1. Application of biotech
Xingzhi Wang
School of Life Sciences
Northeast Normal University

2. History of Biotechnology
The term "biotechnology" was coined in 1919 by Karl Ereky, an Hungarian engineer
Traditional biotechnology has been used for thousands of years to produce improved food and health care products. Today, modern biotechnology enables us to develop improved products more safely and more rapidly than ever before.

3. Examples
Examples:
they could plant their own crops and breed their own animals, they learned to use biotechnology.
The discovery that fruit juices fermented into wine, or that milk could be converted into cheese or yogurt, or that beer could be made by fermenting solutions of malt and hops began the study of biotechnology

4. Examples cont’d
When the first bakers found that they could make a soft, spongy bread rather than a firm, thin cracker, they were acting as fledgling biotechnologists.
The first animal breeders, realizing that different physical traits could be either magnified or lost by mating appropriate pairs of animals, engaged in the manipulations of biotechnology.

5. Definition
Definition: What then is biotechnology? the term "biotechnology" refers to the use of living organisms or their products to modify human health and the human environment.
Other definitions: 1. •Biotechnologists use engineering and science to create new products from biologically based raw materials, such as vaccines or foods. They also develop factory processes to reduce pollution or treat waste products.
•2. Biotechnology uses living cells and materials produced by cells to create pharmaceutical, diagnostic, agricultural, environmental, and other products to benefit society.

6. Introduction Biotechnology is essentially
the use of living organisms (often minute microorganisms) and their products
for health, social or economic purposes.
Biotechnology is widely considered to be the growth technology of the 21st Century which will lead to huge growth in the Biotechnology industry and exciting opportunities for graduates.

7. BIOTECNOLOGY FIELDS OF APPLICATION

8. Introduction
Through genetic engineering scientists can combine DNA from different sources and this process is called “Recombinant DNA technology”
The secrets of DNA structure and functions have led to gene cloning and genetic engineering, manipulating the DNA of an organism

9. Introduction
Biotechnology is an interdisciplinary science including not only biology, but also subjects like mathematics, physics, chemistry, computing and engineering.
It is a blend of various technologies applied together to living cells for production of a particular product or for improving upon it.

10. BIOTECNOLOGY BIOCHEMISTRY GENETICS PHYSIOLOGY MICROBIOLOGY
CELL BIOLOGY
MOLECULAR
BIOLOGY
INMUNOLOGY
EMBRIOLOGY
INFORMATICS
CHEMICAL
ENGINEERING
ANALYTICAL
CHEMISTRY

11. Nature of Work
The nature of work of biotechnologists, being interdisciplinary, requires working together of people from different fields such as
biology, chemistry, biochemistry,
microbiology, molecular biology,
immunology, genetics,
engineering,
food science, agriculture etc.

12. Periods of Biotechnology History
Pre- 1800: Early applications and speculation
: Significant advances in basic understanding
: Genetics
: DNA research, science explodes
1977- present: modern biotechnology

13. Biotechnology Time Lines
6000 BC
Yeast was used to make beer by Sumerians and Babylonians.
4000 BC
The Egyptians discovered how to bake leavened bread using yeast.
420 BC
Socrates (470? BC), the Greek philosopher, speculated on why children don't always resemble their parents.
320 BC
Aristotle ( BC), told his students that all inheritance comes from the father.

14. Biotechnology Time Lines
1000 AD
Hindus observed that certain diseases may "run in the family." Spontaneous Generation is the dominant explanation that organisms arise from non-living matter. Maggots, for example, were supposed to arise from horsehair.
1630 AD
William Harvey concluded that plants and animals alike reproduce in a sexual manner:–egg isolated in 1800’s AD
Marcello Malpighi ( ) in this period used a microscope to study blood circulation in capillaries, described the nervous system as bundles of fibers connected to the brain by the spinal cord.

15. Biotechnology Time Lines
1673 AD
Anton van Leeuwenhoek ( ), He was the first scientist to describe protozoa and bacteria and to recognize that such microorganisms might play a role in fermentation.
1701
Giacomo Pylarini in Constantiople practiced "inoculation"--intentionally giving children smallpox to prevent a serious case later in life. Inoculation will compete with "vaccination"--an alternative method that uses cowpox rather than smallpox as the protecting treatment--for a century.

16. Biotechnology Time Lines
1809
Nicolas Appert devised a technique using heat to can and sterilize food
1827
The worldwide search for the elusive mammalian egg ended with the first observation of canine eggs. Remember 1630 and William Harvey
1850
ONE OF MY FAVORITES Ignaz Semmelweis used epidemiological observations to propose the hypothesis that childbed fever can be spread from mother to mother by physicians. He tested the hypothesis by having physicians wash their hands after examining each patient. He became despised by the medical profession and lost his job.

