginative and persevering studies of bacterial plasmids, for discovering new opportunities for manipulating and investigating the genetics of cells, and for establishing the biological promise of recombinant DNA methodology.
In 1968, Dr. Cohen began to focus his attention on the extrachromosomal elements of DNA known as plasmids, particularly those coding for resistance to antibiotics. He studied how plasmids replicate, the ways in which their DNA is organized, and the effects of transposing segments of the DNA within them. In 1972, he and his co-workers showed that purified plasmids can be introduced into the bacterium E. coli. This new genetic material can alter the biological activity of the bacterial cell. These transformed cells, Dr. Cohen showed, give rise to daughter cells which carry the progeny of the plasmids introduced into their progenitors.
Working with Dr. Herbert Boyer, Dr. Cohen began, in 1973, a stunning series of experiments which demonstrated that the genetics of cells could be manipulated in a variety of inventive ways. With the restriction enzyme EcoRI, an entirely new plasmid was constructed in vitro, and cloned in E. coli. Soon afterward, Dr. Cohen transplanted into E. coli genes from an unrelated bacterium and from an animal species. In both experiments, the transplanted genes were expressed in the new clones of cells.
With these techniques, scientists can now modify the genetics of cells to create results which were unimaginable before the work of Dr. Cohen. It is now possible to use the chemical-synthesizing apparatus of one cell to produce substances from the genetic blueprints of a totally unrelated cell.
For Dr. Cohen's splendid contributions to recombinant DNA methodology, which launched a new era in biological research technology, and for accomplishing the first transplantation of genes between cells, this 1980 Albert Lasker Basic Medical Research Award is given.
A. Dale Kaiser
For his crucial role in creating recombinant DNA methodology through his pathbreaking studies of cohesive single-stranded DNA.
A. Dale Kaiser is honored for his fundamental studies of the virus bacteriophage lambda and his invention of a method to render the ends of DNA fragments cohesive, thus placing in the hands of his fellow scientists both the concept of genetic engineering and an approach to recombining DNA.
In 1957, Dr. Kaiser set out to explore how DNA governs the biological activity of a cell. He reasoned that if DNA were removed from a cell, altered, and introduced into another, identical cell, the second cell would reflect, through differences in its biological activity, the changes in the transplanted DNA. To test this hypothesis, he undertook a series of strikingly original studies of the bacillus E. coli and the bacteriophage lambda.
Dr. Kaiser made the immensely significant discovery that the ends of the viral DNA molecule were single stranded and had a base-pair structure complementary to each other. Thus the ends of the molecule could join together to form a ring-shaped structure. He then devised a method of employing enzymes to create similar cohesiveness at the ends of any fragment of DNA, permitting them to join with each other.
This process, known as "tailing," makes it possible to join together any arbitrary pair of DNA fragments and thus to recombine DNA. Dr. Kaiser's discovery has become one of the basic tools in the field of recombinant DNA.
For his crucial role in creating the methodology of recombinant DNA, through his pathbreaking studies of the single-stranded cohesive ends of the DNA molecule, this 1980 Albert Lasker Basic Medical Research Award is given.
© LASKER FOUNDATION, 2009
www.laskerfoundation.org/awards/1980_b_description.htm
Epigenetics next.
skyship