Meiosis and Chromosome Structure

Question 1

Cytogenetics

Answer 1

The study of chromosomes and cell division

Question 2

What are the elements of chromosome structure (small -> big)?

Answer 2

• Histones = proteins wrapped with 150 bp DNA; 50 bp linkers between histones
• Nucleosomes = segments of DNA wrapped around 8 histone cores
• Solenoid
• Chromatin loops
• Chromosomes = complete package

Question 3

Metaphase spread

Answer 3

Method for viewing chromosomes in cytogenetics:

• spindle fiber inhibitor inhibits anaphase, arresting cells in metaphase
• hypotonic solution causes cell expansion
• fixation hardens the membrane to stabilize

Question 4

What are the different regions of a chromosome?

Answer 4

• Telomere = TTAAGGG repeats on the end
• Short (p) arm = “top” arm
• Centromere = spindle fiber binding site in middle
• Long (q) arm = “bottom” arm
• Telomere

Question 5

Metacentric chromosome

Answer 5

Centromere is in the center; p and q arms of similar length

Question 6

Submetacentric chromosome

Answer 6

Centromere towards one end; p arm much shorter than q

Question 7

Acrocentric chromosome

Answer 7

• 13, 14, 15, 21, 22
• Very small p arm (stalks and satellites)
• All 5 chromosomes have the same stalk DNA => duplications and deletions w/o clinical consequence means little selective pressure to maintain => polymorphism
• Stalks = tandem arrays of rRNA genes
• Satellites = highly repetitive “junk” DNA
• Associate in interphase to form the nucleolus

Question 8

Ideograms

Answer 8

• Banding pattern from enzyme digest of chromosomes
• Identical pattern for all people
• Numbering: 24.3 = region 2, band 4, sub-band 3. Numbers out from centromere

Question 9

Euploid

Answer 9

• Chromosome number is an exact multiple of the haploid set (23, 69, 92)

Question 10

Aneuploid

Answer 10

• Loss or gain of whole chromosomes (45, 47, 49)

Question 11

What are the types of structural chromosome abnormalities?

Answer 11

• Terminal deletion
• Interstitial deletion
• Duplication
• Ring (telomere deletion => circularization to maintain integrity)
• Isochromosome (2 copies of 1 arm)
• Paracentric inversion (inversion of region, not including centromere)
• Pericentric inversion (inversion of region including centromere)
• Translocation (swapping DNA between chromosomes)

Question 12

Lyon hypothesis of X-inactivation

Answer 12

• One X chromosome is “active”, meaning genes are transcribed and translated
• One X is “inactive”, remaining condensed and staining darkly as a Barr body in interphase cells

Question 13

When does X-inactivation occur?

Answer 13

Early in embryonic life (2 wks post-fertilization)

Question 14

Is there a pattern to X-inactivation?

Answer 14

• Random (either paternal or maternal)

- Clonal: all of a cells descendants will have the same inactive X

Question 15

How is X-inactivation mediated genetically>

Answer 15

• XIST (X-inactivation specific transcript) gene located in the X-inactivation center of Xq13
• Transcribed only from inactive X and never translated
• Transcript remains in the nucleus and coats the inactive X affecting replication and condensation
• Methylation: inactive X is hypermethylated; active X is mainly unmethylated

Question 16

What are the effects of the incompleteness of X inactivation?

Answer 16

• For genes that are incompletely inactivated, females (XX) will have 2x the [protein] as males (XY)

Question 17

What is meiosis?

Answer 17

• Specialized cell division that occurs during gametogenesis

- Shuffles genetic material through recombination and divides genetic material in half

Question 18

What is the purpose of meiosis I?

Answer 18

• Reduction division (46 -> 23, 2n -> 1n, diploid -> haploid)

Question 19

What are the stages of prophase I?

Answer 19

1. leptotene = chromosome condensation after interphase
2. zygotene = 2 homologs (maternal and paternal) align forming a synapse and are held together by synaptonemal complexes
3. pachytene = each homolog pair (bivalent) coils tightly and crossing over occurs
4. diplotene = homologs begin to separate but remain attached at chiasmata (crossing-over points)
5. diakinesis = separation of homolog pairs; chromosomes maximally condensed

Question 20

What are some characteristics of recombination?