17. Biotechnology Time Lines
1856
Karl Ludwig discovered a technique for keeping animal organs alive outside the body, by pumping blood through them.
Louis Pasteur ( ) asserted that microbes are responsible for fermentation.
1859
Charles Darwin ( ) hypothesized that animal populations adapt their forms over time to best exploit the environment, a process he referred to as "natural selection." As he traveled in the Galapagos Islands, he observed how the finch's beaks on each island were adapted to their food sources.

18. Biotechnology Time Lines
1863
Louis Pasteur invented the process of pasteurization, heating wine sufficiently to inactivate microbes (that would otherwise turn the "vin" to "vin aigre" or "sour wine") while at the same time not ruining the flavor of the wine ℃ for half hour.
Anton de Bary proved that a fungus causes potato blight. A challenge for scientists during this period was to discern whether a microbe was the cause of, or the result of, a disease.

19. Biotechnology Time Lines
1865
Gregor Mendel ( ), an Augustinian monk, presented his laws of heredity to the Natural Science Society in Brunn, Austria. Mendel proposed that invisible internal units of information account for observable traits, and that these "factors" - which later became known as genes - are passed from one generation to the next. Mendel's work remained unnoticed, languishing in the shadow of Darwin's more sensational publication from five years earlier, until 1900, when Hugo de Vries, Erich Von Tschermak, and Carl Correns published research corroborating Mendel's mechanism of heredity. .

20. Biotechnology Time Lines
Pasteur investigated silkworm disease and established that diseases can be transmitted from one animal to another.
1865 Joseph Lister began using disinfectants such as phenol (=carbolic acid) in wound care and surgery as Pasteur developed the germ theory of disease

21. Biotechnology Time Lines
1868
Davaine used heat treatment to cure a plant of bacterial infection.
Fredrich Miescher, a Swiss biologist, successfully isolated nuclein, a compound that includes nucleic acid, from pus cells obtained from discarded bandages.
1870
W. Flemming discovered mitosis.

22. Biotechnology Time Lines
1871
DNA was isolated from the sperm of trout found in the Rhine River.
1873-6
Robert Koch investigated anthrax and developed techniques to view, grow, and stain organisms. He then photographed them, aided by Gram, Cohn, and Weigart.
1880
Studying fowl cholera, Pasteur published his work on "attenuated" or weakened strains of organisms that could not cause disease but protected against severe forms of the same disease.

23. Biotechnology Time Lines
1881 ANTRAX
Robert Koch described bacterial colonies growing on potato slices, on gelatin medium, and on agar medium. Nutrient agar became a standard tool for obtaining pure cultures and for identifying genetic mutants. This is considered by T.D. Brock to be the single most important discovery in the rise of microbiology.
Pasteur used attenuation to develop vaccines against the bacterial pathogens of fowl cholera and anthrax; this was a founding moment in immunology and opened new areas in the field of preventive medicine.

24. Biotechnology Time Lines
1883
Emil Christian Hansen made the
first pure yeast culture for beer
production in Gamle Carlsberg
Brewery, Copenhagen, Denmark.

25. Biotechnology Time Lines
1884
ROBERT KOCH STATED HIS "POSTULATES" FOR TESTING WHETHER A MICROBE IS THE CAUSAL AGENT OF A DISEASE.
Pasteur developed a rabies vaccine.
Christian Gram described the differential staining technique for bacteria known as the Gram stain.
Gregor Mendel died after 41 years of meticulously studying the heredity "factors" of pea plants. Having received no scientific acclaim during his lifetime, he said not long before his death, "My time will come."

26. Biotechnology Time Lines
Converging on DNA
1900 MENDEL’S WORK FINALLY TOOK ON IMPORTANCE
The science of genetics was finally born when Mendel's work was rediscovered by three scientists - Hugo DeVries, Erich Von Tschermak, and Carl Correns - each one independently researching scientific literature for precedents to their own "original" work.
1902 HUMAN GENETICS BORN
Walter Stanborough Sutton stated that chromosomes are paired and may be the carriers of heredity. He suggested that Mendel's "factors" are located on chromosomes.

27. Biotechnology Time Lines
1905
X AND Y CHROMOSOMES RELATED TO GENDER
Edmund Wilson and Nellie Stevens proposed the idea that separate X and Y chromosomes determine sex. They showed that a single Y chromosome determines maleness, and two copies of the X chromosome determine femaleness.
William Bateson and Reginald Crudell Punnett, along with others, demonstrated that some genes modify the action of other genes.
1906
Paul Erlich investigated atoxyl compounds and discovered the beneficial properties of Salvarsan - the first chemotherapeutic agent.

