The inconsistency and instability of Parkinson's disease motor subtypes.

INTRODUCTION: Tremor-dominant (TD), indeterminate/mixed (ID/M) and postural instability gait difficulty/akinetic-rigid (PIGD/AR) are commonly used subtypes to categorize Parkinson's disease (PD) patients based on their most prominent motor signs. Three different algorithms to determine these motor subtypes are used. Here, we examined if PD subtypes are consistent among algorithms and if subtype stability over time depends on the applied algorithm. METHODS: Using a large longitudinal PD database, we applied 3 published algorithms of PD motor subtype classification in two sets of analyses: 1) cross-sectional analysis in 1185 patients, determining the prevalence of subtypes in 5-year intervals of disease duration; 2) longitudinal analysis of 178 patients, comparing subtypes of individual patients at baseline (within 5 years of diagnosis) and at follow-up ≥ 5 years after baseline. RESULTS: Cross-sectionally, prevalence of subtypes varied widely among the 3 algorithms: 5-32% TD, 9-31% ID/M, and 59-75% PIGD/AR. For all 3 algorithms, cross-sectional analysis showed a marked decline of TD prevalence with disease duration and a corresponding increase in PIGD/AR prevalence, driven by increasing gait/balance scores over time. Longitudinally, only 15-36% of baseline TD patients were still categorized as TD at 6.2 ± 1.0 years of follow-up. In 15-39% of baseline TD patients, the subtype changed to ID/M, and 46-50% changed to PIGD/AR. This shift was observed using all 3 algorithms. CONCLUSION: PD motor subtypes determined by different established algorithms are inconsistent and unstable over time. Lack of subtype fidelity should be considered when interpreting biomarker-subtype correlation and highlights the need for better definition of PD subtypes.

Delivery of recombinant tetanus-superoxide dismutase proteins to central nervous system neurons by retrograde axonal transport.

The nontoxic C fragment of tetanus toxin (TC) can transport other proteins from the circulation to central nervous system (CNS) motor neurons. Increased levels of CuZn superoxide dismutase (SOD) are protective in experimental models of stroke and Parkinson's disease, whereas mutations in SOD can cause motor neuron disease. We have linked TC to SOD and purified the active recombinant proteins in both the TC-SOD and SOD-TC orientations. Light microscopic immunohistochemistry and quantitative enzyme-linked immunosorbant assays (ELISA) of mouse brainstem, after intramuscular injection, demonstrate that the fusion proteins undergo retrograde axonal transport and transsynaptic transfer as efficiently as TC alone.

Molecular cloning of TOPAP: a topographically graded protein in the developing chick visual system.

Topographically graded molecules representing position-specific differences among otherwise similar cells are thought to play a role in the patterning of the developing nervous system. In the embryonic chick visual system, a 40 kDa protein, TOPAP, is expressed in a posterior > anterior gradient in the retina and in an inverted anterior > posterior gradient in the optic tectum, the major retinal projection area. Here we report the isolation and nucleotide sequencing of a complementary DNA clone encoding the chick TOPAP protein and demonstrate that the mRNA encoding this coiled-coil integral membrane protein is topographically graded within the retina and is present in a variety of chick tissues.

Enhanced CNS uptake of systemically administered proteins through conjugation with tetanus C-fragment.

No other exogenous protein enters the central nervous system from the circulation as readily as tetanus toxin. We examined the capability of the non-toxic binding fragment of tetanus toxin (C-Fragment) so serve as a vehicle for transport of other proteins into the mouse CNS. Using periodate oxidation of the enzyme horseradish peroxidase (HRP), we synthesized two separate macromolecular complexes, one containing C-fragment and HRP, and the other C-fragment, HRP and a third "test" protein-human IgG. The distribution of C-fragment-HRP was typical of blood borne proteins including native C-fragment, with labeling of all neurons with known projections outside the blood-brain barrier, particularly large spinal motoneurons. C-fragment-HRP conjugates showed superior neuronal labeling to over 100-fold greater quantities of free HRP. Complexes containing C-fragment, HRP and human IgG were internalized by neurons from both intramuscular and intraperitoneal injections. The efficiency of neuronal uptake of IgG in the C-fragment conjugated form was enhanced over 40-fold compared to free IgG. Linkage of a large protein to C-fragment probably leads to enhanced endocytosis of that protein by neuronal terminals projecting outside the blood-brain barrier. C-fragment can serve as a vehicle to allow selected proteins to bypass the barrier and enter the CNS.

Transsynaptic transfer of retrogradely transported tetanus protein-peroxidase conjugates.

