ENGRAILED-1 transcription factor has a paracrine neurotrophic activity on adult spinal α-motoneurons

Several homeoprotein transcription factors transfer between cells and regulate gene expression, protein translation, and chromatin organization in recipient cells. ENGRAILED-1 is one such homeoprotein expressed in spinal V1 interneurons that synapse on α-motoneurons. Neutralizing extracellular ENGRAILED-1 by expressing a secreted single-chain antibody blocks its capture by spinal motoneurons resulting in α-motoneuron loss and limb weakness. A similar but stronger phenotype is observed in the Engrailed-1 heterozygote mouse, confirming that ENGRAILED-1 exerts a paracrine neurotrophic activity on spinal cord α-motoneurons. Intrathecal injection of ENGRAILED-1 leads to its specific internalization by spinal motoneurons and has long-lasting protective effects against neurodegeneration and weakness. Midbrain dopaminergic neurons express Engrailed-1 and, similarly to spinal cord α-motoneurons, degenerate in the heterozygote. We identify genes expressed in spinal cord motoneurons whose expression changes in mouse Engrailed-1 heterozygote midbrain neurons. Among these, p62/SQSTM1 shows increased expression during aging in spinal cord motoneurons in the Engrailed-1 heterozygote and upon extracellular ENGRAILED-1 neutralization. We conclude that ENGRAILED-1 might regulate motoneuron aging and has non-cell-autonomous neurotrophic activity.

OTX2 stimulates adult retinal ganglion cell regeneration

Retinal ganglion cell (RGC) axons provide the only link between the light sensitive and photon transducing neural retina and visual centers of the brain. RGC axon degeneration occurs in a number of blinding diseases and the ability to stimulate axon regeneration from surviving ganglion cells could provide the anatomic substrate for restoration of vision. OTX2 is a homeoprotein transcription factor expressed in the retina and previous studies showed that, in response to stress, exogenous OTX2 increases the in vitro and in vivo survival of RGCs. Here we examined and quantified the effects of OTX2 on adult RGC axon regeneration in vitro and in vivo. The results show that exogenous OTX2 stimulates the regrowth of axons from RGCs in cultures of dissociated adult retinal cells and from explants of adult retinal tissue and that RGCs respond directly to OTX2 as regrowth is observed in cultures of purified adult rat RGCs. Importantly, after nerve crush in vivo, we observed a positive effect of OTX2 on the number of regenerating axons up to the optic chiasm within 14 days post crush and a very modest level of acuity absent in control mice. The effect of OTX2 on RGC survival and regeneration is of potential interest for degenerative diseases affecting this cell type. All animal procedures were approved by the local “Comié d’éιthique en expérimentation animale n°59” and authorization n° 00702.01 delivered March 28, 2014 by the French “Ministére de l’enseignement supérieur et de la recherche”.

The Physiology of Homeoprotein Transduction

The homeoprotein family comprises ~300 transcription factors and was long seen as primarily involved in developmental programs through cell autonomous regulation. However, recent evidence reveals that many of these factors are also expressed in the adult where they exert physiological functions not yet fully deciphered. Furthermore, the DNA-binding domain of most homeoproteins contains two signal sequences allowing their secretion and internalization, thus intercellular transfer. This review focuses on this new-found signaling in cell migration, axon guidance, and cerebral cortex physiological homeostasis and speculates on how it may play important roles in early arealization of the neuroepithelium. It also describes the use of homeoproteins as therapeutic proteins in mouse models of diseases affecting the central nervous system, in particular Parkinson disease and glaucoma.

Distinct roles of homeoproteins in brain topographic mapping and in neural circuit formation

The construction of the brain is a highly regulated process, requiring coordination of various cellular and molecular mechanisms that together ensure the stability of the cerebrum architecture and functions. The mature brain is an organ that performs complex computational operations using specific sensory information from the outside world and this requires precise organization within sensory networks and a separation of sensory modalities during development. We review here the role of homeoproteins in the arealization of the brain according to sensorimotor functions, the micropartition of its cytoarchitecture, and the maturation of its sensory circuitry. One of the most interesting observation about homeoproteins in recent years concerns their ability to act both in a cell-autonomous and non-cell-autonomous manner. The highlights in the present review collectively show how these two modes of action of homeoproteins confer various functions in shaping cortical maps.

Graded Otx2 activities demonstrate dose-sensitive eye and retina phenotypes

In the human, mutations of OTX2 (Orthodenticle homeobox 2 transcription factor) translate into eye malformations of variable expressivity (even between the two eyes of the same individual) and incomplete penetrance, suggesting the existence of subtle thresholds in OTX2 activity. We have addressed this issue by analyzing retinal structure and function in six mutant mice with graded Otx2 activity: Otx2(+/+), Otx2(+/AA), Otx2(+/GFP), Otx2(AA/AA), Otx2(AA/GFP) and Otx2(GFP/GFP). Null mice (Otx2(GFP/GFP)) fail to develop the head and are embryonic lethal, and compound heterozygous Otx2(AA/GFP) mice show a truncated head and die at birth. All other genotypes develop until adulthood. We analyzed eye structure and visual physiology in the genotypes that develop until adulthood and report that phenotype severity parallels Otx2 activity. Otx2(+/AA) are only mildly affected whereas Otx2(+/GFP) are more affected than Otx2(+/AA) but less than Otx2(AA/AA) mice. Otx2(AA/AA) mice later manifest the most severe defects, with variable expressivity. Electrophysiological and histological analyses of the mouse retina revealed progressive death of bipolar cells and cone photoreceptors that is both Otx2 activity- and age-dependent with the same ranking of phenotypic severity. This study demonstrates the importance of gene dosage in the development of age-dependent pathologies and underscores the fact that small gene dosage differences can cause significant pathological states.

