Inorganic mercury in human astrocytes, oligodendrocytes, corticomotoneurons and the locus ceruleus: implications for multiple sclerosis, neurodegenerative disorders and gliomas

Neurotoxic metals have been implicated in the pathogenesis of multiple sclerosis, neurodegenerative disorders and brain tumours but studies of the location of heavy metals in human brains are rare. In a man who injected himself with metallic mercury the cellular location of mercury in his brain was studied after 5 months of continuous exposure to inorganic mercury arising from metallic mercury deposits in his organs. Paraffin sections from the primary motor and sensory cortices and the locus ceruleus in the pons were stained with autometallography to detect inorganic mercury and combined with glial fibrillary acidic protein immunohistochemistry to identify astrocytes. Inorganic mercury was found in grey matter subpial, interlaminar, protoplasmic and varicose astrocytes, white matter fibrous astrocytes, grey but not white matter oligodendrocytes, corticomotoneurons and some locus ceruleus neurons. In summary, inorganic mercury is taken up by five types of human brain astrocytes, as well as by cortical oligodendrocytes, corticomotoneurons and locus ceruleus neurons. Mercury can induce oxidative stress, stimulate autoimmunity and damage DNA, mitochondria and lipid membranes, so its location in these CNS cells suggests it could play a role in the pathogenesis of multiple sclerosis, neurodegenerative conditions such as Alzheimer's disease and amyotrophic lateral sclerosis, and glial tumours.

Motor cortical dysfunction develops in spinocerebellar ataxia type 3

OBJECTIVE

Spinocerebellar ataxia type 3 (SCA3) is an inherited neurodegenerative disorder characterized by cerebellar ataxia and variable expression of clinical features beyond the cerebellum. To gain further insights into disease pathophysiology, the present study explored motor cortex function in SCA3 to determine whether cortical dysfunction was present and if this contributed to the development of clinical manifestations.

METHODS

Clinical phenotyping and longitudinal assessments were combined with central (threshold-tracking transcranial magnetic stimulation) and peripheral (nerve excitability) techniques in 11 genetically characterized SCA3 patients.

RESULTS

Short-interval intracortical inhibition was significantly reduced in presymptomatic and symptomatic SCA3 patients (-1.3±1.4%) compared to healthy controls (10.3±0.7%, P<0.0005), with changes evident prior to clinical onset of ataxia and related to worsening severity (R=-0.78, P<0.005). Central motor conduction time was also significantly prolonged in presymptomatic and symptomatic SCA3 patients (7.5±0.4ms) compared to healthy controls (5.3±0.2ms, P<0.0005) and related to clinical severity (R=0.81, P<0.005). Markers of peripheral motor neurodegeneration and excitability did not correlate with cortical hyperexcitability or ataxia.

CONCLUSIONS

Simultaneous investigation of clinical status, and central and peripheral nerve function has identified progressive cortical dysfunction in SCA3 patients related to the development of ataxia.

SIGNIFICANCE

These findings suggest alteration in cortical activity is associated with SCA3 pathogenesis and neurodegeneration.