Answer 20

• Number of chiasmata correlates with chromosome size
• > 1 chiasmata/chromosome arm required for normal segregation
• Only one sister chromatid involved in each cross-over event
• Female recombination > male recombination
• Recombination varies by location: less near centromeres and more near telomeres

Question 21

Pseudoautosomal regions

Answer 21

• Two regions of homology on the X and Y chromosomes that undergo very high levels of recombination
• Same genes are on both X and Y so females and males have the same dosage of these proteins

Question 22

What are the odds of 2 gametes from 1 individual having the same chromosomes?

Answer 22

Random segregation => 1 in 2^23 (1 in 8 million)

Question 23

Compare start of meiosis, duration or meiosis, number of mitoses before meiosis, gametes produced per meiosis, and total gamete production for males and females.

Answer 23

Start: puberty (M) and early embryonic life (F)
Duration: 60-65 days (M) and 10-50 years (F)
# mitoses: 30-500 (M) and 20-30 (F)
gametes per meiosis: 4 spermatids and 1 ovum + 2-3 polar bodies
gamete production: 100-200 mil per ejaculate and 1 ovum per cycle

Question 24

When do meiosis I and meiosis II occur in females?

Answer 24

• First meiosis begins in utero and arrests partway at birth
• With each menstrual cycle, 1 oocyte completes meiosis I and begins meiosis II
• Meiosis II is completed after fertilization

Question 25

What are the clinical indications for prenatal constitutional cytogenetic testing?

Answer 25

• Advanced maternal age
• Family history of chromosome abnormality
• Ultrasound or screening test anomalies

Question 26

What are the clinical indications for postnatal constitutional cytogenetic testing?

Answer 26

For babies born with:

• congenital heart defect
• multiple congenital anomalies
• mental retardation of unknown origin or associated with malformations
• ambiguous genitalia
• primary amenorrhea
• 3+ unexplained spontaneous miscarriages

Question 27

How frequent are chromosome abnormalities in live births?

Answer 27

0.6%; often not compatible with life

Question 28

What aneuploidy is associated with Turner syndrome?

Answer 28

• Only one sex chromosome (X)

Question 29

Nondisjunction

Answer 29

• Mechanism of aneuploidy
• Failure of homologous chromosomes (MI) or sister chromatids (MII) to separate
• If homologous don’t separate: fertilized cells either trisomy or monosomy
• If sisters don’t separate: fertilized cells normal, trisomy, or monosomy

Question 30

How is amniocentesis connected to maternal age?

Answer 30

• Amniocentesis = collection of amniotic fluid to screen for abnormalities; 0.5-1% risk of miscarriage
• Risk of miscarriage due to chromosomal abnormalities increases with maternal age
• At age > 35: risk of abnormality > risk of procedure

Question 31

Why is most aneuploidy of maternal origin?

Answer 31

• NDJ sperm are less fit and thus less likely to fertilize an egg
• Most aneuploidy is of maternal MI origin
• Exceptions: +18 is parental MII; X is paternal

Question 32

Balanced chromosomal translocation

Answer 32

• Swapping of genetic material between two chromosomes but no net gain or loss
• Usually no phenotype in self as breaks are usually in a noncoding sequence (only 5% of de novo translocations disrupt a gene)
• Increased risk of abnormal offspring and multiple miscarriages

Question 33

How is meiosis I abnormal when a balanced translocation is present?

Answer 33

• Chromosome homologs don’t align perfectly and form a tetravalent (two chromosomes with the translocation + their original homologs)

Question 34

What are the ways in which homologs can separate after forming a tetravalent?

Answer 34

• normal: normal and translocation carrier
• likely abnormal: slight monosomy A/slight trisomy B and slight monosomy B/slight trisomyA
• likely nonviable: almost monosomy A/almost trisomy B and almost monosomy B/almost trisomy A

Question 35

Which trisomies are viable?

