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Bending Over Backwards: Vitamin Deficiency’s Surprising Role in Double-Jointedness and EDS

Tulane University researchers have found a possible genetic cause for hypermobility and associated connective tissue disorders such as Ehlers-Danlos syndrome (EDS). The study, published in the journal Heliyon, links hypermobility to a deficiency of folate caused by a variation of the MTHFR gene. This deficiency may prevent proteins from binding collagen to the extracellular matrix, resulting in more elastic connective tissue, hypermobility, and related conditions. The discovery could help doctors more accurately diagnose hypermobility and hypermobile EDS using blood tests for elevated folate levels and the MTHFR genetic variant. An existing FDA-approved treatment, methylated folate, has shown promise in improving patients’ symptoms.

Scientists have linked hypermobility and related disorders to a folate deficiency caused by a genetic variation, offering new diagnostic methods and treatment possibilities with methylated folate.

Tulane University researchers have discovered a possible genetic cause for hypermobility (commonly known as double-jointedness) and a range of associated connective tissue disorders such as Ehlers-Danlos syndrome, according to preliminary findings published on April 8, 2023, in the journal Heliyon.

You may know someone with overly flexible joints, a friend or family member who can easily slide into a split or bend limbs to impossible angles. But hypermobility is a more serious condition than being “double-jointed.”

For those with hypermobile Ehlers-Danlos syndrome (EDS), the same conditions that create fragile connective tissue can cause a range of symptoms that, on the surface, can seem unrelated: physical conditions such as joint pain, chronic fatigue, thin tooth enamel, dizziness, digestive trouble, and migraines; and psychiatric disorders, such as anxiety and depression. Women with hypermobile EDS may also be at increased risk for endometriosis or uterine fibroids.

For years, researchers have struggled to find the cause of hypermobility and hypermobile EDS. Of the 13 subtypes of EDS, hypermobile EDS comprises more than 90% of the cases. But until this study, hypermobile EDS was the only subtype without a known genetic correlate. As a result, symptoms have often been treated individually rather than as the result of a single cause.

Researchers at Tulane University School of Medicine have linked hypermobility to a deficiency of folate – the natural form of vitamin B9 – caused by a variation of the MTHFR gene.

Tulane University researcher Dr. Jacques Courseault (left) tests a patient for hypermobility. Courseault is part of a team of researchers that have discovered a possible genetic cause for hypermobility and hypermobile Ehlers-Danlos syndrome. This discovery may for the first time allow for diagnosis and treatment. Credit: Photo by Rusty Costanza

“You’ve got millions of people that likely have this, and until now, there’s been no known cause we’ve known to treat,” said Dr. Gregory Bix, director of the Tulane University Clinical Neuroscience Research Center. “It’s a big deal.”

Those with this genetic variant can’t metabolize folate, which causes unmetabolized folate to accumulate in the bloodstream. The folate deficiency may prevent key proteins from binding collagen to the extracellular matrix. This results in more elastic connective tissue, hypermobility, and a potential cascade of associated conditions.

The discovery could help doctors diagnose hypermobility and hypermobile EDS more accurately by looking for elevated folate levels in blood tests and the MTHFR genetic variant.

“Hypermobility is widespread and unfortunately under-recognized,” said Dr. Jacques Courseault, medical director of the Tulane Fascia Institute and Treatment Center. “I’m excited about being able to treat the masses where people aren’t going their whole lives being frustrated and not getting the treatment they need.”

Previously, hypermobility could only be diagnosed by the Beighton score, a somewhat controversial physical exam that involves measuring the bend of the spine, fingers, and limbs. Combined with a historic lack of acceptance of hypermobility as a distinct body type that requires specialized treatment, the number of people with hypermobility is unclear. However, it could comprise more than half the world’s population.

“Hypermobility is not rare,” Courseault said. “Hypermobility is like a Ferrari that requires a lot of maintenance and the best synthetic oil. After knowing a patient’s name and date of birth, I think it’s prudent for clinicians to know which of these body types they have.”

Doctors discovered the connection between folate deficiency and the MTHFR gene by working with patients at Tulane’s Hypermobility and Ehlers-Danlos Clinic, the only clinic in the U.S. focusing on fascia disorders. Blood tests of hypermobile patients who showed signs of associated medical conditions revealed elevated levels of unmetabolized folate. Subsequent tests showed that most of those with elevated folate serum levels had the genetic polymorphism.

The good news is a treatment already exists. Methylated folate – folate that is already processed – is FDA-approved and widely available.

“It’s an innocuous treatment,” Bix said. “It’s not dangerous, and it’s a vitamin that can improve people’s lives. That’s the biggest thing: We know what’s going on here, and we can treat it.”

Though Courseault said more lab research and clinical testing needs to be done, patients who have been treated with folate have shown improvement: less pain, less brain fog, fewer allergies, and improved gastrointestinal function.

“We’ve discovered something in medicine that can help, not a small group of people, but potentially many across the world,” Courseault said. “This is real, it’s been vetted out well and clinically we’re noticing a difference.”

Reference: “Folate-dependent hypermobility syndrome: A proposed mechanism and diagnosis” by Jacques Courseault, Catherine Kingry, Vivianne Morrison, Christiania Edstrom, Kelli Morrell, Lisa Jaubert, Victoria Elia and Gregory Bix, 8 April 2023, Heliyon.
DOI: 10.1016/j.heliyon.2023.e15387

Source: SciTechDaily