Genetics

Question 1

DNA

Answer 1

• Deoxyribose nucleic acid - Found in the nucleus - All DNA has a similar structure

Question 2

Major components of DNA

Answer 2

• Sugars - Phosphates - Bases - These make up the ‘back bone’ of the DNA structure

Question 3

4 types of bases (an their pairs)

Answer 3

• Adenine always pairs with thymine - Guanine always pairs with cytosine

Question 4

What is a nucleotide?

Answer 4

• Sub-unit of the DNA molecule - Consists of one sugar, one phosphate and one base molecule

Question 5

What is a chromosome?

Answer 5

DNA wrapped into a double helix structure around proteins called histones

Question 6

What is a gene?

Answer 6

• Each section of DNA that controls a trait - Humans have around 25,000 genes in their chromosomes - Genes for a particular trait are controlled at a particular point in the chromosome

Question 7

Somatic cells

Answer 7

46 chromosomes (23 pairs)

Question 8

Gametes

Answer 8

23 single chromosomes

Question 9

Homologous pair

Answer 9

a pair of chromosomes containing the pair of genes for a particular trait

Question 10

What are alleles?

Answer 10

• The alternative forms of a gene that are available - The pairs of alleles that each person inherits from their parents control and determine the characteristics of the individual - Many genes have two alleles (dominant and recessive)

Question 11

What is a genotype?

Answer 11

• The genetic makeup of an individual - It is inherited - E.g. BB/bb/Bb

Question 12

What is a phenotype

Answer 12

• The observed expression of the alleles for the characteristics - Determined by the genotype and the environment

Question 13

What is monogenic inheritance?

Answer 13

• Exists when an individual receives just one pair of alleles for a trait - E.g. blood groupings - The traits are discrete (either there or not there) - Only two alleles for the trait - Only two phenotype

Question 14

What is polygenic inheritance

Answer 14

• Many pairs of genes control the trait - Continuous variation of the trait - Alleles will have an additive effect - E.g. skin colour height and weight - Continuous traits = many phenotypes

Question 15

Skin colour

Answer 15

• Is a polygenic trait - Many genes contribute - Continuous variation - Depends on the amount of melanin in the skin

Question 16

What do melanocytes produce?

Answer 16

Melanocytes produce structures called melanosomes that contain melanin and are found in the bottom of the epidermis of the skin

Question 17

How is melanin produced?

Answer 17

It is made from an amino acid called tyrosine

Question 18

Amounts of melanocytes and melanosomes in different people

Answer 18

Most people have similar amounts of melanocytes and varying amounts of melanosomes

Question 19

Darker skinned people

Answer 19

• Can convert more tyrosine into melanin because they have more tyrosinase - More melanosomes containing more melanin - There are also more evenly distributed throughout the skin - This prevents burning

Question 20

Pale skin

Answer 20

• Less tyrosinase and therefore can’t convert as much tyrosine into melanin - Melanin is not evenly distributed and form clumps - Burns when exposed to UV light

Question 21

Tyrosinase (enzyme)

Answer 21

• Brings about the production of melanin - Stimulated by UV rays - People with the enzyme will become darker skinned in the sun - Those with less tyrosinase will tan less well - Therefore, the environment affects the phenotype - Darker skin will prevent sun burn

Question 22

What is a mutation?

Answer 22

• A permanent change to a gene or chromosome leading to a new characteristic in an organism - Due to changes in the base sequences in a section of DNA which alters the types of proteins that will be synthesised by the body - Can be advantageous or disadvantageous

Question 23

What is a mutant?

Answer 23

An organism with a characteristic resulting from a mutation

Question 24

What are mutagens?

Answer 24

• Agents that are known to increase the rate at which mutations occur - E.g. UV light, X-rays, radiation, chemicals such as sulphur dioxide or antibiotics

Question 25

Somatic mutations

Answer 25

• Occur in a body cell - The reproductive cells are not affected and once the organism dies, the mutation will be lost

Question 26

Germ-line mutations

Answer 26

• Mutation occurring in the gametes - The individual is not usually affected - The individual will produce gametes with changed DNA

Question 27

Main types of mutations

Answer 27

• Gene mutations - Chromosomal mutations

Question 28

Gene mutations

Answer 28

• Change in a single gene - They occur during the replication of the DNA molecule before cell division - If the DNA copies incorrectly, the changed DNA will continue to be copied in all future divisions - May code for a new amino acid and a completely different protein

Question 29

What is a point mutation?

