The mutant gene present in the homozygous state leads to the expression of the trait. Autosomal recessive inheritance, therefore, requires the mutant allele in a double dose. A heterozygous individual becomes a carrier for passing on the trait to the next generation. Consider a mating between two heterozygous individuals. Each of them carries a mutant gene. Hence, the offspring inherits the disorder since he or she receives both the mutant alleles.

Glycosaminoglycans do not get degraded. Instead, get accumulated and lead to various complications.

Sticky mucus formation leading to the blockage of the airways.

The excessive pile-up of phenylalanine in the blood, and excretion of phenylpyruvic acid in the urine. Leads to intellectual, developmental, and behavioral problems.

The review article mainly includes four examples of autosomal recessive disorders in detail.

This metabolic disorder leads to serious health conditions including intellectual and developmental problems. The individuals with PKU have a typical body odor resembling that of a mouse. The skin of these individuals is lighter than normal. They have itchy skin accompanied by eczema. There exist variants of PKU. Mild, severe, variant PKU and non-PKU hyperphenylalaninemia forms of PKU commonly occur depending upon the extent of enzyme deficiency. The severe form of PKU, known as classic PKU, permanently affects the intelligence of a person. The permanent intellectual disability gets accompanied by seizures and other developmental problems. Infants suffer from microcephaly (small head), low birth weight, heart defects, epilepsy, arthritis, intellectual disability, and behavioral problems. Individuals with PKU get advised to completely avoid the intake of foodstuffs rich in phenylalanine amino acid.

About 1 in 10,000 individuals suffer from this inborn error of metabolism. Phenylketonuria involves a complete pile-up of an amino acid known as phenylalanine. It is an essential amino acid. It is usually considered as a precursor of another amino acid known as tyrosine. The blood samples of the individuals suffering from PKU show the elevated levels of phenylalanine. This disorder has a background of both genetic and biochemical imbalance. Meaning, the gene responsible for synthesizing an enzyme gets mutated, leading to the deficiency of the enzyme. Hence, the enzyme deficiency leads to an increase in the level of an intermediate compound. In the case of PKU, the intermediate compound is phenylalanine. The enzyme known as phenylalanine hydroxylase becomes deficient. This enzyme mainly helps in the conversion of phenylalanine to tyrosine. However, the deficiency of this enzyme leads to an unconverted phenylalanine which gets accumulated in the blood stream. Also, the accumulated phenylalanine gets converted into phenylpyruvic acid and gets excreted through urine. Hence, the urine samples of the individuals suffering from phenylketonuria show the presence of phenylpyruvic acid through a biochemical test known as the ferric chloride test.

Image: Phenylalanine pathway and disorders associated with the same

PKU or phenylketonuria is an autosomal recessive disorder, requiring two recessive alleles for manifestation. Most of the times, the affected individual receives two mutated genes from both the parents. Both the father and the mother contribute mutated genes to the offspring.

An important pigment in the skin known as melanin helps in maintaining the skin and hair coloration. However, a deficiency of this pigment melanin leads to a disorder known as albinism. The individuals suffering from this condition show complete whitish pigmentation of the skin. The hair, eyebrows, eyelids, and the overall skin coloration looks whitish. You might know about albino mice. These mice have a white color coat. Similarly, in humans, the skin coloration looks whitish due to the improper synthesis of a pigment known as melanin. This condition leads to sensitivity to sunlight. Hence, these individuals get advised to reduce sun exposure. They also have a very high risk of developing cancer. There is no cure for this condition.

There exist three main types of albinism in humans such as oculocutaneous albinism, oculocutaneous albinism type-1, and oculocutaneous albinism type-2. Oculocutaneos albinism affects the skin as well as the eyes and the hair of the individuals. The affected individual shows a deficiency of pigment melanin in the eyes, skin, hair, eyelids, eyebrows, iris, and the ocular fundus. They have a very poor vision and their eyes appear bluish to brown color. Sometimes they look reddish in the dim light or darkness. They also suffer from an uncontrolled pendular eye movement known as nystagmus. A series of steps lead to the production of the pigment melanin. Phenylalanine amino acid gets converted into tyrosine. This tyrosine further gets converted into DOPA. The conversion of DOPA to melanin requires a key enzyme known as tyrosinase. This enzyme helps in the production of adequate melanin from the DOPA. However, this enzyme deficiency leads to less production of melanin. Mainly the gene responsible for the synthesis of enzyme tyrosinase gets mutated.

The gene responsible for the synthesis of enzyme tyrosinase is present on the 11chromosome. Albinism is an autosomal recessive disorder as it requires two mutated alleles. Both the parents contribute one mutated allele to the child. Hence, the child has two mutated alleles. This is the situation associated with oculocutaneous albinism type I. However, it is not autosomal recessive but X-linked disorder. In another type of albinism known as oculocutaneous albinism type-II, the gene present on the 15chromosome gets mutated. It follows autosomal recessive mutation.

A monosaccharide known as galactose is a sugar or a carbohydrate that helps in supplying energy to the cells. However, in a condition known as galactosemia, this sugar does not get utilized by the body for synthesizing energy. So, an excess of galactose gets accumulated and excreted through urine. Hence, individuals show high levels of this sugar. People suffering from this condition get advised to avoid galactose and lactose-rich foods. Why lactose? The sugar, known as lactose gets converted into galactose. The severe form of galactosemia, known as classic galactosemia affects the feeding ability of the infant, diminishes the energy, and affects the growth and the development of the infant. It occurs due to the deficiency of an enzyme known as galactose-1-phosphate uridyl transferase. Increased galactose levels give a nausea sensation, sometimes accompanied by vomiting, and jaundice. Untreated individuals get affected with cataracts, liver cirrhosis, and complete mental retardation. It affects 1 in 30, 000 individuals or 1 in 60,000 individuals. Early diagnosis and treatment help to control the condition.

Three gene mutations have been reported to date. These include GALT, GALK1, and GALE gene mutations and show autosomal recessive inheritance. These genes encode the enzyme known as galactose-1-phosphate uridyl transferase. However, the mutations in one or all of the above genes lead to the deficiency of the enzyme.

It involves a deficiency of an enzyme known as Alpha-L-iduronidase. It is a lysosomal enzyme. It plays an important role in the degradation of complex macromolecules such as glycosaminoglycans or the sulfated polysaccharides.

The syndrome affects 1 in 2,00,000 individuals in Europe.

The affected infants show a typical corneal clouding, retarded growth, and an affected lower spine.

Later on, they also develop hepatosplenomegaly, coarse facial features, hearing loss, joint stiffness, and other problems. They die mostly in the teenage. Individuals suffering from Hurler’s syndrome excrete dermatan and heparan sulfate in the urine. Bone marrow transplantation may be recommended in some of the cases.

Genetics: