Download - Bio technology-Lecture 14
BIOTECHNOLOGY=COLLECTION OF TECHNOLOGIES
Scientific knoweldge
Biotechnological tools
Useful applications
BIOTECHNOLOGYDEFINITIONS:
It is derived from two words
`BIO`-The use of biological process
`TECHNOLOGY`-To solve problems or make useful products.
`The applications of scientific and engineering principles to the processing of material by biological agents to provide goods and services`
PROCESS BIOTECHNOLOGY:
`It is concerned with what is happening in the industry. It is a discipline which enables its exponents to convert raw materials to final products when either the raw material or a stage in a production process involves biological entities.`
• Biotechnology in broader sense involves:• CLONERS• HYBRIDISERS• MOLECULAR AND CELL BIOLOGISTS
`It is defined as any technique that uses living organisms to make or modify a product, to improve plants or animals or to develop microorganisms for specific uses.`
PHARMACEUTICAL BIOTECHNOLOGY:
This science is based on the production of therapeutic proteins and hormones, fermentation products like antibiotics, vaccines or drugs, gene correction, drug delivery to specific tissue, standardization of therapeutic agents and the diagnostic aid using the gene cloning technology recombinant DNA technology.`
USEFUL APPLICATIONS
Pre- 1800:
Early applications and speculation
1800-1900:
Significant advances in basic understanding
1900-1953:
Genetics
PERIODS OF BIOTECHNOLOGY HISTORY
1953- 1976:
DNA research, science explodes
1977- present:
Modern biotechnology
Ancient biotechnology: Early history as related to food and shelter; Includes domestication
Classical biotechnology: Built on ancient biotechnology; Fermentation promoted food production, and medicine
Modern biotechnology:Manipulates genetic information in organism; Genetic engineering
DEVELOPMENT
Traditional/old biotechnology:
The conventional techniques that have been used to produce beer, wine, cheese, many other food
New/modern biotechnology:
All methods of genetic modification by recombinant DNA and cell fusion techniques, together with the modern development of traditional biotechnological process
Organismic biotechnology:
uses intact organisms; Does not alter genetic material
Molecular biotechnology:
alters genetic makeup to achieve specific goals
Transgenic organism- an organism with artificially altered genetic material
BIOTECHNOLOGY TIMELINES1660-1675 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.
Joseph Lister began using disinfectants such as phenol (=carbolic acid) in wound care and Surgery.
1868:Fredrich Miescher, a Swiss biologist,
successfully isolated nuclein, a compound that includes nucleic acid, from pus cells obtained from discarded bandages.
1902 HUMAN GENETICS BORN:o 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.
1905 X AND Y CHROMOSOMES RELATED TO GENDER:
o 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.
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.
1943-1953: Cortisone was first manufactured in large
amounts.KIND OF A FIRST BIOTECH PRODUCT
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.
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.
1973 AMES TEST: Bruce Ames, a biochemist , developed a
test to identify chemicals that damage DNA. The Ames Test becomes a widely used method to identify carcinogenic substances.
1977 - 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.
1978:a synthetic version of the human insulin
gene was constructed and inserted into the bacterium Escherichia 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.
1977:Genentech, 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
and The City of Hope National Medical Center announced the successful laboratory production of human insulin using recombinant DNA technology.
1980:Kary Mullis invented a technique for
multiplying DNA sequences in vitro by, the polymerase chain reaction (PCR). POLYMERASE CHAIN REACTION
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.
1994: first genetically engineered food the Flavr
Savr tomato is approved.
FUTURE PROSPECTS FOR THE DEVELOPMENT OF BIOTECHNOLOGY
For producing transgenic mice Gene Manipulation and Introduction
in Plant Biotechnology Genetic modification Animal biotechnology Plant biotechnology
GENETIC MODIFICATION
Genetic modification is a new technology.
It changes the genes found in living things.The penicillin gene can be taken from the
fungus and put into bacteria.These ‘genetically modified’ bacteria can
then produce very large quantities of penicillin.
New, more effective antibiotics can also be produced to help fight disease
ENVIRONMENTAL IMPACTSo Cheese making uses the enzyme rennet which
makes the milk proteins clot to form curd.o The liquid left is called whey.o Whey contains sugar. What would happen if
whey was released into rivers?
1. Bacteria would use the whey sugars as food and reproduce.
2. As the number of bacteria increased it would use up the oxygen so oxygen levels would decrease in the water.
3. Fish and other living organisms would start to die as the oxygen level decreased
POLLUTION PREVENTION:
To prevent pollution whey can be:-a. treated before release
b. upgraded (used for something else)UPGRADING WHEY:• Waste whey used as food for growing
some types of yeast.
• In the right conditions these yeast strains produce alcohol from the sugars in the whey.
• Alcohol produced is creamy (found in Baileys Irish Cream)
POLLUTION PREVENTION
Monitor ing waste
T r eat wit h bact er iabacter ia f eed on whey
carbon dioxide and water producedbacter ia removed/ clean water released
U pgr adewhey used as f ood f or yeast
yeast produces creamy alcoholused in product ion of Baileys I rish Cream
W aste whey
ANTIFREEZE PROTEINS(AFP)AFP gene & promoter can survive in
waters as cold as –1.2°C AFPs lower the freezing temperature of blood & fluids
Trout normally do not survive in water below –0.6°C
Transgenic trout containing an antifreeze protein.
ANIMAL BIOREACTORPHARMING
1997, Tracy the sheep, the first transgenic animal to produce a recombinant protein drug in her milk alpha-1-antitrypsin (AAT) treatment for emphysema & cystic fibrosis Created by PPL Therapeutics & The Roslin Institute
EXTRACTION OF SILK FROM GOAT MILK:
Nexia Biotechnologies transferred the silk gene from spiders into goats
Each goat produces several grams of silk protein in her milk
The silk is extracted, dried to a white powder, and spun into fibers
The fibers are stronger and more flexible than steel.
GLOFISH
• GloFish, originally developed in Singapore as a way to monitor water pollution.
• The normally black-and-silver zebra fish was turned green or red by inserting various versions of the GFP gene.
• GloFish are on sale throughout the US except in California.
• GloFish retail for about $5 per fish. Normal zebra fish cost around one tenth of the price.
BIOLOGICAL WASHING POWDERSBiological washing powders contain
enzymes.Enzymes are chemicals that improve the
way in which the powder cleans.
Biological washing powder is made up of: 1% enzymes
99% water softenersbleachother chemicals (to help water
get into the clothes)
• Where do the enzymes in washing powder come from?
• Bacteria are tiny organisms found almost everywhere on Earth.
• Scientists found bacteria that were harmless and produced enzymes that could be used in washing powders.
• Large numbers of these bacteria grow (cultured) very quickly in huge industrial fermenters that give the best conditions for growth.
• Enzymes produced are then separated from the bacteria and used to make biological washing powder.
Enzymes in washing powders digest the stains on clothes like enzymes in the gut digest food.
Different enzymes digest different stains.– Fat digesting enzymes digest fatty
stains.– Starch digesting enzymes digest fatty
stains.
Enzymes make up a small part of powder but a large part of the cleaning power!