Orofacial Genetics for Dentists PDF

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This document is a lecture or presentation on Orofacial Genetics for Dentists given in October 2021. It covers topics like the role of genetics in oral diseases, biomarkers, genes involved in caries, and genetics of periodontal disease.

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Orofacial Genetics for Dentists

Farhad Khosrow Shahian, DDS PhD
 Why do dentists need to know about
genetics?
Recent studies indicate that genetics plays a role in
the etiology of:
- Caries
- Periodontal disease
- Dental anomalies
- Malformation/syndromes (eg. Cleft lip and palate)
- Malocclusion
- Oral cancer
- Many genetics diseases with oral implications
Molecular genetics will likely be used to diagnose
and treat many of these diseases
 Biomarkers for Oral Cancer
S100A7
Predictive marker for premalignant oral lesions
leukoplakia, Lichen planus, and other dysplastic
condition
Role in epithelial, breast and Thyroid Cancer as well
as Alzheimer's disease.
 Genetics and caries
Twin studies suggest partial genetic control (20%-
85%).
Variation due to etiological variation of caries
experience, including population or race-level genetic
or environmental differences.
Early childhood caries is strongly influenced by
maternal health (obesity, diabetes,…)
 Genes involved in caries
Gene Role Disease
Matrix metalloproteinase 20
Early stages of tooth development Caries
(MMP20)
Ameloblastin (AMBN) Enamel matrix Caries, dental fluorosis
Amelogenesis imperfecta, caries,
Amelogenin (AMELX) Tooth mineralization
hypomineralization
Enamelin (ENAM) Enamel matrix Amelogenesis imperfecta,
hypomineralization, caries
Kallikrein 4 (KLK4) Enamel matrix strengthening Hypomaturation, amelogenesis
imperfecta
Aquaporin 5 (AQP5) Saliva production
Caries

Carbonic Anhydrase VI (CA6) Saliva pH regulation
Caries

Mucin 5 (MUC5B) Inhibits biofilm formation
Caries susceptibility
 Genetics and Periodontal disease

Monogenic congenital syndromes can result in aggressive
periodontitis (Papillon-Lefèvre and Chediak-Higashi
syndromes)
Periodontal disease is a two-step process, requiring both
genetic susceptibility followed by a bacterial challenge
Genetics plays a role in the etiology of periodontal disease by
controlling periodontal structural integrity as well as affecting
the host response to subgingival microbiota.
2017 systematic review identified the vitamin D receptor
gene, VDR, Interleukin-10, IL-10, and the immunoglobulin
platelet receptor gene Fc-γRIIA as the strongest candidates.
 Papillon–Lefèvre syndrome (PLS)
Rare autosomal recessive disorder
Diffuse palmoplantar keratoderma
Precocious aggressive periodontitis
Leading to premature loss of deciduous and permanent
dentition at a very young age.

Papillon–Lefèvre syndrome: clinical
presentation and management options
Basapogu Sreeramulu, Naragani DVN
Shyam, Pilla Ajay, Pathipaka Suman
Clin Cosmet Investig Dent. 2015; 7: 75–81.
 Genes involved in periodontal disease
Gene Role Disease
Fc-γRIIA Platelet receptor
Chronic periodontitis

Interleukin-1 (IL-1α, IL-1β) Proinflammatory response
Periodontitis

Proinflammatory response; bone Gingivitis, periodontitis, acute
Interleukin-6 (IL-6)
resorption apical periodontitis
Apical periodontitis, chronic
Interleukin-8 Immune response
periodontitis
Aggressive periodontitis,
Interleukin-10 Immune response
inflammatory bowel disease, type 1
diabetes; chronic periodontitis
Interleukin-37 Immune response Severe periodontitis, tooth loss,
stroke
Matrix metalloproteinase family Degradation of extracellular matrix
Periodontitis
(MMP2, 3, 8, 9) during development, tissue repair
Tooth formation, calcium and Periodontitis
VDR
phosphate balance
 “Personalized Medicine”

Dental and medical care requires:
- Examination and assessment of the patient’s status,
diagnosis, and prescription of treatment
- Not all patient’s respond equally to treatment
- It is believed that an individual’s response to
treatment is largely determined by intrinsic genetic
factors and behavior (lifestyle, diet, exercise, …)
 Personalized Orthodontics
Hartsfield 2008; Seminars in Orthodotics

Genetic tests can compliment clinical and
radiographic data to prevent undesirable treatment
outcomes
Genetic tests (eg. polymorphic studies) may indicate:
- high risk of external apical root resorption
- early detection and confirmation of malocclusion
- Identify individuals who will likely “catch up” in
skeletal growth without treatment or perhaps one who
would respond more with a functional appliance
 Variation in the Human Genome
Person 1 Person 2

= Variations in DNA
 Of the 3.2 billion bases, roughly 99.9 percent are the
same between any two people.

It is the variation in the remaining tiny fraction of the
genome, 0.1 percent--roughly several million bases--
that makes a person unique.

This small amount of variation determines attributes
such as how a person looks or the diseases he or she
develops.
What are Variation Types in the Genome?

