Unit II Flashcards

Question 1

Q

What is important about meiotic prophase I?

Answer

A

Reciprocal recombination occurs here

Question 2

Q

What are bivalents?

Answer

A

Maternal and paternal homologs of
each chromosome become paired or synapsed along their entire lengths, forming
structures known as “bivalents”.

Question 3

Q

What is the synaptonemal complex?

Answer

A

a proteinaceous structure which promotes inter-homolog interactions.

Question 4

Q

Define chiasmata

Answer

A

attachments or crossovers

Question 5

Q

Which step of meiosis is most error prone?

Answer

A

Meiosis I during chromosome nondisjunction

Question 6

Q

What is the proband?

Answer

A

The affected individual through whom a family with a genetic disorder is ascertained

Question 7

Q

What is the consultand?

Answer

A

The individual (not necessarily affected) who presents for genetic evaluation and through whom a family with an inherited disorder comes to attention.

Question 8

Q

Define consanguinity

Answer

A

identifies cases of genetic relatedness between individuals descended from at least one common ancestor.

Question 9

Q

Define Phenotype

Answer

A

The observable expression (of a genotype) as a morphological, clinical, cellular, or biochemical trait

Question 10

Q

Define Genotype

Answer

A

The set of alleles that make up his or her genetic constitution

Question 11

Q

Mendelian Inheritance

Answer

A

disorders that are due to the predominant effects of a single mutant gene

Question 12

Q

Mendel’s First Law

Answer

A

The Law of Segregation

Question 13

Q

What is the law of segregation?

Answer

A

At meiosis, alleles separate from each other such that each gamete receives one copy from each allele pair

Question 14

Q

What is Mendel’s Second Law?

Answer

A

That Law of Independent Assortment

Question 15

Q

What is the Law of Independent Assortment?

Answer

A

At meiosis, the segregation of each PAIR of alleles is independent.

Question 16

Q

Define Codominant

Answer

A

If both traits (alleles) are expressed in the heterozygous state

Question 17

Q

Define Semi- Dominant or incomplete dominant

Answer

A

The heterozygous phenotype is intermediate between the two phenotype. A degree of both phenotypes combined.

Question 18

Q

Define hemizygous?

Answer

A

A chromosome in a diploid organism is hemizygous when only one copy is present.

Question 19

Q

Define Expressivity

Answer

A

The degree to which a trait is expressed in an individual (is a measure of
severity). Expressivity is analogous to a light dimmer (the light is ‘on’ but the brightness
(expressivity) exists along a spectrum (of severity)). The variation in phenotype is
explained (in part) by sex influence, environmental factors, stochastic effects, and
modifier genes.

Question 20

Q

Sex Influence

Answer

A

Phenotypic expression in some conditions is
dependent on the individual’s sex (e.g. gout is more common in males than
premenopausal females)

Question 21

Q

Sex limitation

Answer

A

occurs if only one sex can express a phenotype

e.g. unicornuate uterus

Question 22

Q

Environmental factors

Answer

A

Some environmental factors can affect the expression of
Mendelian diseases. The disease may only manifest in individuals if particular
environmental factors are present.

Example: In acute intermittent porphyria, episodes of
abdominal pain and psychiatric illness are dependent on exposures (alcohol,
medications).

Question 23

Q

Stochastic Effects

Answer

A

Stochastic (random) effects can influence the expression of
phenotypes. This concept pays homage to the fact that some phenotypes may be
influenced by chance events/processes absent any obvious genetic/environmental factor.

Question 24

Q

Modifier genes

Answer

A

Genetic factors outside of the genetic locus causing a disease can be
important for the expression of Mendelian diseases.

Question 25

Q

Phenocopies

Answer

A

Diseases (traits) that are due to non-genetic factors.

Example: A thyroid
cancer due to radiation exposure cannot always be distinguished from a thyroid cancer
due to mutations in RET gene.

Question 26

Q

Pleiotropy

Answer

A

Used to describe multiple different phenotypic effects due to mutation(s) in a
single gene. Often used, when the phenotypes are seemingly unrelated and/or in
multiple different tissues.

