Francesca Vitale’s research while affiliated with Huntington Medical Research Institutes and other places

What is this page?

This page lists works of an author who doesn't have a ResearchGate profile or hasn't added the works to their profile yet. It is automatically generated from public (personal) data to further our legitimate goal of comprehensive and accurate scientific recordkeeping. If you are this author and want this page removed, please let us know.

Publications (5)

Fig. 1 ScFvMC1 detection and peripheral organs' morphology. a Six-month old mice (JNPL3 shown) were IV-injected with saline, 100 μg of IRDye-labelled antibodies (scFvMC1-IR and MC1-IR) and unlabeled antibodies (scFvMC1-UNL and MC1-UNL). Two hours post-injection, brain homogenates from cortex (Ctx), hippocampus (Hip) and hindbrain (HB) were spotted on nitrocellulose and absorbance of the IRDye label measured. Saline and unlabeled antibodies showed no signal (Sapphire Biomolecular Imager, Azure Biosystems). b, c AAV1-CAG-scFvMC1 was injected in tibialis muscle of P301S or JNPL3 (JNPL3 shown), mice sacrificed 4 months later and peripheral organs harvested. Tissue lysates were analyzed for scFvMC1 expression with anti-Myc/tag antibody showing localized expression in the injected site (b, right tibialis, Controls = AAV1-eGFP) while other peripheral organs did not show scFv signal (c). ScFvMC1: MW around 30 kDa; tubulin is used as housekeeper: MW at 55 kDa. d Hematoxylin and eosin (H&E) staining was performed on kidney, liver, tibialis muscle and heart: representative images of each organs show no significant changes in morphology (Controls = AAV1-CAG-eGFP; Bright field microscope, scale bar: 300 μm)
Fig. 6 Phospho-Threonine-231 and MC1-tau immunoreactivity in brain. Brains from P301S and JNPL3 animals were harvested and stained with either anti tau phospho-Thr231 antibody (A) or anti-MC1-tau (B). (A): a, b, d, e Representative images of CA1 hippocampal cell layer and entorhinal cortex (EC) stained with anti-pThr231. Control mice received AAV1-CAG-eGFP injection (n = 13). Treated mice were injected with AAV1-CAG-scFvMC1 (n = 13). (A): c,f Semi-quantification of percentage of area stained by RZ3 shows a trend of reduction in the AAV1-CAG-scFvMC1 injected group, in the CA1 region of hippocampus in the JNPL3 (c, p = 0.1128, unpaired t test with Welch's correction); no trend to reduction is detected in the entorhinal cortex (EC) (f, p = 0.3458, unpaired t test with Welch's correction). (A): g, h, j, k Representative images of the CA1 region and entorhinal cortex (EC) from P301S; pThr-231 staining was performed as above. Control mice received AAV1-CAG-eGFP injection (n = 6), treated mice were injected with AAV1-CAG-scFvMC1 (n = 6); (A) i, l Semi-quantification of percentage of area stained by RZ3 in P301S mice (i, p = 0.2403; l, p = 0.2251; non parametric MannWhitney test). (B): a, b, d, e Representative images of CA1 hippocampal cell layer and entorhinal cortex (EC) stained with anti-MC1 antibody. Control mice received AAV1-CAG-eGFP injection (n = 13). Treated mice were injected with AAV1-CAG-scFvMC1 (n = 13) (c, f) Semi-quantification of percentage of area stained by MC1 shows a trend of reduction in the AAV1-CAG-scFvMC1 injected group, in the CA1 region of hippocampus (c, p = 0.0996; unpaired t test with Welch's correction); no reduction is detected in the entorhinal cortex (EC) (f, p = 0.9558; unpaired t test with Welch's correction) in JNPL3. (g, h, j, k) Representative images of the CA1 region and the entorhinal cortex (EC) from P301S; MC1 staining was performed as above. Control mice received AAV1-CAG-eGFP injection (n = 6), treated mice were injected with AAV1-CAG-scFvMC1 (n = 6). (i, l) Semi-quantification of percentage of area stained by MC1 in P301S mice (i, p = 0.4127; l, p = 0.8413; non parametric Mann-Whitney). (Olympus BH-2 bright field microscope; scale bar: 100 μm). Graphs are expressed as % Control area stained, and means +/− SEM
Fig. 8 Microglia morphology is unchanged upon treatment. Microglia processes morphology was assessed in both P301S and JNPL3 animals. a Representative images of Iba-1 positive microglia (stratum radiatum of the CA1 subfield of the hippocampus): the processes morphology was scored as 0 (> 15 thin processes with multiple branches), 1 (5-15 thick processes with branches), 2 (1-5 thick processes with few branches), 3 (no clear processes). b Microglia from P301S mice did not show any significant morphological changes comparing controls to treated mice. Each single point represents a single cell (n = 50 cells per group, p = 0.5671, non parametric Mann Whitney test). c No significant changes in microglia morphology were detected in the JNPL3 cohort (n = 50 cells per group, p = 0.9628, non parametric Mann Whitney test). Graphs are expressed as arbitrary unit (a.u.) and means +/− SEM. (AxioImager Z1 microscope, Zeiss; 63x oil and 0.58 μm z-steps)
Fig. 9 Microglia uptake phosphorylated tau in vitro, facilitated by scFvMC1. (a) Primary mouse microglia (P2 C57Bl/6 J pups) were treated in vitro for 2 h with PHF-tau +/− scFvMC1 (scFv/PHF ratio of 10/1). Total tau ELISA. Column A: PHF levels are expressed as % of starting PHF concentration measured after incubation on cell-free plates (− primary microglia); column B: amount of PHF in medium upon combination with scFvMC1, on cell-free plates (− primary microglia); column C and column D: PHF levels on microglia seeded plates (+ primary microglia), with or without scFvMC1. A vs C (*p < 0.05, unpaired t test with Welch's correction); C vs D (*p = 0.0137, unpaired t test with Welch's correction); B vs D (**p = 0.0019 unpaired t test with Welch's correction). Data are collected from three different experiments, with treatments run in quadruplicates. Graphs are means +/− SEM. (b, upper panel) Representative immuno-blotting (PHF1 antibody: anti-pSer396/404) of PHF-tau in the corresponding microglia lysates; (b, lower panel) scFvMC1 expression verified using anti Myc-tag antibody. NT is non treated microglia; PHF is microglia treated with PHF-tau; PHF + scFv is microglia co-treated with PHF-tau and scFvMC1; scFv is microglia treated with scFvMC1
Microglia uptake scFvMC1 in vivo. (A) P301S were injected intracranially in the CA1 quadrant of the hippocampus using AAV5-GFAP-scFvMC1. Upper panels: Representative confocal images of the cortex: scFvMC1 (Myc, red) co-localizes within the microglia (Iba1, green); nuclei stained with DAPI (blue). Lower panels: higher magnification to better visualize scFvMC1 in microglia positive cells (Zeiss880 confocal laser microscope; upper panels, scale bar: 20 μm; lower panels, scale bar: 10 μm). (B) Flow cytometry on microglia isolated from adult P301S mice intracranially injected with AAV5-GFAP-scFvMC1 or AAV5-null (a-c) Gating strategy (live, singlets) for subsequent selection of microglia. (d) Gating strategy to isolate microglia from other monocytes. Representative plot showing microglia population: CD11bhigh and CD45low; near-complete absence of macrophages: CD11bhigh and CD45high. (e) Microglia extracted from P301S mice, treated (blue) or not (red) with scFv-MC1: upon permeabilization, anti-Myc-647 detects scFvMC1 in microglia of treated mice (blue)

