The ability to smell in a mouse model of a human genetic disorder that causes congenital anosmia has been restored by scientists funded by the National Institutes of Health. Anosmia is the inability to smell from birth.
The approach uses gene therapy to regrow cilia, cell structures that are essential for olfactory function. The study was funded by four parts of NIH: the National Institute on Deafness and Other Communications Disorders (NIDCD), the National Institute on Diabetes and Digestive and Kidney Diseases (NIDDK), the Eunice Kennedy Shriver National Institute of Child Health and Human Development (NICHD), and the National Eye Institute (NEI). It was published online in the September 2, 2012, issue of the journal Nature Medicine.
"These results could lead to one of the first therapeutic options for treating people with congenital anosmia," said James F. Battey, Jr., M.D., Ph.D., director of NIDCD. "They also set the stage for therapeutic approaches to treating diseases that involve cilia dysfunction in other organ systems, many of which can be fatal if left untreated."
The team of researchers, led by Jeffrey R. Martens, Ph.D., at the University of Michigan, Ann Arbor, and Jeremy C. McIntyre, Ph.D., a post-doctoral fellow in Martens' laboratory, worked with a mouse model carrying a mutation in the IFT88 gene. The mutation causes a decrease in the IFT88 protein, which leads to a dramatic reduction in cilia function in several different organ systems, including the olfactory system.
The researchers used an adenovirus to introduce a healthy copy of the gene as a way to restore IFT88 protein levels in the mice. They wanted to see if the reintroduction of the lost protein could restore cilia to the olfactory sensory neurons and return the ability to smell. For three consecutive days, the mice received intranasal gene delivery therapy and then were allowed 10 days for the infected sensory neurons to express the viral-encoded IFT88 protein. After that time, the mice were tested with increasing concentrations of an odorant (amyl acetate). Their responses were measured at the cellular, tissue, and synaptic levels, which all indicated that the mice had regained olfactory function.
"By restoring the protein back into the olfactory neurons, we could give the cell the ability to regrow and extend cilia off the dendrite knob, which is what the olfactory neuron needs to detect odorants," said McIntyre.
The change in olfactory function also has implications in the feeding behavior of the mice. The mouse model the scientists used is born underweight and its anosmia interferes with the motivation to eat, which in many mammals, including humans, is driven by smell. Treatment with adenovirus therapy increased bodyweight by 60 percent in treated compared to untreated mice, indicating that the restored olfactory function was motivating feeding.
The researchers plan to continue their work by developing another mouse model to look at the impact on olfactory function and the potential for restoring function when the IFT88 gene is completely missing, rather than just mutated. Future studies could begin to plot a way to bring this therapeutic tactic to human study volunteers, which could eventually restore the sense of smell, and a better quality of life, to people who are born with anosmia. Further research could also advance the treatments for other ciliopathies, as these findings show that gene therapy is a viable option for the functional rescue of cilia in established, already differentiated cells.