Answer 29

a change in one base

Question 30

Albinism

Answer 30

• The result of a missing protein - The protein responsible for the pigment (melanin) of hair, skin and eyes is missing - Patients have whitish blond hair, extremely pale skin and pinkish eyes

Question 31

Duchene muscular dystrophy

Answer 31

• The deletion of a base - Missing the protein dystrophin - May arise through a mutation in the mother, which can then be inherited by her sons - Results in the wasting of the leg muscles and later, the arms, shoulders and chest - Usually becomes apparent around the age of 3 to 5 years, when muscle weakness becomes evident - Eventually death occurs due to failure of the respiratory muscles - Boys with the Duchene form of muscular dystrophy are unlikely to live for more than 20 to 25 years

Question 32

Cystic fibrosis

Answer 32

• The mutation occurs in a huge gene on chromosome 7 - Changes to the DNA of the CFTR gene results in different amino acids in the CFTR protein - The CFTR protein regulates the development of the chloride channels in the cell membrane - Without it the person cannot transport chloride ions and regulate the movement of water into and out of the cells - The person suffers from salty tasting skin, persistent coughing, wheezing and digestive problems - Thick, sticky mucous blocks the airway, as well as the pancreatic and bile ducts

Question 33

Lethal recessive alleles

Answer 33

Cause the death of the embryo or foetus (miscarriage or spontaneous abortion) or the early death of the child

Question 34

Tay-sachs disease (TSD)

Answer 34

• Disorder of lipid metabolism that is inherited in an autosomal recessive pattern - Lethal recessive condition - The missing enzyme results in the accumulation of a fatty substance in the nervous system - A baby with two recessive alleles develops normally for the first two months, then deterioration causing mental and physical disabilities begins - Death usually occurs in early childhood

Question 35

Chromosomal mutations

Answer 35

Occur when there is a change in the whole or part of the chromosome. Many genes can be affected

Question 36

Types of chromosomal mutations

Answer 36

1. Deletion – part of the chromosome is lost 2. Duplication – a section of the chromosome occurs twice 3. Inversion – breaks occur in a chromosome and the broken piece joins back in, but the wrong way around 4. Translocation – part of a chromosome breaks off and is re-joined to the wrong chromosome 5. Non-disjunction – during meiosis, a chromosome pair does not separate, so one daughter cell has one extra chromosome (trisomy) and one has one less (monosomy)

Question 37

Examples of non-disjunction (monosomy)

Answer 37

• Cri-du-chat - Turners

Question 38

Cri-du-chat

Answer 38

• Due to a missing portion of chromosome 5 - Infants often have problems with the larynx and nervous system

Question 39

Turners syndrome

Answer 39

• Due to a missing sex chromosome - These individuals are born female, but are short in stature, lack secondary sex characteristics and are infertile

Question 40

Examples of non-disjunction (trisomy)

Answer 40

• Down-syndrome - Patau syndrome - Klinefelter syndrome

Question 41

Down syndrome

Answer 41

• Occurs when an individual has an extra chromosome 21

Question 42

Patau syndrome

Answer 42

• Occurs when an individual has an extra chromosome 13 - Individuals often have a small head, mental retardation, an extra finger on each hand, a cleft palate and malformation of the eyes and ears

Question 43

Klinefelter syndrome

Answer 43

• Occurs when individuals have an extra X or Y chromosome

Question 44

What is biotechnology?

Answer 44

Uses cellular processes to make products that are of use to humans. It includes genetic testing, gene manipulation, cell replacement therapies and tissue engineering

Question 45

How has the age of our population changed?

