The Human Genome and Karyotype

Question 1

The amount of DNA in one copy of the genome

Answer 1

Genome size (C-value)

Question 2

How many base pairs of DNA do humans have in each somatic cell of our bodies?

Answer 2

3.2x10^9 bp

Question 3

How many genes do humans have?

Answer 3

Approximately 22,000

Question 4

During mitosis, DNA is packaged into chromosomes. What is the chromosomal make-up of humans?

Answer 4

22 pairs of autosomal chromosomes and 2 pairs of sex chromosomes

Question 5

Contain distinct DNA (containing 37 known genes) not

associated with chromosomes. It is inherited solely from the mother in humans

Answer 5

Mitochondria

Question 6

Chromatin condenses into chromosomes during

Answer 6

Prophase of mitosis (after replication)

Question 7

After DNA is replicated, chromosomes form a pair of sister chromatids attached by the

Answer 7

Centromere

Question 8

A higher order of DNA organization where DNA is condensed at least by 10,000 times onto itself

-condensed chromatin fibers

Answer 8

Chromosomes

Question 9

Long and thin uncoiled structures found in the nucleus

Answer 9

Chromatin

Question 10

Compact, thick, and ribbon-like. These are coiled structures seen prominently during cell division

Answer 10

Chromosomes

Question 11

Chromosomes are paired, but chromatin is

Answer 11

Unpaired

Question 12

Permissive to DNA replication, RNA synthesis and recombination events

Answer 12

Chromatin

Question 13

Not permissive to DNA replication, RNA synthesis and recombination events

Answer 13

Chromosomes

Question 14

Generally increases with an organisms complexity

Answer 14

Genome size

Question 15

Wide variations exist between genome size and organism complexity; e.g., some single-celled protists have genomes much larger than that of humans. This is called the

Answer 15

C-value enigma

Question 16

Does not correlate with genome size or complexity

Answer 16

Chromosome number (ploidy)

Question 17

Increased genome complexity/size arises by what two basic mechanisms?

Answer 17

Duplication and Incorporation (from other species)

Question 18

In humans, which is more abundant, RNA or DNA?

Answer 18

RNA

Question 19

More complex and diverse in its function and may have preceded DNA in evolution

Answer 19

RNA

Question 20

Has more chemical stability and thus provides evolutionary advantages

Answer 20

DNA

Question 21

Mapped the genome in 80 different human cell types for transcripts and protein-encoding exons, chromatin modification and DNA methylation, DNAse hypersensitivity, and binding of transcription factors

Answer 21

Encyclopedia of DNA elements (ENCODE)

Question 22

Identifies cis-regulatory regions where the binding of regulatory factors exposed DNA to cleavage while DNA in nucleosomes is protected

Answer 22

DNAse hypersensitivity

Question 23

The ENCODE project concluded that chromatin exists in

Answer 23

7 major functional states

Question 24

The ENCODE project concluded that what percentage of chromatin is transcribed into RNA?

Answer 24

60-75%

Question 25

The ENCODE project concluded that non-coding transcripts, many predicted to have regulatory roles, are nearly as abundant as

Answer 25

Protein-encoding genes

Question 26

The ENCODE project concluded that there are only 21,000 protein coding genes, but at least 70,000 promoters and how many enhancers?

Answer 26

400,000 enhancers

Question 27

Concluded that At least 80% of the genome is likely to be “functional” implying thatʻnon-coding regionsʼ may be as, or more important than, protein-encoding regions (as determinants of health and disease)

Answer 27

ENCODE

Question 28

Repetitive sequences are common in the human genome and consist of

Answer 28

1. ) Tandem repeats
2. ) Short repeats
3. ) Retrotransposons

Question 29

Repeats which are products of reverse transcription

Answer 29

Retrotransposons

Question 30

Ancient tandem repeats have diverged in nucleotide sequence over time. However, recent repeats (segmental duplications) have a sequence identity of

Answer 30

> 90%

Question 31

Create “hot spots” for recombination, increasing the chance of structural change in chromosomes and the frequency of some genetic conditions

Answer 31

Repeats

Question 32

Substrates for recombination because they are similar or identical in nucleotide sequence

Answer 32

Repeats

Question 33

If sequence identity exists in more than 2 places, then what can occur between these regions?