+5

Intramuscular injection of vectorized-scFvMC1 reduces pathological tau in two different tau transgenic models
  • Article
  • Full-text available

August 2020

·

239 Reads

·

8 Citations

Acta Neuropathologica Communications

Francesca Vitale

·

·

·

[...]

·

Cristina d’Abramo

Abstract With evidence supporting the prion-like spreading of extracellular tau as a mechanism for the initiation and progression of Alzheimer’s disease (AD), immunotherapy has emerged as a potential disease-modifying strategy to target tau. Many studies have proven effective to clear pathological tau species in animal models of AD, and several clinical trials using conventional immunotherapy with anti-tau native antibodies are currently active. We have previously generated a vectorized scFv derived from the conformation-dependent anti-tau antibody MC1, scFvMC1, and demonstrated that its intracranial injection was able to prevent tau pathology in adult tau mice. Here, we show that, in a prevention paradigm and in two different tau transgenic models (JNPL3 and P301S), a one-time intramuscular injection of AAV1-scFvMC1 generated a long-lasting peripheral source of anti-tau scFvMC1 and significantly reduced insoluble and soluble tau species in the brain. Moreover, our data showed that scFvMC1 was internalized by the microglia, in the absence of overt inflammation. This study demonstrates the efficacy of intramuscular delivery of vectorized scFv to target tau, and suggests a new potential application to treat AD and the other tauopathies.

