Cheryl Leystra-Lantz

TDP43 is a human low molecular weight neurofilament (hNFL) mRNA-binding protein.

The human TAR DNA-binding protein (TDP43) colocalizes with ubiquitinated inclusions in motor neurons in amyotrophic lateral sclerosis (ALS). TDP43 is both a DNA-binding protein with a nuclear export sequence that interacts with (TG)nTm elements in DNA and an RNA-binding protein that interacts with (UG)(6-12) motifs in single-stranded RNA. In control motor neurons, TDP43 was almost exclusively nuclear, whereas in ALS spinal motor neurons, TDP43 was predominantly localized to the cytosol and not the nucleus. TDP43 was observed as punctuate immunoreactivity and as dense skeins, with and without ubiquitinization. We observed that TDP43 stabilizes the human low molecular weight (hNFL) mRNA through a direct interaction with the 3UTR. TDP43 is a unique hNFL mRNA-binding protein that is altered in its somatotopic localization in ALS spinal motor neurons and potentially contributes to the formation of NF aggregates in ALS through alterations in NF stoichiometry.

Divergent patterns of cytosolic TDP-43 and neuronal progranulin expression following axotomy: Implications for TDP-43 in the physiological response to neuronal injury

We have performed sciatic axotomies in adult C57BL/6 mice and observed TDP-43 and progranulin (PGRN) expression patterns over 28 days. TDP-43 expression was markedly upregulated in axotomized motor neurons, with prominent cytosolic immunoreactivity becoming maximal by post-injury day 7 and returning to baseline levels by post-injury day 28. Increased TDP-43 expression was confirmed by western blot. TDP-43 mRNA expression was also increased. This was inversely correlated with neuronal PGRN expression which was clearly reduced by day 7 with a return to baseline by post-injury day 28. In contrast, microglial PGRN expression was dramatically increased, and correlated with the inflammatory response to axotomy. Cytosolic TDP-43 colocalized with Staufen and TIA-1, markers for RNA transport and stress granules respectively. We did not observe colocalization of TDP-43 or PGRN with degradative granules (P-bodies) or activated caspase 3. These results indicate that TDP-43 expression is altered in response to neuronal injury and that normal expression is restored following recovery. These findings suggest that the upregulation of TDP-43 expression with prominent cytosolic localization in motor neurons injured by degenerative processes such as ALS may actually represent an appropriate response to neuronal injury.

Tar DNA binding protein of 43 kDa (TDP-43), 14-3-3 proteins and copper/zinc superoxide dismutase (SOD1) interact to modulate NFL mRNA stability. Implications for altered RNA processing in amyotrophic lateral sclerosis (ALS)

Amyotrophic lateral sclerosis (ALS) is a fatal neurological disease characterized by progressive motor neuron degeneration in association with neurofilament (NF) aggregate formation. This process is accompanied by an alteration in the stoichiometry of NF subunit protein expression such that the steady state levels of the low molecular weight NF (NFL) mRNA levels are selectively suppressed. We have previously shown that each of TDP-43, 14-3-3 and mutant SOD1 can function as NFL mRNA 3UTR binding proteins that directly affect the stability of NFL transcripts. In this study, we demonstrate that the interaction of TDP-43 with the NFL mRNA 3 UTR involves ribonucleotide (UG) motifs present on stem loops of the 3UTR as well as the RRM1 and RRM2 motifs of TDP-43. Ex vivo, TDP-43, 14-3-3 and SOD1 proteins interact to modulate NFL mRNA stability, although in vivo, only TDP-43 and either mutant or wild-type SOD1 co-localize in ALS motor neurons. TDP-43 was observed to co-localize to RNA transport granules (Staufen immunoreactive) in both control and ALS spinal motor neurons. In contrast, both stress granules (TIA-1 immunoreactive) and processing bodies (P-bodies; XRN-1 immunoreactive) were more prevalent in ALS motor neurons than in controls and demonstrated strong co-localization with TDP-43. Using RNA-IP-PCR, we further demonstrate that NFL mRNA is preferentially sequestered to both stress granules and P-bodies in ALS. These data suggest that NFL mRNA processing is fundamentally altered in ALS spinal motor neurons to favour compartmentalization within both stress granules and P-bodies, and that TDP-43 plays a fundamental role in this process.

