Reproductive Biotechnology

81

Click here to load reader

Transcript of Reproductive Biotechnology

Page 1: Reproductive Biotechnology

Reproductive Biotechnology

Dr. B. Victor,St. Xavier’s

College,Tirunelveli-2

Page 2: Reproductive Biotechnology

About the presenter Dr.B.Victor is a highly experienced postgraduate

biology teacher, recently retired from the reputed educational institution St. Xavier’ s College, Palayamkottai, India-627001.

He was the dean of sciences and assistant controller of examinations.

He has more than 32 years of teaching and research experience

His research interest revolve around reproductive technology of Fishes.

Send your comments to : [email protected]

Page 3: Reproductive Biotechnology

Presentation outlineKinds of reproduction Annual Breeding Cycles Reproduction and Development Cloning Technology Types Of Cloningrecombinant DNA cloning, therapeutic cloningreproductive cloningEmbryo splitting, Nuclear Transfer Technology Benefits of human cloning

Page 4: Reproductive Biotechnology

Kinds of reproduction

Asexual reproductionInferior form of reproduction.Requires one parent animal.No involvement of gametes.Offspring identical to their parent.Mitotic chromosome division (Binary fission)E.g., protozoans, coelenterates

Page 5: Reproductive Biotechnology

Cloning / Asexual reproduction

Page 6: Reproductive Biotechnology

Sexual reproduction.

Requires two parents.Involvement of gametes.Meiotic chromosome division.Fusion of gametes results in fertilizationReshuffling of parental genes.Offspring not identical to their parents

Page 7: Reproductive Biotechnology

Sexual reproduction

Page 8: Reproductive Biotechnology

Parthenogenesis

Development of an egg without fertilization by sperm.Offspring genetically identical to their parents.Invertebrates ( e.g., arthropods)Vertebrates ( e.g., some fish )

Page 9: Reproductive Biotechnology

Parthenogenesis

Page 10: Reproductive Biotechnology

Annual Breeding Cycles

Continuous breedersBreeds throughout the year

e.g., human,. guinea pig, rat.

Seasonal breedersBreeds during specific seasons

e.g., dog , cat, sheep. cattle

Oestrus cycleFemales sexually receptive

during heat periode.g., cow, rat, pig

Menstrual cyclePeriodical discharge of menstruation

e.g., monkeys. Ape, man

Reproductive Cycles

Page 11: Reproductive Biotechnology

Reproduction and Development

Page 12: Reproductive Biotechnology

Human Ovary

Page 13: Reproductive Biotechnology

Reproductive hormonal cycles

Page 14: Reproductive Biotechnology

Oogenesis

Page 15: Reproductive Biotechnology

Oogenesis

Page 16: Reproductive Biotechnology

Seminiferous tubule

Page 17: Reproductive Biotechnology

Sperm

Page 18: Reproductive Biotechnology

Human development

Page 19: Reproductive Biotechnology

Human- Early development

Page 20: Reproductive Biotechnology

Human blastocyst

Page 21: Reproductive Biotechnology

Human Life cycle

Page 22: Reproductive Biotechnology

Cloning Technology

Page 23: Reproductive Biotechnology

What Is Cloning?

Cloning is the creation of an exact genetic replica of a small segment of DNA, a cell or a whole organism.

Page 24: Reproductive Biotechnology

Natural cloning : Identical twins and multiple births are an example of human clones that are created naturally.Artificial cloning: Dolly, the cloned sheep, was created artificially in a laboratory in Scotland in 1997 (Nature, 385, 810- 13).

Types of Cloning

Page 25: Reproductive Biotechnology

Natural Cloning

Cloning is a form of asexual reproduction which is widespread in nature. In single-cell organisms and plants, it is an entirely normal process (division, vegetative reproduction),

Page 26: Reproductive Biotechnology

Animal Cloning Animals can be cloned by embryo

splitting or nuclear transfer. Embryo splitting involves

bisecting the multicellular embryo at an early stage of development to generate "twins".