28. Biotechnology Time Lines
1907
Thomas Hunt Morgan began his work with fruit flies that will prove that chromosomes have a definite function in heredity, establish mutation theory, and lead to a fundamental understanding of the mechanisms of heredity.
1909 MENDEL’S LAWS TO ANIMALS
Wilhelm Johannsen coined the terms 'gene' to describe the carrier of heredity; 'genotype' to describe the genetic constitution of an organism; and 'phenotype' to describe the actual organism, which results from a combination of the genotype and the various environmental factors.

29. Biotechnology Time Lines
1910 BASIS OF MODERN GENETICS
Thomas Hunt Morgan proved that genes are carried on chromosomes, establishing the basis of modern genetics. With his co-workers, he pinpointed the location of various fruit fly genes on chromosomes, establishing the use of Drosophila fruit flies to study heredity..
1911
Thomas Hunt Morgan explained the separation of certain inherited characteristics that are usually linked as caused by the breaking of chromosomes sometimes during the process of cell division. Morgan began to map the positions of genes on chromosomes of the fruit fly.

30. Biotechnology Time Lines
1912
Lawrence Bragg discovered that X-rays can be used to study the molecular structure of simple crystalline substances.
1918
Herbert M. Evans found (incorrectly) that human cells contain 48 chromosomes.
1924 EUGENICS IN THE UNITED STATES
Politicians encouraged by the eugenics movement passed the U.S. Immigration Act of 1924, limiting the influx of poorly educated immigrants from Southern and Eastern Europe on the grounds of suspected genetic inferiority.

31. Biotechnology Time Lines
1926
Thomas Hunt Morgan published 'The theory of the gene', the culmination of work on the physical basis for Mendelian genetics based on breeding studies and optical microscopy.
Hermann Muller discovered that X-rays induce genetic mutations in fruit flies 1,500 times more quickly than under normal circumstances. This discovery provided researchers with a way to induce mutations, an important tool for discovering what genes do on their own.

32. Biotechnology Time Lines
1928
Fredrick Griffiths noticed that a rough type of bacterium changed to a smooth type when an unknown "transforming principle" from the smooth type was present. Sixteen years later, Oswald Avery identified that "transforming principle" was DNA.
Alexander Fleming noticed that all the bacteria in a radius surrounding a bit of mold in a petri dish had died. The age of penicillin thus began, although it would be almost 15 years before it was made available to the community for medicinal use.

33. Biotechnology Time Lines
1938
Proteins and DNA were studied in various labs with X-ray crystallography.
The term "molecular biology" was coined.
1941
ONE GENE ONE ENZYME
George Beadle and Edward Tatum experimented with Neurospora, a mold that grows on bread in the tropics, developing the "one-gene-one-enzyme" hypothesis: each gene is translated into an enzyme to perform tasks within an organism.

34. Biotechnology Time Lines
1943
The Rockefeller Foundation, collaborating with the Mexican government, initiated the Mexican Agricultural Program. This was the first use of plant breeding as foreign aid.
Cortisone was first manufactured in large amounts. KIND OF A FIRST BIOTECH PRODUCT
1944
Waksman isolated streptomycin, an effective antibiotic for TB.

35. Biotechnology Time Lines
1945
The U.N. Food and Agriculture Organization (FAO) was formed in Quebec, Canada.
CELLS GROWN IN LAB Isolated animal cell cultures were grown in laboratories.
1947
Barbara McClintock first reported on "transposable elements" - known today as "jumping genes." The scientific community failed to appreciate the significance of her discovery at the time.

36. Biotechnology Time Lines
1950
Erwin Chargaff found that in DNA the amounts of adenine and thymine are about the same, as are the amounts of guanine and cytosine. These relationships are later known as "Chargaff's Rules" and serve as a key principle for Watson and Crick in assessing various models for the structure of DNA. AT ABOUT THE SAME; GC ABOUT THE SAME.

37. Biotechnology Time Lines
: Expanding the Boundaries of DNA Research
The discovery of the structure of DNA resulted in an explosion of research in molecular biology and genetics, paving the way for the biotechnology revolution.
1953
Nature magazine published James Watson's and Francis Crick's manuscript describing the double helix structure of DNA.

