The puzzling question - 'Why does interfering with a process that happens everywhere affect motor neurons first?' - has lurked behind spinal muscular atrophy.
Spinal muscular atrophy (SMA) is the leading genetic cause of death in infants. The disorder leads to reduced levels of the SMN protein, which is thought to be involved in processing RNA, something that occurs in every cell in the body. So why does interfering with a process that happens everywhere affect motor neurons first? This puzzling question has lurked behind SMA.
‘A detailed picture for what researchers think the SMN protein is doing, and how its deficiency causes problems in spinal muscular atrophy (SMA) patients' cells is now available.’
Scientists at Emory University School of Medicine have been building
a case for an answer. It's because motor neurons have long axons. And
RNA must be transported to the end of the axons for motor neurons to
survive and keep us moving, eating and breathing.
Now the Emory researchers have a detailed picture for what they think the SMN protein is doing, and how its deficiency causes problems in SMA patients' cells. The findings are published in Cell Reports.
"Our model explains the specificity - why motor neurons are so vulnerable to reductions in SMN," says Wilfried Rossoll, assistant professor of cell biology at Emory University School of Medicine. "What's new is that we have a mechanism."
Rossoll and his colleagues showed that the SMN protein is acting like a "matchmaker" for messenger RNA that needs partners to transport it into the cell axon.
RNA carries messages from DNA, huddled in the nucleus, to the rest of the cell so that proteins can be produced locally. But RNA can't do that on its own, Rossoll says.
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"It loads the truck, but it's not on the truck," Rossoll says.
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The first author of the paper is Paul Donlin-Asp, a former Biochemistry, Cell and Developmental Biology graduate student, now at the Max Planck Institute in Frankfurt,. Co-senior author is Gary Bassell, chair of the Department of Cell biology at Emory University School of Medicine.
Scientists have known for 20 years that SMN is necessary in every cell of the body, since disrupting the gene in a mouse causes early embryonic death, before muscle or nerve cells form.
However, humans have two SMN genes, one more than mice, so a mutation in the first gene usually leads to reduced levels of SMN protein but not its elimination.
An antisense-based treatment called nusinersen, which removes a roadblock in the expression of the second SMN gene, was recently approved by the FDA.
Rossoll says his team's research helps to clarify SMN's role in motor neurons and other cells, and insights into its function could be important for optimizing delivery of the newly available treatment or development of additional treatments.
Source-Eurekalert