Answer 33

Recombination

Question 34

Depending on the position and orientation of the repeats, recombination between repeats may cause

Answer 34

Inversion, duplication, or deletion

Question 35

Caused by recombination between duplicated genes with almost identical sequence identity on the X-chromosome

Answer 35

Red-green color blindness

Question 36

In red-green colorblindness, there is a misalignment in meiosis followed by

Answer 36

Recombination

Question 37

Due to the presence of three different photoreceptors in the retina, each sensitive to different wavelengths

Answer 37

Color Vision

Question 38

The long (red) and medium (green) wavelength photoreceptors are encoded by genes close together on the

-The two genes differ by only a few bp

Answer 38

X chromosome

Question 39

Recombination during meiosis can delete one gene from the chromosome. Males who carry a deleted X have only one receptor and thus can not distinguish

Answer 39

Long and medium wavelength light

Question 40

Recombination occurs between large repeats resulting in the deletion of a block of DNA that contains multiple genes

-Ex: DiGeorge (Velocardiofacial) Syndrome and Prader-Willi and Angleman syndromes

Answer 40

Contiguous gene (microdeletion or segmental autoploidy) syndromes

Question 41

Characterized by the failure of the pharyngeal pouches to develop. Results in parathyroid, thymus, and cardiac defects

Answer 41

DiGeorge (Velocardiofacial) Syndrome

Question 42

Tandem repeats of sequences of a few hundred base pairs long; hundreds to thousands of copies, mostly at centromeres and telomeres.

Answer 42

Satellite sequences

Question 43

Repeats of a few nucleotides, such as (CA)n dinucleotides. Common, copy number n highly variable. Widely used to identify specific chromosomes in genetic counseling, because often each of the four parental copies will be different.

Answer 43

Micro-Satellites

Question 44

Satellites are called satellites because when DNA is fractionated, there is a small peak next to the DNA peak because it differs in

Answer 44

Base composition

Question 45

Estimated to account for up to 25% of the increased complexity of the human genome

Answer 45

Retrotransposons

Question 46

What are the main types of retrotransposons?

Answer 46

1. ) LINE
2. ) SINE
3. ) Pseudogenes

Question 47

mRNA’s encoding reverse transcriptase

Answer 47

LINE (long interspersed nuclear elements)

Question 48

Copies of a short cellular RNA

-Most abundant are Alu sequences

Answer 48

SINE (short interspersed nuclear elements)

Question 49

The most abundant SINEs are Alu sequences, which are unique to human DNA and are named because they contain a restriction site for

Answer 49

Alul

Question 50

Copies of cellular mRNAs

-not transcribed because they lack promoter sequences

Answer 50

Pseudogenes

Question 51

Insertion of reverse-transcribed RNA into DNA can disrupt a gene at an

-An uncommon but well-known cause of genetic disease

Answer 51

Integration site

Question 52

Analysis of the number and structure of chromosomes

Answer 52

Cytogenesis

Question 53

About what percentage of people have an abnormality of chromosome number or structure?

Answer 53

1.5%

Question 54

If there are problems with physical or mental development, infertility, spontaneous abortion, stillbirth, pregnancy in a woman 35 or older, or cancer, you should consider a diagnosis of

Answer 54

Chromosome abnormality

Question 55

Techniques used for visual identification of chromosomes and to detect changes in their structure

Answer 55

Karyotyping

Question 56

What are three karyotyping techniques?

Answer 56

1. ) G banding
2. ) Fluorescent in situ hybridization (FISH)
3. ) Comparative genomic hybridization (CGH)

Question 57

Giemsa staining creates a pattern of dark and light bands unique to each chromosome in

Answer 57

G banding

Question 58

Detects changes in chromosome structure that are too small to see by G banding

-The location must be known in order to design the probe

Answer 58

FISH

Question 59

Detects deletions or duplications even if their location is not known

Answer 59

Comparative Genomic Hybridization (CGH)

Question 60

In G banding, cells are incubated with colchicine, which binds tubulin, prevents spindle function, and

Answer 60

Arrests cells in metaphase

Question 61

Condense steadily during prolonged metaphase.

-With time, the number of cells in mitosis increases but the number of visible bands decreases

Answer 61

Chromosomes

Question 62

The standard karyotype will have how many bands per haploid set of chromosomes?

Answer 62

500-800

Question 63

In G banding, chromosomes are identified by

Answer 63

1. ) Size (1 largest, 22 smallest)
2. ) Centromere position
3. ) Banding pattern

Question 64

A chromosome is made up of what three regions?

Answer 64

1. ) P (short) arm
2. ) Centromere
3. ) Q (long) arm

Question 65

What are three different styles of chromosome?

