Pathobiology: Genetic Diseases (Poulik)

GENERAL PRINCIPLES OF GENETIC DISEASES AND SINGLE GENE DISORDERS:

·  Genetic Mutations:

-  Definition: stable, heritable alteration in DNA

Different Types of Mutations:

Chromosomal Level: result in cytogenic or karyotypic abnromalities

§  Genome mutation: loss or gain of a whole chromosome (ie. trisomy)

§  Chromosome mutation: structural changes in chromosome that gives rise to visible structure changes in the chromosome (ie. translocations, deletions)

§  Trinucleotide repeats: although gene mutations, may be visible by karyotype when cells cultured in different media (ie. Fragile X syndrome visible in foalte deficient media)

o  Gene Level: most are NOT visible by karyotype (some trinucleotide repeats are the exception) and therefore require molecular genetics techniques to define mutation (ie. DNA sequencing)

§  Point Mutations: single base substitution

Ø  In exon: protein coding sequence of enzyme, structural or regulatory protein

Ø  In intron: in non-protein coding sequences (promoter, enhancer etc.)

o  May lead to reduction or loss of transcription

§  Frameshift Mutations: caused by deletions or insertions in coding sequence and alterations in reading frame of DNA

§  Trinucleotide Repeats

Pathological Significance of Genetic Alterations: may do a number of things

o  Directly cause disease (ie. Tay Sachs)

o  Predispose to disease (ie. X-linked agammaglobulinemia)

o  Alter response to another disease (sickle cell anemia protection against malaria)

Manifestations of Genetic Disease:

o  Abnormal metabolism or physiology

o  Abnormal development that may result in major or minor malformations

o  Spontaneous abortion or stillbirth (with or without malformations)

o  Asymptomatic or subclinical (ie. female carrier of X-linked trait)

·  Single Gene Disorders with Mendelian Inheritance:

-  Definition: diseases resulting from a mutation in a single gene of large effect, inherited according to Mendelian patterns

Inheritance Patterns: most are recessive*

Autosomal Dominant: clinical phenotyp occurs with single copy of mutant allele

§  Usually non-enzymatic proteins

§  1 parent affected (if not affected, de novo mutation)

§  Both males and females affected

§  1 in 2 chance of transmitting disorder

§  Clinical features modified by reduced penetrance and expressivity

Autosomal Recessive: clinical phenotype occurs only when both alleles are defective (although defect in both alleles does not have to be the same)

§  Usually enzymatic proteins

§  Trait usually does not affect parents

§  Both males and females affected

§  1 in 4 chance of transmitting disorder

§  More uniform expression of defect than AD disorders (complete penentrance common)

§  Onset usually early in life

o  X-linked: more common in males (only 1 X cs)

-  Mechanisms of Pathogenesis of Single Gene Disorders:

o  Mutations:

§  Enzymes or enzyme inhibitors

§  Receptors

§  Transport or structural proteins

o  Enzyme Defects: result in reduce or absent enzyme leading to specific block in metabolism (usually of a catabolic pathway) leading to

§  Abnormal accumulation of metabolites (substrates)

§  Decreased amount of end product that is necessary for normal function

§  Failure to inactivate a tissue damaging substance

ENZYME DEFECTS- LYSOSOMAL STORAGE DISEASES:

·  Lysosomal Storage Diseases- General:

-  Lysosomes: “intracellular digestive tract” involved in turnover of macromolecules within the cell

o  Contain degradative enzymes called hydrolases

o  Function in acid environment of the lysosome

o  Made in the ER, sent to the Golgi, undergoes post-translational modification to target it to lysosomes

-  Lysosomal Storage Diseases: due to lack of any protein essential for normal function of lysosomes

o  Distribution of non-degraded material (ie. organ affected) due to an LSD is determined by:

§  Tissue where most of the degraded material is found

§  Location where most of the degradation usually occurs

o  Rare (1/8000 births)

o  Most are autosomal recessive

§  Exceptions: both are X-linked recessive

Ø  Fabry Disease

Ø  Hunter Syndrome

o  Grouped based on type of macromolecule undergoing degradation:

§  Mucopolysaccharides

§  Sphingolipids

§  Sulfatidoses

§  Cerebrosides

·  Mucopolysaccharidoses (MPS):

-  General:

o  Mucopolysaccharides: group of macromolecules composed of glycosaminoglycans (GAGS), which are long chain carbohydrates with disaccharide repeating units

§  GAG Examples:

Ø  Dermatan sulfate (heart, blood vessels, skin)

Ø  Heparan sulfate (lung, arteries, skin)

Ø  Keratan sulfate (cartilage, cornea, intervertebral discs)

Ø  Chondroitin sulfate

Ø  Hyaluronic acid

§  Proteoglycans: GAG + protein (secreted by GAG synthesizing cells)

§  Function: involved in structural integrity of the ECM

§  GAG Synthesizing Cells: fibroblasts, endothelial cells, leukocytes

Ø  Secrete proteoglycans

Ø  GAGs that are not secreted are degraded by lysosomal hydrolases (enzyme deficiency results in accumulation in lysosomes and free GAGs in urine)

o  Mucopolysaccharidoses (MPS):

§  Usually progressive disorders

§  Classified numerically from MPSI-MPSIV

§  Share similar clinical features:

Ø  Multi-system involvement

Ø  Organomegaly

Ø  Abnormal facies

Ø  Joint stiffness and deformity

Ø  Mental retardation

§  Diagnosis:

Ø  Presence of GAGS:

o  Urinary: age-dependent (present in normal infants up to a year old)

§  Look for larger than normal amounts of heparan and dermatan sulfate (normal urine contains mostly chondroitin sulfate)

o  Amniotic fluid

Ø  Enzyme Assays:

o  Prenatal:

§  Cultured cells from amniotic fluid

§  Chorionic villus biopsy less suitable (have low enzyme activity)

o  Postnatal: measure enzyme activity in plasma, leukocytes or skin fibroblasts

-  Hurler Syndrome (MPS I):

o  Inheritance Pattern: autosomal recessive

o  Deficiency: α-L-idurondase enzyme activity

o  Onset: 6-8 months

o  Common Features: severe mental and motor regression with death usually before 10 years of age

§  Respiratory disease

Ø  Storage in airway epithelium and bone

Ø  Small ribcage (oar-shaped ribs) and stiff joints

Ø  Decreased expansion due to hepatomegaly

Ø  Upper airway obstruction due to storage in tongue, lymphoid tissue, airway epithelium, pharyngeal soft tissue

§  Coarse facial features

§  Ophthalmic disease with early corneal clouding (retinal disease, glaucoma)

§  CV disease (valve disease, CAD, congestive heart failure)

Ø  Accumulation of GAGs in histiocytes, mycocardial cells, heart valves, coronary arteries and aorta

§  Dwarfing

Ø  Accumulates in bone (growth plates) and prevents linear growth

§  Stiff joints

§  Hepatosplenomegaly

Ø  Storage in hepatocytes and Kupffer cells of lvier

Ø  Storage in histiocytes in the spleen

§  CNS disease (mental retardation, hydrocephalus, spinal cord compression)

Ø  Storage in neurons, macrophages and meninges

§  Deafness

§  Alder-Reilly anomaly (accumulation of MPS in PMNs- granular appearance)

o  Diagnosis: urinary excretion of dermatan and heparan sulfate

-  Hunter Syndome (MPS II):

o  Inheritance Pattern: X-linked recessive

o  Deficiency: iduronate sulfatase

o  Onset: in early infancy or childhood

o  Common Features: similar clinical features to Hurler, but LESS severe (mental deterioration with varying degrees of neurological involvement)

§  Coarse facial features

§  Dwarfing

§  Stiff joints

§  Progressive deafness

§  NO corneal clouding*

o  Diagnosis: urinary excretion of dermatan and heparan sulfate

·  Sphingolipidoses:

-  General:

o  Cause: defect in metabolism of sphingolipids

o  Sphingolipids: long-chain amino alcohols (sphingosine) attached to a fatty acid to produce a complex lipid (ceremide)

