Abstract
Mutations in the tau gene cause familial frontotemporal dementia and parkinsonism linked to chromosome 17. Here we describe a novel missense mutation in exon 12 of the tau gene, G335V, in a German family with frontotemporal dementia of early age at onset, in the third decade of life. Functional analysis of recombinant tau protein with the G335V mutation showed a dramatically reduced ability to promote microtubule assembly and a more rapid and accelerated tau filament formation, suggesting that the primary effect of the mutation might be the provision of a pool of unbound tau making it available for aberrant tau aggregation.
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Introduction
The identification of mutations in the tau gene in familial frontotemporal dementia and parkinsonism linked to chromosome 17 (FTDP-17) has established the important role of the tau protein as a cause of neurodegeneration [1–3]. The neuropathological hallmarks of FTDP-17 with tau gene mutations are prominent filamentous deposits consisting of the microtubule-associated protein tau in neuronal and glial cells. So far, 34 different pathogenic tau gene mutations have been described. These include missense, deletion or silent mutations in the coding region, or intronic mutations located close to the splice-donor site of the intron following exon 10 [4]. Functionally, the mutations fall into two categories. All intronic and some exon 10 mutations influence the alternative splicing of tau pre-mRNA, thereby disturbing the normal splicing balance of exon 10 [2, 3, 5]. By contrast, most missense mutations reduce the ability of tau to interact with microtubules (MTs) [6–8], except for the S305N and the recently identified Q336R mutation, which lead to an increased ability of tau to promote MT assembly [9, 10]. Moreover, several missense mutations also stimulate the in vitro assembly of tau into filaments [8, 11–13].
Here we report a novel missense mutation (G335V) in the tau gene in a German family with early onset frontotemporal dementia. In contrast to the effect of the adjacent Q336R mutation [10], the G335V mutation results in a dramatically reduced ability of tau to promote MT assembly. In addition, the G335V mutation leads to an increased heparin-induced assembly of recombinant tau into filaments.
Materials and methods
Genetic analysis
Genomic DNA was extracted from whole blood using the Wizard Genomic DNA Purification Kit (Promega, Mannheim, Germany). All exons of the tau gene were amplified by polymerase chain reaction (PCR) using primers from the intronic sequences surrounding the exons [1]. The PCR products were checked for size by agarose gel electrophoresis and purified using QIAquick spin columns (Qiagen). DNA sequencing was carried out using the SequiTherm EXCEL long-read kit LC (Epicenture Technologies, Madison, Wis.) and 5′ 41-IRD labelled oligonucleotides. The labelled products were separated by denaturing gel electrophoresis on a 4.3% Long-Ranger gel (AT Biochem, Malvern, Wis.) and monitored using an automated DNA sequencing system (Model 4000L, LI-COR, Lincoln, N.E.). The G335V mutation was confirmed by PCR restriction fragment length polymorphism (RFLP) analysis by MscI digestion of the exon 12 PCR products; the mutation eliminates an MscI site.
Informed consent for genetic testing of the tau gene was obtained from either the subjects or their next of kin.
Microtubule assembly
Site-directed mutagenesis was used to change glycine 335 to valine (using the numbering of the 441-amino acid isoform of human tau) in the three-repeat 381 amino acid isoform and the four-repeat 412 amino acid isoform of human tau, expressed from cDNA clones htau37 and htau46, respectively. Wild-type and mutant tau proteins were expressed in Escherichia coli BL21(DE3) as described previously [14]. Tau proteins were purified and their concentration determined by densitometry and Coomassie staining.
Purified wild-type and mutant htau37 (0.3 mg/ml) and htau46 (0.2 mg/ml) were incubated with bovine tubulin (1 mg/ml; Cytoskeleton, Denver, Colo.) in assembly buffer (80 mM PIPES, 0.2 mM MgCl2, 1 mM EGTA, 1 mM DTT, 1 mM GTP) at 37°C as described [7]. Assembly of tubulin into microtubules was monitored over time by the change in turbidity at 350 nm using a Specord S100 photometer (Analytic Jena, Jena, Germany). Estimates of the initial rate of MT assembly and of the extent of assembly for each tau protein sample were based on results from four separate assembly reactions.
Heparin-induced tau assembly
Purified wild-type and mutant htau37 and htau46 (0.2 mg/ml) were incubated in 30 mM MOPS buffer at pH 7.4 in the presence of 0.02 mg/ml heparin (Sigma, St. Louis, Mo.) at 37°C as described previously [15]. Assembly was monitored quantitatively at intervals from 0–48 h by thioflavin S fluorescence as previously described [16] using the LS55 Luminescence Spectrometer (Perkin-Elmer Instruments, Shelton, Conn.) with excitation at 440 nm and emission at 490 nm. Measurements were carried out at room temperature in the presence of 10 μM thioflavin S (Sigma). Values were analyzed for significance by a two-tailed Student’s t test.
Results
Clinical description and family history
The pedigree of the kindred is shown in Fig. 1. To maintain patient confidentiality, their sexes are not shown and birth orders have been modified. Both sexes were affected with female to male and male to female transmission of the disorder.
In the index patient (IV:2), family members noticed early personality changes including lack of interest, unsocial behaviour and personal neglect at age 25 years. About 1 year later the patient was suspected of being schizophrenic and was admitted to a psychiatric hospital. The patient had no past medical or psychiatric history and no history of illegal drug abuse; developmental milestones had been normal. The patient had worked successfully until the onset of the disease. Neuropsychological examination revealed obvious deficits in attention and in executive functions, such as abstraction, planning and mental set-shifting. Orientation and memory functions were relatively preserved. Reduced speech output was observed with a tendency to answer “don’t know”. No neurologic abnormalities, especially no signs of parkinsonism have been noted to date. A wide range of serum and cerebrospinal fluid investigations including metabolic studies as well as an EEG were normal. MRI and CCT revealed marked bilateral fronto-temporal atrophy.