Example: Neurofibromatosis Type I leads to: café au lait spots
(skin), neurofibromas (peripheral nervous tissue), hammartomas in the eyes (ocular),
abnormal freckling (skin again), and learning difficulties (central nervous system).

Question 27

Q

Penetrance

Answer

A

The fraction of individuals with a trait (disease) genotype who show
manifestations of the disease.

Penetrance is analogous to a light switch (can be ‘on’ or ‘off’).

Question 28

Q

How frequently is a SNP likely to occur between two individuals?

Answer

A

1 in every 1000 bp

Question 29

Q

Name a chromosome that is gene rich?

Answer

A

Chromosome 19

Question 30

Q

Name a chromosome that is gene poor?

Answer

A

Chromosome 13, 18, 21

Question 31

Q

Is most of the genome stable or unstable?

Question 32

Q

Percentage of genome that is GC rich?

Question 33

Q

Percentage of genome that is AT rich?

Question 34

Q

What percent of genome is protein coding?

Question 35

Q

What percent of the genome is represented by genes?

Question 36

Q

percent of genome that is repeptitive dna?

Question 37

Q

alpha satellite repeats

Answer

A

171 bp repeat unit near the centromere.

may be important to chromosome segregation in mitosis and meiosis.

Question 38

Q

Alu family

Answer

A

example of DISPERSED DNA repeats about 300 bp in length.

500,000 copies in the genome

retrotransposition can cause insertional inactivation of genes via non-allelic homologous recombination

Question 39

Q

L1 family

Answer

A

An example of DISPERSED DNA repeats about 6 kb in length

100,000 copies in the genome

can lead to disease via non-allelic homologous recombination

Question 40

Q

Microsatellites

Answer

A

2-4 bp nucleotide repeats

5x10^4 per genome

aka short tandem repeat polymorphism

Useful in DNA fingerprinting

Question 41

Q

Minisatellites

Answer

A

tandem repeats about 10-100 bp

aka variable nucleotide tandem repeats.

useful in DNA fingerprinting

Question 42

Q

Gene Families

Answer

A

Gene family is composed of genes with high sequence similarity (e.g. >85-90%) that may carry out similar but distinct functions

Question 43

Q

Copy number variation

Answer

A

primary type of structural variation

may cover 12% of genome

involved in rapid & recent evolutionary changes

Link between evolutionary adaptive copy number increasing and increase in human disease. EX: 1q21

Question 44

Q

When does the synaptonemal complex disassemble?

Answer

A

At the end of prophase I

Question 45

Q

Define metacentric

Answer

A

the centromere is located in the middle of the chromosome,

such that the two chromosome arms are approximately equal in length.

Question 46

Q

Submetacentric

Answer

A

the centromere is slightly removed from the center

Question 47

Q

Acrocentric

Answer

A

the centromere is near one end of the chromosome

Question 48

Q

heterochromatic regions are right with what nucleotides?

Question 49

Q

Euchromatin is __ rich?

Question 50

Q

G banding uses what type of dye?

Question 51

Q

G banding stains what structures?

Answer

A

heterochromatic/ AT regions which are typically gene poor

Question 52

Q

Aneuploidy

Answer

A

the condition in which cells contain an abnormal chromosome number

Question 53

Q

Monosomy

Answer

A

the condition in which a cell lacks one copy of a chromosome

Question 54

Q

trisomy

Answer

A

the situation in which an extra copy of an entire chromosome is
present in the cell.

Question 55

Q

Most common cause of down syndrome?

Answer

A

nondisjunction during maternal meiosis I

Question 56

Q

Tolerated Aneuploidy conceptions?

Answer

A

45 X, trisomy 16, 21, and 22

Question 57

Q

Tolerated Live Birth Aneuploidy

Answer

A

Trisomy 13, 18 or 21

Gain of X and Y chromosome

Loss of X or Y chromosome

Question 58

Q

List the characteristics of Down Syndrom

Answer

A

Trisomy 21

Short stature
Hypotonia 
Moderate intellectual disability
Cardiac anomalies / congenital heart defect 
leukemia in infancy
early onset Alzheimers 
hearing loss

Question 59

Q

Trisomy 18

Answer

A

Edwards syndrom
small for gestational age
small head
clenched fingers
rocker bottom feet

Question 60

Q

Most common chromosomal abnormality in spontaneous abortions?