Download
ScFv-MC1 design, expression and characterization. a scFv-MC1 diagram: 5’-terminal signal peptide (SP), variable heavy (VH) and variable light (VL) chains joined together by a 15 amino acid residue linker (Gly4Ser)3, and 3’-terminal Myc and His6X tags. b HEK293 cells were transiently transfected with empty vector (empty v.) or scFv-MC1. In the cell lysate (immunoblotting) the scFv-MC1 was detected as a 30 kDa band; c in the conditioned medium the presence of scFv-MC1 was assessed using a specific ELISA and was expressed as ODs (optical densities). Cells transfected with the empty vector did not show any sign of reactivity in western blotting or ELISA. d Purified scFv-MC1, run on SDS-PAGE gel and stained with Coomassie: two different purified preparations (1, 2) revealed the expected molecular weight (30 kDa). e scFv-MC1 antigen-binding specificity: purified scFv-MC1 tested for its activity on the specific peptide (998b) was compared to the MC1 mAb, showing a comparable reactivity; CP13 and DA31 were used as negative controls. f Representative images of AD brain immunohystochemistry: both scFv-MC1 and MC1 (1:500 dilution) showed specificity for the neurofibrillary pathology (Olympus BH-2 microscope, bar: 50 μm)
AAV5-scFv-MC1 transduction in vivo.a Representative images of JNPL3 mice brain sections, 4 weeks post injection (n = 6): the AAV5-scFv-MC1 injected brain showed clear expression of the recombinant antibody in the hippocampus using an anti-Myc antibody (red). Nuclei were stained with DAPI (blue). No signal was detected in the not injected brains (Zeiss Axio Imager Apotome, bar: 500 μm). b western blotting on hippocampus lysates of injected (Inj.) or not-injected (Not Inj.) JNPL3 mice, using anti-Myc antibody. Neuronal N-cadherin was used as a marker of neuronal integrity, and actin was used as a housekeeper
AAV5-scFv-MC1 cellular selectivity. Representative immunofluorescent confocal images of the hippocampus (CA1 quadrant) from JNPL3 mice. a-e When mice were injected with AAV5-CAG-scFvMC1 (n = 6), the scFv was expressed mainly in neurons: scFv-MC1 (a, Myc-red), MAP2-positive neurons (b, green), GFAP-positive astrocytes (c, magenta); co-localization is shown as merge of red and green (e, orange/yellow). f-j Upon injection with AAV5-GFAP-scFvMC1 (n = 6), scFvMC1 was expressed primarily in astrocytes: scFv-MC1 (f, Myc-red), GFAP-positive astrocytes (g, green), NeuN-positive neurons (h, magenta); co-localization is shown as merge of red and green (j, yellow). Nuclei were stained with DAPI (blue, panel d and i). Images represent maximum-intensity projection of z-stacks (Zeiss 880 confocal laser miscroscope, bar: 50 μm)
Brain parenchyma expression and diffusibility. ScFv-MC1 is expressed and released in the extracellular milieu: anti Myc-tag staining performed 4 months after the one time intracranial injection with AAV5-eGFP (a-g) (n = 15), AAV5-CAG-scFvMC1 (h-n) (n = 15) and AAV5-GFAP-scFvMC1 (o-u) (n = 15). Representative images from the whole hippocampus (Olympus BH-2 bright field microscope, bar: 500 μm), CA1, subiculum, dentate gyrus (DG), entorhinal cortex (EC), frontal cortex and HB (bar: 100 μm). The scFv is visualized as a brown signal and shows extensive expression in hippocampi from treated mice, with spreading in areas distant from the site of injection. (v) Immunoblot analysis of lysates from the hippocampus, cortex and hindbrain: AAV5-eGFP injected (1), AAV5-CAG-scFMC1 injected (2), AAV5-GFAP-scFvMC1 injected (3). Three representative lysates from each group of treatment were pulled together and loaded on SDS-PAGE (40μg proteins of hippocampus; 300μg proteins of cortex; 150μg proteins of HB plus HRP substrate enhancer when developing). Anti Myc-tag was used to track the scFv in the brain parenchyma; actin was used as a housekeeper and N-cadherin as a marker of neuronal integrity. Of note, immunoblots images shown represent optimal exposure samples to visualize differences within the brain areas
MC1-tau immunoreactivity. Representative images of MC1 staining on JNPL3 brains. a, b, c Non-treated mice received AAV5-eGFP injection. Treated mice were injected with AAV5-CAG-scFvMC1 d, e, f or AAV5-GFAP-scFvMC1 g, h, i (Olympus BH-2 bright field microscope; bar: 500 μm a, d, g; bar: 100 μm b, c, e, f, h, i). j Quantification of percentage of area stained by MC1 shows a significant reduction in the AAV5-GFAP-scFvMC1 injected group, in the CA1 region of hippocampus (*P = 0.0320 by non-parametric Kruskall-Wallis test) and k in the EC (**P = 0.0025 by one-way ANOVA followed by Dunnett’s post hoc test). AAV5-CAG-scFvMC1 injected mice only showed a non-significant trend reduction in MC1 staining in (j) CA1 (p = 0.3999) and in k EC (p = 0.2626). All graphs are means +/− SEM (n = 15 in each group of treatment)