Tetanus toxin and its atoxic binding fragment, C-fragment (CF), are the only known proteins which undergo extensive transfer from motoneurons to presynaptic terminals in the spinal cord. Intramuscular injection of CF conjugated to horseradish peroxidase (HRP) was used to elucidate the ultrastructural basis for this unique property. Motoneurons labeled by retrograde axonal transport contained enzymatic reaction product within cytoplasmic vesicles and were surrounded by presynaptic terminals with label in the synaptic cleft and synaptic vesicles. Membranous structures on both sides of the synapse remained labeled for several days after the injection. Nonsynaptic regions were virtually free of CF-HRP. Transport of CF may reflect the movement of the tetanus toxin receptor in a unique synaptic compartment.

Selective localization by neuroglia of immunoglobulin G in normal mice.

Plasma proteins including immunoglobulins have been previously localized in neurons with processes extending outside the blood-brain barrier, but not within glia under normal conditions. Immune modulating functions have been proposed for both microglia and astrocytes in several pathological states. Using immunocytochemistry, we have found that large numbers of neuroglial cells contain immunoglobulin G (IgG) in normal mice of the C57 BL/6 strain. Most IgG-positive cells had both the morphology and distribution of microglia, including a higher density in grey matter, and were frequently found in perivascular or perineuronal locations. The accumulation of IgG does not appear to be by nonselective phagocytosis of extracellular fluid, since serum albumin could not be detected within microglia. There was little overlap in the distribution of cellular processes positive for IgG and those which showed astrocytic markers. Neuronal accumulation of plasma proteins was also seen in a distribution described by previous investigators. The function of this selective accumulation of IgG by normal microglia is unknown, but may reflect a role in the immune response within the central nervous system.

The development of amine substituted analogues of MPTP as unique tools for the study of MPTP toxicity and Parkinson's disease.

We are currently developing amino-substituted MPTP analogues as useful probes for understanding the mechanism of MPTP toxicity and Parkinson's disease. One analogue, 4'-amino MPTP, induces a loss of striatal dopamine and is thus a suitable substitute for MPTP. This probe will be used as a histologically fixable MPTP which can be used to answer detailed anatomical questions concerning the sites of MPTP, MPP+ uptake and storage. In addition, antibodies have been raised against MPTP and MPP+ in rabbits using diazo-linked bovine serum albumin conjugates. The antibodies have been characterized with regard to their recognition of relevant structural analogues using an enzymelinked immunoassay (ELISA) procedure. Antibodies to MPTP detected MPTP in mouse brain extracts derived from as little as 5 micrograms of tissue. The antibodies will be used for immunohistochemical localization of 4'-NH2-MPTP and 4'-NH2-MPP+ in brain, as well as probes for the screening of parkinsonian brain tissue for any MPTP- or MPP+-like materials which might exist.

Corticotropin releasing factor-like immunoreactivity in sensory ganglia and capsaicin sensitive neurons of the rat central nervous system: colocalization with other neuropeptides.

Immunohistochemistry and radioimmunoassay (RIA) revealed that corticotropin releasing factor (CRF)-like immunoreactivity was found to be colocalized with substance P (SP)-, somatostatin (SST)- and leu-enkephalin (LENK)-like immunoreactivity in the dorsal root- and trigeminal ganglia, the dorsal horn of the spinal cord (laminae I and II), the substantia gelatinosa, and at the lateral border of the spinal nucleus and in the tractus spinalis of the trigeminal nerve. These peptides were also located in fast blue labeled cells of the trigeminal ganglion following injection of the dye into the spinal trigeminal area. This indicates that there are possible sensory projections of these peptides into the spinal trigeminal area. Capsaicin treatment of neonatal rats resulted in a marked decrease in the density of CRF-, SP-, VIP- and CCK-containing neurons in the above mentioned hindbrain areas, whereas SST- and LENK-immunoreactivity were not changed. RIA revealed that, compared to controls, CRF, SP and VIP concentrations in these areas were decreased in rats pretreated with capsaicin, while SST levels were increased; CCK and LENK levels were unchanged. It is concluded that the primary afferent neurons of the nucleus and tractus spinalis of the trigeminal nerve are richly endowed with a number of peptides some of which are sensitive to capsaicin action. The close anatomical proximity of these peptide containing neurons suggests the possibility of a coexistance of one or more of these substances.

Suggestive evidence for a functional unit between mast cells and substance P fibers in the rat diaphragm and mesentery.

A close spatial relationship between serotonin-containing mast cells and substance P-containing nerves was shown by immunohistochemistry using a combination of antisera specific for serotonin and substance P. This supports earlier morphological results suggesting an innervation of mast cells and pharmacological studies which postulate an influence of substance P on the release of histamine from mast cells.