This type of cloning occurs naturally and has also been performed in the laboratory with a number of animal species.

Page 27: Reproductive Biotechnology

History of Cloning:1952 – Robert Briggs and Thomas King of the

Institute for Cancer Research, developed the first major technique, Somatic Cell Nuclear Transfer (SCNT)

1966 – John Gurdon of Oxford University created an adult frog clone using a tadpole somatic cell.

1980 – Embryo splitting, developed for livestock breeding.

1980 – 1996 –Various research groups cloned frogs, mice, and cattle.

1996 –Ian Wilmut and colleagues of Roslin Institute in Scotland created the first clone of an adult mammal using adult somatic cells and SCNT. Dolly, the famous cloned sheep is born.

Page 28: Reproductive Biotechnology

History of Cloning:

1997 – Ian Wilmut and colleagues cloned two other sheep, Molly and Polly.

1998 –Univ. of Hawaii announced the creation of 50 mice clones using adult cells.

2000 – PPL Therapeutics, Inc. cloned pigs from adult female pig body cells.

2001 – PPL Therapeutics, Inc. applied genetic engineering to pig cloning, so that the pigs contain a jellyfish gene.

2004 – South Korean scientists achieved the first successful human somatic cell nuclear transfer.

Page 29: Reproductive Biotechnology

TYPES OF CLONING

1. DNA Cloning DNA cloning is also

known as recombinant DNA technology, molecular cloning and gene cloning.

Gene cloning is also important for the development of drugs and treatments such as in pharmacogenetics and gene therapy

Page 30: Reproductive Biotechnology

TYPES OF CLONING

2.. Reproductive Cloning

Reproductive cloning is also called adult DNA cloning.

The purpose is to produce a genetic duplicate of an existing or previously existing organism.

Page 31: Reproductive Biotechnology

Traditional Reproduction and Cloning

Page 32: Reproductive Biotechnology

Types of Genetic Cloning

recombinant DNA cloning,

reproductive cloning

therapeutic cloning

Page 33: Reproductive Biotechnology

Recombinant DNA Cloning

Recombinant DNA cloning or gene cloning refers to the process by which a fragment of DNA is transferred from one organism to a self-replicating genetic element such as a bacterial plasmid or a virus. Plasmids are self-replicating extra-chromosomal circular DNA molecules and can be used to make many copies of the gene. These genetic elements can then be inserted into a host cell of interest and the function of the gene of interest studied.

Page 34: Reproductive Biotechnology

Reproductive Cloning

Reproductive cloning refers to the process by which an animal is created which had the same nuclear DNA as a previously existing animal. This is accomplished by the removal of the DNA containing nucleus of an egg and its replacement by the DNA from another cell. The egg is then stimulated to divide and following a number of divisions it can be transferred into the uterus of a suitable female host until its birth.

Page 35: Reproductive Biotechnology

Therapeutic cloning

Therapeutic cloning, or embryo cloning refers to the production of human embryos for research purposes. The goal of this is not to create cloned babies but to harvest the stem cells of the embryo that have the potential to develop into almost any cell in the body

Page 36: Reproductive Biotechnology

Artificial cloning procedures

Embryo splitting, Nuclear Transfer

Technology

Page 37: Reproductive Biotechnology

Embryo splitting Embryo splitting and nucleus transfer

differ in the degree of genetic identity achieved in the resulting embryos.

Embryo splitting changes neither the age nor the (toti-)potency of the cells used.

The (two) embryos from the splitting are in the same stage of development, exactly the same age as the undivided embryo would have been and genetically completely identical.

Page 38: Reproductive Biotechnology

The nucleus transfer technique

Transfer of the genetic program (the cell nucleus with the desired genetic material) from a totipotent blastomere to an unfertilised egg cell whose nucleus has previously been removed.

This technique basically offers the possibility of replicating an adult individual and their genetic program.

Page 39: Reproductive Biotechnology

Errors in nuclear-cloning technology First, most clones die early in gestation,

and only a few survive to birth or beyond. Second, cloned animals have common

abnormalities regardless of the type of donor cell or the species used, and

third, these abnormalities correlate with aberrant gene expression, which most likely results from faulty genomic reprogramming.