Polymorphism

Deletions

Insertions

Chromosome
Translocations
 Polymorphism
Genetic variation that is observed at a frequency of
>1% in a population (~90% of all DNA variation)

Single nucleotide polymorphisms (SNPs)
- Single base mutation which substitutes one nucleotide
for another

- Most commonly, these variations are found in the
DNA between genes.
- As biological markers, SNPs locate genes that are
associated with disease.
 Within a gene or in a regulatory region near a gene,
they may play a more direct role in disease by
affecting the gene’s function.

Most SNPs have no effect on health or development.

Help predict an individual’s response to certain drugs,
susceptibility to environmental factors such as toxins,
and risk of developing particular diseases.

SNPs can also be used to track the inheritance of
disease genes within families.
 SNPs Are the Most Common
Type of Variation
At least 1 percent of
Most of the population the population

G to C

Common Variant
sequence sequence

SNP
site
 Tandem Repeat Polymorphisms
Tandem repeats or variable number of tandem repeats (VNTR)
are a class of polymorphism, consisting of variable length of
sequence motifs that are repeated in tandem in a variable copy
number.

Based on the size of the tandem repeat units:
Microsatellites or Short Tandem Repeat (STR)
repeat unit:1-6 (dinucleotide repeat: CACACACACACA)
Minisatellites
repeat unit: 14-100
Number of repeats is highly variable due to “slippage” during
DNA replication.
 SNPs in linkage analysis

identify SNP that segregate
family pedigree together with the disease

+ ~ location
fine mapping
SNP typing using DNA of affected
and unaffected family members

candidate gene
 SNPs in association studies

to test whether a particular SNP allele
is enriched in patients compared
to healthy controls
Causes of human congenital anomalies
 Mutations
Muller – Mutation of fruit flies by X-rays

3 types
– Substitution
– Deletion
– Insertion
 Mutations
Single Base Substitutions
– alter the triplet codon
– one amino acid to be replaced
Deletions and insertions
– if a single base pair is deleted or inserted, the
entire frame of the DNA strand gets shifted
Single base substitutions – proteins produced
Frame shift mutations – no proteins
 Mutations
Chain termination mutations –
– Termination codons can be added
prematurely or be deleted
Splice Mutations –
– These interfere with the way introns
are removed from the messenger RNA.
Mutations in regulatory
sequences
– These affect the TATA box and the
CAT box regions of the gene.
 Single gene disorders
Mutations found in single genes can be transmitted through
mendelian inheritance.
Mendelian inheritance/Single Gene Traits
– Patterns of single gene inheritance depend on chromosomal
location and dominance or recessiveness of the phenotype
associated with the allele
– 4 types of inheritance
Autosomal dominant
Autosomal recessive
X-linked dominant
X-linked recessive
 Mendelian Disorders
Dental Disorders
– Amelogenesis imperfecta
– Dentinogenesis imperfecta
– Familial hypodontia
– Some ectodermal dysplasias
– Other syndromes with dental defects
Craniofacial Disorders
– Cleidocranial Dysostosis
– Nevoid Basal Cell Carcinoma Syndrome
– Craniosynostosis Syndromes
– Oro-facial Clefting Syndromes
 Mendelian Disorders
Systemic disorders that may affect dental care
Sickle cell anemia:
- Susceptibility to dental infections, Delayed eruption and
hypoplasia of the dentition secondary to their general
underdevelopment.
- hypercementosis and osteoporosis of the jaw
- general anesthesia is hazardous in sickle cell patients
because of severe anemia and a crisis may be precipitated.
- Acute infections should be treated immediately since they
may precipitate a sickling crisis.
- Patients are more prone to developing osteomyelitis
because of hypovascularity
Cystic fibrosis:
- antibiotics side effects
 Inheritance – Single gene disorders

Autosomal dominant
– one gene or allele is defective and the other complementary
allele is normal
– Rare
– Patient usually heterozygous
– Parent affected
– New mutation (mutation in an egg or sperm)
– Achondroplasia, Osteogenesis imperfecta
– Porphyria variegata – one couple (1688)
– ½ the children affected – irrespective of sex
How do autosomal dominant diseases stay in the
population?

Variable Expressivity
Late Onset
High Recurrent Mutation Rate
Incomplete Penetrance
 Variable Expressivity
Marfan syndrome is an autosomal dominant disease caused by
a mutation in collagen formation.
It affects about 1/60,000 live births.
Symptoms of Marfan syndrome include:
- Skeletal/Dental: Narrow jaws and high-arched palate,
arachnodactyly (long fingers and toes), extreme lengthening of
the long bones, scoliosis, rib and sternum abnormalities, …
- Optical: ectopia lentis, a dislocation of the lens into the
anterior chamber of the eye.
- cardiovascular abnormalities: Including dissecting
aneurysms, Also seen with Ehlers-Danlos syndrome. Mitral
valve prolapse and artificial heart valves- endocarditis?

*Each patient may express all of the symptoms, or only a few.
 The disease is maintained in the population through recurrent
mutations and the reproduction of less severely affected
individuals with normal individuals.

