Yunhong Bai

Curcumin derivatives promote Schwann cell differentiation and improve neuropathy in R98C CMT1B mice

Charcot-Marie-Tooth disease type 1B is caused by mutations in myelin protein zero. R98C mice, an authentic model of early onset Charcot-Marie-Tooth disease type 1B, develop neuropathy in part because the misfolded mutant myelin protein zero is retained in the endoplasmic reticulum where it activates the unfolded protein response. Because oral curcumin, a component of the spice turmeric, has been shown to relieve endoplasmic reticulum stress and decrease the activation of the unfolded protein response, we treated R98C mutant mice with daily gastric lavage of curcumin or curcumin derivatives starting at 4 days of age and analysed them for clinical disability, electrophysiological parameters and peripheral nerve morphology. Heterozygous R98C mice treated with curcumin dissolved in sesame oil or phosphatidylcholine curcumin performed as well as wild-type littermates on a rotarod test and had increased numbers of large-diameter axons in their sciatic nerves. Treatment with the latter two compounds also increased compound muscle action potential amplitudes and the innervation of neuromuscular junctions in both heterozygous and homozygous R98C animals, but it did not improve nerve conduction velocity, myelin thickness, G-ratios or myelin period. The expression of c-Jun and suppressed cAMP-inducible POU (SCIP)-transcription factors that inhibit myelination when overexpressed-was also decreased by treatment. Consistent with its role in reducing endoplasmic reticulum stress, treatment with curcumin dissolved in sesame oil or phosphatidylcholine curcumin was associated with decreased X-box binding protein (XBP1) splicing. Taken together, these data demonstrate that treatment with curcumin dissolved in sesame oil or phosphatidylcholine curcumin improves the peripheral neuropathy of R98C mice by alleviating endoplasmic reticulum stress, by reducing the activation of unfolded protein response and by promoting Schwann cell differentiation.

Major myelin protein gene (P0) mutation causes a novel form of axonal degeneration.

Mutations in the major peripheral nervous system (PNS) myelin protein, myelin protein zero (MPZ), cause Charcot‐Marie‐Tooth Disease type 1B (CMT1B), typically thought of as a demyelinating peripheral neuropathy. Certain MPZ mutations, however, cause adult onset neuropathy with minimal demyelination but pronounced axonal degeneration. Mechanism(s) for this phenotype are unknown. We performed an autopsy of a 73‐year‐old woman with a late‐onset neuropathy caused by an H10P MPZ mutation whose nerve conduction studies suggested severe axonal loss but no demyelination. The autopsy demonstrated axonal loss and reorganization of the molecular architecture of the axolemma. Segmental demyelination was negligible. In addition, we identified focal nerve enlargements containing MPZ and ubiquitin either in the inner myelin intralaminar and/or periaxonal space that separates axons from myelinating Schwann cells. Taken together, these data confirmed that a mutation in MPZ can cause axonal neuropathy, in the absence of segmental demyelination, thus uncoupling the two pathological processes. More important, it also provided potential molecular mechanisms as to how the axonal degeneration occurred: either by disruption of glial–axon interaction by protein aggregates or by alterations in the molecular architecture of internodes and paranodes. This report represents the first study in which the molecular basis of axonal degeneration in the late‐onset CMT1B has been explored in human tissue. J. Comp. Neurol. 498:252–265, 2006.