38. Biotechnology Time Lines
1953
Gey developed the HeLa human cell line. HENRIETTA LACKS- DIED IN 1951 OF CERVICAL CANCER- MOTHER OF 5- HER CELLS FIRST SHOWN TO GROW OUTSIDE THE BODY FOR EXTENDED PERIODS- USED TO DEVELOP THE POLIO VACCINE

39. Biotechnology Time Lines
1957 CENTRAL DOGMA OF DNA- HOW DNA MAKES A PROTEIN
Francis Crick and George Gamov worked out the "central dogma," explaining how DNA functions to make protein.
1959
Francois Jacob and Jacques Monod established the existence of genetic regulation - mappable control functions located on the chromosome in the DNA sequence - which they named the repressor and operon.

40. Biotechnology Time Lines
1962
Watson and Crick shared the 1962 Nobel Prize for Physiology and Medicine with Maurice Wilkins. Unfortunately, Rosalind Franklin, whose work greatly contributed to the discovery of the double helical structure of DNA, died before this date, and the Nobel Prize rules do not allow a prize to be awarded posthumously.

41. Biotechnology Time Lines
1966 GENETIC CODE CRACKED
The genetic code was "cracked". Marshall Nirenberg, Heinrich Mathaei, and Severo Ochoa demonstrated that a sequence of three nucleotide bases (a codon) determines each of 20 amino acids.

42. Biotechnology Time Lines
1967
Arthur Kornberg conducted a study using one strand of natural viral DNA to assemble 5,300 nucleotide building blocks. Kornberg's Stanford group then synthesized infectious viral DNA.
1970
ONCOGENES Peter Duesberg and Peter Vogt, virologists at UCSF, discovered the first oncogene in a virus. This SRC gene has since been implicated in many human cancers.

43. Biotechnology Time Lines
1972
FIRST RECOMBINANT DNA MOLECULE
Paul Berg isolated and employed a restriction enzyme to cut DNA. Berg used ligase to paste two DNA strands together to form a hybrid circular molecule. This was the first recombinant DNA molecule.
1972 NIH GUIDELINES FOR RECOMBINANT DNA
In a letter to Science, Stanford biochemist Paul Berg and others called for the National Institutes of Health to enact guidelines for DNA splicing.. Their concerns eventually led to the 1975 Asilomar Conference.

44. Biotechnology Time Lines
1973 AMES TEST
Bruce Ames, a biochemist at UC Berkeley, developed a test to identify chemicals that damage DNA. The Ames Test becomes a widely used method to identify carcinogenic substances-carcinogen.
1975 RECOMBINANT DNA MORITORIUM
A moratorium on recombinant DNA experiments was called for at an international meeting at Asilomar, California, where scientists urged the government to adopt guidelines regulating recombinant DNA experimentation. The scientists insisted on the development of "safe" bacteria and plasmids that could not escape from the laboratory

45. Biotechnology Time Lines
1976 MORE ABOUT ONCOGENES
J. Michael Bishop and Harold Varmus, virologists at UCSF, showed that oncogenes appear on animal chromosomes, and alterations in their structure or expression can result in cancerous growth.
1976 RELEASE OF NIH GUIDELINES
The NIH released the first guidelines for recombinant DNA experimentation. The guidelines restricted many categories of experiments.

46. Biotechnology Time Lines
Present: The Dawn of Biotech
Genetic engineering became a reality when a man-made gene was used to manufacture a human protein in a bacteria for the first time.
Biotech companies and universities were off to the races, and the world would never be the same again. In 1978, in the laboratory of Herbert Boyer at the University of California at San Francisco, a synthetic version of the human insulin gene was constructed and inserted into the bacterium Escheria coli. Since that key moment, the trickle of biotechnological developments has become a torrent of diagnostic and therapeutic tools, accompanied by ever faster and more powerful DNA sequencing and cloning techniques.

47. Biotechnology Time Lines
1977
Genentech, Inc., reports the production of the first human protein manufactured in a bacteria: somatostatin, a human growth hormone-releasing inhibitory factor. For the first time, a synthetic, recombinant gene was used to clone a protein. Many consider this to be the advent of the Age of Biotechnology.
1978
RECOMBINANT INSULIN Genentech, Inc. and The City of Hope National Medical Center announced the successful laboratory production of human insulin using recombinant DNA technology.

48. Biotechnology Time Lines
1980 PATENTS ALLOWED
The U.S. Supreme Court ruled in that genetically altered life forms can be patented a Supreme Court decision in 1980 allowed the Exxon oil company to patent an oil-eating microorganism.
Kary Mullis and others at Cetus Corporation in Berkeley, California, invented a technique for multiplying DNA sequences in vitro by, the polymerase chain reaction (PCR).

49. Biotechnology Time Lines
1982
Genentech, Inc. received approval from the Food and Drug Administration to market genetically engineered human insulin The U.S. Food and Drug Administration approves the first genetically engineered drug, a form of human insulin produced by bacteria.
Michael Smith at the University of British Columbia, Vancouver, developed a procedure for making precise amino acid changes anywhere in a protein. SITE DIRECTED MUTAGENESIS.