Answer 45

The maximum age to which people can live does not seem to have changed a great deal, although the number of people reaching theses ages has increased enormously

Question 46

What is a genome?

Answer 46

The complete set of genetic information of an organism

Question 47

The human genome project

Answer 47

• The compete sequence of the nucleotides that make up approximately 21,000 genes in our chromosomes - An international research effort - Mapped the location of all 46 chromosomes in the human nucleus - Completed in 2003, but analysis of the data is continuing - 4,000 genetic disorders have been identified on the chromosomes already - Identified the location of all these faulty genes

Question 48

Why is the human genome project important?

Answer 48

• If you are able to identify where faulty genes are, they can be replaced with healthy ones (gene replacement therapy) - If you know where genes are located that cause diseases, then you can monitor the gene expression - If you know where genes that cause diseases are located, then you can screen for these diseases using genetic tests so that you are aware of the disease - The diseases could be prevented by changes in lifestyle or preventative drug treatment

Question 49

Hereditary diseases

Answer 49

• Caused by defective genetic information being transmitted from one generation to another - Inherited in the same fashion as ‘healthy’ traits - Often caused by mutations to the normal DNA

Question 50

What is a mutation?

Answer 50

A disruption (change) to a healthy nucleotide sequence

Question 51

What is DNA sequencing?

Answer 51

The determination of the precise order of nucleotides in a sample of DNA

Question 52

Spastic paraplegia

Answer 52

• Progressive limb weaknesses and stiffness resulting in paralysis - Symptoms begin from mid-20’s to mid-50’s - Researchers studies families in which the disease occurred - Sequences (alleles) in parts of chromosome 2 were different in affected family members (from those not affected) - No cure – treatment involves physical therapy to try to improve muscle strength and safeguard muscular movements - Knowing the location of the responsible gene allows people to be screened for the disorder and to seek effective treatment to prevent the disease or reduce its effects

Question 53

DNA sequencing can be used to determine alleles for:

Answer 53

1. Sickle cell anaemia 2. Cystic fibrosis 3. Some cancers 4. Spastic paraplegia 5. Can also be used for maternity and paternity testing

Question 54

Gel electrophoresis

Answer 54

• The DNA pieces are placed on a bed of semi-solid gel - An electrical current is passed through electrodes at either end - The DNA (negatively charged), moves through the gel towards the positive electrode - The smaller segments move faster than the larger ones, resulting in a pattern of bands

Question 55

Restriction enzymes

Answer 55

• Cut long strands of DNA into shorter pieces of DNA - Cuts are made at particular sequences in the DNA called recognition sites

Question 56

Types of restriction fragments

Answer 56

• Blunt ends - Sticky ends

Question 57

What is the banding pattern called?

Answer 57

DNA fingerprint or DNA profile

Question 58

Polymerase chain reaction

Answer 58

segments of DNA are artificially multiplied through a series of repeated cycles of duplication using an enzyme called DNA polymerase

Question 59

What is the role of a primer?

Answer 59

• Initiates duplication - A segment of DNA, complementary to the target sequence of DNA, which initiates replication by the DNA polymerase

Question 60

What is a chain reaction?

Answer 60

Compounding amplification of the ordinary molecule

Question 61

Steps to PCR

Answer 61

1. Denaturation: the DNA is heated to 96®C causing the DNA to split into two strands o At this temperature, the DNA polymerase was destroyed o More of the enzyme had to be added after the heating stage 2. Annealing: o DNA is cooled o Primers are required (begin the duplication at a certain point) o The primers join bases together to form a complementary strand 3. Extension: o The enzyme DNA polymerase is used to duplicate the targeted section of DNA o Both the original and complementary strands can be used to make more DNA

Question 62

DNA polymmerase

Answer 62

• Occurs in living things - Duplicated DNA when cells divide - Lives at a temperature of 37.5®C - It is destroyed during the heating stage of PCR

Question 63

Taq polymerase

Answer 63

• Used as a substitute for DNA polymerase - Does not breakdown when heated and can be used throughout the entire process