Homeoprotein signaling in development, health, and disease: a shaking of dogmas offers challenges and promises from bench to bed

Homeoproteins constitute a major class of transcription factors active throughout development and in adulthood. Their membrane transduction properties were discovered over 20 years ago, opening an original field of research in the domain of vector peptides and signal transduction. In early development, homeoprotein transfer participates in tissue patterning, cell/axon guidance, and migration. In the axon guidance model, homeoproteins exert their non-cell autonomous activity through the regulation of translation, in particular, that of nuclear-transcribed mitochondrial mRNAs. An important aspect of these studies on patterning and migration is that homeoproteins sensitize the cells to the action of other growth factors, thus cooperating with established signaling pathways. The role of homeoprotein signaling at later developmental stages is also of interest. In particular, the transfer of homeoprotein Otx2 into parvalbumin-expressing inhibitory neurons (PV-cells) in the visual cortex regulates cortical plasticity. The molecular deciphering of the interaction of Otx2 with binding sites at the surface of PV-cells has allowed the development of a specific Otx2 antagonist that reopens plasticity in the adult cortex and cures mice from experimental amblyopia, a neurodevelopmental disease. Finally, the use of homeoproteins as therapeutic proteins in mouse models of glaucoma and Parkinson disease is reviewed. In the latter case, engrailed homeoproteins protect mesencephalic dopaminergic neurons by increasing the local translation of complex I mitochondrial mRNAs. In conclusion, this review synthesizes 20 years of work on the fundamental and potentially translational aspects of homeoprotein signaling.

Engrailed signaling in axon guidance and neuron survival

Several homeoproteins can function in a direct cell non-autonomous fashion to control various biological processes. In the developing nervous system, this mode of signaling has been well documented for Engrailed in the guidance of retinal ganglion cell axons and retino-tectal patterning. Engrailed is also a key factor for mesencephalic dopaminergic (mDA) neurons, not only during development but also in the adult. Haplodeficiency for Engrailed1 leads to progressive adult-onset loss of mDA neurons and several phenotypic alterations reminiscent of Parkinson's disease (PD). Thanks to its transduction properties, Engrailed has been shown to confer neuroprotection in several experimental models of PD. Study of the mechanisms underlying these two Engrailed-mediated effects has revealed a key role of the translation regulation by Engrailed and uncovered an unsuspected link between a homeoprotein and mitochondrial activity. These studies highlight the crucial role of cellular energetic metabolism in neuron development, survival and neurodegeneration, and may help to identify novel therapeutic targets.

Engrailed homeoprotein recruits the adenosine A1 receptor to potentiate ephrin A5 function in retinal growth cones

Engrailed 1 and engrailed 2 homeoprotein transcription factors (collectively Engrailed) display graded expression in the chick optic tectum where they participate in retino-tectal patterning. In vitro, extracellular Engrailed guides retinal ganglion cell (RGC) axons and synergises with ephrin A5 to provoke the collapse of temporal growth cones. In vivo disruption of endogenous extracellular Engrailed leads to misrouting of RGC axons. Here we characterise the signalling pathway of extracellular Engrailed. Our results show that Engrailed/ephrin A5 synergy in growth cone collapse involves adenosine A1 receptor activation after Engrailed-dependent ATP synthesis, followed by ATP secretion and hydrolysis to adenosine. This is, to our knowledge, the first evidence for a role of the adenosine A1 receptor in axon guidance. Based on these results, together with higher expression of the adenosine A1 receptor in temporal than nasal growth cones, we propose a computational model that illustrates how the interaction between Engrailed, ephrin A5 and adenosine could increase the precision of the retinal projection map.

Cell non-autonomous functions of homeoproteins in neuroprotection in the brain

Homeoproteins transcription factors can transfer between cells and play important roles in development. However, some of these homeoproteins are expressed in the adult, but their function is unknown. The loss of mesencephalic dopaminergic (mDA) neurons is the cause of Parkinson's disease. In mice lacking a functional allele for the Engrailed 1 homeoprotein, mDA neurons progressively die starting about 6 weeks after birth. Infusion of recombinant Engrailed stops the death of these neurons demonstrating that homeoproteins can be neuroprotective. This has been extended to retinal ganglion cell neurons (RGCs), which die in glaucoma and optic neuropathies. The homeoprotein Otx2 promotes the survival of injured adult RGCs both in vitro and in vivo. These examples raise the possibility that homeoproteins may provide neuroprotection to neurons vulnerable in other neurodegenerative diseases.

Developmental changes in cellular prion protein in primate visual cortex

Cellular prion protein (PrP(c)) is a cell surface glycoprotein highly expressed in neurons, and a protease-resistant conformer of the protein accumulates in the brain parenchyma in prion diseases. In human prion diseases, visual cortex and visual function can be affected. We examined both the levels and the localization of PrP(c) in developing visual cortex of the common marmoset. Western blot analysis showed that PrP(c) increased from the day of birth through adulthood, and this increase correlated with the progression of synapse formation. Immunohistochemistry showed that PrP(c) was present in fiber tracts of the neonate, and this immunoreactivity was lost with maturation. Within the neuropil, the laminar distribution of PrP(c) changed with age. In the neonate, PrP(c) immunoreactivity was strongest in layer 1, where the earliest synapses form. At the end of the first postnatal week, layer 4C, as identified by its strong cytochrome oxidase activity, was noticeably lighter in terms of PrP(c) immunoreactivity than the adjacent layers. The contrast between the strong immunoreactivity in both supragranular and infragranular layers and weak immunoreactivity in layer 4C increased with age. Layers 2/3 and 5 contained more intense PrP(c) immunoreactivity; these layers receive thalamic input from the koniocellular division of the LGN, and these layers of the LGN also had strong PrP(c) immunoreactivity. Together, these results provide evidence for PrP(c) localization in an identified functional pathway and may shed some light on prion disease pathogenesis.