50. Biotechnology Time Lines
1983
Eli Lilly received a license to make insulin.
1985
Genetic fingerprinting enters the court room.
Cal Bio cloned the gene that encodes human lung surfactant protein, a major step toward reducing a premature birth complication.
Genetically engineered plants resistant to insects, viruses, and bacteria were field tested for the first time.
The NIH approved guidelines for performing experiments in gene therapy on humans.

51. Biotechnology Time Lines
1986
The FDA granted a license for the first recombinant vaccine (for hepatitis) to Chiron Corp.
The EPA approved the release of the first genetically engineered crop, gene-altered tobacco plants.
1987
Calgene, Inc. received a patent for tomato polygalacturonase DNA sequence, used to produce an antisense RNA sequence that can extend the shelf-life of fruit.

52. Biotechnology Time Lines
1988
Harvard molecular geneticists Philip Leder and Timothy Stewart awarded the first patent for a genetically altered animal, a mouse that is highly susceptible to breast cancer.
1990
UCSF and Stanford University were issued their 100th recombinant DNA patent license. By the end of fiscal 1991, both campuses had earned $40 million from the patent. PATENTS AND MONEY

53. Biotechnology Time Lines
1990
The first gene therapy takes place, on a four-year-old girl with an immune-system disorder called ADA deficiency. The therapy appeared to work, but set off a fury of discussion of ethics both in academia and in the media.
The Human Genome Project, the international effort to map all of the genes in the human body, was launched. Estimated cost: $13 billion Formal launch of the international Human Genome Project.
Publication of Michael Crichton's novel Jurassic Park, in which bioengineered dinosaurs roam a paleontological theme park; the experiment goes awry, with deadly results.

54. Biotechnology Time Lines
1992
The U.S. Army begins collecting blood and tissue samples from all new recruits as part of a "genetic dog tag" program aimed at better identification of soldiers killed in combat.
1993
Kary Mullis won the Nobel Prize in Chemistry for inventing the technology of polymerase chain reaction (PCR).

55. Biotechnology Time Lines
1994
The first genetically engineered food product, the Flavr Savr tomato, gained FDA approval.
The first crude but thorough linkage map of the human genome appears.(See Science, v.265, Sep.30, '94, for the full color pull-out).
1995
A new coalition of mainstream religions launched a campaign seeking to overturn current laws allowing the patenting of genes used for medical and research applications. The group also includes Jeremy Rifkin, the controversial and outspoken critic of the biotechnology industry. SHOULD PATENTS BE ALLOWED?

56. Biotechnology Time Lines
1996
The discovery of a gene associated with Parkinson's disease provides an important new avenue of research into the cause and potential treatment of the debilitating neurological ailment.
A new inexpensive diagnostic biosensor test for the first time allow instantaneous detection of the toxic strain of E. coli E. coli strain 0157:H7, the bacteria responsible for several recent food-poisoning outbreaks. CAN IT BE DONE FOR ANTRAX OR OTHER BIOTERRORISM AGENTS?
Surveys indicate the public regards research into the workings of the human genome and gene therapy with a combination of fear and mistrust

57. Biotechnology Time Lines
1997
Researchers at Scotland's Roslin Institute report that they have cloned a sheep--named Dolly--from the cell of an adult ewe. Dolly the first sheep cloned by nuclear transfer technology bearing a human gene appears later. Nuclear transfer involves transferring the complete genetic material (the DNA contained in a nucleus) from one cell into an unfertilized egg cell whose own nucleus has been removed. .

58. Biotechnology Time Lines
1998
Two research teams succeed in growing embryonic stem cells, the long sought grail of molecular biology.
Scientists at Japan's Kinki University clone eight identical calves using cells taken from a single adult cow.
A rough draft of the human genome map is produced, showing the locations of more than 30,000 genes.

59. Biotechnology Time Lines
1999
MAD COW DISEASEA new medical diagnostic test for the first time allow quick identification of BSE/CJD a rare but devastating form of neurologic disease transmitted from cattle to humans.

61. Application of Biotechnology
Its use and application ranges from fields like agriculture to industry (food, pharmaceutical, chemical, bioproducts, textiles etc.), medicine, nutrition, environmental conservation, animal sciences etc. making it one of the fastest growing fields.
The work is generally carried out in the laboratories, as it is a scientific research oriented field.