Microtubule-associated tau protein positive neuronal and glial inclusions in ALS

Background: The authors compared tau protein deposition in the frontal cortex of patients with cognitive impairment of amyotrophic lateral sclerosis (ALSci) (n = 6), cognitively intact patients with ALS (n = 6), and age-matched controls (n = 6) in order to determine the pathologic substrate of ALSci. Methods: Archival paraffin-embedded tissue was examined using Gallyas staining and immunostaining for tau-1 (phosphorylation-dependent tau epitope), tau-2 (phosphorylation independent), Alzheimer-specific tau phosphoepitopes (AT 8; ser396 phosphorylation), β-amyloid, glial fibrillary acid protein, SMI 31 (recognizing phosphorylated NFH), α-synuclein, or ubiquitin. Results: Tau immunoreactive astrocytic and dense neuronal inclusions were found in both ALS and ALSci, although to a greater extent in ALSci. Superficial linear spongiosis and Gallyas-positive intraneuronal aggregates, immunoreactive with tau-1 and AT 8 but rarely to ser396 tau, were unique to ALSci. Dense extracellular aggregates were observed by both Gallyas staining and tau-1 immunostaining. Tufted degenerating astrocytes containing tau-1 and AT 8 immunoreactive aggregates and, rarely, dense Gallyas positive neuritic plaques immunoreactive with tau-1 and AT 8, but not with ser396 tau or β-amyloid, were observed in ALSci. Tau positive glial coiled bodies were observed in the deep cortical layers and adjacent subcortical white matter in ALSci. Although 3R and 4R tau mRNA isoforms were expressed to similar levels in the frontal cortex of all cases, the total amount of tau mRNA was increased in both ALS and ALSci. Both gray and white matter soluble tau protein expression was similar among control, ALS, and ALSci cases. Conclusions: Cognitive dysfunction in ALS may reflect abnormal tau protein metabolism.

Tau protein hyperphosphorylation in sporadic ALS with cognitive impairment

The authors have characterized frontal cortical tau protein in cognitively intact (4) and cognitively impaired (ALSci, 4) ALS patients and compared it with control (2) or Alzheimer disease (AD, 1)- derived tau. The authors observed expression of both 3R and 4R tau isoforms; increased insoluble tau protein; phosphatase resistance; and hyperphosphorylation at T175, S208, and S210. Soluble tau from both AD and ALSci was also phosphorylated at S237. Tau hyperphosphorylation is associated with ALS.

Upregulation of GSK3β expression in frontal and temporal cortex in ALS with cognitive impairment (ALSci)

The deposition of highly phosphorylated microtubule-associated tau protein has been observed in ALS with cognitive impairment (ALSci). In these studies, we have examined whether the expression of two candidate protein kinases for mediating tau hyperphosphorylation (GSK3beta or CDK5) are also altered. The expression of GSK, CDK and p25/p35 was assayed in human frontal, hippocampal, cerebellar, cervical (dorsal and ventral) and lumbar (dorsal and ventral) tissue from neurologically intact control (5), ALS (5) or ALSci (5) patients using RT-PCR, Western blot or immunohistochemistry. To assess GSK-3beta activity, we examined GSK3beta, phospho-GSK3beta and phospho-beta-catenin expression. Expression levels relative to that of beta-actin were compared by ANOVA. The expression of GSK, GSK3beta and phospho-GSK3beta was increased in both ALS and ALSci compared to that of the control. This was accompanied by an increased expression of phospho-beta-catenin. No significant difference between control, ALS or ALSci was observed with respect to the expression of CDK5 or p25/p35. Both GSK3beta and phospho-GSK3beta immunoreactive neurons were mainly located in layer II and layer III in the frontal cortex and in layer II in the hippocampus. This was consistent with the previously described distribution of hyperphosphorylated tau bearing neurons in ALS and ALSci. These data suggest that GSK3beta expression is upregulated in ALS and ALSci and that GSK3beta activation is associated with the intraneuronal deposition of hyperphosphorylated tau protein. This supports the potential role for GSK3beta as a therapeutic target in ALS.

