AxonQuantifier: A semi-automated program for quantifying axonal density from whole-mounted optic nerves.

BACKGROUND: Here, we present a semi-automated method for quantifying retinal ganglion cell (RGC) axon density at different distances from the optic nerve crush site using longitudinal, confocal microscopy images taken from whole-mounted optic nerves. This method employs the algorithm AxonQuantifier which operates on the freely available program, ImageJ. NEW METHOD: To validate this method, seven adult male Long Evans rats underwent optic nerve crush injury followed by in vivo treatment with electric fields of varying strengths for 30 days to produce optic nerves with a wide range of axon densities distal to the optic nerve crush site. Prior to euthanasia, RGC axons were labelled with intravitreal injections of cholera toxin B conjugated to Alexa Fluor 647. After dissection, optic nerves underwent tissue clearing, were whole-mounted, and imaged longitudinally using confocal microscopy. COMPARISON WITH EXISTING METHODS: Five masked raters quantified RGC axon density at 250, 500, 750, 1000, 1250, 1500, 1750, and 2000 µm distances past the optic nerve crush site for the seven optic nerves manually and using AxonQuantifier. Agreement between these methods was assessed using Bland-Altman plots and linear regression. Inter-rater agreement was assessed using the intra-class coefficient. RESULTS: Semi-automated quantification of RGC axon density demonstrated improved inter-rater agreement and reduced bias values as compared to manual quantification, while also increasing time efficiency 4-fold. Relative to manual quantification, AxonQuantifier tended to underestimate axon density. CONCLUSIONS: AxonQuantifier is a reliable and efficient method for quantifying axon density from whole mount optic nerves.

Internuclear Ophthalmoplegia Characterizes Multiple Sclerosis Rather Than Neuromyelitis Optica Spectrum Disease.

BACKGROUND: Neuromyelitis optica spectrum disease (NMOSD) and multiple sclerosis (MS) share clinical presentations including optic neuritis and brainstem syndromes. Internuclear ophthalmoplegia (INO) is characterized by slowed ipsilateral adduction saccades and results from a lesion in the medial longitudinal fasciculus (MLF). Although INO is a common clinical finding in MS, its prevalence in NMOSD is unknown. The objective of this work is to determine the comparative frequencies of INO in patients with NMOSD and MS and compare clinical features of both disease processes. METHODS: This is a retrospective study of patients 18 years and older who have an established diagnosis of NMOSD or MS and were evaluated by both neuro-ophthalmology and neuro-immunology specialists between 2014 and 2020. Electronic medical records were screened for documentation of an acute INO at any time during follow-up. Incidence rates were calculated from number of cases of new-onset INO and patient years observed. Logistic regression was used to evaluate the likelihood of developing an INO at any time point for NMOSD vs MS patients. Multivariable analysis was performed by adjusting for age, race, gender, and length of follow-up. RESULTS: Two hundred eighty patients (80 NMOSD, 200 MS) were included. Age range was 18-79 years with a mean age of 35.14 (SD ± 12.41 years). Average length of follow-up in MS and NMOSD patients was 4.18 years vs 3.79 years, respectively (P > 0.05), and disease duration before the start of the study in MS and NMOSD was 8.76 years vs 4.65 years, respectively (P < 0.01). Mean disease duration and follow-up time of both groups was 7.58 years and 4.07 ± 2.51 years, respectively. NMOSD patients were predominantly seropositive for AQP4 antibody (61.25%, n = 49). Individuals who had MOG antibody but also met NMOSD criteria were also included (18.75%, n = 15). The frequency of INO at any time point was 1.25% (n = 1) in NMOSD compared with 16% (n = 32) in MS. The incidence rate of new-onset INO in NMOSD (excluding MOGAD) was 3.8/1,000 person years and 23.9/1,000 person years in MS. Adjusted analysis showed that NMOSD patients were 13.89 times (odds ratio [OR] 0.07, 95% confidence interval [CI] 0.01-0.598, P = 0.015) less likely to develop an INO compared with those with MS when including MOGAD patients, 12.5 times less likely (OR 0.08, 95% CI: 0.10-0.67, P = 0.02) when excluding MOGAD patients and 9.62 times less likely (OR 0.10, 95% CI: 0.01-0.87, P = 0.036) for AQP4+ patients. CONCLUSIONS: Our study shows that the incidence of new INO (3.8 vs 23.9 per 1,000 person years), and the odds of having INO at any time point are significantly lower in NMOSD than MS. This suggests that INO and consequently MLF lesions are less common in NMOSD. The presence of an INO may help in the differentiation of NMOSD from MS and may aid in earlier implementation of disease appropriate therapy.