Truncated PrP(c) in mammalian brain: interspecies variation and location in membrane rafts

A key molecular event in prion diseases is the conversion of cellular prion protein (PrP(c)) into an abnormal misfolded conformer (PrP(sc)). The PrP(c) N-terminal domain plays a central role in PrP(c) functions and in prion propagation. Because mammalian PrP(c) is found as a full-length and N-terminally truncated form, we examined the presence and amount of PrP(c) C-terminal fragment in the brain of different species. We found important variations between primates and rodents. In addition, our data show that the PrP(c) fragment is present in detergent-resistant raft domains, a membrane domain of critical importance for PrP(c) functions and its conversion into PrP(sc).

siRNA targeted against amyloid precursor protein impairs synaptic activity in vivo

The amyloid precursor protein (APP) plays a central role in Alzheimer's disease (AD) pathogenesis through its cleavage leading to the accumulation of the peptide betaA4. Diffusible oligomeric assemblies of amyloid beta peptide are thought to induce synaptic dysfunction, an early change in AD. We tested the hypothesis that a reduction in presynaptic APP could itself lead to a decrease in synaptic efficacy in vivo. Twenty-four hours after intraocular injection, siRNA targeted against APP accumulated in retinal cells and the APP in retinal terminals in the superior colliculus was significantly reduced. Surprisingly, the amyloid precursor-like protein 2 (APLP2) was reduced as well. Functional imaging experiments in rats during visual stimulation showed that knockdown of presynaptic APP/APLP2 significantly reduced the stimulation-induced glucose utilization in the superior colliculus. Our results suggest that perturbations in the amount of APP/APLP2 axonally transported to, and/or in their turnover in the nerve terminal alter synaptic function and could be a pathogenic mechanism in AD.

The N-terminal cleavage of cellular prion protein in the human brain

Human brain cellular prion protein (PrP(c)) is cleaved within its highly conserved domain at amino acid 110/111/112. This cleavage generates a highly stable C-terminal fragment (C1). We examined the relative abundance of holo- and truncated PrP(c) in human cerebral cortex and we found important inter-individual variations in the proportion of C1. Neither age nor postmortem interval explain the large variability observed in C1 amount. Interestingly, our results show that high levels of C1 are associated with the presence of the active ADAM 10 suggesting this zinc metalloprotease as a candidate for the cleavage of PrP(c) in the human brain.

The potential role of tau protein O-glycosylation in Alzheimer's disease

Single O-linked N-acetylglucosamine (O-GlcNAc) sugar residues can compete with phosphate groups to occupy specific sites on certain nuclear and cytosolic proteins. Here we show that inhibiting cellular kinase activities resulted in changes in protein O-glycosylation levels in heat-stable cytoskeletal protein fractions derived from primary neuronal cells. As increased phosphorylation of the microtubule-associated protein tau is one of the pathological hallmarks of Alzheimer's disease and glycosylation may play an influential role in this process. We observed a significant decrease in the protein O-GlcNAc glycosylation of a tau-enriched cytoskeletal fraction generated from AD post-mortem brain samples as compared with control, suggesting an inverse relationship between the two post-translational modifications. Finally, cells transfected with the cDNA coding for O-GlcNAc transferase (OGT) displayed altered tau phosphorylation patterns as compared with control cells, suggesting that changes in tau glycosylation may influence its phosphorylation state. The specificity of the changes in the phosphorylation of individual amino acid residues provides evidence for a targeted O-glycosylation of tau.

Axonal transport of the cellular prion protein is increased during axon regeneration

The cellular prion protein, PrPc, is a glycosylphosphatidylinositol-anchored cell surface glycoprotein and a protease-resistant conformer of the protein may be the infectious agent in transmissible spongiform encephalopathies. PrPc is localized on growing axons in vitro and along fibre bundles that contain elongating axons in developing and adult brain. To determine whether the growth state of axons influenced the expression and axonal transport of PrPc, we examined changes in the protein following post-traumatic regeneration in the hamster sciatic nerve. Our results show (1) that PrPc in nerve is significantly increased during nerve regeneration; (2) that this increase involves an increase in axonally transported PrPc; and (3) that the PrPc preferentially targeted for the newly formed portions of the regenerating axons consists of higher molecular weight glycoforms. These results raise the possibility that PrPc may play a role in the growth of axons in vivo, perhaps as an adhesion molecule interacting with the extracellular environment through specialized glycosylation.

Enhanced detection and retrograde axonal transport of PrPc in peripheral nerve

Neuroinvasion of the CNS during orally acquired transmissible spongiform encephalopathies (TSEs) may involve the transport of the infectious agent from the periphery to the CNS via the peripheral nerves. If this occurs within axons, the mechanism of axonal transport may be fundamental to the process. In studies of peripheral nerve we observed that the cellular prion protein (PrPc) is highly resistant to detergent extraction. The implication of this is an underestimation of the abundance of PrPc in peripheral nerve. We have developed nerve extraction conditions that enhance the quantification of the protein in nerve 16-fold. Application of these conditions to evaluate the accumulation of PrPc distal to a cut nerve now reveals that PrPc is retrogradely transported from the axon ending. These results provide a potential cellular mechanism for TSE infectivity to gain entry to the CNS from the periphery.

Developmental expression of the cellular prion protein in elongating axons

PrPc, a sialoglycoprotein present in the normal adult hamster brain, is particularly abundant in plastic brain regions but little is known about the level of expression and the localization of the protein during development. Western blot analysis of whole brain homogenates with mab3F4 show very low levels of the three main molecular weight forms of the protein at birth, in contrast to the strong and wide expression of mRNA transcripts. The PrPc levels increase sharply through P14 and are diminished somewhat in the adult. Regional analysis showed that in structures with ongoing growth or plasticity such as the olfactory bulb and hippocampus, PrPc remains high in the adult, while in areas where structural and functional relationships stabilize during development, such as the cortex and the thalamus, PrPc levels decline after the third postnatal week. In the neonate brain PrPc was prominent along fiber tracts similar to markers of axon elongation and in vitro experiments showed that the protein was present on the surface of elongating axons. PrPc is then localized to the synaptic neuropil in close spatio-temporal association with synapse formation. The localization of PrPc on elongating axons suggests a role for the protein in axon growth. In addition, the relative abundance of the protein in developing axon pathways and during synaptogenesis may provide a basis for the age-dependent susceptibility to transmissible spongiform encephalopathies.