Answer 65

1. ) Metacentric
2. ) Submetacentric
3. ) Acrocentric

Question 66

The centromere is located in the middle of a

ex: chromosome 3

Answer 66

Metacentric chromosome

Question 67

The centromere is located above the midline, but not at the top of the chromosome in a

-Ex: chromosome 18

Answer 67

Sub-metacentric Chromosome

Question 68

The centromere is located high, towards the top of the chromosome in a

-Ex: chromosome 22

Answer 68

Acrocentric Chromosome

Question 69

Has the centromere at the end of the chromosome

-Not present in humans

Answer 69

Telocentric Chromosome

Question 70

Chromosome bands are numbered on each arm outward from the

Answer 70

Centromere

Question 71

The chromosome bands are further divided with increasing

Answer 71

Resolution

Question 72

Can detect structural changes regardless of the nature or location, but detects only relatively large changes in chromosome structure

Answer 72

G-banding

Question 73

The lower resolution limit of G banding is

Answer 73

One band

Question 74

For metaphase G banding, there are about

Answer 74

500-800 bands

Question 75

A single band is about

Answer 75

4-7 Mb (45 or so genes)

Question 76

To detect smaller changes in a chromosome, we want to use

Answer 76

FISH or CGH

Question 77

Chromatin or chromosomes are fixed to a slide and a fluorescent probe binds to DNA of the complimentary sequence

Answer 77

Fluorescent in situ hybridization (FISH)

Question 78

Faster because it can be done directly on clinical samples

Answer 78

Interphase FISH (on Chromatin)

Question 79

Requires culture to amplify cell number and then incubation in colchicine

Answer 79

Metaphase FISH (on Chromosomes)

Question 80

Has a lower resolution because DNA is not condensed

Answer 80

Interphase FISH

Question 81

Because it is faster, Interphase fish is often used for

Answer 81

Prenatal diagnosis

Question 82

Interphase fish is also used to identify common

Answer 82

Trisomies

Question 83

An example of a use of Metaphase FISH is screening for

Answer 83

DiGeorge syndrome

Question 84

FISH only indicates that a region of DNA complementary to the probe is present. But it will not reveal a single nucleotide deletion/change in the gene or changes elsewhere in the genome. Thus FISH can not rule out a

Answer 84

Mutation or Small deletion in the gene

Question 85

When using FISH, a small deletion will only be revealed with a very specific

Answer 85

Probe

Question 86

Detects alterations too small to be seen by G banding but requires a specific probe and only detects the presence/absence/position of the DNA to which the probe binds

Answer 86

FISH

Question 87

One problem with FISH is that single probes detect the presence of an exon or gene but cannot detect

Answer 87

Single nucleotide changes

Question 88

In FISH, a family of probes can detect a single chromosome or region, but resolution decreases as the number of probes

Answer 88

Increases

Question 89

An array of oligonucleotides are immobilized at different positions on a glass slide (microarray), complementary to sequences spaced across the genome in

Answer 89

Comparative Genome Hybridization (CGH)

Question 90

Compares PCR-amplified patient genome (test) DNA with reference genome (control) DNA in the ability to hybridize with oligonucleotides

Answer 90

CGH

Question 91

You can analyze the CGH by comparing the

Answer 91

Green (patients DNA) to Red (control DNA) ratios

Question 92

For example, if the control has two DNA sequences that hybridize to oligonucleotides, but the patient (Green) experiences a deletion in one of those sequences, the green to red ratio will be

Answer 92

1 : 2, or 0.5 : 1

Question 93

Detects very small changes anywhere in the genome

-i.e. you do not need to know where to look

Answer 93

CGH

Question 94

A weakness of CGH is that it detects only

Answer 94

Deletions or duplications

Question 95

CGH can not detect rearrangements without gain or loss, such as

Answer 95

Inversions or translocations

Question 96

Refers to the chromosome number

Answer 96

Ploidy

Question 97

Sperm have one copy of each chromosome, meaning they are

Answer 97

Haploid (N)

Question 98

Zygotes and somatic cells contain two copies of each chromosome, meaning they are

Answer 98

Diploid (2N)

Question 99

In diploid cells, the two copies of each chromosome are

Answer 99

Homologues (form a homologous pair)

Question 100

Normally, one homologue is maternal, from the egg, and one is paternal, from the sperm. They carry the same genes in the same order, but not necessarily identical