Calcium mediated excitotoxicity in neurofilament aggregate-bearing neurons in vitro is NMDA receptor dependant

We have previously shown that the co-localization of neuronal nitric oxide synthase (nNOS) with neurofilament (NF) aggregates in motor neurons derived from transgenic mice over-expressing the human low molecular weight NF protein (hNFL+/+) is associated with a deregulation of calcium influx via the N-methyl-d-aspartate (NMDA) receptor, resulting in apoptosis. Because the absence of the GluR2 subunit of the alpha-amino-3-hydroxy-5-methyl-4-isoazolepropionic acid (AMPA) receptor confers calcium permeability and has been implicated in the process of excitotoxicity in ALS, we have examined the role of the AMPA receptor in this model. GluR2 protein expression and mRNA were examined in hNFL+/+ and wild-type motor neurons (wt). Live cell calcium imaging was performed using Oregon-Green Bapta and Fura-2 calcium dyes. For apoptotic studies, neurons were treated with glutamate, with or without glutamate receptor antagonists [6-cyano-7-nitroquinoxaline-2, 3-dione (CNQX) or (+)-5-methyl-10, 11-dihydro-5H-dibenzo[a,d]cyclohepten-5,10-imine maleate (MK-801)] and examined for active caspase-3 or phospholipid inversion. We observed that although both GluR2 mRNA and protein levels were decreased in hNFL+/+ motor neurons compared to wt, there was no appreciable calcium influx via the AMPA receptor. These studies demonstrate that calcium mediated excitotoxicity in NF aggregate-bearing neurons is NMDA receptor dependant.

14-3-3 protein binds to the low molecular weight neurofilament (NFL) mRNA 3' UTR

We have previously reported that altered stability of low molecular weight neurofilament (NFL) mRNA in lumbar spinal cord homogenates in amyotrophic lateral sclerosis (ALS) is associated with altered expression of trans-acting 3 UTR mRNA binding proteins. We have identified two hexanucleotide motifs as the main cis elements and, using LC/MS/MS of peptide digests of NFL 3 UTR interacting proteins from human spinal cord, observed that 14-3-3 proteins interact with these motifs. 14-3-3 beta, zeta, tau, gamma, and eta isoforms were found to be expressed in human spinal cord. Each isoform was expressed in vitro and shown to interact with NFL 3 UTR mRNA. Mutation of one or both motifs resulted in decreased 14-3-3 interaction, changes in predicted mRNA structure or alteration in stability of the mRNA. These data show a novel interaction for 14-3-3 with NFL mRNA, and suggests that 14-3-3 may play a role in regulating NFL mRNA stability.

The complement factor C5a receptor is upregulated in NFL-/- mouse motor neurons.

In NFL-/- mice, a model of motor neuron degeneration in ALS, degenerating spinal motor neurons express high levels of the receptor for the C5a anaphylatoxin (C5aR) early in the disease process. C5a is a potent in vitro neurotoxin for both Neuro2A and NGF-differentiated PC12 cells. While no interaction was observed between glutamate and C5a, both C5a and kainate upregulated the expression of activated C5aR. C5aR expression was increased in motor neurons in ALS. This data suggests that the early upregulation of C5aR may contribute to motor neuron damage that potentiates excitotoxicity in ALS.

Temporal profiles of neuronal degeneration, glial proliferation, and cell death in hNFL(+/+) and NFL(−/−)mice

Neurofilament (NF) aggregate formation within motor neurons is a pathological hallmark of both the sporadic and familial forms of amyotrophic lateral sclerosis (ALS). The relationship between aggregate formation and both microglial and astrocytic proliferation, as well as additional neuropathological features of ALS, is unknown. To examine this, we have used transgenic mice that develop NF aggregates, through either a lack of the low‐molecular‐weight NF subunit [NFL (−/−)] or the overexpression of human NFL [hNFL (+/+)]. Transgenic and wild‐type C57bl/6 mice were examined from 1 month to 18 months of age, and the temporal pattern of motor neuron degeneration, microglial and astrocytic proliferation, and heat shock protein‐70 (HSP‐70) expression characterized. We observed three overlapping phases in both transgenic mice, including transient aggregate formation, reactive microgliosis, and progressive motor neuron loss. However, only NFL (−/−) mice demonstrated significant astrogliosis and HSP‐70 upregulation in both motor neurons and astrocytes. These in vivo models suggest that the development of NF aggregates in motor neurons leads to motor neuron death, but that the interaction between the degenerating motor neurons and the adjacent non‐neuronal cells may differ significantly depending on the etiology of the NF aggregate itself.