High expression and anterograde axonal transport of aminoterminal sonic hedgehog in the adult hamster brain

Sonic hedgehog (SHH) is considered to play an important role in tissue induction and patterning during development, particularly in determining neuronal cell fate in the ventral neural tube and in the embryonic forebrain. SHH precursor is autoproteolytically cleaved to an aminoterminal fragment (SHHN) which retains all known SHH biological activities. Here, we demonstrate the expression of a 22-kDa SHHN immunoreactive peptide in developing and adult hamster brain regions using a rabbit antiserum directed against a mouse SHHN fragment. Interestingly, SHHN was developmentally regulated with the highest expression observed in the adult brain, was resistant to Triton X-100 solubilization at 4 degrees C and partitioned with the raft component ganglioside GM1 during density gradient centrifugation. In rat brain, Shh transcripts were identified by double in situ hybridization in GABAergic neurons located in various basal forebrain nuclei including globus pallidus, ventral pallidum, medial septum-diagonal band complex, magnocellular preoptic nucleus and in cerebellar Purkinje cells as well as in motoneurons of several cranial nerve nuclei and of the spinal cord. We show that radiolabelled SHHN peptides are synthesized in the adult hamster retina and are transported axonally along the optic nerve to the superior colliculus in vivo. Our data indicate that SHHN is associated with cholesterol rich raft-like microdomains and anterogradely transported in the adult brain, and suggest that the roles of this extracellular protein are more diverse than originally thought.

Early postnatal expression of L1 by retinal fibers in the optic tract and synaptic targets of the Syrian hamster

Previous immunohistochemical studies in mouse, rat, and chick have reported that the expression of the glycoprotein and cell adhesion molecule L1, a member of the immunoglobulin superfamily, shows regulation during development of retina and optic nerve. To extend our understanding of the role of L1 in developing neural circuitry, we have examined L1 expression in the optic tract and thalamic and midbrain synaptic targets of retinal fibers in the early postnatal Syrian hamster, a well-characterized developmental model of the primary visual projection. Metabolic labeling studies reveal that a synaptically targeted, sulfated, and glycosylated form of L1 undergoes rapid axonal transport from the retina. Retinofugal transport of L1 decreases commensurate with the decline in immunoreactivity of retinal fibers in the visual pathway. Retinal ganglion cell axons show intense L1 immunoreactivity as they navigate in highly fasciculated bundles in the optic tract overlying the lateral geniculate body and in the superior colliculus. We found no evidence of L1 immunoreactivity on retinal axon collaterals as they defasciculate from the optic tract and branch into target neuropils. L1 immunoreactivity wanes in optic tract as axon terminal arbors are elaborated in the lateral geniculate body and superior colliculus and as myelination in the visual pathway commences. This pattern of L1 expression suggests that, in the early postnatal period, L1 may support fasciculation of retinal fibers, maintaining them within the optic tract, and that subsequent down-regulation of L1 may facilitate their terminal arborization and myelination.

Immunolocalization of the cellular prion protein in normal brain

We examined the localization of PrP(c) in normal brain using free-floating section immunohistochemistry and monclonal antibody 3F4. In the mature hamster and baboon brain, PrP(c) is localized to the neuropil with a synaptic distribution and the PrP(c) immunoreactivity is denser in regions known for ongoing plasticity. Cell bodies and major fiber tracts have little or no PrP(c) immunoreactivity. At the electron microscopic level, PrP(c) immunoreactivity decorates synaptic profiles, both pre- and postsynaptically. Results obtained with two additional antibodies, 3B5 and Pri-304, showed similar patterns of PrP(c) bands on Western blots, although Pri-304 was less sensitive. On sections through the adult hamster hippocampus, 3B5 and Pri-304 both stained the synaptic neuropil while cell bodies in the pyramidal and dentate granule cell layers were not immunoreactive. Pri-304 differentiated between synaptic layers in the hippocampus and closely resembled the pattern of staining obtained with 3F4. Preliminary results of developing brain showed that PrP(c) is initially localized along fiber tracts in the neonate brain. These results show that PrP(c) has a synaptic distribution in the adult brain and suggest that there are important changes in its distribution during brain development. These results also characterize two additional reagents for studies of PrP(c) localization.

Inhibition of N-glycan processing alters axonal transport of synaptic glycoproteins in vivo

Synaptic glycoproteins are synthesized and glycosylated in the neuronal cell body, and conveyed to terminals by fast axonal transport. We used the alpha-mannosidase inhibitor, 2-deoxymannojirimycin (dMan), to investigate the effects of disrupting N-glycan processing on the axonal trafficking of proteins in vivo. dMan significantly reduced rapid axonal transport in retinal ganglion cells to about 34% of control values 4h after metabolic labeling; at 8 h post-labeling the inhibition was reversed. 2-D gel analysis showed that dMan completely inhibited the arrival of radiolabeled L1 and NCAM at axon terminals, and resulted in the appearance of two novel proteins of 230 kDa and 155 kDa. Our results show that disruption of the N-glycosylation pathway has an immediate inhibitory effect on total axonal transport and longer lasting effects on the trafficking of specific glycoproteins to axon terminals in vivo.

A novel cellular prion protein isoform present in rapid anterograde axonal transport

We studied the axonal transport of PrP(C) in hamster retinal and sciatic nerve axons. Our results show that a novel 38kDa form is the predominant form in rapid anterograde axonal transport while the 36kDa and 33kDa PrP(C) forms, abundant in nerve and brain, appear to be either stationary or slowly transported. We did not detect any significant retrograde transport of PrP(C). These results show that 38kDa PrP(C) is the form exported from the cell body to the axonal compartment where it may represent the precursor to the more abundant PrP(C) forms after its modification in nerve fibres or terminals.