Answer 100

Alleles

Question 101

If the homologous chromosomes differ genetically, normally they are distributed into gametes in a 1:1 ratio. This is what gives rise to

Answer 101

Mendel’s Laws

Question 102

Diploid conceptions with two maternal or two paternal chromosomes are not

Answer 102

Viable

Question 103

Characterized as having a normal number of chromosomes: 22 pairs of autosomes and one pair of sex chromosomes

Answer 103

Euploidy

Question 104

The karyotype designation for Euploidy is

Answer 104

46, XX or 46, XY

Question 105

Characterized as having missing (2N-1, monosomy) or extra (2N+1, trisomy) chromosomes

Answer 105

Aneuploidy

Question 106

Aneuploidy for most chromosomes is

-exceptions: X, Y and trisomy for a few small autosomes

Answer 106

Lethal

Question 107

When 2 sperm fertilize one egg resulting in 3 complete chromosome sets

-Lethal

Answer 107

Triploidy

Question 108

Down syndrome in a male is indicated by

Answer 108

Trisomy 21

Karyotype designation: 47, XY, +21

Question 109

Down syndrome in a female is indicated by

Answer 109

Trisomy 13

Karyotype designation: 47, XX, +13

Question 110

A female with monosomy X (45, X) has

-only nonlethal monosomy

Answer 110

Turner’s syndrome

Question 111

When genetic material is moved from one chromosome to another

Answer 111

Translocation

Question 112

What are the two types of translocation?

Answer 112

1. ) Reciprocal

2. ) Non-reciprocal

Question 113

When 2 chromosomes exchange segments

Answer 113

Reciprocal translocation

Question 114

The movement of DNA from one chromosome to another

Answer 114

Non-reciprocal Translocation

Question 115

When a segment of DNA is inverted with respect to the rest of the chromosome

Answer 115

Inversion

Question 116

What are three abnormalities in chromosome structure

Answer 116

1. ) Translocation
2. ) Inversion
3. ) Duplication or deletion

Question 117

When a double stranded DNA break occurs, the chromosomes are healed by recombination, NHEJ, or slower backup mechanisms. If the ends are not rejoined correctly, there will be a

Answer 117

Structural alteration of the chromosome

Question 118

Structural alterations of a chromosome are important in carcinogenesis because they can alter gene structure or expression. They are increased by

Answer 118

Radiation

Question 119

The general rule is that the number of chromosomes = the

Answer 119

Number of centromeres

Question 120

The identity of a chromosome = the identity of its

Answer 120

Centromere

Question 121

Most common translocations are between

Answer 121

Acrocentric autosomes

Question 122

Breakpoints occur within the centromeres of D- and G-group chromosomes, with fusion of chromosomes and loss of p arms

-i.e. two q arms fuse together and lose their p arms

Answer 122

Robertsonian Translocations

Question 123

Is Robertsonian translocation always lethal?

Answer 123

No, not always

Question 124

During metaphase, the Robertsonian chromosome will pair with

Answer 124

2 chromosomes (1 that contains one q arms and the other containing the other q arm)

Question 125

In Robertsonian translocation, the pairing of homologous chromosomes during metaphase will occur between

Answer 125

3 chromosomes (2 normal and 1 translocation)

Question 126

A chromosome where both arms are from the q arm of chromosome 21

Answer 126

Isochromosome 21 (i21q)

Question 127

Fertilization of a cell with i21q will result in either

Answer 127

trisomy 21 (downs) or monosomy 21 (lethal)

Question 128

Any live-born children with i21q qill have

Answer 128

Down Syndrome

Question 129

An inversion in which the break points are in different arms of the same chromosome and thus the inversion includes the centromere

Answer 129

Pericentric inverison

Question 130

Inversion where the 2 breakpoints are in the same arm and thus the centromere is not included in the inversion

Answer 130

Paracentric inversion

Question 131

What does 46, XY, t(1:3)(q31;q24) mean?

Answer 131

Male with 46 chromosomes that has a translocation between chromosomes 1 and 3, and the position of the translocation is the q31 for chromosome 1 and q24 for chromosome 3

Question 132

What does rob(14;21) mean?

Answer 132

Robertsonian translocation where the q arms of chromosomes 14 and 21 are joined

Question 133

What does 46, XY, inv(6)(p23;q21) mean

Answer 133

A male with 46 chromosomes has an inversion on chromosome 6 between p23 and q21, and since the inversion is in different arms, it is a pericentric inversion