Fourth, the efficiency of cloning depends on the state of differentiation of the donor cell.

Page 40: Reproductive Biotechnology

Applications of DNA cloning

1. Genetic components (whole genes or parts of genes) can be reconstructed into unique combinations not easily achieved by natural selection, or synthetic genes can be constructed--Recombinant DNA. 2. Recombinant DNA can be introduced or reintroduced into bacteria, plants, or animals. 3. If an organism integrates recombinant DNA into their genome or genetic make-up, they are transgenic.

Page 41: Reproductive Biotechnology

Transgenic Technology An animal whose genetic

composition has been altered to include selected genes from other animals or species by methods other than those used in traditional breeding

Page 42: Reproductive Biotechnology
Page 43: Reproductive Biotechnology

Methods of Producing Transgenics A. Nuclear Transfer/Cloning a. Example: Dolly the Sheep b. Transfect primary cells c. Tranfer nucleus to oocyte B. Gene Targeting a. Infusion of mammary gland with genetically

manipulated virus --Similar to retroviral method b. Mitotically active alveoli incorporate gene (s) C. Spermatogonal Transfer a. Transfect Spermatogonia with recombinant

DNA b. Inject into Testis

Page 44: Reproductive Biotechnology

Techniques of Reproduction-Related Biotechnologies

A. Artificial inseminationB. Birth Control Pill C. Estrus synchronizationD. Superovulation E. Embryo transferF. In Vitro FertilizationG. Sperm & Embryo Sexing H. Embryo Splitting I. Transgenic Animals J. Cloning

Page 45: Reproductive Biotechnology

Steps in producing a transgenic animal.

Superovulation of Donor animala. Pregnant Mare Serum Gonadotropin (PMSG) --Follicle Stimulating Hormone-like --Increase number of developing follicles b. Human Chorionic Gonadotropin (hCG) --Luteinizing Hormone-like --Causes ovulation

Page 46: Reproductive Biotechnology

Oocyte Recovery Ovulation occurs every 21 days ( Cow,

horse) and 16 days (sheep, goat).In well managed domestic cattles, 8 – 10 eggs are superovulated.

Antral ( graffian follicles) are collected by laproscopic surgery.

Recovered follicles are allowed to grow in vitro.

Slaughterhouse ovaries also often used in livestock

Page 47: Reproductive Biotechnology

In vitro fertilization

1. Fertilization outside the mother2. First done in 1959 A. Accomplished technique in rodents, pigs, cows, and humans3. Must induce sperm capacitation A. Oviductal fluid in media B. New medias have been developed 4. Keep fertilization area small A. Buffer drop under paraffin oil

Page 48: Reproductive Biotechnology

in vitro Fertilization (IVF)

IVF is carried out in microdroplets of culture medium.

Each microdroplet contain 10 oocytes and 1 million sperms per ml ( one dose)

Page 49: Reproductive Biotechnology

Insertion of Recombinant DNA into Embryo

• Calcium phosphate precipitation

• Microinjection• Retroviral infection• Particle gun delivery• Electrophoration

Page 50: Reproductive Biotechnology

In vitro Oocyte Maturation (IVM)

a. Cleavage stage to Morulab. New Technology: PCR --Used to determine if genes is incorporated in blastomere's genome at this stage.

Page 51: Reproductive Biotechnology

Embryo Transfer Technology

a. Recipients are estrus synchronized with donor during the previous estrous cycleb. Prostaglandin F2-alpha commonly used--Causes luteolysis c. Surgical and non-surgical means are used in the transfers.

Page 52: Reproductive Biotechnology

Gestation and Parturtion

In Normal reproduction an animal produces about 4-5 offsprings in a lifetime

IVF technology can produce 50-80 offsprings in a lifetime.