Cellular prion protein localization in rodent and primate brain

The presence of an abnormal, protease-resistant form of the prion protein (PrP) is the hallmark of various forms of transmissible spongiform encephalopathies (TSE) which can affect a number of mammalian species, including humans. The normal, cellular form of this protein, PrPc, while abundant in brain is also present in many tissues and a number of species. In order to address the unresolved question of the precise localization of normal cerebral PrPc, we used a free-floating immunohistochemistry procedure to localize the protein at both the light and the electron microscopic levels in the brain of three TSE-sensitive species: hamster, macaque and humans. This method shows that PrPc is abundant in synaptic terminal fields in olfactory bulb, limbic-associated structures and in the striato-nigral complex, whereas many other regions of the hamster brain are essentially devoid of immunoreactivity. With the striking exception of the olfactory nerve, in which axons are continually growing throughout life, PrPc is not abundant in fibre pathways. PrPc distribution in the primate hippocampus and cortex is very similar to the distribution observed in hamster. PrPc was present at synaptic profiles as shown by immunoelectron microscopy, but was not detectable in neuronal perikaryon either by light or electron microscopy. Our results show that PrPc is abundant in a number of brain structures known for ongoing plasticity, and are consistent with the hypothesis that the protein also plays a role in synaptic function.

Post-translational processing and turnover kinetics of presynaptically targeted amyloid precursor superfamily proteins in the central nervous system

The amyloid precursor superfamily is composed of three highly conserved transmembrane glycoproteins, the amyloid precursor protein (APP) and amyloid precursor-like proteins 1 and 2 (APLP1, APLP2), whose functions are unknown. Proteolytic cleavage of APP yields the betaA4 peptide, the major component of cerebral amyloid in Alzheimer's disease. Here we show that five post-translationally modified, full-length species of APP and APLP2 (but not APLP1) arrive at the mature presynaptic terminal in the fastest wave of axonal transport and are subsequently rapidly cleared (mean half-life of 3.5 h). Rapid turnover of presynaptic APP and APLP2 occurs independently of visual activity. Turnover of the most rapidly arriving APP species was accompanied by a delayed accumulation of a 120-kDa, APP fragment lacking the C terminus, consistent with presynaptic APP turnover via constitutive proteolysis. Turnover of APLP2 was not accompanied by detectable APLP2 fragment peptides, suggesting either that APLP2 either is more rapidly degraded than is APP or is retrogradely transported shortly after reaching the terminus. A single 150-kDa APLP2 species containing the Kunitz protease inhibitor domain is the major amyloid precursor superfamily protein transported to the presynapse. Presynaptic APP and APLP2 are sialylated and N- and O-glycosylated, and some also carry chondroitin sulfate glycosaminoglycan and/or dermatan sulfate glycosaminoglycan. The rapid kinetics for turnover of APP and APLP2 predict a sensitive balance of synthesis, transport, and elimination rates that may be critical to normal neuronal functions and metabolic fates of these proteins.

Developmental shift of synaptic vesicle protein 2 from axons to terminals in the primary visual projection of the hamster

Synaptic vesicle protein 2 is an integral synaptic vesicle membrane glycoprotein which is present in all synapses for which it has been examined. We used an anti-synaptic vesicle protein 2 monoclonal antibody to examine synaptic vesicle protein 2 localization in the developing hamster retinofugal pathway. From postnatal day 0 to day 1, a period of elongation of retinal ganglion cell axons to their central targets, fiber fascicles in the optic tract over the lateral geniculate nucleus were intensely synaptic vesicle protein 2-immunoreactive. Adjacent to the optic tract, single fibers could be seen. We also observed a marked immunostaining in growth cones and fiber fascicles in retinal explants in culture. By postnatal day 2, the staining of single fibers had ended, and by postnatal day 5, during the formation of terminal arbors, numerous fine puncta of synaptic vesicle protein 2 immunoreactivity were distributed within the neuropil of the lateral geniculate nucleus. In the adult, the optic tract was devoid of synaptic vesicle protein 2 staining, while the neuropil contained distinct immunoreactive profiles, particularly in the outer shell of the lateral geniculate. These synaptic vesicle protein 2-positive profiles closely resembled the grape-like clusters and large swellings of two known retinal axon terminal types. Eye removal resulted in the rapid disappearance of these synaptic vesicle protein 2-labelled terminal profiles contralateral to the enucleation. A similar pattern of synaptic vesicle protein 2 immunoreactivity was observed in the superior colliculus. From postnatal day 0 to day 2, retinal fiber fascicles in the stratum griseum superficiale/stratum opticum were darkly stained for synaptic vesicle protein 2. By postnatal day 5, the immunoreactivity shifted to the neuropil and from postnatal day 6 onwards, the synaptic vesicle protein 2 immunoreactivity was more intense in the stratum griseum superficiale than in the optic fibre layer. This study demonstrates dense synaptic vesicle protein 2-labelling of elongating axons both in vivo and in vitro. However, coincident with the transition from retinal ganglion cell axon elongation to terminal arborization, synaptic vesicle protein 2 is progressively restricted to synaptic terminals and becomes undetectable in axons. This study is the first to document an axonal localization of synaptic vesicle protein 2 during development and raises the question as to its role during axonal elongation.

