Kogi State University Pathophysiology of Diseases Discussion
Kogi State University Pathophysiology of Diseases Discussion
“The main terms used in this course like what is mean Pathophysiology and What is a disease in your own words?
Introduction
- Diseases as manifestations of disordered functions
- Proper knowledge of body’s normal structure and function (and how they can become disordered) gives us ability to design rational and effective treatment
- Although phenotypes of genetic diseases are diverse, their causes are not
- Primary cause of any genetic disease is a change in the sequence or cellular content of DNA that ultimately deranges gene expression.
- Most genetic diseases are caused by an alteration in DNA sequence that alters the synthesis of a single gene product.
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Genetic Disease Terminology
- Gamete: egg or sperm cell that represents a potential reproductive contribution to the next generation
- Mosaicism: situation in which a genetic alteration is present in some but not all of the cells of a single individual
- Gene: short stretch of DNA responsible for a measurable trait
- Locus: the place where a particular gene lies on its chromosome
- Alleles: variant sequences of DNA
- Mutation: biochemical event such as a nucleotide change, deletion, or insertion that has produced a new allele
- Homozygous: having two alleles at the same locus that are the same
- Heterozygous: having two alleles at the same locus that are different
- Phenotype: any characteristic that can be measured
Penetrance & Expressivity
- Two individuals with same mutated gene may have different phenotypes
- Penetrance refers to whether or not the variant genotype can be inferred based on defined phenotypic criteria
- Penetrance may vary with age and according to the set of criteria being used
- Same mutated gene can give rise to different spectrum of phenotypes, called variable expressivity
- Type 1 osteogenesis results in short stature for one sibling and confinement to wheelchair for another
- Both have penetrance of the mutation, but the expression is variable
Mechanisms of Mutation & Inheritance Patterns
- Mutations can be characterized by their molecular nature and effects on gene activity
- Dominant inheritance: disease state or trait is apparent when one copy each of the mutated allele and the normal allele are present
- Recessive inheritance: two copies of the mutated allele must be present for the disease state or trait to be apparent
- Hemizygosity: the presence of one allele at a locus because the other allele is deleted or because it is normally not present (eg, X-linked genes in males)
Recessive Inheritance & Loss-of-Function Mutations
Two general principles when considering loss-of-function mutations:
- Expression from the non-mutant allele usually does not change, gene expression in a heterozygous carrier of a loss-of-function allele is reduced to 50% of normal
- For most biochemical pathways, a 50% reduction in enzyme concentration is not sufficient to produce a disease state
- Most diseases resulting from enzyme deficiencies (such as phenylketonuria) are inherited in a recessive fashion
Dominant Inheritance & Loss-of-function Mutations
- Most dominantly inherited phenotypes are actually semidominant, meaning an individual that carries two copies of the mutant allele is affected more severely than someone who carries one mutant and one normal allele
- Two general principles to keep in mind when considering loss-of-function mutations
- First, because expression from the nonmutant allele usually does not change (i.e., there is no dosage compensation), gene expression in a heterozygous carrier of a loss-of-function allele is reduced to 50% of normal.
- Second, for most biochemical pathways, a 50% reduction in enzyme concentration is not sufficient to produce a disease state.