Answer

A

Turner Syndrome (loss of X chromosome)

Question 61

Q

Phenotype of Turner Syndrome

Answer

A

(loss of x chromosome)

short stature
webbed neck
edema of hands and feet 
broad shield like neck 
gonadal dysgenesis 
renal and cardiovascular anomalies

Question 62

Q

Klienfelter syndrome

Answer

A

male with extra X chromsome

XXY

Question 63

Q

Mosaicism

Answer

A

Mosaicism is defined as the presence of at least two genetically different cells in a
tissue that is derived from a single zygote.

EX: mosaicism turner syndrome has a chromosomal change in only SOME of their cells. Some cells have 46 chromosomes and others have 45

Question 64

Q

Trisomy 13

Answer

A

Patau Syndrome 
Most clinically severe of the 3  
CNS abnormalities  
Omphalocele (herniation of GI organs outside abdomen)  
Renal dysplasia  
Congenital heart disease

Answer 56

A

inversion that occurs outside of the centromere. During meiosis, an inversion loop is required for the associated regions to align. If a crossover occurs WITHIN the loop, you end up with a chromosome that has two centromeres (dicentric) and one WITHOUT a centromere (acentric)

= infertility

Answer 57

A

inversion that occurs within the centromere. During meiosis, an inversion loop is required for the associated regions to align. If cross over occurs WITHIN the loop, you end up with a chromosome that is unbalanced with both having some duplications and some deletions.

Answer 58

A

results from the breakage and rejoining of non-homologous
chromosomes, with a reciprocal exchange of the broken segments.

creates quadrivalent so all four chromosomes can align

Answer 59

A

the fusion of two acrocentric chromosomes within their

centromeric regions, resulting in the loss of both short arms (containing rDNA repeats).

Answer 60

A

A BALANCED ONE.

It does result in a reduction of chromosome however the loss of ribosomal DNA is not considered deleterious

Answer 61

A

The carrier is phenotypically normal however the rearrangement may lead to unbalanced karyotypes in their offspring. Can lead to monosomies or trisomies in their offspring

Answer 62

A

The chromosome set has additional or missing material

Answer 63

A

Duplication of genetic material can lead to partial trisomies.

Deletions of genetic material can lead to monosomies.

Phenotypically ABNORMAL

Answer 64

A

Chromosomes 13 and 14.

Can occur in chromosome 21

Answer 65

A

13, 14, 15, 21, and 22

Answer 66

A

13 and 14

14 and 21

Answer 67

A

9 qh, 16 qh, 1 qh, and Yqh

These are within the heterochromatic region

Does NOT result in spontaneous abortions, infertility, or recombinant offspring

Answer 68

A

0-30%

maternal carriers are morel likely to have a progeny with a phenotype

Answer 69

A

Numerical abnormalities are more common than structural abnormalities

Answer 70

A

Mitotically and meiotically heritable variations in gene expression that are not caused by changes in DNA sequence

EX: post-translational modifications of histones and DNA methylation.

Answer 71

A

HDAC

MeCP2

Answer 72

A

CpG islands

Answer 73

A

Usually gene silencer BUT in some cases acts as a gene activator!

Answer 74

A

Sex-Dependent epigenetic modulation of regulatory regions such as promoter sequences

Answer 75

A

Less than 10%

Answer 76

A

Maintenance methyltransferase

Answer 77

A

In primordial germ cells demethylation occurs. If you produce oocytes, the specific corresponding region is methylated. If you produce sperm, then the male corresponding region is methylated.

Somehow the cell KNOWS. So that you pass on the correct methylation pattern to your progeny.