The extent of severity of affected does not affect the severity
of expression in the next generation, that is, the offspring of
mildly affected individuals range from mildly affected to
severely affected, with equal probability.
 Polydactyly

Often in genes for structural proteins
Often associated with advanced
paternal age
 Late Onset
Some autosomal dominant diseases do not express themselves until later in
life.

Huntington disease
Age of onset varies from the teens to the late sixties

Most of the individuals born with the defective allele will develop the
disease by the time they are 70.

The disease is progressive with death usually occurring between four and
twenty-five years after the first symptoms develop.

Poor Coordination, Involuntary Movements, Depression, Short-Term
Memory Loss, Slight Lack of Emotion (Apathy)

Emotional changes often are the first symptoms.
 It is caused by the expansion of an unstable trinucleotide
repeat sequence, CAG, in the coding region of the gene.

Huntington's disease occurs when there are more than 35 CAG
repeats on the gene coding for the protein HTT.

Trinucleotide repeat disorders are the result of extensive
duplication of a single codon.

What is inherited at birth in Huntington disease is a gene with
several repeats and the instability that allows somatic
recombination and extension.
 Myotonic dystrophy

Progressive muscle wasting and weakness beginning in their
20's or 30’s.
The muscle wasting and weakness develop in their lower legs,
hands, neck and face.
The expression is delayed due to unstable trinucleotide
sequences (CTG) of DMPK gene.

This unstable sequence lies in a non-translated region of the
gene.

Alleles with greater than 37 repeats are unstable and additional
trinucleotide repeats may be inserted during cell division in
mitosis and meiosis.
 High Recurrent Mutation Rate
Achondroplasia: major causes of dwarfism.
Motor skills may not develop as quickly as their normal
siblings, but intelligence is not reduced.
It occurs in about 1/10,000 live births.
Like many autosomal dominant diseases, individuals
homozygous for the mutant allele do not survive to term.
85% of the cases are the result of new mutations, where both
parents have a normal phenotype.
The mutation rate for achondroplasia may be as much as 10
times the "normal" mutation rate in humans.
This high recurrent mutation is largely responsible for keeping
the mutant gene in the population at its present rate.
 Incomplete Penetrance

The proportion of people who show symptoms from the
mutation is called the penetrance of the gene.
Not all individuals carrying a deleterious gene express the
associated trait.
Complete penetrance: The presence of a genetic mutation
always results in disease (FGFR3 mutation results in
achondroplasia/dwarfism).
Incomplete penetrance: Mutations that have less than 100
percent penetrance (BRCA1 gene mutation results in 80% of
women to develop breast cancer).
 Crouzon Syndrome

Autosomal dominant; complete penetrance; Many cases are
due to sporadic mutation; increased risk with higher paternal
age
Premature craniosynostosis, may be present at birth
Coronal fuses first in most cases – changes in head and facial
form
 Crouzon Syndrome

Midfacial and maxillary hypoplasia
Orbital proptosis (protrusion of orbital contents)
Brachycephaly (flat-head)
Clinically normal hands
Measurable alteration in proportions of the bones of the hand –
shortened proximal phalanx of the first and second fingers,
terminal phalanx of the first finger (short thumbs)
Hands in Crouzon Syndrome
Cleidocranial Dysplasia
 Cleidocranial Dysplasia
Multiple unerupted teeth
Delayed dental eruption
Supernumerary teeth
Characteristic facial phenotype –frontal bossing,
hypertelorism, delayed closure of the fontanels
Hypoplastic/absent clavicles
Cementum deficient on roots
Autosomal dominant inheritance
CBFA1 gene (RUNX2) – a transcription factor involved in
osteoblast differentiation.
Cleidocranial Dysplasia
 Autosomal Recessive

Parents of affected offspring have 25% recurrence risk
Each parent contributes a mutated copy of the gene
Often associated with genes for enzymes
Phenotype is often not variable
Both sexes – homozygous
Extremely rare – heterozygous are normal
 Inheritance – Single gene disorders

Consanguineous marriages
– Chance that cousins will carry the same genes is 1 in 8
– The rarer the disease  more probability of
consanguineous marriage of parents.
– Eg – Alkaptonuria
Most common autosomal recessive disorder – Cystic fibrosis –
1 in 22 is a carrier.
 Amelogenesis Imperfecta

Mutations in the AMELX, ENAM, MMP20, and KLK-4
Amelogenesis imperfecta can have different inheritance
patterns depending on the gene that is altered.
Most cases are caused by mutations in the ENAM gene and
are inherited in an autosomal dominant pattern.
Amelogenesis imperfecta is also inherited in an autosomal
recessive pattern; this form of the disorder can result from
mutations in the ENAM or MMP20 gene.
About 5% of amelogenesis imperfecta cases are caused by
mutations in the AMELX gene and are inherited in an X-
linked pattern
In most cases, males with an X-linked form of this condition
experience more severe dental abnormalities than affected
females.
Amelogenesis imperfecta – hypoplastic type