Gary K. Steinberg - US grants

DESCRIPTION: (Applicant's Abstract) In recent years there has been a resurgence of interest in mild hypothermia (30-35 degrees C) as a method of cerebral protection. This project aims at defining optimal parameters in which mild hypothermia can be applied in animal models of focal stroke and explores the mechanisms of neuroprotection by which temperature manipulations and pharmacological intervention may work. Using an intraluminal suture occlusion model of focal cerebral ischemia in the rat, a series of experiments will be performed to: 1) determine the optimal depth and duration of hypothermia which provides maximal reduction in infarct size while avoiding systemic complications; 2) address the extent to which hypothermia can be delayed and still be neuroprotective as well as whether the protective effects are sustained over time; 3) determine if mild hypothermia protects against both permanent and transient focal ischemia; 4) characterize the physiological changes resulting from mild hypothermia under ischemic conditions including its effects on metabolism, excitatory amino acid release, cerebral blood flow, and blood-brain-barrier integrity; and 5) determine whether the neuroprotective effects of mild hypothermia and glutamate receptor antagonists are additive. In order to examine the feasibility of hypothermia in a potential clinical setting, hypothermia will be used in conjunction with a thrombolytic agent in a rabbit model of thromboembolic stroke. The time course of ischemia and response to treatment with hypothermia and thrombolysis will be monitored using sequential diffusion and perfusion MRIs. This project will also investigate the use of diffusion-weighted MRI (DWI) in characterizing ischemic stroke in response to alterations in brain temperature. The time course of diffusion changes and infarct size will be studied as well as the potential of DWI as a predictor of infarct severity. The knowledge gained from this project will have direct implications for the treatment of ischemic stroke in humans including its use in both medical and surgical patients with cerebrovascular disease.

The integrating theme of this project is that three classes of gene products are intimately involved with modulating injury of neurons and glia following hypoxia/ischemia and, more specifically, that altering expression of these gene products can attenuate such hypoxic/ischemic damage. The program aims to define more precisely the roles of SOD, bcl-2 and hsp70 in modifying the detrimental effects of oxidative stress on cerebral neurons/glia and determining the ultimate survival or death (necrotic versus apoptotic) of these cells. The selection of these three genes for intense study reflects their potential therapeutic value, as well as the important information their investigation will yield regarding basic biologic mechanisms of ischemic cell death in central nervous tissue. The experimental results of this project could potentially lead to novel strategies for treating clinical stroke, as well as other traumatic and degenerative neurologic disorders showing a similar pathogenesis. The Program includes three interrelated projects utilizing advanced molecular biology techniques, including gene transfer therapy and transgenic technology in several paradigms of both in vitro and in vivo neuronal and glial injury. The protective potential of the three different genes will be examined using gene transfer in neuronal and glial cultures, and in transgenic and knockout cultures under anoxic and aglycemic conditions (Project 1). The neuroprotective benefit of the same three classes of genes will be studied in several models of ischemia using gene transfer in genetically normal rats (Project 2), as well as investigating protection against ischemia in transgenic or knockout rodents (Project 3). The Vector Core 9Core C) will prepare viral vectors to be used in the gene transfer experiments of Projects 1 and 2. The Transgenic Core (Core B) will produce transgenic mice and rats, as well as knockout mutants to be used in Projects 1 and 3. The Administrative Core (Core A) will provide grant management, financial administration, statistical consultation, centralized purchase, seminar arrangements, clerical assistance, and scientific consultation through Advisory Committees.

The integrating theme of this PPG is to investigate the role of oxidative stress and reactive oxygen species (ROS) in mediating ischemic brain injury, focusing on detrimental effects involving neurons, astrocytes, microglia and endothelial cells, and the interactions between these various components in contributing to cerebral damage. Our initial PPG studied the role of SOD, Bcl-2 and HSP70 in protecting against necrotic and apoptotic neuronal and astroglial death. The current PPG represents an evolution in our approach based on results obtained in our labs over the last 5 years. It has become clear that ischemia/reperfusion induced ROS are also involved in inflammatory events mediated by microglia, leukocytes and astrocytes as well as causing endothelial cell death, in addition to direct neuronal and astroglial injury. It is also apparent that downstream apoptotic events precipitated by ROS are more complex and interrelated than previously assumed. We therefore propose to explore the delayed effects of ROS mediated injury on neurons, astrocytes, microglia and endothelial cells. The development of the 3 interrelated projects has benefited greatly from our ongoing collaboration during the first 5 years of this Program, and will continue to employ advanced molecular biology techniques, including gene transfer, transgenic/knockout technology and bone marrow transplant chimeras using in vivo and in vitro models of ischemic injury. Project by Giffard will examine ROS-related mechanisms of microglial exacerbation of ischemic injury, in vivo and in vitro. Project by Steinberg will study the role of ROS in initiating key apoptotic pathways leading to neuronal death using in vivo and in vitro models. Project by Chan will explore mechanisms of endothelial cell death in ROS-mediated brain damage utilizing in vivo models. The Transgenic Core will provide transgenic and knockout mice for use in each project, and the Vector Core will prepare viral vectors for gene transfer to be used in Projects by Giffard and Steinberg. The administrative Core will provide grant management, financial administration, centralized purchasing, seminar arrangement, statistical consulting, clerical and scientific consultation through the Advisory Committees.