62. Current Applications of Biotech
Before going in-depth with a few areas of biotech research, it is important to gain a brief understanding of the many applications of biotechnological advancements.
Microbial
Agricultural
Animal
Forensic
Environmental
Aquatic
Medical

63. Biotecnology Application
RED BIOTECHNOLOGY:
Medicine and pharmaceutics
GREEN BIOTECNOLOGY:
Agriculture and food
WHITE BIOTECNOLOGY:
Industrial proccesses
BLUE BIOTECNOLOGY:
Environment

64. Biotech Applications
Biopolymers and Medical Devices- natural substances useful as medical devices
hyaluronate- an elastic, plastic like substance used to treat arthritis, prevent postsurgical scarring in cataract surgery, used for drug delivery
adhesive substances to replace stitches
Designing Drugs – using computer modeling to design drugs without the lab- protein structure

65. Biotech Applications
Replacement Therapies- lack of production of normal substances
Factor VIII- missing in hemophilia
Insulin
Use of Transgenic Animals and Plants

66. Biotech Applications
Gene Therapy – replace defective genes with functional ones
ADA (adenosine deaminase) deficiency
cystic fibrosis
Immunosuppressive Therapies – used to inhibit rejection (organ transplants)
Cancer Therapies -one method is antisense technology
Vaccines – biggest break through in biotechnology- prevention of disease

67. Products of Modern Biotechnology
There are a wide variety of products that the biotechnology field has produced.
More than 65% of biotech companies in the U.S. are involved in pharmaceutical production (relating to drugs developed for medical use).
Genentech developed Humulin (human insulin) to treat diabetes.
It was the first biotech drug to be FDA approved.

68. Products of Modern Biotechnology
There are more than 80 biotech drugs, vaccines, and diagnostics with more than 400 biotech medicines in development targeting over 2oo diseases!
Nearly 1/2 of new drugs target cancer

69. Top 10 Selling Biotech Drugs
Developer
Function
Betaseron
Chiron/Berlex
Multiple sclerosis
Ceredase
Genzyme
Gaucher’s disease
Engerix B
Genentech
Hepatitis B vaccine
Epiver
GlaxoSmithKlein
Anti-HIV
Epogen
Amgen
Red blood cell enhancement
Genotropin
Growth failure
Humulin
Diabetes
Intron
Biogen
Cancer & viral infections
Neupogen
Neutropenia reduction
Procrit
Platelet enhancement

70. Biotech Treatments
In the near future, it may be commonplace for treatments to include the use of gene therapy (attempt to replace “defective” gene with “normal” gene) and tissue engineering (designing & growing tissues for use in regenerative medicines).
1st Genetically Modified Organism (GMO) to produce human protein was E. coli (pictured right) that was given DNA to produce somatostatin (hGH -human growth hormone )

71. tPA
One of the first genetically engineered (GE) products sold was tissue plasminogen activator (tPA)
tPA is a blood clot dissolving enzyme used immediately after a heart attack or stroke to clear blocked vessels

72. Other Biotech Products
Other biotech products include proteins in:
home pregnancy tests (monoclonal antibodies)
frost-resistant strawberry plants
Although many are focused on medical and agricultural applications, some are for our own fashion interests (specialty apparel)!

73. Genes for Jeans?
Stonewashed jeans use genetically engineered enzymes (amylase & cellulase) to create a faded look
Originally, pumice stones were used (jeans washed with the stones)
This method damaged the machines

74. Microbial Applications
Bacteria & yeast are the most frequently used microbes
Better enzymes and organisms for making foods, simplifying manufacture and production processes, and making decontamination processes for industrial waste product removal more efficient.
Microbes used to clone and produce batch amounts of important proteins

75. Agricultural Applications
Agricultural Biotechnology is estimated to be $6 billion market (2005), including applications such as:
Pest-resistant plants
Higher protein & vitamin content in foods
Drugs developed and grown as plant products
Drought-resistant, cold-tolerant, and higher-yielding crops

76. Plant Advantage
The Ag-Biotech field boasts about the plant advantage over microbial biotech.
Plant advantage refers to the fact that the cost of producing plant material with recombinant proteins is often significantly lower than bacteria
Also, the Ag biotech may combine with medical biotech in order to produce drugs with molecular pharming

77. Molecular Pharming
Molecular pharming is the use of genetically modified plants (or animals) as a source of pharmaceutical products.
These are usually recombinant proteins with a therapeutic value.
This is an emerging but very challenging field that requires:
manipulation (at the genetic engineering level) of protein glycosylation (addition of polysaccharide chain)
subcellular protein targeting in plant cells

78. Animal Applications Animals can be used as bioreactors!
Many human therapeutic proteins are needed in massive quantities (>100s of kgs), so scientists create female transgenic animals to express therapeutic proteins in milk.
Goats, cattle, sheep, & chickens are sources of antibodies (protective proteins that recognize & destroy foreign material)
Transgenic refers to containing genes from another source