Answer 78

A

Deletion of paternal 15q 11- 13

Answer 79

A

Deletion of maternal chromosome 15 q 11- 13

Answer 80

A

Primordial cells

Answer 81

A

Prader Willi Syndrome

Answer 82

A

Angelman syndrome

Answer 83

A

misalignment and homologous recombination

Answer 84

A

generates repeats that flank the 15q 11 -13 region on chromosome 15

Answer 85

A

short stature
excessive eating
hypogonadism
some degree of intellectual disability

Answer 86

A

Severe intellectual disability
Spasticity
Seizures
Short stature

Answer 87

A

Leukemia and lymphomas

Answer 88

A

Chromosomal Microarray (CMA) AKA Array CGH

Answer 89

A

Chromosome analysis and FISH

Answer 90

A

Bone Marrow
Unstimulated Blood
Lymph node tissue
Solid tumor tissue
Cerebrospinal fluid

Answer 91

A

INITIAL differential diagnosis

monitor treatments or disease progression

Answer 92

A

Suggests Myelogenous Leukemia

Answer 93

A

Chromosomal Microarray detects gains and losses ONLY

It uses interphase DNA instead of mitotic cells

Analyzes ALL CELLS

Technology Dependent

Detects runs of homozygosity

Answer 94

A

can evaluate greater than or equal to 5 Mb with a 10 Mb threshold

Answer 95

A

Cannot detect very low level mosaicism, heterodisomy, or balanced chromosome rearrangement

Answer 96

A

If deletion or duplication is detected by CMA consult Database of Genomic Variance
Parental FISH studies will be offered to determine if this finding is a rare,
normal, familial variant.
If a deletion or duplication is found in one or both parents, other family
members may be tested by FISH. Often extensive consultation between
the clinical geneticist, genetic counselors and cytogeneticist are required.
If the deletion or duplication is not found in either parent, and it is not found in
the genomic variants Database, further data-base mining, literature
searches are performed. Often a gene or genes mapped in the region of
deletion or duplication reveals a syndromic association.

Answer 97

A

Variable response due to individual genes

Answer 98

A

Variable response due to multiple loci across the genome

Answer 99

A

the rate at which the body absorbs, transports, metabolizes, or excretes drugs or their metabolites

“What the body does to the drug”

Answer 100

A

The differences in the way the body responds to the drug.

“What the drug does to the body”

Answer 101

A

the introduction of a more polar group to a compound that allows a side group to be more readily attached

The hydroxyl group attached in phase I
provides a site for a sugar or acetyl group to be attached to the drug to detoxify it and make it much easier to excrete in what is referred to as phase II of drug metabolism

Answer 102

A

splicing or frameshift mutations

Answer 103

A

missense mutation

Answer 104

A

Mostly in the liver.

Also, intestinal epithelium

Answer 105

A

CYP1, CYP2, CYP3

Answer 106

A

takes part in metabolism of 40% of all drugs

Answer 107

A

Felodipine (CA channel blocker that can be used for hypertension) and Cyclosporine (immunosuppressant)

Answer 108

A

grapefruit juice and ketoconazole (an antifungal agent)

need to reduce drug dosage so that patient does not suffer from drug toxicity

Answer 109

A

rifampicin.

Need to increase drug dosage

Answer 110

A

It ACTIVATES codeine into morphine

Answer 111

A

Isonizad for tuberculosis

Answer 112

A

6-mercaptopurine and 6-thioguanine

Answer 113

A

6-mercaptopurine is a drug used to treat ALL but in .5% of children the TPMT activity is so low (due to a mutation) that drug toxicity can occur and the child will die. Only 10% of standard drug dose is needed for these children.

TPMT is an enzyme transcribed from the TMPT gene and detoxifies the 6-mercaptopurine drug.