Differential synaptic vesicle protein expression in the barrel field of developing cortex

The distribution of four proteins associated with synaptic vesicles, SV2, synaptophysin, synapsin I, and rab3a, was investigated during postnatal development of the posteromedial barrel subfield (PMBSF) in the rat somatosensory cortex. A distinct progression in the appearance of the different synaptic vesicle proteins within the PMBSF was observed. SV2, synapsin I, and synaptophysin revealed the organization of the barrel field in the neonate. This early demarcation of the cortical representation of the vibrissal array coincides with the earliest known age for the emergence of the cytoarchitectonic organization of this region. In contrast, rab3a did not delimit the barrels until the end of the 1st postnatal week, coincident with the known onset of adult-like physiological activity and the loss of plasticity in afferents to this region. In addition, the appearance of the different synaptic vesicle proteins occurred earlier within the PMBSF than in the adjacent extra-barrel regions of the cortex. These results show that the molecular differentiation of synaptic fields across the cortex is not a homogeneous and synchronous process in terms of synaptic vesicle protein expression. Because these proteins act together in mature synapses to ensure the regulated release of neurotransmitters, our results suggest that this temporo-spatial asynchrony may underlie different potentials for synaptic activity and thus contribute to the development of cortical maps.

Differential effect of functional olfactory deprivation on synaptic vesicle proteins in rat olfactory bulb

The effects of functional odour deprivation on three different proteins associated with the membrane of the synaptic vesicle were examined in the rat olfactory bulb. Six weeks after neonatal unilateral nostril closure, Rab3a, a ras-like GTPase, was down-regulated in the odour-deprived bulb in the same manner as tyrosine hydroxylase. In contrast, synaptophysin, a protein of the channel family, and SV2, a putative transporter protein, were not altered. These results suggest that afferent activity is a factor controlling the level of some, but not all, proteins associated with presynaptic vesicles.

In vivo neuronal synthesis and axonal transport of Kunitz protease inhibitor (KPI)-containing forms of the amyloid precursor protein

We have shown previously that the amyloid precursor protein (APP) is synthesized in retinal ganglion cells and is rapidly transported down the axons, and that different molecular weight forms of the precursor have different developmental time courses. Some APP isoforms contain a Kunitz protease inhibitor (KPI) domain, and APP that lacks the KPI domain is considered the predominant isoform in neurons. We now show that, among the various rapidly transported APPs, a 140-kDa isoform contains the KPI domain. This APP isoform is highly expressed in rapidly growing retinal axons, and it is also prominent in adult axon endings. This 140-kDa KPI-containing APP is highly sulfated compared with other axonally transported isoforms. These results show that APP with the KPI domain is a prominent isoform synthesized in neurons in vivo, and they suggest that the regulation of protease activity may be an important factor during the establishment of neuronal connections.

Amyloid precursor protein in cortical neurons: coexistence of two pools differentially distributed in axons and dendrites and association with cytoskeleton

Embryonic cortical neurons in culture contain transmembrane amyloid precursor protein (APP) capable of associating with the detergent-insoluble cytoskeleton through interactions requiring the presence of its C-terminal. These transmembrane APPs are not detectable at the surface of living cells. When neurons are fixed with paraformaldehyde alone, APP is mainly visualized close to the membrane of the axon and cell body of 40% of neurons, with virtually no dendritic staining. Membrane permeabilization with detergent or methanol extends APP immunostaining to 100% of the cells and to all compartments, including the dendrites. Taken together, these results suggest that APP in embryonic neurons is present in two compartments, one more readily detectable in some axons and cell bodies and the other distributed throughout all neurons. The axonal and somatic pool of APP detectable after paraformaldehyde fixation alone is highly and rapidly augmented after exposure to calcium ionophores. We propose that calcium entry increases the amount of axonal APP close to the cell surface, but that the stabilization of the protein at the cell surface and its subsequent secretion require further physiological stimuli.

Developmental changes in the localization of the synaptic vesicle protein rab3A in rat brain

Rab3A is a protein associated with the membrane of synaptic vesicles and is involved in the control of the targeting or docking of these vesicles at the presynaptic membrane for the release of neurotransmitters. Here, we have examined the expression and localization of this protein during the development of the rat brain. Relative to total protein, the concentration of rab3A greatly increased during brain development. Both the intracellular localization of the protein and its cerebral distribution showed an age-dependent shift. In contrast to other synaptic vesicle proteins, rab3A was heavily concentrated in cell bodies when immature neurons were migrating and during early differentiation. Later, the protein disappeared from perikarya and had a diffuse distribution in the neuropil, indicating a redistribution to nerve terminals, its exclusive localization in the adult. In the developing somatosensory cortex, rab3A delimited the modular organization of the barrels well after the afferents have arrived but just around the time that mature synaptic activity has been observed. In the hippocampus, rab3A defined a novel "blob-like" organization of the mossy fibre terminals and its appearance in terminal fields closely preceded the known onset of long-term potentiation. The appearance of rab3A in specific terminal fields during the period of increased physiological activity suggests that this small GTP-binding protein may be an important late element in the establishment of the mature characteristics of the presynaptic terminal.

Identification of a peripherin dimer: changes during axonal development and regeneration of the rat sciatic nerve

Western blotting of rat dorsal root ganglion (DRG) and sciatic nerve under nonreducing conditions revealed that a peripherin-specific antibody recognized a protein species of 116/130 kDa, pI 5.6, in addition to peripherin (56 kDa, pI 5.6). We showed that this 116/130 kDa protein is a disulfide dimer of peripherin, because it gave rise to a single protein band comigrating with peripherin under reducing conditions and yielded the same proteolytic pattern as peripherin upon N-chlorosuccinimide digestion. In addition, the immunological characteristics of the resulting peptides were identical to those of peripherin. We investigated the changes in peripherin monomer and dimer protein levels during axonal development and regeneration. During postnatal development, quantitative analysis of western blots of DRG proteins showed a significant increase in peripherin monomer (+52%) and dimer (+33%) levels from the day of birth [postnatal day 0 (P0)] to P7. The monomer levels remained high until P14 and then decreased so that at P21 and later ages, the monomer levels were similar to those observed at birth. In contrast, the dimer levels decreased continuously after P7, and in the adult, its level represented only 30% of the level at birth. Changes in [35S]methionine incorporation into adult DRG proteins were studied during regeneration of axotomized sciatic axons. Quantitative analysis of proteins showed a strong increase in labeling of both peripherin monomer (+56%) and dimer (+88%) 7 days after the crush. These levels, which remained high until 28 days after the axotomy, had returned to normal 70 days post axotomy. Our results show that peripherin monomer and dimer greatly increase during DRG fiber development and regeneration, suggesting that the two forms are involved in the growth of axons.

