The Alzheimer’s Association’s division devoted to frontotemporal dementia and related disorders has just announced its award for best publication of the year for 2004.  It’s entitled, “Genetic, transcriptomic, histological, and biochemical analysis of progressive supranuclear palsy implicates glial activation and novel risk genes.” The lead author is Dr. Kurt Farrell of the Icahn School of Medicine at Mt. Sinai in New York, and the senior author is Dr. Adam Naj of the David Geffen School of Medicine at UCLA.  Full disclosure: I played a very minor role in an early phase of the work and am 34^th of the 48 co-authors.

The study sought to identify new genes conferring risk for PSP by comparing genetic markers between a group of 2,779 people with PSP (a large majority autopsy-confirmed) and 5,584 people with no neurodegenerative conditions.  This is the largest such study in PSP to date, the first having been published in 2011. The study’s large size gives it greater power to distinguish a genuine PSP-related genetic variant from a statistical fluke. 

This technique can identify not a specific gene, but a small region of a chromosome, typically with 50 to 200 genes.  But the researchers then nominated a couple of the most likely genes in that region and tested brain tissue for excessive amounts or abnormal forms of the protein encoded by the candidate genes.

Besides confirming PSP’s previously-identified genetic risk factors, Farrell and colleagues identified a new risk gene called C4A, located on chromosome 6. The protein it encodes is part of the cell’s “innate immune system.” The C stands for “complement,” a complicated group of proteins that assist the antibodies.  Once an antibody latches onto an unwanted invader like a bacterium or virus, proteins from the complement system attach to the other end of the antibody, initiating a series of interactions that eventually produces an “attack complex” that pokes a major hole in the invader.

The other important finding from the same study was a strong tendency for all the genes known to increase PSP risk to affect the oligodendrocytes.  Those are the brain cells that form the myelin sheath insulating the axons of most of the brain’s neurons, greatly facilitating electrical conduction.  We’ve known for decades that loss of myelin is an early feature in PSP, and that some PSP risk genes encode proteins related to oligodendrocytes.  But the new paper provides important confirmation in a larger patient group, using techniques not previously available.

So, bottom line: Although the genetic basis of PSP is not usually enough to make the disease occur in more than one member of a family, it could still be one important factor, along with things like a poorly-understood toxin exposure.  Furthermore, the new evidence that the oligodendrocytes might be the first cells to get sick in PSP points researchers in that direction in their search for new, easily addressable drug targets.  Plus, the discovery that an important part of the immune system could be what’s ailing the oligodendrocytes means that the array of potential drug targets is now much better focused. Shotgun approaches to taming components of the complement system have been under way for about a decade now, and the new finding of Farrell et al could focus those efforts nicely.