Question 64

DNA fingerprinting is used to…

Answer 64

1. Determine biological relationships 2. Trace ancestry 3. Identify victims and criminals 4. Identify disaster victims 5. Predict disease

Question 65

Recombinant DNA (rDNA)

Answer 65

• Introduction of foreign DNA into a cell - Genes (alleles) from one organism are added to the chromosomes of another organism - There is an enormous potential to replace faulty genes with healthy ones

Question 66

Transgenic organisms

Answer 66

• Any organism whose genome has been altered by the transfer of a gene or genes from another organism - The introduced genes become part of the transgenic organism’s DNA and are then passed on the subsequent generations

Question 67

Florescent genes

Answer 67

• Jelly fish contain a florescent gene to make then glow in the dark - The florescent gene is removed from the jelly fish - Viruses are used to insert the gene into a single-celled mouse embryo

Question 68

Introducing genes into a cell

Answer 68

• Use of vectors: carry the gene from one place to another o Bacteriophages o Plasmids (found in bacteria) - Use of restriction enzymes

Question 69

Restriction enzymes

Answer 69

• Able to cut up pieces of DNA at specific base sequences - Cuts the DNA from the donor genome to expose the gene of interest - Cuts the DNA of the vector so that the gene of interest can be inserted

Question 70

Recognition sites

Answer 70

the sequence of bases where a particular enzyme always cuts

Question 71

What is a vector?

Answer 71

a bacteriophage or virus used to transfer genetic material from one cell to another

Question 72

Bacteriophages

Answer 72

• Also called phages - Viruses that infect bacterial cells - The viruses’ DNA is cut and the gene of interest is inserted into the viruses’ DNA - Viruses are then used as vectors to introduce genes to a cell’s DNA

Question 73

Plasmids

Answer 73

• Circular stands of DNA found within bacteria - Capable of self-replication - Can be cut by a restriction enzyme - Desired genes can then be inserted into the plasmid - The plasmid is placed back into the bacteria - The plasmid reproduces, amplifying the amount of DNA available

Question 74

DNA ligase

Answer 74

• An enzyme that is capable of joining or recombining pieces of DNA - Originally found in a bacterium called Escherichia coli (E. coli) - Ligation is the process where pieces of DNAQ are joined together

Question 75

Steps in the rDNA process

Answer 75

1. Isolate the desired gene 2. Insert the gene into the vector and clone it (viruses or plasmids in bacteria) 3. Large quantities of the vector are introduced to the selected host cell

Question 76

Insulin production

Answer 76

• Identify and isolate the gene for insulin production from human pancreas cells using restriction enzymes - Remove plasmid from bacterium. Use a restriction enzyme to cut the plasmid. The plasmid is used as a vector for this process - Combine spliced plasmid and the insulin gene. Sticky ends combine. Ligase is used to permanently join the insulin gene to the plasmid - The transgenic plasmid is placed back into the bacterium. The plasmid undergoes self-replication - The transgenic bacterium undergoes mitosis, producing more transgenic bacteria capable of transcribing and translating the insulin gene - This produces large quantities of insulin. The insulin is drained off, bottled and then injected into diabetics

Question 77

Factor VII production

Answer 77

• Identify and isolate the gene for factor VIII production from a human liver cell using restriction enzymes - Remove plasmid from bacterium. Use a restriction enzyme to cut the plasmid. The plasmid is used as a vector for this process - Combine spliced plasmid and the factor VIII gene. Sticky ends combine. Ligase is used to permanently join the factor VIII gene to the plasmid - The transgenic plasmid is placed into a mammalian cell. The plasmid undergoes self-replication - The mammalian cell undergoes mitosis, producing more plasmids capable of transcribing and translating the insulin gene - This produces large quantities of factor VIII. The factor VIII is drained off, bottled and then injected into haemophiliacs