79. Dolly
In 1996, Dolly sheep became the first cloned animal created by somatic cell nuclear transfer process.
Born: July 5, 1996
Announced: February 22, 1997
Died: February 14, 2003
Dolly was cloned from a cell taken from a six-year-old ewe
She became the center of much controversy that still exists today

80. Dolly the sheep, the first mammal to be cloned from an adult cell
Dolly gave birth to four lambs

81. Cloned kitty
The first two cats cloned by chromatin transfer

82. Human Clone
Britain grants embryo cloning patent and became the first country in the world to grant a patent covering cloned early-stage human embryos. The decision ignited new controversy among biotechnology critics even though the Geron Corporation, the company licensed to use the patent, has no intention of creating cloned humans.

83. Cloning in the public eye: myths and misconceptions!!!
Bush says cloning human embryos is 'morally wrong.'

84. Knock Outs
Basic research in biotech uses knock-out experiments, which are very helpful for learning about the function of a gene.
A knock-out is created when an active gene is replaced with DNA that has no functional information.
Without the gene present, it may be possible to determine how the gene affects the organism (its function)

85. Aquatic Applications
Aquaculture is a common aquatic application of biotech.
Aquaculture is the process of raising finfish or shellfish in controlled conditions for food sources.
Products include:
transgenic salmon (increased growth rates)
disease-resistant oysters
vaccines against viruses that infect aquatic species
Overall, aquatic organisms are thought to be rich & valuable sources for new genes, proteins, & metabolic processes.

86. Medical Applications
Medical applications of biotech include preventative, diagnostic, and treatment.
The Human Genome Project is very useful within this field.
Gene therapy and stem cell technologies are two up-and-coming fields within the medical area of biotech.
Stem cell technologies include immature cells that have the potential to develop and specialize into a variety of other cell types.

87. Stem Cells
Different chemicals can coax them to develop into different cell types.
Newest, most promising area
Most controversial

88. Forensic Applications
DNA fingerprinting is the classic example of a forensic application. It is used most commonly for law enforcement and crime scene investigation (CSI).
It was first used in 1987 to convict a rapist in England.
Other applications of DNA fingerprinting include:
identifying human remains
paternity tests
endangered species (reduces poaching)
epidemiology (spread of disease )

89. Environmental Applications
The major environmental use is for bioremediation.
Bioremediation is the use of biotech to process or degrade a variety of natural and manmade products, especially those contributing to pollution
Therefore, cleaning up environmental hazards produced by industrial progress is a major application of this type of biotechnology.
There is a strong tie to microbial biotech (since many microbes are helpful for this area).

90. Bioremediation
Bioremediation can be defined as any process that uses microorganisms or their enzymes to return the environment altered by contaminants to its original condition.

91. ENVIRONMENT
Environmental biotechnology has become another area of extensive work due to the dangers brought about by increasing levels of environmental pollution.
A lot of hard work is being done to protect our environment. In this field, the job of a biotechnologist spans from checking industrial air pollution levels, treatment of industrial waste to recycling of sewage sludge.

92. Oil Spill
In the 1970s, the first U.S. GMO patent was granted to a scientist for a strain of bacteria capable of degrading components in crude oil.
In 1989, the Exxon Valdez oil spill in Alaska used Pseudomonas species (oil-degrading bacteria) to clean up the spill
It was 3x faster & without increased environmental effects

93. Waste Management Environmental Pollution is a major problem
Landfills are becoming full
Old dump sites are creating problems
Waste is piling up
Sewage and chemical disposal is a constant problem
Environmental pollution and the elimination of waste products from home, business, industry, utility, government, the military, and other sources has become a major problem throughout the world. Landfills are becoming full and causing problems of leakage into the ground water, old dump sites are creating new problems, waste is piling up, and sewage and chemical disposal is a constant problem. The “tipping” or unloading fee for dumping solid waste material in landfills has risen from as low as $3.00 per ton in some communities in the early 1980s to over $ per ton for New York City in the middle 1990s. Further, from 1993 levels, the environmental laws mandate a reduction in solid waste disposal by 10 percent by 1995, 27 percent by 1997, and 40 percent by the year 2000.

94. Waste Management
Genetically altered bacteria are used to feed on oil slicks and spills
Bacteria are being developed to decompose or deactivate dioxin, PCBs, insecticides, herbicides, and other chemicals
Bacteria are under development to convert solid wastes into sugars and fuel
Biotechnology is being used to help solve waste disposal problems. Already, genetically altered bacteria are used to feed on oil slicks and spills to transform this serious pollutant into less harmful products. Similarly, bacteria have been developed to decompose or deactivate dioxin, PCBs, insecticides, herbicides, and other chemicals in our rivers, lakes, and streams. And, bacteria strains are under development to convert solid waste from humans and livestock into sugars and fuels.
While great progress has been made in pollution reduction in some areas, pollution is still one of the world’s greatest problems. Biotechnology has brought some spectacular breakthroughs in waste use and decomposition and promises much more in the future.

