Hyperkalemic periodic paralysis

Hyperkalemic periodic paralysis
Classification and external resources
Specialty neurology
ICD-10 G72.3
ICD-9-CM 359.3
OMIM 170500
DiseasesDB 6252
MedlinePlus 000316
eMedicine article/1171678
MeSH D020513
GeneReviews

Hyperkalemic periodic paralysis (HYPP, HyperKPP) is a genetic disorder. It occurs in humans, horses (where it is also known as Impressive syndrome, after an index case in a horse named Impressive, or possibly one of his ancestors), and perhaps other animals. It is an inherited autosomal dominant disorder that affects sodium channels in muscle cells and the ability to regulate potassium levels in the blood. It is most commonly associated with horses, but occurs in humans, where it may be called Gamstorp episodic adynamy. It is characterized by muscle hyperexcitability or weakness which, exacerbated by potassium, heat or cold, can lead to uncontrolled shaking followed by paralysis. Onset in humans usually occurs in early childhood, but still occurs with adults.

The mutation which causes this disorder is dominant on SCN4A with linkage to the sodium channel expressed in muscle. The mutation causes single amino acid changes in parts of the channel which are important for inactivation. In the presence of high potassium levels, including those induced by diet, sodium channels fail to inactivate properly.

Equine hyperkalemic periodic paralysis occurs in 1 in 50 Quarter Horses and can be traced to a single ancestor, a stallion named Impressive.

Disease in equines

Symptoms and presentation

This inherited disease is characterized by violent muscle twitching and substantial muscle weakness or paralysis among affected horses. HYPP is a dominant genetic disorder; therefore, heterozygotes bred to genotypically normal horses have a statistic probability of producing clinically affected offspring 50% of the time.

Horses with HYPP can be treated with some possibility of reducing clinical signs, but the degree that medical treatment helps varies from horse to horse. There is no cure. Horses with HYPP often lose muscle control during an attack.

Some horses are more affected by the disease than others and some attacks will be more severe than others, even in the same horse. Symptoms of an HYPP attack may include:

HYPP attacks occur randomly and can strike a horse standing calmly in a stable just as easily as during exercise. Following an HYPP attack, the horse appears normal and is not in any pain which helps to distinguish it from Equine Exertional Rhabdomyolysis (ER), commonly known as "Azoturia," "Monday Morning Sickness" or "tying up." Horses that are tying up usually suffer attacks in connection with exercise and may take anywhere from 12 hours to several days to recover. Muscle tissue is damaged in an attack of ER, and the horse will be in pain during and following an attack. A blood test will reveal elevations in certain muscle enzymes after an episode of ER and so the two diseases, while superficially similar, are easily distinguished from one another in the laboratory.

Unlike with seizures, horses with HYPP are fully conscious and lucid during an attack. Horses may suffocate during an HYPP attack due to paralysis of the respiratory system. Horses that collapse during an episode are clearly distressed as they repeatedly struggle to get to their feet. If this occurs while the horse is being ridden or otherwise handled, the human handler or rider may be at risk of being injured by the movement of the horse.

Genetics

In 1994, researchers at the University of Pittsburgh, with a grant from horse organizations, isolated the genetic mutation responsible for the problem and developed a blood test for it. Using this test, horses may be identified as:

In the case of the horse Impressive, the muscles were always contracting which was equivalent to a constant work-out. Thus the development of an impressive musculature.

Inheritance and prevalence

The disease is linked to the bloodline of the famous American Quarter Horse stallion Impressive, who has over 55,000 living descendants as of 2003. Although the disease is primarily limited to the American Quarter Horse and closely related breeds such as American Paint Horses and Appaloosas at this time, cross-breeding has begun to extend it to crossbreds recognized by other breed registries as well as grade horses. Until the AQHA restricted the registration of animals with the condition, the spread of the disease was perpetuated by the favorable placings given to affected horses in halter competition at horse shows, because a secondary characteristic associated with N/H and H/H horses is heavy, bulky muscling that is favored by stock horse judges, a trend that began with Impressive and predates the modern understanding of the disease. Some stock horse breeds with Quarter Horse bloodlines have yet to restrict registration in order to limit the perpetuation of HYPP.

Regulation

Some horse organizations have instituted rules to attempt to eliminate this widespread disease. The American Quarter Horse Association (AQHA) mandates testing for foals descended from Impressive if both of the foal's parents were not homozygous negative (N/N) for the gene,[1] and, since 2007, has not registered foals homozygous (H/H) for the gene.[2] Since 2007, the Appaloosa Horse Club (ApHC) has required foals descended from Impressive to be tested, so that the results may be recorded on its certificate.[3] The American Paint Horse Association (APHA) mandated that, after 2017, stallions must be tested for HYPP so that mare owners may make an informed decision before choosing a stallion for breeding to their mare.[4]

Disease in humans

Although much less publicized, hyperkalemic periodic paralysis has been observed in humans. In humans the disorder causes episodes of extreme muscle weakness, with attacks often beginning in infancy. Depending on the type and severity of the HyperKPP, it can increase or stabilize until the fourth or fifth decade where attacks may cease, decline, or, depending on the type, continue on into old age. Factors that can trigger attacks include rest after exercise, potassium-rich foods, stress, fatigue, weather changes, certain pollutants (e.g., cigarette smoke) and fasting. Muscle strength often improves between attacks, although many affected people may have increasing bouts of muscle weakness as the disorder progresses (abortive attacks). Sometimes with HyperKPP those affected may experience degrees of muscle stiffness and spasms (myotonia) in the affected muscles. This can be caused by the same things that trigger the paralysis, dependent on the type of myotonia.