Answer 114

A

Warfarin which is a blood thinner that is always started at 5 mg/day and then adjusted from there

Answer 115

A

The proportion of total variance in a trait the at is due to variation in genes

Answer 116

A

Different alleles at same location can cause CF

Answer 117

A

Alleles at different location or Loci can cause AD

Answer 118

A

Some cancers
diabetes I and II
Alzheimers
Inflammatory bowel disease
Asthma
Schizophrenia
Hypertension
Cleft lip / palate
Rheumatoid arthritis

Answer 119

A

Risk of disease if carrying a given gene variant/ risk of disease if not carrying a given gene variant

Answer 120

A

Start with disease –> MAP genome –> find gene –> figure out its functio

Answer 121

A

haplotype blocks because they are so close together that recombination does not typically occur

Answer 122

A

Hypothesis driven

“I think this disease is caused by this gene”

Leads to FALSE POSITIVES 97% of the time

Answer 123

A

Stratification - no such thing as a homozygous population

Publication bias - the only studies that get published are the ones with positive confirming results

Answer 124

A

Using patterns of inheritance to guess whats going on in a rare disorder

Answer 125

A

For UNCOMMON Mendelian traits

Answer 126

A

unit of genetic distance/recombination

Answer 127

A

“Log of Odds”

statistical measure of likelihood that loci are linked together given the inheritance/disease pattern

Answer 128

A

Genetic Linkage

Genome-Wide Association Study

Answer 129

A

Tests ALL parts of the genome simultaneously between individuals for patterns of SNPs associated with diseases

Answer 130

A

can accurately measure and correct for population stratification

You know the number of tests performed genome-wide (don’t care about other studies)

Answer 131

A

For COMMON alleles with small to moderate effect size

Can discover NEW genes as well

Answer 132

A

You sequence the coding region oof the genome and can combine result with other affected family members to narrow down the cause of disease.

Will eventually be replaced BY GENOME SEQUENCING

Answer 133

A

Data interpretation can be difficult due to Variant of Unkown Significance.

Creates a lot of “noise”

Answer 134

A

Microsatellites
Single-Nucleotide-Polymorphisms (SNPs)
Copy-Number-Variants (CNVs)

Answer 135

A

The existance of multiple mutant alleles of a single gene

Answer 136

A

One who carries two different mutant alleles of the same gene

Answer 137

A

High phenylalanine level in the blood
hyperactivity
epilepsy
mental disability
microcephaly

Answer 138

A

Autosomal Recessive

Answer 139

A

mutation in PAH that encodes phenylalanine hydroxylase (PAH) in 98% of case.

PAH converts phenylalanine to tyrosine

Answer 140

A

Defects in the PAH cofactor BH4 that disrupts production of tyrosine, dopamine, and serotonin

Answer 141

A

compound heterozygotes

Answer 142

A

Low phenylalanine diet.

Phenylalanine is an essential amino acid so you need some

Answer 143

A

Not dictated by the child’s gene. Mom who is not on a restricted diet will lead to an increase in F in the maternal circulation leading to MISCARRIAGE and DEVELOPMENTAL ABNORMALITIES

Answer 144

A

newborn won’t have elevated F because mom’s enzyme was working. Need to wait a couple days after birth to compare.

Answer 145

A

Mass spectroscopy

Answer 146

A

The old way to test for PKU.

thienalalnin inhibits growth of bacteria. This can be inhibited by high level of phenylalanine causing bacteria to grow = + test

Answer 147

A

emphysema (shortness of breath)
increased risk for liver cirrhosis
LATE ONSET

Answer 148

A

Northern Europeans

Answer 149

A

Deficiency in protease inhibitor alpha1-antitrypsin (SERPINA1, AAT) which inhibits elastase

Answer 150

A

breaks down elastin in CT

Answer 151

A

Glu342Lys and the Z allele protein is not folded properly and accumulates in liver cells leading to liver damage

ZZ genotype = 15% normal alpha1-antitrypsin function

Answer 152

A

Glu264Val makes unstable SERPINA1 protein

50-60% of normal SERPINA1 level

Answer 153

A

intravenous infusion and aerosol inhalation of SERPINA1

Answer 154

A

progressive destruction of the central nervous system

neurological deterioration 3-6 months

Die by 2-4 years

Answer 155

A

muscle weakness and startle response at sudden sound

Answer 156

A

Ashkenazi Jews

Answer 157

A

Inability to degrade GM2 ganglioside which leads to a build up within lysosomes in neurons found in the CNS

Defective Hexoaminidase A enzyme

Answer 158

A

HEXB gene and affects HexA and HexB enzyme activity

Answer 159

A

rare form that does not affect Hex A or Hex B activity. Instead mutation on the GM2 activator protein which leads to build up of GM2 ganglioside

Answer 160

A

Sex chromosome disorder. Women missing an X chromosome 45X

Answer 161

A

aortic coarctation
bicuspid aortic valve
systemic hypertension
conduction difficulties

Answer 162

A

inner epicanthal folds
ptosis (drooping of the eye)
Blue Sclera

Answer 163

A

Short 4th metacarpal

short stature

Answer 164

A

Web neck
low hairline
cystic hygroma

Answer 165

A

difficulty in math
visual spatial skills
low non-verbal skills

Answer 166

A

widely spaced nipples

Answer 167

A

95% of patients with Down Syndrome

due to nondisjunction in maternal meiosis I

Answer 168

A

3-4% of patients with Down Syndrome

Due to a Robertsonian Translocation leading to the fusion of chromosome 21 and 14

Answer 169

A

1-2% of patients with Down syndrome
mixture of normal and abnormal cells
milder symptoms

Answer 170

A

upslanting palpebral fissure
epicanthal folds 
midfacial hypoplasia 
small ears
large appearing tongue
low muscle tone

Answer 171

A

congenital heart disease
atrioventricular canal (hole between all four heart chambers)

Answer 172

A

esophageal atresia - leads to blind pouch rather than stomach

Answer 173

A

Child is unable to swallow amniotic fluid

Answer 174

A

a prenatal test that is used to detect birth defects, genetic diseases, and other problems during pregnancy. Sample taken from the placenta where it attaches to the wall of the uterus.

Answer 175

A

FISH or microarray

II. Methylation testing

Answer 176

A

hypotonia
undescended testes
lighter pigmentation
feeding issues

Answer 177

A

Increase appetite

persistant hunger

Answer 178

A

strabismus - lazy eye

nystagmus - jiggly eye

Answer 179

A

mild-moderate developmental delays

behavioral issues

Answer 180

A

IDIC 15

Maternally inherited interstitial duplication

Answer 181

A

childhood- learning disability
delayed speech and language
tendency to be quiet

Answer 182

A

tall stature
small testes
reduced facial hair
infertility
hypospadia - urethra is underside of penis
gynecomastia - enlarged breasts in males

Answer 183

A

learning disabilities
speech delays
developmental delays 
behavioral and emotional difficulties
autism spectrum 
tall stature

Answer 184

A

learning disabilities 
delayed speech 
delayed motor
seizure
kidney abnormalities

Answer 185

A

can’t convert testosterone to dihydrotestosterone

under virilized male then increased during puberty

Answer 186

A

Cleft lip / palate
congenital heart disoders
Thymus defect
parathyroid defect

Answer 187

A

amniocentesis and FISH

Answer 188

A

Trisomy 13

Answer 189

A

Maintenance methylation

Answer 190

A

Phenotype depends on whether the mutation is maternal or paternal in origin.

Their effects are dependent on sex-specific methylation patterns that silence the only good copy of a gene.

Answer 191

A

Modification must be established in gametes
Must be stably maintained after fertilization
Must be reversible so appropriate sex-specific imprint is passed on

Answer 192

A

identification of markers and translocations

Answer 193

A

1/100 (1%) plus maternal age risk

Answer 194

A

Down Syndrome

Answer 195

A

They are non-functional genes that can be synthesized through reverse transcription

Answer 196

A

Trisomy 18

Answer 197

A

small for gestational age
microcephaly
clenched hands/overlapping fingers
Rocker bottom feet 
Heart/brain abnormalities 
90% perinatal lethality

Answer 198

A

Characteristic facies
severe intellectual disabilities
Congenital malformations (fusion of brain lobes, facial clefts, polydactyly, renal defects)