Optic Nerve Regeneration: How Will We Get There?

BACKGROUND: Restoration of vision in patients blinded by advanced optic neuropathies requires technologies that can either 1) salvage damaged and prevent further degeneration of retinal ganglion cells (RGCs), or 2) replace lost RGCs. EVIDENCE ACQUISITION: Review of scientific literature. RESULTS: In this article, we discuss the different barriers to cell-replacement based strategies for optic nerve regeneration and provide an update regarding what progress that has been made to overcome them. We also provide an update on current stem cell-based therapies for optic nerve regeneration. CONCLUSIONS: As neuro-regenerative and cell-transplantation based strategies for optic nerve regeneration continue to be refined, researchers and clinicians will need to work together to determine who will be a good candidate for such therapies.

Neuro-protection and neuro-regeneration of the optic nerve: recent advances and future directions.

PURPOSE OF REVIEW: Optic neuropathies refer to a collection of diseases in which retinal ganglion cells (RGCs), the specialized neuron of the retina whose axons make up the optic nerve, are selectively damaged. Blindness secondary to optic neuropathies is irreversible as RGCs do not have the capacity for self-renewal and have a limited capacity for self-repair. Numerous strategies are being developed to either prevent further RGC degeneration or replace the cells that have degenerated. In this review, we aim to discuss known limitations to regeneration in central nervous system (CNS), followed by a discussion of previous, current, and future strategies for optic nerve neuroprotection as well as approaches for neuro-regeneration, with an emphasis on developments in the past two years. RECENT FINDINGS: Neuro-regeneration in the CNS is limited by both intrinsic and extrinsic factors. Environmental barriers to axon regeneration can be divided into two major categories: failure to clear myelin and formation of glial scar. Although inflammatory scars block axon growth past the site of injury, inflammation also provides important signals that activate reparative and regenerative pathways in RGCs. Neuroprotection with neurotrophins as monotherapy is not effective at preventing RGC degeneration likely secondary to rapid clearance of growth factors. Novel approaches involve exploiting different technologies to provide sustained delivery of neurotrophins. Other approaches include application of anti-apoptosis molecules and anti-axon retraction molecules. Although stem cells are becoming a viable option for generating RGCs for cell-replacement-based strategies, there are still many critical barriers to overcome before they can be used in clinical practice. Adjuvant treatments, such as application of electrical fields, scaffolds, and magnetic field stimulation, may be useful in helping transplanted RGCs extend axons in the proper orientation and assist with new synapse formation. SUMMARY: Different optic neuropathies will benefit from neuro-protective versus neuro-regenerative approaches. Developing clinically effective treatments for optic nerve disease will require a collaborative approach that not only employs neurotrophic factors but also incorporates signals that promote axonogenesis, direct axon growth towards intended targets, and promote appropriate synaptogenesis.

EGFR-Pak Signaling Selectively Regulates Glutamine Deprivation-Induced Macropinocytosis.