Question 78

Vaccine production

Answer 78

• Identify and isolate the gene for the (attenuated) antigen form a pathogen using restriction enzymes - Remove plasmid from bacterium. Use a restriction enzyme to cut the plasmid. The plasmid is used as a vector for this process - Combine spliced plasmid and the antigen gene. Sticky ends combine. Ligase is used to permanently join the antigen gene to the plasmid - The transgenic plasmid is placed into a yeast cell. The plasmid undergoes self-replication - The transgenic bacterium undergoes mitosis, producing more plasmids capable of transcribing and translating the antigen gene - This produces large quantities of the antigen. The antigen is drained off, bottled and then used to vaccinate people

Question 79

Human growth hormone production

Answer 79

• Identify and isolate the gene for HCG production from a human pancreas cells using restriction enzymes - Remove plasmid from bacterium. Use a restriction enzyme to cut the plasmid. The plasmid is used as a vector for this process - Combine spliced plasmid and the HCG gene. Sticky ends combine. Ligase is used to permanently join the HCG gene to the plasmid - The transgenic plasmid is placed into a bacterium. The plasmid undergoes self-replication - The transgenic bacterium undergoes mitosis, producing more transgenic bacteria capable of transcribing and translating the HCG gene - This produces large quantities of HCG. The insulin is drained off, bottled and then injected people who are producing too little of their own hormone

Question 80

What is gene therapy?

Answer 80

Involves the transfer of genetic material, and the uptake of that material into the cell nuclei of the body - The transfer of a therapeutic or working copy of a gene into specific cells of an individual in order to repair a faulty gene - Only somatic cells are targeted

Question 81

Vectors

Answer 81

• Used to introduce DNA to a host (body) cell - Generally, plasmids or viruses - Introduced either in vivo or vitro

Question 82

A viral vector must:

Answer 82

1. Target the right cell 2. Integrate the gene into the host cell DNA 3. Activate the gene 4. Avoid harmful side-effects

Question 83

Disadvantages to viral vectors

Answer 83

1. Can only carry a limited amount of genetic material 2. Can cause illness in patient 3. Can be destroyed by the immune system

Question 84

Gene therapy for cystic fibrosis

Answer 84

• Cells are removed form a heathy patient that carries the CFTR gene - In a laboratory, a virus is altered using a restriction enzyme so that it cannot reproduce - The healthy CFTR gene is inserted into the virus - The altered virus is mixed with the lung cells of the patient that carries the faulty CFTR gene - The cells of the patient become genetically altered as it now contains the CFTR gene - The altered cells produce the desired hormone or protein, which is CFTR, preventing mucous from building up in the lungs

Question 85

Gene therapy for Huntington’s disease

Answer 85

• Caused by a faulty gene on chromosome 4 - Brain cells are removed from a healthy patient that carries the correct Huntington’s disease - In a laboratory, a virus is altered using a restriction enzyme so that it cannot reproduce - The healthy Huntington’s gene is inserted into the virus - The altered virus is mixed with the brain cells of the patient that carries the faulty Huntington’s gene - The cells of the patient become genetically altered as it now contains the heathy Huntington’s gene - The altered cells are injected into the brain of the patient - The altered cells produce the Huntington’s protein

Question 86

Pros and cons to plasmids

Answer 86

• Can transfer large amounts of DNA - Less efficient at getting into cells - Are sometimes wrapped in a cell membrane (liposomes) to make it easier to enter a cell

Question 87

Cell replacement therapy

Answer 87

• Involves the transfer of cells with the relevant (healthy) function into the patient. - Uses stem cells - Healthy cells derived from stem cells are introduced into the body - These healthy, differentiated cells function in the place of the damaged cells

Question 88

Embryonic stem cells

Answer 88

• Harvested from 4-6 day old blastocysts - From the inner cell mass - Can differentiate into any one of over 200 cell types found in the body - They are pluripotent

Question 89

Parkinson’s and Alzheimer’s

Answer 89

• Are both neurodegenerative disorders in which cell replacement therapy can be used - In both diseases, dying neurons can be replaced with healthy neurons derived from stem cells

Question 90

Stem cells and tissue engineering

Answer 90

• uses a scaffold on which stem cells are induced to grow on, to produce a three dimensional tissue - the cell-covered scaffold is then implanted into the patient at the site where new tissue is needed - used for tissues including bone, skin, cartilage and adipose tissue