Hepatic arginase deficiency fosters dysmyelination during postnatal CNS development
Xiao-Bo Liu, Jillian R. Haney, Gloria Cantero, Jenna R. Lambert, Marcos Otero-Garcia, Brian Truong, Andrea Gropman, Inma Cobos, Stephen D. Cederbaum, Gerald S. Lipshutz
Xiao-Bo Liu, Jillian R. Haney, Gloria Cantero, Jenna R. Lambert, Marcos Otero-Garcia, Brian Truong, Andrea Gropman, Inma Cobos, Stephen D. Cederbaum, Gerald S. Lipshutz
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Research Article Neuroscience

Hepatic arginase deficiency fosters dysmyelination during postnatal CNS development

Abstract

Deficiency of arginase is associated with hyperargininemia, and prominent features include spastic diplegia/tetraplegia, clonus, and hyperreflexia; loss of ambulation, intellectual disability and progressive neurological decline are other signs. To gain greater insight into the unique neuromotor features, we performed gene expression profiling of the motor cortex of a murine model of the disorder. Coexpression network analysis suggested an abnormality with myelination, which was supported by limited existing human data. Utilizing electron microscopy, marked dysmyelination was detected in 2-week-old homozygous Arg1-KO mice. The corticospinal tract was found to be adversely affected, supporting dysmyelination as the cause of the unique neuromotor features and implicating oligodendrocyte impairment in a deficiency of hepatic Arg1. Following neonatal hepatic gene therapy to express Arg1, the subcortical white matter, pyramidal tract, and corticospinal tract all showed a remarkable recovery in terms of myelinated axon density and ultrastructural integrity with active wrapping of axons by nearby oligodendrocyte processes. These findings support the following conclusions: arginase deficiency is a leukodystrophy affecting the brain and spinal cord while sparing the peripheral nervous system, and neonatal AAV hepatic gene therapy can rescue the defects associated with myelinated axons, strongly implicating the functional recovery of oligodendrocytes after restoration of hepatic arginase activity.

Authors

Xiao-Bo Liu, Jillian R. Haney, Gloria Cantero, Jenna R. Lambert, Marcos Otero-Garcia, Brian Truong, Andrea Gropman, Inma Cobos, Stephen D. Cederbaum, Gerald S. Lipshutz

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Figure 4

Analysis demonstrates distribution of myelinated axon fibers in the subcortical white matter of the motor cortex of P15 Arg1-deficient mice to be greatly reduced with Arg1 deficiency and restored with hepatic gene therapy.

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Analysis demonstrates distribution of myelinated axon fibers in the subc...
(A) Diagram with corticospinal tract illustrated. Representative regions that were examined are displayed: motor cortex with layer V pyramidal neurons and their descending axons; medulla, pyramidal tract; cervical segment of spinal cord, corticospinal tract in dorsal funiculus. (B) Assessment of myelination in subcortical white matter of the motor cortex. WT (top) image shows many differently sized myelinated axons; myelin sheath thickness is variable among fibers. WT (bottom) shows higher-magnification image (4,000×). Arg1-KO (top) Image shows only a few axon profiles. Note in the middle is a degenerated axon; another axon with a thin myelin sheath layer is adjacent. Arg1-KO (bottom) shows higher-power view with some fragments of myelin sheath debris; a vacuolar structure (vo) is associated with a degenerated axon indicating debris engulfment (5,000×). One thin myelinated axon (ax) and unmyelinated axon (nax) are closely associated with the degenerated axon. Treated Arg1-KO (top) image shows a significant number of myelinated axons. Treated Arg1-KO (bottom) shows high-power (5,000×) normal axonal features and myelin sheath layers. Scale bars: 2 μm. (C) Micrograph showing electron-dense oligodendrocyte soma (oligo) and a major process wrapping axon fibers (arrows); insets demonstrate the processes tightly enclosing axons. Scale bar: 2 μm and 1 μm [insets]) (D) Density comparison of myelinated axons in subcortical white matter of the Arg1 genotypes. WT has the highest density; untreated KO has the lowest. Treated KO shows remarkable recovery and has the second highest density. Het group shows lower density compared with the WT and treated KO group. P values determined by one-way ANOVA with Tukey’s multiple comparisons. Error bars represent SD. (KO = knockout, Het = heterozygote) (n = 3 per genotype group)