Although often considered as a group, spinal motor neurons are highly diverse in terms of their morphology, connectivity, and functional properties and differ significantly in their response to disease. Recent studies of motor neuron diversity have clarified developmental mechanisms and provided novel insights into neurodegeneration in amyotrophic lateral sclerosis (ALS). Motor neurons of different classes and subtypes--fast/slow, alpha/gamma--are grouped together into motor pools, each of which innervates a single skeletal muscle. Distinct mechanisms regulate their development. For example, glial cell line-derived neurotrophic factor (GDNF) has effects that are pool-specific on motor neuron connectivity, column-specific on axonal growth, and subtype-specific on survival. In multiple degenerative contexts including ALS, spinal muscular atrophy (SMA), and aging, fast-fatigable (FF) motor units degenerate early, whereas motor neurons innervating slow muscles and those involved in eye movement and pelvic sphincter control are strikingly preserved. Extrinsic and intrinsic mechanisms that confer resistance represent promising therapeutic targets in these currently incurable diseases.
SUMMARY
Selective neuronal loss is the hallmark of neurodegenerative diseases. In patients with amyotrophic lateral sclerosis (ALS), most motor neurons die but those innervating extraocular, pelvic sphincter and slow limb muscles exhibit selective resistance. We identified 18 genes that show >10-fold differential expression between resistant and vulnerable motor neurons. One of these, matrix metalloproteinase-9 (MMP-9), is expressed only by fast motor neurons, which are selectively vulnerable. In ALS model mice expressing mutant SOD1, reduction of MMP-9 function using gene ablation, viral gene therapy or pharmacological inhibition significantly delayed muscle denervation. In the presence of mutant SOD1, MMP-9 expressed by fast motor neurons themselves enhances activation of ER stress and is sufficient to trigger axonal die-back. These findings define MMP-9 as a candidate therapeutic target for ALS. The molecular basis of neuronal diversity thus provides novel insights into mechanisms of selective vulnerability to neurodegeneration.
Retroviral Gag proteins perform important functions in viral assembly, but are also involved in other steps in the viral life cycle. Conventional mutational analysis has yielded considerable information about domains essential for these functions, yet many regions of gag remain uncharacterized. We used genetic footprinting, a technique that permits the generation and simultaneous analysis of large numbers of mutations, to perform a near-saturation mutagenesis and functional analysis of 639 nucleotides in the gag region of Moloney murine leukemia virus. We report here the resulting functional map defined by eight footprints representing regions of Moloney murine leukemia virus gag, some previously uncharacterized, that are essential for replication. We found that significant portions of matrix and p12 proteins were tolerant of insertions, in contrast to the N-terminal half of capsid, which was not. We analyzed 30 mutants from our library by using conventional methods to validate the footprints. Six of these mutants were characterized in detail, identifying the precise stage at which their replication is blocked. In addition to providing the most comprehensive functional map of a retroviral gag gene, our study demonstrates the abundance of information that can be gleaned by genetic footprinting of viral sequences.
Reasons for therapeutic failure in CIDP are inadequate immunotherapy and alternative diagnoses. Certain clinical and electrophysiological features help to distinguish true CIDP from mimics. Once CIDP is confirmed, optimization of IVIg dosing, addition of corticosteroids, plasmapheresis, or chemotherapy results in consistent improvement. Caution is advised when using response to therapy to diagnose CIDP. Muscle Nerve 55: 476-482, 2017.
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