Page 53: Reproductive Biotechnology

DNA from offspring analyzed for presence of transgene.

a. DNA isolated from tail, blood, etc.

b. Amplified by PCR if needed c. Analyzed by DNA

fingerprinting

Page 54: Reproductive Biotechnology

Methods of getting Recombinant DNA into the embryo

A. Microinjection of recombinant DNA into pronuclei (male) of 1 cell embryo or zygote, before syngamy occurs. a. Most successful method in farm speciesb. Recombinant DNA must have promotor and polyadenylation signals

Page 55: Reproductive Biotechnology

Retroviral Vectors

a. Infect early cleavage stage embryob. Can only incorporate DNA < 8 kbc. Dangerous

Page 56: Reproductive Biotechnology

Embryonic Stem (ES) Cells

a. May eventually replace microinjectionb. Techniquei. ES cells grown in tissue cultureii. Clonal cell lines selected iii. ES cells injected into inner cell mass of

blastocyst iv. Chimeric offspring have transgene c. Problemi. Few ES cells exist for other mammals ii. Recently pig ES cell line developed and used successfully to produce transgenic pig

Page 57: Reproductive Biotechnology

Sperm and Embryo Sexing

1. Production Applications A. Dairy and Egg production require more females B. Meat production prefer males C. Parents could pick the sex of a child2. Flow Cytometry A. Most successful methods for sperm sexing in animals B. Separates sperm by density (Y sperm have slightly less DNA) by FACs3. PCR amplification of sex-specific genes now possible for sexing embryos A. PCR = Polymerase Chain Reaction a. Amplifies DNAb. Specific sex-related genes i. HY antigen ii. SRY

Page 58: Reproductive Biotechnology

Nuclear FusionA. Fusion of same sex gametes (Pronuclei) a. Male/Male—androgenomes b. Female/Female--gynegenomes B. Only develop through blastocyst to gastrula stages a. Female genome needed for conceptus developmentb. Male genome needed for placental developmentC. Oocytes can be induced to undergo parthenogenesis a. Electrical shockb. Cold shockc. Hyaluronidase treatmentd. Gynegenomes

Page 59: Reproductive Biotechnology

Nuclear Fusion

Page 60: Reproductive Biotechnology

Embryo Splitting

1. Blastomeres must be totipotent --8-16 cell stage 2. Cell Mass cut with glass knife dividing groups of blastomeres 3. One set of cells put into denuded zona pellucida4. Identical twins result

Page 61: Reproductive Biotechnology
Page 62: Reproductive Biotechnology

Nuclear Transfer "Cloning"

1. Cell nucleus from another donor put into enucleated recipientA. Resulting offspring is a clone of the donor B. Until "Dolly" all donors were embryonic in origin 2. Frogs done in early 70s3. MammalsA. Mice (Early 80s) B. Cattle (Mid 80s) C. Sheep (Late 80s)

Page 63: Reproductive Biotechnology
Page 64: Reproductive Biotechnology

Technique of Nuclear transfer technology

First, the donor cells are grown under special conditions in culture. The number of cells can be increased by several orders of magnitude. It is also possible to make genetic modifications and to select just those cells in which the desired modification has occurred and multiply these up.

These cells are then fused with an unfertilised egg from which the introduced nucleus can lead to the formation of an embryo.

The embryos are then transplanted into sheep and lambs are born naturally.

This technology could allow the production of genetically identical groups of animals which possess a desirable genetic trait.

Page 65: Reproductive Biotechnology

Cloning technology of sheep

The Egg The unfertilised eggs are flushed out of a sheep which has been induced

to produce a larger than normal number of eggs.

The Cell Previously a sample of tissue was from the udder of a six year old ewe was

taken and cultured in a dish (Dolly 1). The cultured cells are starved to send them into a resting or quiescent

state.

The fusion A cell is placed beside the egg and an electric current used to fuse the

couplet.

Culture The reconstructed embryo is put into culture and grows for seven days.

Development Embryos which grow successfully are taken and transferred to a sheep

which is at the the same stage of the oestrus cycle as the egg. The sheep becomes pregnant and produces a lamb after 21 weeks (Dolly).