Macropinocytosis has emerged as an important nutrient-scavenging pathway that supports tumor cell fitness. By internalizing extracellular protein and targeting it for lysosomal degradation, this endocytic pathway functions as an amino acid supply route, permitting tumor cell growth and survival despite the nutrient-poor conditions of the tumor microenvironment. Here, we provide evidence that a subset of pancreatic ductal adenocarcinoma (PDAC) tumors are wired to integrate contextual metabolic inputs to regulate macropinocytosis, dialing up or down this uptake pathway depending on nutrient availability. We find that regional depletion of amino acids coincides with increased levels of macropinocytosis and that the scarcity of glutamine uniquely drives this process. Mechanistically, this stimulation of macropinocytosis depends on the nutrient stress-induced potentiation of epidermal growth factor receptor signaling that, through the activation of Pak, controls the extent of macropinocytosis in these cells. These results provide a mechanistic understanding of how nutritional cues can control protein scavenging in PDAC tumors.

Quantitation of Macropinocytosis in Cancer Cells.

Macropinocytosis has emerged as an important nutrient supply pathway that sustains cell growth of cancer cells within the nutrient-poor tumor microenvironment. By internalizing extracellular fluid through this bulk endocytic pathway, albumin is supplied to the cancer cells, which, after degradation, serves as an amino acid source to meet the high nutrient demands of these highly proliferating cells. Here, we describe a streamlined protocol for visualization and quantitation of macropinosomes in adherent cancer cells grown in vitro. The determination of the "macropinocytic index" provides a tool for measuring the extent to which this internalization pathway is utilized within the cancer cells and allows for comparison between different cell lines and treatments. The protocol provided herein has been optimized for reproducibility and is readily adaptable to multiple conditions and settings.

Detection and Quantification of Macropinosomes in Pancreatic Tumors.

Macropinocytosis is a mechanism of fluid-phase endocytosis that functions in the nonspecific internalization of extracellular fluid. This uptake pathway has specialized roles in different cell types and organisms, and its importance has recently been established in several diseases, including cancer. In cancer, macropinocytosis is stimulated by oncogenes, such as Ras, and macropinocytic cargo is targeted to lysosomes for degradation, providing a catabolic route for tumor cells to obtain amino acids from the tumor microenvironment. Here, we describe a protocol to employ fluorescently labeled dextran molecules in order to visualize and quantify the extent of macropinocytosis in pancreatic tumors. Multiple samples can be processed in parallel by this method, and the protocol can be easily customized for pancreatic tumor tissue isolated from subcutaneous, orthotopic and genetically engineered mouse models (GEMM), or human patients.

Neuron-specific caveolin-1 overexpression improves motor function and preserves memory in mice subjected to brain trauma.

Studies in vitro and in vivo demonstrate that membrane/lipid rafts and caveolin (Cav) organize progrowth receptors, and, when overexpressed specifically in neurons, Cav-1 augments neuronal signaling and growth and improves cognitive function in adult and aged mice; however, whether neuronal Cav-1 overexpression can preserve motor and cognitive function in the brain trauma setting is unknown. Here, we generated a neuron-targeted Cav-1-overexpressing transgenic (Tg) mouse [synapsin-driven Cav-1 (SynCav1 Tg)] and subjected it to a controlled cortical impact model of brain trauma and measured biochemical, anatomic, and behavioral changes. SynCav1 Tg mice exhibited increased hippocampal expression of Cav-1 and membrane/lipid raft localization of postsynaptic density protein 95, NMDA receptor, and tropomyosin receptor kinase B. When subjected to a controlled cortical impact, SynCav1 Tg mice demonstrated preserved hippocampus-dependent fear learning and memory, improved motor function recovery, and decreased brain lesion volume compared with wild-type controls. Neuron-targeted overexpression of Cav-1 in the adult brain prevents hippocampus-dependent learning and memory deficits, restores motor function after brain trauma, and decreases brain lesion size induced by trauma. Our findings demonstrate that neuron-targeted Cav-1 can be used as a novel therapeutic strategy to restore brain function and prevent trauma-associated maladaptive plasticity.-Egawa, J., Schilling, J. M., Cui, W., Posadas, E., Sawada, A., Alas, B., Zemljic-Harpf, A. E., Fannon-Pavlich, M. J., Mandyam, C. D., Roth, D. M., Patel, H. H., Patel, P. M., Head, B. P. Neuron-specific caveolin-1 overexpression improves motor function and preserves memory in mice subjected to brain trauma.