There was a history of a similar dementing disorder in several other family members IV:1 (onset at 26 years), III:10 (onset not known), III:2 (onset at 26 years), III:12 (onset at 22 years), II:3 (onset at 28 years); I:1 (onset not known) with a mean age at onset of 25.4±2.1 years.
No autopsies had been performed on the deceased family members.
Genetic analysis
Sequence analysis of genomic DNA from the index patient (IV:2) and the affected second cousin (IV:1) identified a G→T transition at the second base position in codon 335 in exon 12 of the tau gene (Fig. 2), resulting in a glycine to valine substitution in the repeat-binding domain of tau. The presence of the mutation was confirmed by PCR-RFLP. The mutation was absent in the tested healthy family members (III:3, III:13) and in 100 controls, checked by PCR-RFLP.
Microtubule assembly
Recombinant three-repeat and four-repeat human tau isoforms with the G335V mutation showed a markedly reduced ability to promote MT assembly when compared with the corresponding wild-type proteins (Fig. 3a, b). The rate of MT assembly was reduced to ∼5% for the three-repeat isoform and ∼30% for the four-repeat isoform when expressed as the optical density at 2 min (Fig. 3c).
Heparin-induced tau assembly
The effect of the G335V mutation on the heparin-induced assembly of recombinant three-repeat and four-repeat tau isoforms was quantified with the thioflavin-S assay (Fig. 4). Both G335V mutants showed an increased extent of aggregation when compared with the corresponding wild-type proteins, leading to an ∼1.5-fold higher thioflavin-S fluorescence after a 48 h incubation time (htau37-G335V 1.48-fold, P=0.0019; htau46-G335V 1.51-fold, P=0.00002). Particularly remarkable was the more rapid and accelerated aggregation rate of the G335V mutants, as demonstrated by a ∼6.5-fold higher thioflavin-S fluorescence after a 6-h incubation period (htau37-G335V 6.49-fold, P=0.0002; htau46-G335V 6.41-fold, P=0.00002).
Discussion
This study describes a novel mutation, G335V, in exon 12 of the tau gene in a family with frontotemporal dementia. It is highly likely that this mutation is pathogenic since it segregates with the clinical phenotype in the family and this genetic variation has not been found in 100 unaffected individuals.
The clinical features in the G335V family with early signs of personality changes and frontotemporal dementia are consistent with other clinical phenotypes described in FTDP-17 families. Interestingly, the initial diagnosis in the proband with the G335V mutation that we studied was schizophrenia, which has also been described in patients with the V337M mutation [17]. The age at onset in this family, with a mean of 25.4 years, differs from the later onset in most other FTDP-17 families, with an average age at onset of 49 years [18, 19]. So far, a similar early onset of disease has only been reported in families with the P301S mutation [20, 21]. Because no autopsies have been performed on deceased family members, no neuropathological data are available for the G335V mutation.
In the adult human brain, six tau isoforms are generated by alternative mRNA splicing, which differ by having either no, one or two 29-amino acid inserts in the amino-terminal half and either three or four carboxy-terminal repeat motifs in the MT-binding domain [22]. These motifs are composed of highly conserved 18-amino acid long binding elements with an invariant PGGG motif separated by flexible, but less conserved, 13–14 amino acids interrepeat sequences [23, 24]. The G335V mutation is the fifth identified mutation in exon 12 (Q336R, V337M, E342V, K369I) [1, 10, 25, 26]. It affects a highly conserved residue within the repeat sequence by changing the invariant PGGG motif in the third MT-binding repeat (numbering according to the longest tau isoform) to PGGV. A glycine is found in all known tau species [27, 28]. So far, three other mutations (P301L, P301S and G272V) located in the PGGG motif have been described, affecting adjacent positions. Thus, for G272V the PGGG motif in the first repeat becomes PGVG and for P301L and P301S in the second repeat it becomes LGGG and SGGG, respectively [2, 21]. Functionally, the G335V mutation leads to a dramatic decrease in the ability of recombinant tau to promote MT assembly, consistent with results obtained with other mutations in the PGGG motif and most other missense mutations in the MT-binding domains [2, 7, 21]. Remarkably, this is in contrast to the inverse effect of the Q336R mutation affecting the adjacent amino acid residue, where an increased ability to interact with MT has been reported [10]. In addition, the G335V mutation leads to a highly significant increase in the heparin-induced tau filament formation for both the three-repeat and the four-repeat tau isoforms, as described for several other missense tau mutations including the Q336R mutation [8, 10–13].
In summary, the description of the novel G335V mutation in a family with early onset of FTDP-17 extends the spectrum of tau gene mutations whose primary pathological effect might be the reduced MT binding affinity. Consequently, this might increase the cytosolic concentration of unbound mutant tau making it available for aberrant tau aggregation and inclusion body formation.
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Acknowledgements
We thank M. Goedert for the tau cDNAs. This work was supported by the Deutsche Forschungsgemeinschaft grant KFO 113/1 to H.A.K. and M.N.
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M. Neumann and S. Diekmann contributed equally to this work.
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Neumann, M., Diekmann, S., Bertsch, U. et al. Novel G335V mutation in the tau gene associated with early onset familial frontotemporal dementia. Neurogenetics 6, 91–95 (2005). https://doi.org/10.1007/s10048-005-0210-y
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DOI: https://doi.org/10.1007/s10048-005-0210-y