The amyloid precursor protein is developmentally regulated and correlated with synaptogenesis

Metabolism of the amyloid precursor protein (APP) may contribute to the molecular changes observed in Alzheimer's disease, but the function of the protein in the non-pathologic nervous system remains unknown. In vitro studies have suggested that APP can participate in cellular adhesion and may thus contribute to neuronal differentiation in cultured cells. Here we show, in the primary visual pathway of the hamster, that APPs are developmentally regulated proteins rapidly transported to the growing tips of nerve fibers. Transmembrane forms of higher molecular weight (120 and 140 kDa) are preferentially associated with the rapid elongation of axons. Interestingly, another full-length form of 110 kDa and a soluble form of 100 kDa which lacks the C-terminal domain increase at the time of end-arbor formation and synaptogenesis and then decline when mature connections are established, suggesting that target recognition and synaptic contact may result in a signal for APP cleavage in the CNS in vivo.

Localization of the ras-like rab3A protein in the adult rat brain

Rab3A is a small GTP-binding synaptic vesicle protein, shown to dissociate from synaptic vesicle membranes upon depolarization-induced exocytosis. Using an antiserum raised against rab3A, we found that the antigen was localized to the neuropil of specific brain regions, but was not present in major fiber tracts or most cell bodies. For example, the neuropil of several thalamic nuclei (i.e., dorsal lateral geniculate nucleus, lateral posterior nucleus, ventroposterior nucleus), cerebral cortex, upper layers of the superior colliculus and matrix zones of the neostriatum, were strongly immunoreactive, while the anterior commissure, corpus callosum, optic tract and internal capsule were devoid of staining. The hippocampus, regions of cerebral cortex and the cerebellum exhibited striking laminar distributions of rab3A immunoreactivity. In the hippocampus, dark staining was observed in the stratum oriens, stratum radiatum and molecular layer of the dentate gyrus, while the pyramidal, stratum lacunosum moleculare and dentate granule layers were not stained. In cerebellum the molecular layer and to a lesser extent, the underlying granule cell layer showed enhanced immunoreactivity. Seven days after excitotoxic lesions of the cerebral cortex, rab3A immunoreactivity was diminished in the mirror locus in the contralateral cortical hemisphere and in certain thalamic nuclei ipsilateral to the injection site. These results show that rab3A is localized to a number of specific regions. Its absence from other areas suggests that this synaptic vesicle protein is not universal to all neuronal terminals and pathways. In addition, our lesion studies indicate that for some brain regions, much of the antigen originates in cortical neurons and is distributed within specific axonal projections.

Changes in rapidly transported proteins associated with development of abnormal projections in the diencephalon

The development of the hamster visual system is accompanied by striking changes in the pattern of proteins that are synthesized in retinal ganglion cells and rapidly transported to their nerve terminals. To determine whether any of these protein changes are regulated by interactions between the developing nerve endings and the cells with which they form synapses, we induced retinofugal axons to form abnormal projections in the lateral posterior (LP) nucleus of the thalamus and dense patches of hyperinnervation in the lateral geniculate nucleus (LGN) by removing their principal target, the superior colliculus (SC), the day after birth. Under these experimental conditions, two rapidly transported proteins, including the neural cell adhesion molecule, NCAM, showed significant changes in their time course of expression. NCAM, identified here using a monospecific antibody, is normally synthesized and transported at high levels at early stages of development and then declines during the second and third postnatal weeks. However, this decline was delayed when optic fibers were re-routed. A second rapidly transported protein, M(r) = 67 kDa, pI = 4.7, normally shows a rise in its synthesis and transport during terminal arbor formation and a subsequent decline, but it also remained elevated for a prolonged period when the SC was absent. These findings cannot be accounted for by a simple delay in the retinal ganglion cells' program of axonal growth, since other rapidly transported proteins, including the growth-associated protein GAP-43, showed a normal developmental time-course when the SC was removed. Target interactions therefore appear to influence the retinal ganglion cells' expression of different proteins in a specific fashion.

Abnormal retinal projections alter GAP-43 patterns in the diencephalon

In Syrian hamsters, mature retinal terminals contain only low levels of the growth-associated protein, GAP-43, whereas the lateral posterior nucleus (LP) of the thalamus contains high levels of this protein. Damage to the superior colliculus in neonatal hamsters induces retinal terminals to form dense patches of innervation in the LP, an area which otherwise receives little if any direct retinal input. The present study used GAP-43 antibodies to examine the interaction between abnormally routed optic fibers and the cells in the anomalous thalamic target zone. Immunohistochemistry revealed very little GAP-43 in the abnormal retinal projection to the LP, indicating that the normal developmental decline in GAP-43 levels occurs even in an inappropriate extracellular environment. Moreover, retinal fibers were found to exclude the protein from its normal territory, forming negatively-stained islands in those regions of the LP containing the retinal terminals. In order to identify the normal source of GAP-43-positive terminals in the LP, we surgically removed two major extrinsic afferents to this region, or we chemically eliminated local interneurons. Whereas removing projections from the SC or posterior cortex did not alter GAP-43 immunoreactivity in the LP, destruction of local interneurons with ibotenic acid resulted in markedly diminished levels of this protein. These results show that retinal terminals induced to form in an abnormal target area undergo their normal diminution of GAP-43, and that these retinal projections displace other GAP-43-rich terminals in the LP that appear to arise from local interneurons.