Answer 199

A

zeta - alpha 2 - alpha 1 on CHROMOSOME 16

Answer 200

A

epsilon - gammaG - gammaA - delta - beta on CHROMOSOME 11

Answer 201

A

Majority of hemoglobin made up of alpha2 and beta2

Answer 202

A

zeta2 and epsilon2

Answer 203

A

alpha 2 and epsilon2

Answer 204

A

zeta2 gamma 2

Answer 205

A

turn off zeta and epsilon, turn on alpha and gamma during early embryogenesis

Answer 206

A

turn off gamma and turn on delta and beta at time of birth

Answer 207

A

Fetal Hemoglobin alpha2-gamma2

Has higher affinity for O2 at low pO2 than HbA

Answer 208

A

Caused by the deletion of the Locus Control Region (LCR) on the beta like cluster

Answer 209

A

Hb^Kemsey (binds oxygen too tight)

Hb^Kansas (bind too weak)

Answer 210

A

mutation glutamate –> valine at codon 6

Hemoglobin is now 80% less soluble when not bound to O1 and polymerizes into long fibers

Answer 211

A

Milder form of hemolytic anemia

mutation glutamate –> lysine at codon #6

forms crystals

Answer 212

A

HbS trait

heterozygous HbS/HbA

clinically normal except when under severe low pO2

Answer 213

A

MstII

cannot distinguish Hemoglobin C disease!

Answer 214

A

Over production of blood cells - Polycythemia

Answer 215

A

caused by deletion of one or both copies of the alpha-globin gene in the alpha cluster.

gamma and beta globin now in excess

Answer 216

A

Hydrops Fetalis - - / - - ton of gamma 4
HbH disease a - / - - beta 4
mild anemia aa / - - alpha thalassemia - 1 trait

Answer 217

A

mild anemia a - / a - alpha thalassemia - 2 trait

Answer 218

A

Hydrops Fetalis - - / - - ton of gamma 4
HbH disease a - / - - beta 4
mild anemia aa / - - alpha thalassemia - 1 trait

Answer 219

A

mild anemia a - / a - alpha thalassemia - 2 trait

Answer 220

A

Fibroblast Growth Factor Receptor 3

FGFR3

Answer 221

A

Chromosome 4p16.3 nucleotide 1138
missense mutation Gly380Arg
Mutation increases the activity of the protein interfering with skeletal development

Answer 222

A

The likely explanation of the rare situations where a person without a dominant condition can have two children with the same autosomal dominant condition

Answer 223

A

Malignant tumor of the retina

Answer 224

A

Mutation in the NF1 gene in Chromosome 17q11.2

Loss of function of a tumor suppressor gene NF1

Answer 225

A

6 or more café-au-lait spots
2 or more neurofibromas
1 plexiform neurofibroma
2 or more Lisch Nodules

Answer 226

A

Mutation in the NF1 gene in Chromosome 17q11.2

Loss of function of a tumor suppressor gene NF1

Answer 227

A

Multiple fractures
Mild short stature
Adult onset hearing loss
Blue sclera

Answer 228

A

Collagen type 1 alpha 1 COL1A1 on Chromosome 7q21.3

Reduced production of pro-alpha 1 chains that reduces the type 1 collagen production by half

Answer 229

A

Systemic disorder of connective tissue, musculoskeletal and cardiovascular problems.

Aortic Root enlargement seen!

Answer 230

A

Thumb and wrist sign
scoliosis
ectopia lentis
pectus excavatum

Answer 231

A

Fibrillin gene FBN1 on Chromosome 15q21.1

Answer 232

A

CAG repeats >39

Answer 233

A

Progressive neuronal degeneration causing motor, cognitive and psychiatric disturbances
Age of onset 35-44
Death approximately 15 years after onset

Answer 234

A

Progressive neuronal degeneration causing motor, cognitive and psychiatric disturbances
Age of onset 35-44
Death approximately 15 years after onset

Answer 235

A

Paternal transmission

Answer 236

A

Adult onset muscular dystrophy
Progressive muscle wasting and weakness
Myotonia
Cataracts
Cardiac conduction defects

Answer 237

A

CTG repeat >50

Myotonic dystrophy protein kinase (DMPK) gene on Chromosome 19q13.3

Answer 238

A

Maternally!

Answer 239

A

Typically autosomal recessive

ex: PKU and Gaucher’s disease

Answer 240

A

Ideal for looking at the sequence of a known disease gene

Can detect NOVEL mutations

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Unit II Flashcards

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