Conduction Block in PMP22 Deficiency

Patients with PMP22 deficiency present with focal sensory and motor deficits when peripheral nerves are stressed by mechanical force. It has been hypothesized that these focal deficits are due to mechanically induced conduction block (CB). To test this hypothesis, we induced 60–70% CB (defined by electrophysiological criteria) by nerve compression in an authentic mouse model of hereditary neuropathy with liability to pressure palsies (HNPP) with an inactivation of one of the two pmp22 alleles (pmp22+/−). Induction time for the CB was significantly shorter in pmp22+/− mice than that in pmp22+/+ mice. This shortened induction was also found in myelin-associated glycoprotein knock-out mice, but not in the mice with deficiency of myelin protein zero, a major structural protein of compact myelin. Pmp22+/− nerves showed intact tomacula with no segmental demyelination in both noncompressed and compressed conditions, normal molecular architecture, and normal concentration of voltage-gated sodium channels by [3H]-saxitoxin binding assay. However, focal constrictions were observed in the axonal segments enclosed by tomacula, a pathological hallmark of HNPP. The constricted axons increase axial resistance to action potential propagation, which may hasten the induction of CB in Pmp22 deficiency. Together, these results demonstrate that a function of Pmp22 is to protect the nerve from mechanical injury.

Distinct pathogenic processes between Fig4-deficient motor and sensory neurons.

Loss of function of the FIG4 gene causes Charcot‐Marie‐Tooth disease (CMT)‐4J with many features also found in motor neuron disease (MND). Mechanisms for the degeneration are unknown. We investigated this using Fig4‐deficient pale tremor (plt) mice, a mouse model of CMT4J. Ultrastructural studies in sensory neurons of dorsal root ganglion (DRG) confirmed abundant vacuoles with membrane disruption. The vacuoles became detectable as early as postnatal day 4 in the DRG. However, the vacuoles were absent or minimal in the spinal motor neurons or cortical neurons in 2‐ to 5‐week‐old plt mice. Instead, a large number of electron‐dense organelles, reminiscent of those in lysosomal storage disorders, accumulated in the motor neurons, but not in the sensory neurons of DRG. This accumulation was associated with increased levels of lysosomal proteins, such as LAMP2 and NPC1, but not mannose‐6‐phosphate receptor, an endosomal protein that is usually excluded from the lysosomes. Our results suggest that Fig4 deficiency affects motor neurons differently from sensory neurons by mechanisms involving excessive retention of molecules in lysosomes or disruption of vacuolated organelles. These two distinct pathological changes may contribute to neuronal degeneration.

Demyelinating CMT–what’s known, what’s new and what’s in store?

Inherited neuropathies known collectively as Charcot-Marie-Tooth disease are one of the most common inherited neurological conditions affecting ∼1 in 2500 people. A heterogenous disorder, CMT is divided into subtypes based on the pattern of inheritance and also by neurophysiological studies. Despite the clinical similarities among patients with demyelinating CMT, it is recognized that this group of disorders is both genetically and phenotypically heterogenous. Understanding the pathogenesis of these disorders requires an intimate knowledge of normal myelin development and homeostasis. Improvements in genetic testing techniques over the last 20 years have contributed majorly to the identification of specific genes, proteins, and molecular pathways that are providing the basis for understanding the disease processes and developing rational approaches to therapy.

Absence of Dystrophin Related Protein-2 disrupts Cajal bands in a patient with Charcot–Marie–Tooth disease

Using exome sequencing in an individual with Charcot-Marie-Tooth disease (CMT) we have identified a mutation in the X-linked dystrophin-related protein 2 (DRP2) gene. A 60-year-old gentleman presented to our clinic and underwent clinical, electrophysiological and skin biopsy studies. The patient had clinical features of a length dependent sensorimotor neuropathy with an age of onset of 50 years. Neurophysiology revealed prolonged latencies with intermediate conduction velocities but no conduction block or temporal dispersion. A panel of 23 disease causing genes was sequenced and ultimately was uninformative. Whole exome sequencing revealed a stop mutation in DRP2, c.805C>T (Q269*). DRP2 interacts with periaxin and dystroglycan to form the periaxin-DRP2-dystroglycan complex which plays a role in the maintenance of the well-characterized Cajal bands of myelinating Schwann cells. Skin biopsies from our patient revealed a lack of DRP2 in myelinated dermal nerves by immunofluorescence. Furthermore electron microscopy failed to identify Cajal bands in the patients dermal myelinated axons in keeping with ultrastructural pathology seen in the Drp2 knockout mouse. Both the electrophysiologic and dermal nerve twig pathology support the interpretation that this patients DRP2 mutation causes characteristic morphological abnormalities recapitulating the Drp2 knockout model and potentially represents a novel genetic cause of CMT.

