Repeats of the seemingly innocuous hexanucleotide sequence GGGGCC cause amyotrophic lateral sclerosis (ALS) more than any other known factor. Taking one step closer to understanding how, researchers led by Brian Black at the University of California, San Francisco, have uncovered a zinc finger protein, Zfp106, which associates with the fateful sequence, as well as with several RNA binding proteins implicated in the disease, including TDP-43 and FUS. As described in eLife on January 10, mice lacking Zfp106 succumb to a progressive, ALS-like disorder, while expressing the zinc finger protein in a C9ORF72 fly model suppressed motor neuron disease. The study adds to other recent reports linking C9ORF72 to the derailment of RNA metabolism and processing. Exactly how Zfp106 dampens the neurotoxicity caused by C9ORF72, and whether the protein’s protective prowess extends to other forms of ALS, are exciting questions that remain unanswered, Black told Alzforum.
Compared to healthy people, who have between two and 23 repeats of the G4C2 sequence in their C9ORF72 gene, people with ALS can have hundreds to thousands. While some researchers contend that aggregates of poly-dipeptides translated from expanded C9ORF72 RNA harms neurons, others claim that the G4C2 repeat RNAs do the damage. To investigate, first author Barbara Celona and colleagues used a string of eight G4C2 repeats to fish for proteins that bind the RNA expansions. The researchers pulled out more than a dozen known and predicted RNA binding proteins. Celona decided to focus further on Zfp106 because the human gene lies in a region on chromosome 15 implicated in a rare recessive form of ALS (Hentati et al., 1998). Furthermore, Zfp106 knockout mice have a progressive neuromuscular disorder (Anderson et al., 2016; Joyce et al., 2016).
In a cultured neuronal cell line and in lower motor neurons from postmortem human spinal cord samples from people free of ALS, the researchers found Zfp106 primarily located in the nucleolus and occasionally in clusters inside the nucleus. Using mass spectrometry to identify proteins that buddy up with Zfp106 revealed 39 partners, many being RNA binding proteins. These included TDP-43 and FUS, as well as the nucleolar protein Nucleolin, and the nuclear pore component, Nup107. Together, these findings placed Zfp106 right at the heart of predicted ALS hotspots: the RNA processing, metabolism, and splicing centers of the nucleolus and nucleus.
To investigate the role of Zfp106 in vivo, the researchers characterized Zfp106 knockout mice that were generated as part of a large-scale phenotypic screen called the Sanger Mouse Genetics Project. The Zfp106 knockout animals—in which the β-galactosidase gene replaced part of Zfp106—behaved similarly to wild-type mice for the first month of life, but then all of them started showing signs of muscle weakness and loss. By three months of age, the knockout animals had extensive muscular atrophy and degeneration of the muscle fibers, as well as a widespread death of choline acetyltransferase (ChAT)-positive motor neurons in the spinal cord. A separate Zfp106-deficient mouse line that the researchers generated via CRISPR struggled with the same pathologies. To see if deficiency of Zfp106 specifically in motor neurons drove their neurodegeneration, the researchers next crossed the knockout mice with animals expressing Zfp106 under control of the Mnx1 promoter, which is active only in motor neurons. Offspring were largely spared from cell death, and from the muscle loss and weakness in the Zfp106 knockouts.
How would Zfp106 behave in a C9ORF72 model of ALS? To find out, the researchers turned to flies. In a Drosophila model expressing 30 copies of G4C2, half of the insects die before emerging from their pupal case, and those that do manage to creep out are stricken with severe movement problems. Co-expressing Zfp106 in these insects allowed the embryos to survive past the pupal stage, and partially suppressed the locomotor defects. These findings support the idea that Zfp106 dampens the neurodegenerative effects of C9ORF72 repeat expansions.
Though the function of Zfp106, especially in humans, is unknown, Black proposed that the protein might latch onto C9ORF72 RNA and somehow prevent translation of dipeptide repeats, which he views as the toxic entities in C9-ALS. If so, perhaps therapeutic strategies that bestow motor neurons with extra Zfp106, or small molecules that mimic its binding to RNA, could stave off the disease, he told Alzforum.
Interestingly, two recent studies reported that the dipeptide repeats translated from C9ORF72 expansions associated with some of the same ALS-associated RNA binding proteins that Zfp106 does, and that these partnerships fouled up the function of so-called liquid organelles such as the nucleolus, where RNA metabolism and processing take place (see Oct 2016 news). While Black would not speculate on whether Zfp106 binding to these proteins also affected liquid organelle dynamics, he said that it is certainly possible, given the close quarters the proteins all share in densely packed organelles.
How might Zfp106 play a role in other forms of ALS without C9ORF72 repeat expansions? “This is a major question that needs to be answered next,” commented Abraham Acevedo-Arozena of the Hospital Universitario de Canarias in the Canary Islands, Spain. Acevedo-Arozena, who led one of the studies first characterizing the neuromuscular disorder in Zfp106 knockout mice, added that it is possible the zinc finger protein could protect by associating with RNA binding proteins implicated in the disease, including TDP-43 and FUS, which are known to translocate from the nucleus to the cytoplasm in neurons affected by ALS. Figuring out what the protein does, and whether it can broadly protect against sporadic forms of the disease, are the next major challenges, he added.
Celona B, von Dollen J, Vatsavayai SC, Kashima R, Johnson JR, Tang AA, Hata A, Miller BL, Huang EJ, Krogan NJ, Seeley WW, Black BL. Suppression of C9orf72 RNA repeat-induced neurotoxicity by the ALS-associated RNA-binding protein Zfp106. Elife. 2017 Jan 10;6. pii: e19032. [PubMed]
Hentati A, Ouahchi K, Pericak-Vance MA, Nijhawan D, Ahmad A, Yang Y, Rimmler J, Hung W, Schlotter B, Ahmed A, Ben Hamida M, Hentati F, Siddique T. Linkage of a commoner form of recessive amyotrophic lateral sclerosis to chromosome 15q15-q22 markers. Neurogenetics. 1998 Dec;2(1):55-60. [PubMed].
Anderson DM, Cannavino J, Li H, Anderson KM, Nelson BR, McAnally J, Bezprozvannaya S, Liu Y, Lin W, Liu N, Bassel-Duby R, Olson EN. Severe muscle wasting and denervation in mice lacking the RNA-binding protein ZFP106. Proc Natl Acad Sci U S A. 2016 Aug 2;113(31):E4494-503. [PubMed].
Joyce PI, Fratta P, Landman AS, Mcgoldrick P, Wackerhage H, Groves M, Busam BS, Galino J, Corrochano S, Beskina OA, Esapa C, Ryder E, Carter S, Stewart M, Codner G, Hilton H, Teboul L, Tucker J, Lionikas A, Estabel J, Ramirez-Solis R, White JK, Brandner S, Plagnol V, Bennet DL, Abramov AY, Greensmith L, Fisher EM, Acevedo-Arozena A. Deficiency of the zinc finger protein ZFP106 causes motor and sensory neurodegeneration. Hum Mol Genet. 2016 Jan 15;25(2):291-307. [PubMed].
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On home page. Image courtesy of [Celona et al., 2017].