Answer 35

13, 18, 21

Question 36

Robertsonian Translocation

Answer 36

• Translocation between two acrocentric chromosomes, resulting in the loss of both short arms but doesn’t affect the DNA content of the long arms
• Either occurs by centromere fusion (stalk and satellite DNA lost) or by translocation (stalk and satellite chromosome lost)

Question 37

Nucleolus organizer regions

Answer 37

Acrocentric chromosomes; associate during interphase to form the nucleolus

Question 38

How frequent are Robertsonian translocations

Answer 38

der(13;14) = 1 in 1500

Question 39

How do chromosomes associate in meiosis after Robertsonian translocation?

Answer 39

Trivalent forms: two normal chromosomes + translocated combo chromosome

Question 40

What are the possibilities for fertilized gametes with a Robertsonian translocation der(14;21)(q10;q10)?

Answer 40

1. normal + balanced translocation (normal, balanced)
2. unbalanced translocation + monosomy (unbalanced, unviable)
3. trisomy + monosomy (both unviable)

Theoretical risk of Down’s is 33% but in reality: 10-15% for female carriers and 0-2% for male carriers

Question 41

Paracentric inversion

Answer 41

Break and inversion on one chromosome arm

Question 42

Pericentric inversion

Answer 42

Break on both chromosome arms and inversion (includes centromere)

Question 43

What are the clinical consequences of inversion?

Answer 43

• Usually no clinical consequence for carrier because no gain/loss and breaks usually occur in noncoding regions
• Abnormal meiosis

Question 44

Paracentric inversions and meiosis

Answer 44

• Inverted chromosome will stretch to align with normal homolog, forming an inversion loop
• If recombination occurs within the loop => acentric and dicentric products => miscarriage
• If recombination does not occur within the loop => normal

Question 45

What are acentric and dicentric chromosomes?

Answer 45

• Products of meiosis after paracentric inversion
• Acentric = no centromere; dicentric = 2 centromeres
• Not stable/non-viable

Question 46

Pericentric inversions and meiosis

Answer 46

• Inverted chromosome will stretch to align with normal homolog, forming an inversion loop
• If recombination occurs within loop => both homologs will have a centromere, but each will have a deletion and a duplication => viable or nonviable gametes depending
• If recombination doesn’t occur within loop => normal

Question 47

Microdeletion syndromes

Answer 47

• phenotypically and genetically characterized
• usually not inherited but can be inherited in a dominant fashion
• deletion of < 5Mb (10-100) genes; not visible by cytogenetics
• low incidence: each individual syndrome is rare but all together, same frequency as Down’s

Question 48

How do microdeletions occur during recombination?

Answer 48

• Misalignment between direct repeats => duplication and deletion
• Alignment between inverted repeats => non homologous end joining or U-type exchange => deletion of region between repeats

Question 49

How does karyotype resolution vary?

Answer 49

• Depends on exact stage of condensation in metaphase
• Band level = level of condensation (400-850)
• More bands = less condensed = greater sensitivity

Question 50

What is Fluorescent In-Situ Hybridization (FISH)?

Answer 50

• Fluorescently labeled probes target 100kb-1Mb regions of interest
• Probes added in excess to sample DNA
• Sample DNA is heat denatured and then probes allowed to anneal to targets on ss sample

Question 51

What are the clinical uses of FISH?

Answer 51

• detect numerical abnormalities using dividing or nondividing cells (interphase)
• detect abnormalities that are not visible via karyotype (microdeletions)
• detect trisomies prenatally

Question 52

Array based comparative genomic hybridization (aCGH)

Answer 52

• FISH clones (probes) arrayed on a chip
• fluorescently labelled patient and control DNA added
• patient and control DNA should compete equally for probe binding (color ratio of 1:1 or 0.8-1.2)
• look for gain or loss in color ratio

Question 53

What can aCGH detect and with what sensitivity?

Answer 53

• can detect: copy number imbalances at a genome wide level (not all CNVs are pathogenic; 2-15 per patient)
• cannot detect: mechanism of abnormality (trisomy, translocation)
• microarray analysis more sensitive than chromosome analysis
• 108,000+ probes at ~10-50kb intervals along the genome