Reactive oxygen species (ROS) generated after cerebral ischemia and reperfusion activate both caspase-dependent and caspase-independent pathways leading to delayed neuronal death. This project will use a combination of in vivo and in vitro models of ischemia, viral-mediated gene transfer, and knockout models to address the central role of oxidative stress and ROS in initiating key apoptotic pathways. It will also explore the temporal dynamics and interactions between those pathways, and determine whether hypothermia alters those dynamics and interactions, and thus enhances neuroprotection. Additionally, preservation of neuronal function conferred by gene transfer therapy will be examined. First, we will explore the role of reactive oxygen species (ROS) in activating both caspase-dependent and -independent apoptotic events, assess whether and how they are altered by over-expression of anti-oxidant genes, whether such over-expression protects ischemia-vulnerable SOD2 knockout mice, and explore effects of deltaPKC on ROS and apoptosis post-ischemia. Second, we propose to examine the interactions between various mediators of apoptotic pathways after cerebral ischemia. We will investigate the effects of gene therapy using over-expression of the caspase inhibitors p35 and crmA, as well as pharmacologic caspase antagonists, and examine their effects on interactions between AIF- and caspase-dependent apoptotic pathways after ischemia. Finally, we will investigate whether post-ischemic hypothermia prolongs the temporal therapeutic window for gene therapy against global cerebral ischemia, and whether gene therapy with or without hypothermia spares neuronal function. Specifically, we will determine whether hypothermia blocks or delays ROS activity and apoptotic mediators, prolongs the time window for protection by over-expression of GPX, catalase, or other anti-apoptotic proteins, and permits gene therapy to spare neuronal function following global ischemia. We believe that by combining well-established in vivo and in vitro models of stroke with gene transfer and transgenic technology, we can apply unique and novel approaches to elucidate ROS-related mechanisms of neuronal death, survival, and function.

? DESCRIPTION (provided by applicant): The purpose of this Stanford Neurosurgery Resident Research Education Program is to provide education in basic and clinical research to neurosurgery residents with the goal of fostering their growth into clinician scientists. Its goal s to educate and train neurosurgeons capable of establishing and directing a scientific laboratory throughout their careers. The strategy is to identify residents with the potential for scientific research and place them for a two year term in the laboratories of senior, highly experienced research scientists. They will also receive extensive counseling by the neurosurgical directors of the program and participate in seminars on research skills and ethical research behavior. Their progress and the success of the overall program will be repeatedly assessed and appropriate changes in the program will be made. It is hoped that this program will produce neurosurgeons capable of making new discoveries regarding the causes of diseases of the brain and spinal cord, that new, more effective treatments will result, and, in fulfillment of the mission of the NI, that the health of persons afflicted with these diseases will be improved.

This proposal seeks to establish essential core research facilities to meet the following identified shared needs of the Stanford Neuroscience research community: (1) gene vector and virus production, (2) advanced microscopy data acquisition and analysis, and (3) automated behavioral phenotyping. Viral vectors are used to express recombinant proteins and/or knock down expression of endogenous proteins in specific subsets of cells in brain tissue. It is even possible to express proteins that enable precise temporal control over the activity of individual neurons. Use of such viral tools is revolutionizing neuroscience research. A centralized core facility will vastly improve the efficiency and cost-effectiveness of virus production. Three dimensional image analysis and visualization are essential for quantifying information from volume imaging techniques, such as Array Tomography, and single- and two-photon confocal microscopy. Software and hardware for this type of analysis is expensive, and has a steep learning curve. This proposal will fund the Image Analysis Center, a central resource with technical expertise to assist scientists with image analysis problems, and an electrophysiological recording setup for an existing shared two-photon tissue slice rig. Standardized, replicable behavioral tests are critical to translating progress from basic neuroscience research to treatments relevant to human disease. Automated behavioral phenotyping can provide more consistent results by eliminating stress due to removal from the home cage and novelty effects from the test environment. Automated testing can also Improve throughput and reduce costs. This proposal will provide funds to expand capacity for automated behavioral testing in an existing core facility. These core facilities will be a central part of SINTN's effort to advance our understanding of normal brain and spinal cord function at the molecular, cellular, and neural circuit level, and to elucidate the pathological processes underlying malfunction of the nervous system following injury or neurologic and psychiatric diseases. Creating core services to meet these shared research needs will foster efficiency and productivity by minimizing the unnecessary duplication of equipment and creating a centralized source of expertise for shared tasks with the net effect of better solutions in less time. Moreover, the resulting formal and informal collaborations will provide the foundation for a richer, stronger, and more vibrant research community.

