Eukaryotic Chromosome Structure and Function

Question 1

What did Boveri and Sutton do in 1902?

Answer 1

• Spotted the chromosome under the light microscope
• Saw them double in number and then divide into 2 cells
• Speculated heritable factors determined cell phenotypes
• CHROMOSOME THEORY OF INHERITANCE
• Thought genes are on chromosomes

Question 2

What did Morgan do in 1915?

Answer 2

• Identified using the light microscope STRUCTURAL REARRANGEMENTS which correlate with phenotypic changes in fruit flies
• FULLY established the link between genes and chromosomes

Question 3

What do chromosomes contain?

Answer 3

Linear DNA

And many other proteins that confer specialist functions

Question 4

What functions do the proteins carried by chromosomes have? (5)

Answer 4

1) Packing and unfolding of DNA within the nucleus (in a regulated way)
2) Genetic recombination (in germ cells)
3) Maintain chromosome integrity (prevent loss of end sequences)
4) Govern proper chromosome segregation
5) Regulate gene expression

Question 5

Where are chromosomes located in eukaryotes?

Answer 5

In the nucleus

Question 6

What does unfolding of DNA allow?

Answer 6

Genes to be accessible to machineries for replication/repair/transcription

Question 7

What organelles contain chromosomes and how?

Answer 7

Mitochondria and chloroplasts

Small, circular chromosomes

Question 8

At what stage in the cell cycle can chromosomes be easily distinguished?

Answer 8

Metaphase - they have been replicated

Question 9

How do chromosomes differ from each other?

Answer 9

Size, DNA sequence content (genes), banding

Question 10

How many chromosomes are present in eukaryotic DNA?

Answer 10

23 pairs

Question 11

How is a ‘metaphase spread’ made?

Answer 11

By smashing dividing cells (to break open the nucleus) onto a microscopic slide

Chromosomes laid out in a random arrangement

Question 12

What is ‘chromosome painting’?

Answer 12

Used to distinguish chromosomes from each other - done in metaphase

• Hybridise DNA with probes that have sequences which match the DNA sequence of a specific chromosome
• Each probe is labelled different colour of fluorescence
• Each chromosome will have a specific colours to them

Question 13

What is a karyotype?

Answer 13

The organised representation of all the chromosomes in a eukaryotic cell at METAPHASE

Question 14

What can a karyotype be used for?

Answer 14

To spot abnormalities in the karyotype and therefore in the genome

Question 15

In chromosome painting/ karyotyping, what does a chromosome of 2 different colours show?

What is this typical of?

Answer 15

Translocation

Typical of leukemias

Question 16

What do individual chromosomes occupy, even in interphase nuclei?

How is this seen?

Answer 16

Distinct 3D regions of the nuclei, which is separate to regions of the other chromosomes

Each chromosome is specific relations to other chromosomes - may influence each other

Seen using chromosome paints - each area of the nucleus is a different colour

Question 17

When in the cell cycle does transcription occur?

Answer 17

In interphase

Question 18

What is contained in the nuclear periphery?

Answer 18

Highly condensed transcriptionally inactive DNA

Question 19

What is contained in the centre of the nucleus?

Answer 19

Active genes

Question 20

What happens to a gene when it becomes active?

How is this seen?

Answer 20

Moves from the periphery to the centre of the nucleus

Seen using chromosome paints and following the movement

Question 21

What is the structure of a chromosome?

Answer 21

• Highly ordered chromatin
• 10nm thick fibre of DNA wrapped TWICE around a histone octamer to form a HISTONE
• ‘Beads on a string’
• Can be supercoiled to give 30nm fiber and then again to give fully condensed chromosomes

Question 22

How many base pairs of DNA wrap around a histone octamer?

Answer 22

146

Question 23

What is the structure of a core histone?

Answer 23

Octamer:

- Each subunit has a terminal end tail of 30 amino acids which project away from the nucleosomal core

Question 24

What does the tail of a histone monomer allow?

Answer 24

• Interaction with the regulatory proteins which covalently modify the properties of the end terminal tails (modifications are reversible)
• To add or remove METHYL, ACETYL, PHOSPHORYL groups
• Which act as signals to machinery (DNA repair, replication etc.) to carry out their functions
• Facilitating the regulation of chromatin structure and function

Question 25

Which groups can be added/removed from the N terminal tails of histones?

What do these acts as signals for?

Answer 25

Methyl
Acetyl
Phosphoryl

Act as signals to machinery (DNA repair, replication etc.) to carry out their functions

Question 26

What is histone H1?

What does it do?

Answer 26

• A linker histone
• Fixes the entry and exit strand of DNA around a histone together - stablising the position of the histone with respect to DNA and limiting the movement of DNA
• Governs the transition of chromatin from a condensed, to an accessible state

Question 27

How does histone H1 interact with DNA?

Answer 27

H1 is net positive (rich in basic amino acids)

DNA is net negative

Question 28

What is bound/unbound to transcriptionally active DNA

Answer 28

Actively transcribed DNA is FREE of histones and H1

Bound by sequence-specific binding proteins

Question 29

What does chromatin remodelling allow?

Answer 29

Accommodation of protein complexes involved in gene transcription/DNA replication

Question 30

When does chromatin remodelling occur?

Answer 30

In response to changes in cell differentiation status and environmental signals which change transcription factors

Question 31

What is a replication origin?

Where are they located?

Answer 31

A specific DNA sequence where DNA replication is initiated

Located in multiple positions a long the DNA of most eukaryotic chromosomes

Question 32

How many replication origins are present in yeast?

Answer 32

One

Question 33

What are telomeres?

What do they do?

Answer 33

Specific DNA sequences at the ends of linear chromosomes

• Maintain chromosome integrity, preventing the chromosome from shortening at each cell cycle
• Preventing the loss of genes

Question 34

What is a centromere?