+2

Anti-tau conformational scFv MC1 antibody efficiently reduces pathological tau species in adult JNPL3 mice

August 2018

·

760 Reads

·

45 Citations

Acta Neuropathologica Communications

Francesca Vitale

·

·

Santiago Ruiz

·

[...]

·

Cristina d’Abramo

Tau, the main component of the neurofibrillary tangles (NFTs), is an attractive target for immunotherapy in Alzheimer’s disease (AD) and other tauopathies. MC1/Alz50 are currently the only antibodies targeting a disease-specific conformational modification of tau. Passive immunization experiments using intra-peritoneal injections have previously shown that MC1 is effective at reducing tau pathology in the forebrain of tau transgenic JNPL3 mice. In order to reach a long-term and sustained brain delivery, and avoid multiple injection protocols, we tested the efficacy of the single-chain variable fragment of MC1 (scFv-MC1) to reduce tau pathology in the same animal model, with focus on brain regional differences. ScFv-MC1 was cloned into an AAV delivery system and was directly injected into the hippocampus of adult JNPL3 mice. Specific promoters were employed to selectively target neurons or astrocytes for scFv-MC1 expression. ScFv-MC1 was able to decrease soluble, oligomeric and insoluble tau species, in our model. The effect was evident in the cortex, hippocampus and hindbrain. The astrocytic machinery appeared more efficient than the neuronal, with significant reduction of pathology in areas distant from the site of injection. To our knowledge, this is the first evidence that an anti-tau conformational scFv antibody, delivered directly into the mouse adult brain, is able to reduce pathological tau, providing further insight into the nature of immunotherapy strategies. Electronic supplementary material The online version of this article (10.1186/s40478-018-0585-2) contains supplementary material, which is available to authorized users.