DESCRIPTION (provided by applicant): Stroke is a major acute neurological insult that disrupts brain function and causes neuron death. Each year about 800,000 people are affected by stroke in the United States, and most survivors often live with long-term disability. Functional recovery can occur after stroke, and this recovery is attributed to brain remodeling and neuroplasticity, when the brain repairs and rebuilds connections between neurons. Brain stimulation techniques such as electrical stimulation or transcranial magnetic stimulation have been used in animals and humans to enhance recovery after stroke. However, the neural circuits involved and the mechanisms mediating this recovery are not well understood. In addition, these stimulation techniques non-specifically stimulate all cell types near the stimulation site, leading to undesired side effects. In this proposal, we will use the optogenetic approach to specifically stimulate neurons after stroke and examine the effects on functional recovery and the underlying mechanisms. Optogenetics is a novel strategy that utilizes light-sensitive algal proteins, such as Channelrhodopsin (ChR2), to manipulate the excitability of specific cell groups in the brain, in a fast and precise manner. Optogenetic stimulation can increase neuronal excitability, potentially leading to release of neurotrophic factors, enhancement of axonal spouting/synaptogenesis and increased cerebral blood flow, all of which are important in functional recovery after stroke. Therefore, we hypothesize that optogenetic stimulation of neurons in the primary motor cortex (M1) can augment endogenous repair/plasticity mechanisms and promote recovery after stroke. We will use a transgenic mouse line expressing ChR2 under a neuronal promoter to test our hypothesis. Our preliminary data show that optogenetic stimulation of neurons in the ipsilesional primary motor cortex of mice improved their behavioral recovery after stroke. In Aim 1, we will use sensorimotor behavior tests to evaluate functional recovery after optogenetic neuronal stimulation in various brain regions after stroke. We will start stimulation during the recovery phase of stroke and determine the most optimal brain stimulation target for promoting stroke recovery. In Aim2, we will investigate the underlying mechanisms that drive this recovery, including changes in cerebral blood flow, release of neurotrophic factors, axonal sprouting and synaptogenesis. Our study will advance the understanding of endogenous repair and plasticity mechanisms underlying recovery after stroke, as well as determine the most optimal brain stimulation target to promote recovery. Understanding the proteins and processes involved during repair and recovery could lead to novel discoveries of therapeutic drug targets able to facilitate recovery after stroke.

PROJECT SUMMARY Stroke is the leading cause of death with very limited treatment options. This devastating neurological disease is increasingly viewed as a disease of brain connectivity as a damaged stroke area can affect both local and connected brain regions, causing disruptions in neuronal activity and metabolism network-wide. Recovery of lost function can occur after stroke and is attributed to brain remodeling in areas adjacent to or connected to the infarct. In this proposal, we aim to investigate the role of key brain circuits in post-stroke recovery at the functional, cellular and molecular level, using optogenetics, advanced live imaging and high throughput RNA sequencing techniques. Previously our lab has demonstrated that selective optogenetic neuronal stimulation in the ipsilesional motor cortex (iM1) can activate plasticity mechanisms and promote recovery. Recently we have employed the optogenetic functional MRI technique to systematically map brain-wide changes in neural circuits after stroke. We have identified key circuits altered by stroke and demonstrated two key circuits restored by iM1 stimulations. Our map data also revealed two candidate circuits that were not restored by iM1 stimulations, suggesting that greater recovery could be achieved if we can rescue these circuits by directly stimulating them. In this proposal we aim to investigate key neural circuits we identified from our activation maps and elucidate their role in post-stroke recovery. In Aim1 we will use circuit-specific optogenetic tools and functional behavior tests to interrogate the role of key circuits in post-stroke recovery. This aim will address whether these circuits have beneficial or maladaptive role during post-stroke recovery. In Aim2 we will examine cellular resolution of real-time neuronal activity dynamics in key circuits after stroke using a portable live calcium imaging system. This will elucidate the neural activity dynamics (excitatory and inhibitory) of key circuits at the cellular level, allowing us to identify the temporal profile and the key neuronal populations altered by stroke, and how iM1 stimulations affect these characteristics to enhance recovery. In Aim3 we will investigate the transcriptome of key circuit areas using RNAseq, in order to identify key molecular targets and pathways altered by stroke and by iM1 stimulations. Preliminary RNAseq analysis revealed distinct pathways altered by iM1 stimulations. We aim to perform RNAseq in multiple regions including iM1 (stimulation site) and ipsilesional thalamus (iM1- connected region) to elucidate whether similar pathways are involved, and if we can identify a common molecular signature that drive recovery. We will also perform RNAseq in both sexes in order to ascertain any sex-specific differences that may be present in post-stroke recovery. Together these results will 1) advance the understanding of neural circuit dynamics during post-stroke recovery; and 2) identify key neural circuits/cell types/molecular targets and optimal time window for designing brain stimulation strategies and other therapeutic interventions in future clinical studies.