95. Biomaterials
Biotechnology is the technology connected with plant, animal, and human life.
For example, knowledge about the joints, muscles, and nerve endings in our bodies can be combined with engineering to develop an artificial hand.
These human-made materials designed to be placed within the human body are called biomaterials.

96. Transplant Organs for Humans
Inadequate supplies of human organs for transplantation result in more than 25,000 deaths annually.
Researchers are studying ways to develop organs in animals suitable to be transplanted into humans until human organs become available.
Especially promising are pig organs!!!

97. Photo of mouse growing a "human ear" - a shape made of cartilage

98. Biohand: knowledge from the joints, muscles, and nerve

99. Genetically Modified Food
Can animal genes be jammed into plants? Would tomatoes with catfish genes taste fishy? Have you ever eaten a genetically modified food? The answers are: “yes”, “no” and almost definitely “yes”
Despite dire warnings about "Frankenfoods“, there have been no reports of illness from these products of biotechnology.

102. GM potato 'could improve child health'

103. Approved Biotech Products
1982: FDA approves genetically engineered human insulin
1986: Orthoclone OKT3 (Muromonab-CD3) approved for reversal of kidney transplant rejection.
1986: first recombinant vaccine approved- hepatitis
1987: Genentech gets approval for rt-PA (tissue plasminogen activatior) for heart attacks

104. Approved Biotech Products
1990: Actimmune (interferon 1b) approved for chronic granulomatous disease
Adagen (adenosine deaminase) approved for severe combined immunodeficiency disease.
1994: first genetically engineered food the Flavr Savr tomato is approved.
1994: Genentech’s Nutropin is approved (growth hormone deficiency)

105. Approved Biotech Products
1994: Centocor’s ReoPro approved (for patients undergoing balloon angioplasty)
Genzymes Ceredase/Cerezyme approved for Gaucher’s Disease (inherited metabolic disease)
Recombinant GM-CSF approved (chemotherapy induced neutropenia)
1998: Centocor’s RemicadeTM approved (monoclonal antibody for Crohn’s disease)

106. Focus on “Famous” Biotech Product: Insulin
Insulin is a hormone, and therefore, a protein.  
Insulin was the first hormone identified (late 1920's) which won the doctor and medical student who discovered it the Nobel Prize (Banting and Best). 
They discovered insulin by tying a string around the pancreatic duct of several dogs. 
Note that there are other hormones produced by different types of cells within pancreatic islets (glucagon, somatostatin, etc) but insulin is produced in far greater amounts under normal conditions making the simple approach used by Banting and Best quite successful.

107. Properties of Insulin
Insulin is secreted by groups of cells within the pancreas called islet cells.
The pancreas is an organ that sits behind the stomach and has many functions in addition to insulin production.
The pancreas also produces digestive enzymes and other.
Without insulin, you can eat lots of food and actually be in a state of starvation since many of our cells cannot access the calories contained in the glucose very well without the action of insulin.

108. Insulin (cont’d)
The first successful insulin preparations came from cows (and later pigs).  The pancreatic islets and the insulin protein contained within them were isolated from animals slaughtered for food in a similar but more complex fashion than was used by our doctor and med-student duo. 

109. Wockhardt launches indigenous human recombinant insulin
Mr H. Khorakiwala, Chairman, Wockhardt Ltd, with
Dr M. Sahib, Director, Genomics & Biotech Research, at the launch of human recombinant insulin `Wosulin' in Mumbai

110. Thank you

111. Biotech Applications Diagnostics Therapeutics Antibodies Biosensors
PCR
Therapeutics
Natural Products
Foxglove:
digitalis: heart conditions
Yew tree- cancer agent (taxol) breast and ovarian cancers
Endogenous Therapeutic agents – proteins produced by the body that can be replicated by genetically engineered: tPA – tissue plasminogen factor (dissolves blood clots)

112. Approved Biotech Products
1938: Howard Florey/Ernst Chain, Oxford U., England isolated penicillin
: Large scale production of penicillin
: Cortisone first manufactured in large amounts
1977: Genentech produced somatostatin (human growth hormone-releasing inhibitory factor), manufactured in bacteria. First time a recombinant gene was used to clone a protein.
1978: Harvard researchers produced rat insulin by recombinant DNA.