RISK-1: a novel MAPK homologue in axoplasm that is activated and retrogradely transported after nerve injury.

Sensory neurons (SNs) of Aplysia are widely used to study the molecular correlates of learning. Among these is the activation of an Aplysia (ap) MAPK that phosphorylates the transcription factor apC/EBPbeta. Because crushing the axons of the SNs induces changes similar to learning, we tested the hypothesis that apMAPK is a point of convergence on the pathways for learning and injury. One event in common is long-term hyperexcitability (LTH), and LTH was induced in the SNs after intrasomatic injection of active vertebrate extracellular signal-regulated kinase 1 (ERK1; as an apMAPK surrogate). Nerve crush activated an axoplasmic kinase at the site of injury that phosphorylated apC/EBPbeta. Surprisingly, this was not apMAPK, but a kinase that was recognized by antibodies to vertebrate ERKs and to doubly phosphorylated, activated ERKs. The activated kinase was transported to the cell body and nucleus and its arrival was concurrent with an injury-induced increase in apC/EBPbeta mRNA and protein. We call this retrogradely transported kinase RISK-1. RISK-1 initiated the binding of apC/EBPbeta to the ERE enhancer site in vitro and an increase in ERE-binding was detected in injured neurons containing active RISK-1. Thus, Aplysia neurons contain two MAPK homologues, one of which is a late acting retrogradely transported injury signal.

Direct interactions between immunocytes and neurons after axotomy in Aplysia.

Axon growth during development and after injury has processes in common, but also differs in that regeneration requires the participation of cells of the immune system. To investigate how neuron-immunocyte interactions might influence regeneration, we developed an in vitro model whereby neurons and hemocytes from Aplysia californica were cocultured. The hemocytes, which behave like vertebrate macrophages, migrated randomly throughout the dish. When a neuron was encountered, some hemocytes exhibited an avoidance response, whereas others formed stable contacts. Hemocytes did not distinguish between neurons from different animals. Stable contacts occurred on neurites and growth cones, but not the cell soma, and were benign in that the hemocytes did not impede neurite growth. When hemocytes attached to the cell body, it presaged the destruction of the neuron. Destruction was a dynamic process that was initiated when groups of one to three hemocytes adhered to various regions of the cell soma. Each group was then joined by other hemocytes. They did not contact the neuron, but interconnected the initial groups, forming a network around the neuron. The network then contracted to dismember the cell. Once a neuron was destroyed, hemocytes removed the debris by phagocytosis. Both damaged neurons and those without apparent damage were targets for destruction. Severing neurites with a needle resulted in the destruction of only one of six cells. Our studies suggest that hemocytes, and by extrapolation, vertebrate macrophages, exhibit highly complex interactions with neurons that can exert a variety of influences on the course of nerve regeneration.

An NF-kappaB-like transcription factor in axoplasm is rapidly inactivated after nerve injury in Aplysia.

We found a protein in Aplysia neurons that has many characteristics of the transcription factor NF-kappaB. Thus, the protein recognized a radiolabeled probe containing the kappaB sequence from the human interferon-beta gene enhancer element (PRDII), and the binding was not affected by PRDIV, an ATF-2 enhancer sequence from the same gene. Binding was efficiently inhibited, however, by nonradioactive oligonucleotides containing H2, the kappaB site from the major histocompatibility complex I gene promotor. In addition, recombinant mammalian IkappaB-alpha, which associates specifically with the P65 subunit of NF-kappaB, inhibited the binding to the PRDII probe in a dose-dependent manner. The nuclear form of the Aplysia protein was constitutively active. Axoplasm, however, contained the constitutively active form as well as a latent form. The latter was activated by treatment with deoxycholate under the same conditions as mammalian NF-kappaB. Based on these findings, we believe the protein to be a homolog of NF-kappaB. To investigate the role of apNF-kappaB in the axon, we crushed the peripheral nerves to the body wall. Surprisingly, there was a rapid loss of apNF-kappaB binding at the crush site and, within 15 min, as far as 2.5 cm along the axon. In contrast, exposing either the intact animal or the nervous system in situ to levels of 5-HT that induce synaptic facilitation did not affect apNF-kappaB activity.

Intrinsic injury signals enhance growth, survival, and excitability of Aplysia neurons.

Neurons undergo extensive changes in growth and electrophysiological properties in response to axon injury. Efforts to understand the molecular mechanisms that initiate these changes have focused almost exclusively on the role of extrinsic signals, primarily neurotrophic factors released from target and glial cells. The objective of the present investigation was to determine whether the response to axonal injury also involves intrinsic axoplasmic signals. Aplysia neurons were removed from their ganglia and placed in vitro on a substratum permissive for growth, but in the absence of glia and soluble growth factors. Under these conditions, neurites emerged and grew for approximately 4 d. Once growth had ceased, the neurites were transected. In all, 46 of 50 cells regenerated, either by resorbing the remaining neurites and elaborating a new neuritic arbor or by merely replacing the neurites that had been severed. Cut cells also exhibited enhanced excitability and, paradoxically, prolonged survival, when compared with uninjured neurons. These findings indicate that axons contain intrinsic molecular signals that are directly activated by injury to trigger changes underlying regeneration and compensatory plasticity.