Download
Figure 1. Generation and characterization of Tau DN mice. Confirmation of positive embryonic stem (ES) clones by Southern blotting analysis. (a) Long homology arm (LA) analysis. Southern blot analysis of ScaI-digested genomic DNA with P1/2. Schematic is represented on the left and the Southern blot is shown on the right. The wild-type (WT) band is 10 728 bp, whereas the knock-in (KI) band is 7052 bp. (b) Short homology arm (SA) analysis. Southern blot analysis of AflII-digested genomic DNA with P3/4. Schematic is represented on the left and the Southern blot is shown on the right. The WT band is 6093 bp, whereas the KI band is 5477 bp. (c) Quantification of total brain Tau mRNA levels shows similar level of Tau expression is in WT and Tau DN/DN littermates. (d) Quantification of total Tau protein shows that Tau DN/DN mice present higher levels of total Tau as compared with the WT littermates. The samples analyzed in c and d are derived from the same animals (half brain was used for RNA extraction, the other half for protein preparation). The animals were littermates and were analyzed at 3 weeks of age. 
Figure 2. Tau DN/DN mice do not produce δTau. (a) Brain homogenates from 3 week-old Tau DN/DN and wild-type (WT) littermate mice were treated with (+) or without (− ) Caspase-3 prior to western blot analysis with the anti-δTau antibody C3. WT, but not Tau DN/DN , brain lysates show presence of δTau after Caspase-3 digestion. The (?) indicates a band produced by Caspase-3 in WT sample and reactive with C3 of uncertain nature. (b) ELISA with C3 shows that δTau is present in WT but not Tau DN/DN brain lysates (F (2, 20) = 126; Po0.0001). Rec. Tau was used as an internal control. All data represent means ± s.e.m. (****P o0.0001). 
Figure 3. Mild short-term memory deficits in tau-mutant mice. (a) Elevated Zero Maze test shows no significant effect of genotype. (b–d) The two-trial Y-maze test showed mild deficit of short-term spatial recognition memory in Tau DN/WT and Tau DN/DN mice. (b) Mice of all genotypes entered the arms a similar number of times. (c) Percentage of entries into the novel (N) and known (K) arm. Mice of all genotypes entered the novel arm significantly more than the known arm, albeit the significance was lower for Tau DN/DN mice. (d) Time spent in the novel and known arm. Only wild-type (WT) mice and spent significantly more time in the novel arm than in the known arm. (e–h) Open field test shows no statistical differences among the three genotypes in total distance traveled (e), average speed (f), amount of time in which the animal ambulated at speed 450 mm s −1 (g), amount of time the animal spent in the center of the arena (h). In the novel object recognition task, mice of all genotypes spend similar amount of time exploring the two identical objects during the first trial (i). Only WT mice spent significantly more time exploring the novel object 4 h later (j). All data represent means ± s.e.m. (*P o0.05; **P o0.01; ***P o0.001; ****Po0.0001). 
Figure 4. Tau DN/DN and Tau DN/WT mice have a deficit in spatial learning and long-term memory. (a) Schematic illustration of the Morris water maze task. (b) During the first acquisition trial (A1) of spatial reference memory in the hidden platform task, a significant difference was found between WT and the two mutant mice (Tau DN/WT and Tau DN/DN ), with the WT mice traveling a significantly shorter path before reaching the platform. Mice of all genotypes perform similarly during the P1 (c-e) and A2 (f) trials. (g) Percentage of time spent in the four quadrants in the P2 trial. Tau DN/WT mice spent significantly less time in the target quadrant (NW in bold) as compared with WT mice. There were no significant differences in the number of counter crossings in the target quadrant (h) and in the average proximity to the former platform location (i) among the three genotypes. (j) In the P3 trial, Tau DN/WT and Tau DN/DN mice spent significantly less time in the target quadrant as compared with WT mice. (l) Tau DN/WT and Tau DN/WT mice crossed the target quadrant significantly less than WT animals. (h) Tau DN/WT mice were on average significantly farther from the former platform location as compared with WT animals. All data represent means ± s.e.m. (*Po 0.05; **Po 0.01).
Figure 5. Long-term potentiation (LTP) is impaired in ~ 18 months-old Tau DN/DN mice. (a) Normal basal synaptic transmission in Tau DN/DN animals. Summary graph of field input–output relationship for different stimulation intensities (5–35 V). Two-way ANOVA showed no difference between the two genotypes. (b) LTP impairment in Tau DN/DN animals (F (1, 14) = 5.390, P = 0.0359). CA1 field-excitatory postsynaptic potentials (fEPSPs) were recorded in the Schaffer Collateral pathway in the hippocampus. A 20-min baseline was recorded every minute at an intensity that evoked a response of ∼ 35% of the maximum evoked response. LTP was induced using a theta-burst stimulation (four pulses at 100 Hz, with the bursts repeated at 5 Hz and each tetanus including 3 ten-burst trains separated by 15 s). Responses were measured as fEPSP slopes expressed as percentage of baseline and were recorded for 2 h after tetanization. 

+2

Abolishing Tau cleavage by caspases at Aspartate421 causes memory/synaptic plasticity deficits and pre-pathological Tau alterations

August 2017

·

150 Reads

·

23 Citations

Translational Psychiatry

·

C d'Abramo

·

M D Tambini

·

[...]

