Researchers discover new cellular component with importance for the sense of smell

Researchers at Umeå University have discovered a previously unknown cellular component, an organelle, inside neurons that we use to perceive smell. The discovery may have implications for further research on impaired sense of smell, which is a common symptom of COVID-19.

A prerequisite for finding a treatment for impaired sense of smell is to first understand how the sense of smell works.”

Staffan Bohm, Professor, Department of Molecular Biology, Umeå University

What the researchers have discovered is a so-called organelle inside nerve cells, that has not previously been observed. The newly discovered organelle has been given the name multivesicular transducosome by the researchers. The discovery was made possible thanks to Umeå University’s unique microscopy infrastructure.

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Organelles are distinct ‘workstations’ inside cells that can be compared to the different organs of the body, i.e. different organelles have different functions in the cell. Most organelles are common to different cell types, but there are also organelles with specific functions that only occur in certain cell types. Olfactory nerve cells have long projections, i.e. cilia, that protrude into the nasal cavity and contain the proteins that bind odorous substances and thus initiate nerve impulses to the brain. The conversion of odor into nerve impulses is called transduction and the newly discovered organelle, contains only transduction proteins.

The role of the transductosome is to both store and keep transduction proteins separate from each other until they are needed. Upon olfactory stimulation, the outer membrane of the organelle ruptures, releasing the transduction proteins so that they can reach the cilia of the neuron, and smell is perceived.
The researchers also discovered that the transductosome carries a protein called retinitis pigmentosa 2, RP2, which is otherwise known to regulate transduction in the eye’s photoreceptor cells. If the RP2 gene is mutated, it can cause a variant of the eye disease retinitis pigmentosa that damages the eye’s light-sensitive cells.

“A question for further research is whether the transductosome has a role in vision and whether it is present in brain neurons that are activated by neurotransmitters and not light and smell. If so, the discovery may prove even more significant,” says Staffan Bohm.

The transducosome was discovered when researcher Devendra Kumar Maurya used a new technique called correlative microscopy. The technique combines electron microscopy and confocal microscopy so that a cell’s internal structures and the location of different proteins can be imaged simultaneously. Crucial to the discovery was Devendra’s method development, which enabled the technique to be used to analyze intact neurons in tissue sections.

The study is published in the scientific journal Nature Communications.


Umeå University

Journal reference:

Maurya, D.K., et al. (2023) A multivesicular body-like organelle mediates stimulus-regulated trafficking of olfactory ciliary transduction proteins. Nature Communications.

Posted in: Molecular & Structural Biology | Cell Biology | Histology & Microscopy

Tags: Brain, Cell, Cilia, Confocal microscopy, covid-19, Electron, Electron Microscopy, Eye, Eye Disease, Gene, Membrane, Microscopy, Molecular Biology, Nerve, Neuron, Neurons, Organelle, Protein, Research, Retinitis Pigmentosa

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