Impaired verbal reasoning and constructional apraxia in subjects with right hemisphere damage

In addition to causing visuospatial deficits, damage to the right cerebral hemisphere also impairs other cognitive abilities, including those requiring higher-order aspects of language. The present study used a standardized test battery to examine the relationship between visuospatial abilities and comprehension of narrative material in subjects having unilateral right hemisphere damage (RHD). In a series of 41 consecutively admitted RHD subjects, impairments in abstracting information from narrative passages were as prevalent and as severe in magnitude as constructional apraxia. Moreover, the extent of the visuospatial and linguistic impairments were highly correlated. Although age, educational levels, and degree of premorbid brain atrophy were all found to influence performance, analysis of a select subgroup of the population established that the covariation of visuospatial and verbal impairments is related to right hemisphere damage per se. Clinically, these findings may be of significance for understanding the pervasive cognitive impairments that are often evidenced by RHD patients.

Immunohistochemical localization of GAP-43 in the developing hamster retinofugal pathway

Metabolic labeling studies have shown that the developing hamster retinotectal pathway is marked by a high level of synthesis and axonal transport of the neuron-specific phosphoprotein GAP-43, which then decline sharply with synaptic maturation. To understand better the relationship of GAP-43 to specific developmental events, we used a monospecific antibody to examine the location of this protein in the optic tract and retinal target areas at various stages. In late embryonic and in neonatal hamsters, dense GAP-43 immunostaining was seen along the entire extent of the optic tract axons, including fascicles coursing over and through the lateral geniculate body (LGB) and within the upper layers of the superior colliculus (SC). The retinal origin of many of these fascicles was confirmed by their rapid disappearance after removal of the contralateral eye. During the first postnatal week, immunostaining in the fiber fascicles showed a marked decline, though the protein was still present throughout the neuropil of the LGB and SC. In the second postnatal week, the neuropil staining also diminished, and by 12 days after birth, both structures showed only light immunoreactivity. The high levels of GAP-43 in embryonic and neonatal optic tract axons coincide temporally with axon elongation, initial target contact, and collateral formation by the retinofugal fibers, whereas subsequent concentration of the protein in the neuropil suggests its involvement in the elaboration of terminal arbors and synaptogenesis.

Peripheral nerve regeneration induces elevated expression of GAP-43 in the brainstem trigeminal complex of adult hamsters

A polyclonal antibody was used to delineate the pattern of GAP-43 expression in central processes of trigeminal ganglion cells while their peripheral processes were undergoing regeneration. Two weeks after transection of the infraorbital nerve, levels of GAP-43 ipsilateral to the transection were greatly increased along the trajectory of infraorbital axons in the central trigeminal tract and also within the target neuropil. We conclude that elevated levels of GAP-43 in central processes of injured trigeminal ganglion cells occur in direct response to the regenerative response of the cell body and may have important implications for 'plasticity'-related changes seen in the adult trigeminal system.

Changes in rapidly transported proteins in developing hamster retinofugal axons

Proteins synthesized in retinal ganglion cells and conveyed to the terminals of optic tract axons in the rapid phase of axonal transport were analyzed at different developmental stages in the hamster. Animals between 2 d of age and adulthood were labeled intraocularly with 35S-methionine, and after a 4 hr survival time, the superior colliculus was dissected out, subjected to subcellular fractionation, and radiolabeled proteins in the particulate fraction analyzed by 2-dimensional gel electrophoresis and fluorography. The previously identified growth-associated phosphoprotein, GAP-43 (GAP-48, B-50, F1, pp46), was synthesized and transported at high levels in the neonate, but these levels declined precipitously after the second postnatal week. Immunohistochemical studies using a monospecific antibody showed that GAP-43 was localized along the entire length of retinal axons in the optic tract and target areas in P2 animals but was virtually absent in the adult visual pathway. By metabolic labeling, 2 proteins with molecular weights of about 230 kDa also showed a sharp decrease during development. In contrast, acidic proteins of 27 and 64 kDa, which were barely detectable in the neonate, increased steadily to become the most heavily labeled proteins of rapid axonal transport by the second postnatal week. Another group of proteins, of about 94-110 kDa, also rose to peak levels after birth but then declined. Temporal correlations between the molecular changes described here and the known anatomical events in optic tract development suggest that the synthesis and transport of particular membrane proteins may be directly related to the sequence of morphological changes.

Enhanced visualization of axonally transported proteins in the immature CNS by suppression of systemic labeling

In the neonate hamster, visualization of axonally transported proteins in the retinofugal pathway is obscured by high levels of systemic (background) labeling. Radiolabeled precursors injected into the eye diffuse rapidly into the general circulation and then across the immature blood-brain barrier to be incorporated into proteins that are synthesized throughout the brain. Systemic labeling can be suppressed, however, by i.p. injections of large amounts of either non-radioactive methionine 30 min after intraocular labeling with [35S]methionine, or non-radioactive leucine given at the time of intraocular labeling. Whereas the former competes with the radioactive precursor during incorporation into brain proteins (after most of the retinal labeling has already been achieved), the latter competes at the earlier stage of access to the brain. Both methods reduced background labeling by more than 60%, thereby allowing for unambiguous identification of axonally transported proteins. The pattern of rapidly transported proteins was found to be strikingly different between neonates and mature animals, including marked changes in an identified 'growth-associated protein' (50 kDa, pI 4.8).

Covariant defects in visuospatial abilities and recall of verbal narrative after right hemisphere stroke

Eighteen patients with right hemisphere strokes and 10 age-matched normal controls were tested for visuospatial abilities and for recall of brief narrative passages. Visuospatial and verbal abilities were evaluated using an objective scoring protocol that quantified accuracy in reproducing individual details, appreciation of structural relationships, and the appearance of unwarranted intrusions. The right hemisphere damaged group was found to be impaired on all measures of verbal recall. Across subjects these defects, particularly the inability to abstract information from the narrative passages, correlated with the degree of constructional apraxia. Analysis of CT scans failed to define a discrete region of the right hemisphere selectively associated with either the visuospatial or verbal defects, but indicated that both are exacerbated by the presence of premorbid brain atrophy.