Project Summary (Administrative Core) The adminstrative Core was successfully created 4 years ago to oversee the strategic development of the Stanford neuroscience cores and to assist in the daily operation of the scientific cores, providing a solid administrative, financial, IT, and web infrastructure. The support and oversight of the administrative core has made the operation of these 3 cores a success. Going forward the administrative core will continue to oversee the strategic development of the Stanford Neuroscience Cores. The Administrative Core Steering Committee will provide overall strategic direction to the cores during their biannual or as needed meetings, which will bring together the leadership of the Stanford Neuroscience Institute and key NINDS-funded investigators to critically review and guide its operation. The Steering Committee will insure close coordination of cross-disciplinary projects conducted in the cores and will make sure the tools, material, and technology is widely and openly disseminated to the neuroscience community both at Stanford and internationally. In addition to strategic direction, the Administrative Core has and will continue to provide centralized support services that will enable the scientific cores to do a better job of delivering research services. With dedicated personnel, the Administrative Core has been assisting with internal advertising, soliciting and analyzing user feedback, and creating online communication tools for scientific core user groups. The Administrative Core will also provide the following essential support functions for the neuroscience cores with dedicated time from expert staff, 1) End-user communication and web infrastructure. 2) Information technology services, 3) Accounting and 4) General administrative support. This centralized administrative support has provided many benefits to the scientific cores to enhance their ability to deliver research support.

Human neural stem cell (hNSC) therapy for stroke is showing promise as it moves from the bench into early clinical trials to treat the long term disabilities resulting from stroke. This provides hope for the millions of Americans living with the chronic, debilitating effects of stroke. Major questions remain, however, about how stem cells injected into the brain drive stroke recovery. A clue to stem cell mechanism of action is the recent discovery of the positive correlation between stroke recovery and a brain MRI signal ? T2-FLAIR signal? in stroke patients treated with stem cells. We have successfully reproduced this stem cell-induced FLAIR signal in stroke-injured rats, and shown that its associated with inflammation. This led to our central hypothesis: stem cell transplantation drives recovery by inducing a regenerative inflammatory response. The objective of this grant is to use a rat model of subcortical stroke to investigate the immunomodulatory effects of hNSC transplanted at the chronic stage of stroke, at the regional, cellular and molecular levels using a multimodal approach. In Aim1 we use MRI and PET imaging to identify which brain regions show inflammatory changes after hNSC transplantation, and which inflammatory regions best correlate with recovery. This will also test the utility of these clinically relevant imaging modalities as biomarkers for stroke recovery. In Aim 2 we identify the immune changes induced by hNSC treatment using multiple tools to characterize the types and molecular signatures of the immune cells present, and their spatial interactions. In Aim 3 we determine which hNSC-secreted factors modulate the immune response by testing several candidates, in vitro and in vivo, using CRISPR tools to modulate expression of key candidate factors. We will study the impact of manipulating the levels of these proteins on stroke recovery and immunomodulation. Upon conclusion of the study, we will have made significant advancements in understanding how hNSC-induced immunomodulation affects brain repair. This contribution is significant because it will: a) identify potential biomarkers, both pre- and post-treatment, for hNSC-induced recovery; b) begin to delineate the molecular pathways involved in brain repair; and c) ultimately lead to identification of novel therapies for stroke.

Project Summary / Abstract The Stanford Neurosurgery and Neurology Resident Research Education Program provides training in basic and clinical research, with the goal of fostering resident and fellow growth into independent physician scientists. Through this education participants are then capable of establishing and directing an independent scientific program and obtaining individual research funding. We identify residents with the potential for and commitment to scientific research, and place them for a one to two year term in the laboratories of highly experienced and productive research scientists. Participants also receive extensive counseling and participate in seminars on research skills and ethical research behavior. Their progress and the success of the overall program is repeatedly assessed, including obtaining individual research funding, and appropriate changes in the program will be made. This program will produce neurosurgeons and neurologists making new discoveries regarding the causes of diseases of the brain and spinal cord, and enabling more effective treatments of these diseases.