What does it mediate?

Answer 34

DNA sequences on which the kinetochore assembles and the mitotic spindle attaches

Mediates the segregation of chromosomes in mitosis and meosis

Question 35

What is the kinetochore?

Answer 35

A protein complex which binds microtubules in the mitotic spindle to the DNA sequence in the centromere

Question 36

What is the sequence of a telomere?

Answer 36

TTAGGG

Question 37

What is the structure of a telomere?

Answer 37

Initially double stranded but at the extreme 3’ end there are many single stranded repeats - forming an overhang

Question 38

How are repeats added to the 3’ overhang of the telomere?

Answer 38

By a special DNA polymerase TELOMERASE

Question 39

What is the structure of the centromere?

Answer 39

Has short alpha satellite-DNA repeats, within higher order repeats

Forms condensed heterochromatin with histone octomers which contain unusual subunits

Question 40

What allows the centromere to interact with the kinetochore proteins?

Answer 40

Specialised histones which interact with the DNA repeats in the centromere (which have formed heterochromatin)

Question 41

What is the structure of the kinetochore?

Answer 41

Bilayer structure:

• Inner plate - binds to alpha satellite DNA in the centromere
• Outer plate - binds to protein components of the mitotic spindle (microtubules)

Question 42

What histone allows the centromere to interact with the kinetochore?

What is the name of this histone?

Answer 42

Centromere-specific H3 variant

CENP-A
- Makes specific interactions with the components of the kinetochore

Question 43

Why do some parts of the centromere interact with the kinetochore and others don’t?

Answer 43

The histones which interact with the repeats of the centromere are different

Question 44

What is the structure of normal histone H3?

What do these histones do?

Answer 44

DImethylated at lysine 4

They act to hold sister chromatids together

Question 45

What is the name of the histone which holds the sister chromatids together?

Answer 45

H3-K4me

Question 46

What is the name of the histone which allows attachment to the kinetochore?

Answer 46

CENP-A

Question 47

What is the structure of the kinetochore in yeast?

Answer 47

Basket-like structure which links a SINGLE subunit of a SINGLE nucleosome of centromeric chromatin (containing CENP-A (centromere specific H3 varient) to a SINGLE microtubule

Inner kinetochore plate is a basket shaped structure and is linked through a set of helically interacting proteins to the OUTER kinetochore plate

Outer kinetochore plate exists as a RING of subunits, into which a SINGLE microtubule bundle is inserted

Question 48

How much of the DNA encodes information to make proteins?

Answer 48

1.5%

Question 49

How much of the DNA is made of repeated sequences which are not centromeric?

What DNA element does this include?

Answer 49

50%

Includes transposons

Question 50

How much of the DNA is made of unique sequences?

Answer 50

50%

Question 51

What in the DNA contributes to UNIQUE sequences?

Answer 51

• Exons
• Introns
• Non-repetitive unique sequences that is neither exons or introns

Question 52

What percentage of the DNA is introns?

Answer 52

20%

Question 53

What percentage of the DNA is Non-repetitive unique sequences that is neither exons or introns?

What are these?

Answer 53

30%

These act as transcriptional regulatory sequences (eg. enhancer, promotors)

Question 54

What happens to the protein coding genes and non-protein coding genes in more complex organisms?

Answer 54

They increase

Can regulate and organise access to protein coding genes more precisely

Question 55

What are transposons?

What can they do?

Answer 55

Mobile genetic elements which can jump around the genome by transposition

Can reorganise the genome

Question 56

What are 3 classes of transposons?

Answer 56

1) DNA transposons
2) Retroviral transposons
3) Non-retroviral - polyA transposons

Question 57

How do DNA transposons move in the genome?

Answer 57

By ‘cut and paste’ WITHOUT self-duplication:

1) Chromosome is cut
2) Chromosome position is repaired
3) Transposon inserts elsewhere

• Require enzyme transposase - which removes it from the genome

Question 58

What are examples of DNA transposons?

Answer 58

P-element (fly)
Ac-Ds (maize)
Tn3/Tn10 (E.coli)

Question 59

What can DNA transposons do?

Answer 59

Shuffle sequences - are powerful mutagens

Question 60

Who discovered DNA transposons and how?

Answer 60

Barbra McClintock

When she saw spontaneous mutations occurring in her maize which changes the pigmentation

Question 61

What are retroviral-like transposons?

How do they move in the genome?

Answer 61

Transposons which act like retroviruses
They exist as DNA within the genome

1) They are TRANSCRIBED - producing an RNA copy
2) One of the genes they encode is a REVERSE TRANSCRIPTASE

3) Reverse transcriptase uses the RNA to make a DNA copy - RNA/DNA hybrid intermediate
4) DNA copy is inserted elsewhere in the genome using INTERGRASE

Question 62

How are retroviral-like transposons different to retroviruses?

Answer 62

They cannot LEAVE the cell BUT they are passed on to descendants of the cell

(Lack a protein coat)

Question 63

What are examples of retroviral transposons?

Answer 63

Ty1-copia
Ty3-gypsy
ERV elements

Question 64

What are examples of non-retroviral retrotransposons?

Answer 64

LINE-1 elements (human)
Mouse B1 elements
LINEs (long interspersed elements)
SINEs (short interspersed elements)

Question 65

How are retroviral like transposons different to non-retroviral poly-A retrotransposons?

Answer 65

Differ in genetic structure:

Retroviral like transposons have a LTR sequence at the end - which are characteristic of retroviruses

Non-retroviral like transposons DONT

Question 66

How are retroviral like transposons the same as non-retroviral poly-A retrotransposons?

Answer 66

They both contain reverse transcriptase and move by ‘copy and past’ using intergrase