Genetic Conditions and Inheritance: Difference between revisions

Introduction[edit | edit source]

Genetic conditions are diseases or disabilities that are caused by inherited or aquired abnormalities in the sequencing of the genome. They can be caused by mutations of the desoxyribonucleic acid (DNA) of single or multiple genes up to full chromosomal changes.^[1] Genetic conditions that are caused by the modification of one single gene are called monogenic diseases.^[2] The WHO estimates that there are around 10,000 human monogenic diseases which affect millions of people worldwide.

Heredity or genetic inheritance is the process of passing off trades or characteristics from parents to their offspring, also referred to as the study of genetics.^[3] Traits get inherited through genes. These are sections of the DNA molecule which hold all information needed to for an organism to build new cells.

History[edit | edit source]

Gregor Mendel (1822-1884) was a scientist and monk from the Austrian Empire (today's Czech Republic) and is referred to as "the founder of the science of modern genetics".^[4] His scientific experiments, which he conducted during his life in the monastery using pea plants, led him to construct the theory of inheritance of trades. Mendel was the first person to identify and prove the correct hypothesis of genetic inheritance of characteristics through "recessive" and "dominant" trades, which are both terms that he coined. He published his findings in 1865 but only gained posthumous recognition for the relevance of his work.

Genetic inheritance / Heredity[edit | edit source]

This chapter will capture the basics about inheritance. For a great visualisation about this topic see the YouTube video by the Crash Course brothers below.

Definitions[edit | edit source]

Traits[edit | edit source]

Traits - or characteristics - are observable details of an organism, e.g. in humans: one's eye colour, the shape of one's finger nails, ...

• Mendelian trait: A characteristic or trait that is determined by one gene only.^[5] This means that a specific characteristic's information is found on only one of the 23 chromosome pairs that a human DNA. Therefore, the information about this particular characteristic is linked to one specific location within the DNA. The typical example is the colour of pea plant flowers, which was the trait that Mendel examined in his experiments.
• Poligenic trait: A characteristic or trait that is a composition of information from different genes, ergo not tied to one single location within the DNA. Most traits, since they are quite elaborate, are poligenic traits.
• Pleiotropic: A gene that influences how other genes are interpreted.

To best comprehend the pathway of genetic inheritance most commonly examples of Mendelian traits are used, since the observed trait is determined by one single gene.

Chromosomes[edit | edit source]

Chromosomes are the strings made of the DNA. In the human body they come in pairs. Humans have 23 pairs of chromosomes, each pair containing one set of genetic information from the mother and one from the father. Every cell in the human body holds 23 chromosome pairs, except for reproductive cells which only contain 23 single chromosome strings.^[5]

Genes[edit | edit source]

Genes are the "basic physical unit of inheritance"^[6] and are made of sequences within the DNA. They hold information about any type of process needed to grow, maintain and renew an organism's traits. The 23 chromosome pairs of humans hold around 20,000 genes.

Alleles[edit | edit source]

Humans have two sets of each genes, one in each of the chromosomes.^[2] A pair of genes is called an allele. These genes do not necessarily need to be the same since one of them is inherited from the mother and the other one from the father.

Genotype[edit | edit source]

The genotype is the composition of the two parentally inherited alleles. ^[3]

• Heterozygous: Genotype has two alleles that are different.
• Homozygous: Genotype has two alleles that are alike.

Phenotype[edit | edit source]

The phenotype is defined as "the set of characteristics of a living thing, resulting from its combination of genes and the effect of its environment"^[7] hence the 'final result' of the composition of parentally inherited and environmentally acquired information.

Genetic inheritance pathways[edit | edit source]

Genetic abnormalities can be inherited through different pathways, depending on the location and type of the affected gene. The three types of inheritance for monogenic (single-gene) diseases are^[2]:

• Dominant

• Recessive
• X-linked

The Punnet Square[edit | edit source]

The Punnet Square can be used to determine the possible outcomes of traits being transferred from the parents to the offspring.

Diagnosis[edit | edit source]

Newborn genetic screening is a standard procedure for most babies which is conducted right after birth in many countries.^[8] It helps to identify genetic disorders at an early stage so that prevention and treatment methods can set in from the very beginning.

Clinical relevance[edit | edit source]

Most common disorders[edit | edit source]

Monogenic diseases:

• Haemophilia
• Von Willebrand Disease (specific form of haemophilia)
• Thalassaemia
• Sickle Cell Anaemia
• Cystic fibrosis
• Tay Sachs disease
• Huntington's disease

Poligenic diseases:

Others:

• Down Syndrome/ Trisomy 21 (caused by an extra chromosome on the 21st chromosome pair)
• Edward's Syndrome/ Trisomy 18 (caused by an extra chromosome on the 18th chromosome pair)

Disorders relevant for physiotherapy practice[edit | edit source]

• Osteogenesis Imperfecta (brittle bone disease)

Treatment[edit | edit source]

Experimental genometherapy[edit | edit source]

Physiotherapy[edit | edit source]

References[edit | edit source]