§  Membrane Lipids:

Ø  Sphingomyelin

Ø  Glycosphingolipids:

o  Cerebrosides (add sugar to ceremide)

o  Sulfatides

o  Globosides

o  Gangliosides (add polysaccharide + N-acetylnueramic acid to ceramide)

-  Niemann-Pick Disease:

o  General:

§  Type I (A and B):

Ø  Cause: deficiency of sphingomyelinase enzyme, leading to progressive accumulation of sphingomyelin (ubiquitous component of cellular organellar membranes)

§  Type II (C and D):

Ø  Cause: defect in cholesol esterification causing lysosomal accumulation of unesterified cholesterol

o  Type I:

§  Type A (Severe Infantile):

Ø  Most common of type I: 70-80% of all cases (often in Eastern European Jews)

Ø  Presentation: within the first weeks of life (death occurs by age 3 or 4)

o  Severe neurologic impairment (hypotonia, progressive psychomotor retardation)

o  Failure to thrive

o  Hepatosplenomegaly (marked)

o  Macular cherry red spot (50% of patients)

o  Accumulation of foamy lipid macrophages in many tissues (liver, lung, spleen, LNs, kidneys, bone marrow, peripheral and central neurons)

o  Atrophy of the brain

§  Type B (Chronic Visceral):

Ø  Less common than Type A: also often seen in Eastern European Jews

Ø  Presentation: infancy or childhood (typically survive into adulthood)

o  Organomegaly (often present with splenomegaly and then develop generalized visceral involvement)

o  Generally NO CNS involvement

o  Type II:

§  Type C:

Ø  Most common: more common than A and B combined

Ø  Cause: defect in NPC-1 (95%) or NPC-2 gene that encodes for a protein involved in cellular trafficking of exogenous cholesterol (normally brings free cholesterol from the lysosome to the cytoplasm)

Ø  Clinical Features: variable

o  Classic Phenotype (Neurovisceral): presents in childhood (2-4 years) with death typically occurring between 5-15 years of age

§  Variable hepatosplenomegaly

§  Vertical supranuclear opthamoplegia (supranuclear palsy)

§  Progressive ataxia

§  Seizures

§  Psychomotor regression (accumulation of cholesterol in neurons is lethal to those cells)

§  Bone marrow contains Niemann-pick cells (foamy) and sea blue histiocytes

o  May present at birth with hydrops fetalis and still birth

o  Fatal neonatal liver disease (giant cell hepatitis)

o  If live into adulthood, may present with dementia and psychosis

§  Type D:

Ø  Rare variant of type C: found in Nova Scotia (less severely affected)

-  Gangliosidoses:

o  GM1 Gangliosidoses:

§  Deficiency: deficiency in β-galactosidase enzyme that results in accumulation of ganglioside in neurons (clinical variability depends on amount of residual enzyme activity)

Ø  Β-Galactosidase Enzyme: 3 isoenzymes (A,B,C)

o  Transcription of this enzyme requires an activator that may cause similar features if deficient

§  Type I (Generalized/Infantile):

Ø  Deficiency: virtual absence of all 3 isoenzymes of B-galactosidase

Ø  Onset: birth to 6 months (death often before age 2)

Ø  Clinical Features:

o  Progressive neurologic deterioration (seizures)

o  Coarse facial features

o  Hepatosplenomegaly (accumulation of gangliosides in liver, spleen, renal tubular epithelium)

o  Macular cherry red spots (50% of patients)

o  Skeletal deformities (dystosis multiplex)

o  Has features of both neurolipidoses and MPS, leading to a “pseudo-Hurler phenotype”

§  Type II (Juvenille):

Ø  Deficiency: absence of A and B isoenzymes only

Ø  Onset: juvenile (1-2 years old) with death occurring by age 3-10

Ø  Clinical Features:

o  Slower psychomotor retardation

o  Less visceromegaly

o  Milder skeletal disease

§  Diagnosis:

Ø  Measurement of B-galactosidase activity in peripheral blood leukocytes:

o  Type I: virtually no activity

o  Type II: 5-10% activity

Ø  Peripheral Blood Smear: vacuolization of lymphocytes (crude method due to the fact that many LSDs have this feature)

o  GM2 Gangliosidoses:

§  Cause: inability to catabolize GM2 ganglioside (required 3 polypeptides encoded by 3 separate loci)

Ø  Tay Sachs Disease: defect in α subunit of Heaminidase A

Ø  Sandhoff’s Disease: defect in β subunit of Hexaminidase A

Ø  GM2 Activator Deficiency Gangliosidosis: defect in GM2 activator

§  Clinical Features: similar because they all result in GM accumulation

Ø  GM2 accumulates in many tissues, but CNS and retina are the dominant features of the disease

o  Neurons are swollen and contain cytoplasmic vacuoles

o  Lysosomes contain whorled material by EM

o  Brain first enlarges, and then becomes atrophic

Ø  Infants appear normal at birth, followed by rapidly progressive neurodegenerative disease with seizures, dementia and blindness

o  Loss of motor skills at 3-6 months

o  Death by 2-4 years of age

Ø  Macular cherry red spot

§  Ethnic Risk: 1/30 carrier rate in the Askenazi Jewish population

-  Sulfatidoses:

o  Metachromatic Leukodystrophy:

§  Cause: deficiency of arylsulfatase A enzyme, leading to the accumulation of non-degradeable galactocerebroside sulfate in the white matter of the brain, peripheral nerves, liver and kidney

Ø  Results in breakdown of myelin sheath (demyelination and gliosis)

Ø  As a result, predominantly a neurodegenerative disorder

Ø  Arylsulfatase A also requires presence of saposin B (solubilizes hydrophobic lipid to allow it to be accessible to the enzyme) and therefore, absence of SAP will cause similar disease

§  3 Forms:

Ø  Late Infantile: most common (diagnosed by age 2; death before age 5)

o  Regression of motor skills (hypotonia, muscle weakness)

o  Mental deterioration (loss of milestones)

o  Rigidity and convulsions

o  Unusual loss of white matter on CNS imaging

Ø  Juvenile: diagnosed between 3-16 years of age; death 6-8 years after diagnosis

o  Changes in gait and cognitive skills

o  Progressive regression of all skills

Ø  Adult Onset: diagnosed after 16 years of age

o  Psychiatric or cognitive symptoms occur first

o  Motor symptoms (neurologic) appear later

§  Diagnosis:

Ø  Urine: spot screening test (shows metachromasia due to presence of sulfatide)

Ø  Imaging: usual loss of white matter due to demyelination

Ø  Biopsy: usually of a sural nerve (demyelination, metachromatic granules and unusual cytoplasmic inclusions)

o  Stains: PAS +, Alcian blue, acidified Cresyl violet

Ø  Arylsulfatase A activity levels

Ø  Genetic testing: gene located on long arm of cs 22

o  Multiple Sulfatase Deficiency:

§  Cause: reduction in activities of several sulfatidases (arylsulfatidase A,B,C) resulting in the accumulation of sulfatides, sulfated GAGs, sphingolipids and steroid sulfates

§  Clinical Presentation: combines clinical features of metachromatic leukodystrophy and MPS

-  Cerebrosidoses:

o  Gaucher Disease: most common lysosomal storage disease*

§  Defect: glucocerebrosidase enzyme (results in accumulation of glucocerebrosides and other glycolipids)

Ø  Glucocerebrosides: derived from breakdown of the membranes of senescent leukocytes and RBCs

Ø  Accumulation: incompletely metabolized substrate stored in monocytes and macrophages (stains positively with PAS)

o  Gaucher Cell: crumpled paper appearance to cytoplasm with eccentrically displaced nucleus

§  Type 1 (Chronic Non-Neuronopathic Form):

Ø  Cause: reduced levels of glucocerebrosidase

Ø  Most common type: 99% of cases

Ø  Population affected: children and adults (common in Ashkenazi Jews)

Ø  Clinical features: accumulation of glucocerebrosidase limited to mononuclear phagocytes throughout the body, WITHOUT brain involvement