·

TAU mutations are genetically linked to fronto-temporal dementia (FTD) and hyper-phosphorylated aggregates of Tau form neurofibrillary tangles (NFTs) that constitute a pathological hallmark of Alzheimer disease (AD) and FTD. These observations indicate that Tau has a pivotal role in the pathogenesis of neurodegenerative disorders. Tau is cleaved by caspases at Aspartate421, to form a Tau metabolite known as δTau; δTau is increased in AD, due to the hyper-activation of caspases in AD brains. δTau is considered a critical toxic moiety underlying neurodegeneration, which initiates and facilitates NFT formation. As Tau is a therapeutic target in neurodegeneration, it is important to rigorously determine whether δTau is a toxic Tau species that should be pharmacologically attacked. To directly address these questions, we have generated a knock-in (KI) mouse called TauDN—that expresses a Tau mutant that cannot be cleaved by caspases. TauDN mice present short-term memory deficits and synaptic plasticity defects. Moreover, mice carrying two mutant Tau alleles show increased total insoluble hyper-phosphorylated Tau in the forebrain. These data are in contrast with the concept that δTau is a critical toxic moiety underlying neurodegeneration, and suggest that cleavage of Tau by caspases represents a negative feedback mechanism aimed to eliminate toxic Tau species. Alternatively, it is possible that either a reduction or an increase in δTau leads to synaptic dysfunction, memory impairments and Tau pathology. Both possibilities will have to be considered when targeting caspase cleavage of Tau in AD therapy.

Download

Citations (3)

... Interestingly, Vitale et al. demonstrated the in vivo feasibility and efficacy of targeting pathological tau in the brain, by employing intramuscular (IM) delivery of vectorized anti-tau scFvMCI. Two different tau transgenic models received a single IM injection of AAV1-scFvMC1, showing a significant reduction of tau pathology and more interestingly even if the scFvMC1 was internalized by the microglia they could not find any inflammatory reactions in the brain [114]. However, understanding the consequence of tau knockdown at adulthood is fundamental to halt pathological tau while preserving healthy tau. ...

Reference:

Advances and Challenges in Gene Therapy for Alzheimer’s Disease
Intramuscular injection of vectorized-scFvMC1 reduces pathological tau in two different tau transgenic models

Acta Neuropathologica Communications

Francesca Vitale

·

·

·

[...]

·

Cristina d’Abramo

... This has spurred a flurry of pre-clinical and clinical trials targeting total tau and pathogenic strains of tau. Pre-clinical immunotherapy trials have found varying levels of success in alleviating tau pathology (hyperphosphorylation, insolubility, tau seeding and spread) and associated behavioral abnormalities (motor, memory) [47][48][49][50][51][52]. Five clinical trials have found evidence of target engagement and have progressed towards Phase 2 efficacy trials [53]. ...

Reference:

Development and characterization of novel anti-acetylated tau monoclonal antibodies to probe pathogenic tau species in Alzheimer’s disease
Anti-tau conformational scFv MC1 antibody efficiently reduces pathological tau species in adult JNPL3 mice

Acta Neuropathologica Communications

Francesca Vitale

·

·

Santiago Ruiz

·

[...]

·

Cristina d’Abramo

... However, these findings often emerge from 262 studies involving transgenic mice or AD patients with abnormal tau hyperphosphorylation. 263Conversely, emerging evidence suggests that TauC3 may have neuroprotective roles under 264 physiological conditions. Some studies report no correlation between TauC3 and NFT formation or 265 cognitive decline in AD (51, 52), while others evidenced that TauC3 may help eliminate toxic tau 266 species or inhibit hyperphosphorylated tau accumulation(53, 54). Voss et al. (55) proposed that 267 TauC3 is likely degraded by autophagy pathways under physiological conditions (56), reducing its 268 seeding potential. ...

Reference:

Sleep-wake variation in body temperature regulates tau secretion and correlates with CSF and plasma tau
Abolishing Tau cleavage by caspases at Aspartate421 causes memory/synaptic plasticity deficits and pre-pathological Tau alterations

Translational Psychiatry

·

C d'Abramo

·

M D Tambini

·

[...]

·