Page 66: Reproductive Biotechnology
Page 67: Reproductive Biotechnology

Applications

Page 68: Reproductive Biotechnology

Animals as drug producers

“Gene pharming", i.e. the use of transgenic animals to manufacture (human) proteins with therapeutic use, e.g. in their milk.

The active ingredients from biogenetic manufacturing processes (such as insulin, blood factors or other human bodily substances) can be obtained in much purer form.

Production of active ingredients can be on a large scale and relatively cheap.

Hazards to people (pathogens) can be avoided as far as possible by careful testing of drugs.

Page 69: Reproductive Biotechnology

Animal models

Cloning could be used in producing transgenic animals as animal models for human diseases.

Animal models are used to study the biochemical and physiological processes, human diseases and possible therapies.

New drugs can be tested in animal models for their toxicity and pharmacological effect on humans

Page 70: Reproductive Biotechnology

Xenotransplantation

Xenotransplantation is transplanting animal organs into humans.

Cloning of "donor animals",are made with the desired genetic modifications using nucleus transfer.

the alien animal organ will perform its function in the human recipient.

Page 71: Reproductive Biotechnology

Transgenic clones Animal cloning will increase the genetic

knowledge of productive animals. Animal cloning technologies will make

the "production" of transgenic animals with modified (agricultural) characteristics.

The goals for gene transfer in livestock breeding in combination with cloning are: quality enhancement, gene pharming, boosting resistance to disease, and cost reduction.

Page 72: Reproductive Biotechnology

Future of therapeutic cloning

Advances in stem cell therapy.

The availability of eggs. Learning to correct gene

defects in inherited diseases.

Page 73: Reproductive Biotechnology

Benefits of human cloning

Page 74: Reproductive Biotechnology

Benefits of human cloning-1

1. Aging: possible to reverse the aging process. 2. Cure for heart problems:.  possible to treat

heart attack victims by cloning their healthy heart cells and injecting them into the areas of the heart that have been damaged. 

3. Organ and tissue repair: Embryonic stem cells can be grown to produce organs or tissues to repair or replace damaged ones.  Skin for burn victims, brain cells for the brain damaged, spinal cord cells for quadriplegics and paraplegics, hearts, lungs, livers, and kidneys could be produced.

4.  Cure for Incurable diseases: Conditions such as Alzheimer's disease, Parkinson's disease, diabetes, heart failure, degenerative joint disease, and other problems may be made curable.

Page 75: Reproductive Biotechnology

Benefits of human cloning-2

5. Infertility: Human cloning could make it possible for infertile couples to have children .

6. Plastic, reconstructive, and cosmetic surgery: Instead of using materials foreign to the body for such procedures, doctors will be able to manufacture bone, fat, connective tissue, or cartilage that matches the patients tissues exactly.

Page 76: Reproductive Biotechnology

Benefits of human cloning-3

7.Defective genes. possible to inactivate defective genes.

8.Down's syndrome. women at high risk for Down's syndrome can avoid that risk by cloning.

9.Tay-Sachs disease. This is an autosomal recessive genetic disorder could be prevented by using cloning.

Page 77: Reproductive Biotechnology

Benefits of human cloning-4

10.liver failure. possible to clone livers for liver transplants.

11.kidney failure. possible to clone kidneys for kidney transplants.

12.leukemia.  possible to clone the bone marrow for children and adults suffering from leukemia. 

Page 78: Reproductive Biotechnology

Benefits of human cloning-5

13.cancer. possible to switch cells on and off through cloning and thus be able to cure cancer. 

14.cystic fibrosis. possible to produce effective genetic therapy against cystic fibrosis. 

Page 79: Reproductive Biotechnology

Benefits of human cloning-6

15.spinal cord injury. possible to grow nerves or the spinal cord back again when they are injured. 

16.testing for genetic disease. Cloning technology can be used to test for and perhaps cure genetic diseases.

Page 80: Reproductive Biotechnology
Page 81: Reproductive Biotechnology

Thank you