Some people with hyperkalemic periodic paralysis have increased levels of potassium in their blood (hyperkalemia) during attacks. In other cases, attacks are associated with normal blood potassium levels (normokalemia). Ingesting potassium can trigger attacks in affected individuals, even if blood potassium levels do not rise in response.

In contrast to HyperKPP, hypokalemic periodic paralysis (noted in humans) refers to loss-of-function mutations in channels that prevent muscle depolarisation and therefore are aggravated by low potassium ion concentrations.

Genetics

In humans, the most common underlying genetic cause is one of several possible point mutations in the gene SCN4A.[5] This gene codes for a voltage-gated sodium channel Nav1.4 found at the neuromuscular junction. This condition is inherited in an autosomal dominant pattern, which means one copy of the altered gene in each cell is sufficient to cause it.

Action potentials from the central nervous system cause end-plate potentials at the NMJ which causes sodium ions to enter by Nav1.4 and depolarise the muscle cells. This depolarisation triggers the entry of calcium from the sarcoplasmic reticulum to cause contraction (tensing) of the muscle. To prevent the muscle from being perpetually contracted, the channel contains a fast inactivation gate that plugs the sodium pore very quickly after it opens. This prevents further entry of sodium. In time, potassium ions will leave the muscle cells, repolarising the cells and causing the pumping of calcium away from the contractile apparatus to relax the muscle.

Mutations altering the usual structure and function of this sodium channel therefore disrupt regulation of muscle contraction, leading to episodes of severe muscle weakness or paralysis. Mutations have been identified in residues between transmembrane domains III and IV which make up the fast inactivation gate of Nav1.4. Mutations have been found on the cytoplasmic loops between the S4 and S5 helices of domains II, III and IV, which are the binding sites of the inactivation gate.[6][7]

In patients with mutations in SCN4A, therefore, the channel is unable to inactivate, sodium conductance is sustained and the muscle remains permanently tense. Since the motor end plate is depolarised, further signals to contract have no effect (paralysis). The condition is hyperkalemic because a high extracellular potassium ion concentration will make it even more unfavourable for potassium to leave the cell to repolarise it to the resting potential. This further prolongs the sodium conductance and keeps the muscle contracted. Hence, the severity would be reduced if extracellular (serum) potassium ion concentrations are kept low.[8][9]

Treatment

See also

References

  1. Khatib, Hasan, ed. (2014). "Dominant disorders". Animal Genetics. Blackwell Publications. p. 112. ISBN 978-1-118-67740-7.
  2. Lynghaug, Fran (2009). "American Quarter Horse". The official horse breeds standards book: The complete guide to the standards of all North American equine breed associations. Minneapolis: Voyageur Press. pp. 24–31. ISBN 9781616731717.
  3. Toribio, RE (2015). "Chapter 29: Electrolyte abnormalities and neurologic dysfunction in horses". In Furr, Martin; Reed, Stephen. Equine Neurology (2nd ed.). John Wiley & Sons. p. 376. ISBN 9781118501566.
  4. "Paint registry to require genetic testing" (464). Equus. 24 May 2016. Retrieved 2017-06-13.
  5. Online Mendelian Inheritance in Man (OMIM) Hyperkalemic Periodic Paralysis; HYPP -17050
  6. Rojas CV, Wang JZ, Schwartz LS, Hoffman EP, Powell BR, Brown RH (December 1991). "A Met-to-Val mutation in the skeletal muscle Na+ channel alpha-subunit in hyperkalaemic periodic paralysis". Nature. 354 (6352): 387–9. PMID 1659668. doi:10.1038/354387a0.
  7. Bendahhou S, Cummins TR, Kula RW, Fu YH, Ptácek LJ (April 2002). "Impairment of slow inactivation as a common mechanism for periodic paralysis in DIIS4-S5". Neurology. 58 (8): 1266–72. PMID 11971097. doi:10.1212/wnl.58.8.1266.
  8. Rüdel R, Lehmann-Horn F, Ricker K, Küther G (February 1984). "Hypokalemic periodic paralysis: in vitro investigation of muscle fiber membrane parameters". Muscle Nerve. 7 (2): 110–20. PMID 6325904. doi:10.1002/mus.880070205.
  9. Jurkat-Rott K, Lehmann-Horn F (August 2005). "Muscle channelopathies and critical points in functional and genetic studies". J. Clin. Invest. 115 (8): 2000–9. PMC 1180551Freely accessible. PMID 16075040. doi:10.1172/JCI25525.
  10. 1 2 3 4 5 6 MedlinePlus: Hyperkalemic periodic paralysis Update Date: 7/25/2006. Updated by: David M. Charytan, M.D., M.Sc., Department of Medicine, Division of Nephrology, Brigham and Women's Hospital, Boston, MA.
  11. Lee, GM; Kim, JB (June 2011). "Hyperkalemic periodic paralysis and paramyotonia congenita caused by a de novo mutation in the SCN4A gene". Neurology Asia. 16 (2): 163–6.
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