Reduced neurofilament expression in cutaneous nerve fibers of patients with CMT2E

Objective: To investigate the effects of NEFL Glu396Lys mutation on the expression and assembly of neurofilaments (NFs) in cutaneous nerve fibers of patients with Charcot-Marie-Tooth disease type 2E (CMT2E). Methods: A large family with CMT2E underwent clinical, electrophysiologic, and skin biopsy studies. Biopsies were processed by indirect immunofluorescence (IF), electron microscopy (EM), and Western blot analysis. Results: The clinical features demonstrated intrafamilial phenotypic variability, and the electrophysiologic findings revealed nerve conductions that were either slow or in the intermediate range. All patients had reduced or absent compound muscular action potential amplitudes. Skin biopsies showed axons labeled with the axonal markers protein gene product 9.5 and α-tubulin, but not with NFs. The results of Western blot analysis were consistent with those of IF, showing reduced or absent NFs and normal expression of α-tubulin. EM revealed clusters of regenerated fibers, in absence of myelin sheath abnormalities. Both IF and EM failed to show NF aggregates in dermal axons. The morphometric analysis showed a smaller axonal caliber in patients than in controls. The study of the nodal/paranodal architecture demonstrated that sodium channels and Caspr were correctly localized in patients with CMT2E. Conclusions: Decrease in NF abundance may be a pathologic marker of CMT2E. The lack of NF aggregates, consistent with prior studies, suggests that they occur proximally leading to subsequent alterations in the axonal cytoskeleton. The small axonal caliber, along with the normal molecular architecture of nodes and paranodes, explain the reduced velocities detected in patients with CMT2E. Our results also demonstrate that skin biopsy can provide evidence of pathologic and pathogenic abnormalities in patients with CMT2E.

Unfolded protein response, treatment and CMT1B.

CMT1B is the second most frequent autosomal dominant inherited neuropathy and is caused by assorted mutations of the myelin protein zero (MPZ) gene. MPZ mutations cause neuropathy gain of function mechanisms that are largely independent MPZs normal role of mediating myelin compaction. Whether there are only a few or multiple pathogenic mechanisms that cause CMT1B is unknown. Arg98Cys and Ser63Del MPZ are two CMT1B causing mutations that have been shown to cause neuropathy in mice at least in part by activating the unfolded protein response (UPR). We have recently treated Arg98Cys mice with derivatives of curcumin that improved the neuropathy and reduced UPR activation.1 Future studies will address whether manipulating the UPR will be a common or rare strategy for treating CMT1B or other forms of inherited neuropathies.

Trauma does not accelerate neuronal degeneration in Fig4 insufficient mice.

Fig4 null reduces phosphatidylinositol-3,5-diphosphate concentration and causes severe neuronal degeneration in both pale-tremor (plt) mice and patients with Charcot-Marie-Tooth disease type 4J (CMT4J), an inherited condition with recessive mutations in FIG4. Our previous study shows that minor trauma is associated with an accelerated course of motor neuron degeneration in patients with CMT4J. Heterozygous loss of FIG4 function has been suggested to be a risk factor in developing sporadic amyotrophic lateral sclerosis. We therefore hypothesize that minor trauma may trigger or exacerbate motor neuron degeneration in mice with fig4 haploinsufficiency (plt+/-). We have studied 18 wild-type and 18 plt+/- mice and created nerve injury by compressing the sciatic nerve. Outcomes in the mice were evaluated by nerve conduction study, Rotarod, and nerve morphology. No differences were found between wild-type and plt+/- mice. Taken together, our results demonstrate that haploinsufficiency of fig4 does not impose risks in rodents to develop neuronal degeneration in either naïve or traumatic conditions.