- The CIRM Genomics Data Coordination and Management Center has made steady progress on our milestones over the last six months. We continued development of a database that stores files and descriptive tags for stem cell genomics projects, and developed a web site that allows authorized users controlled access to these data. The site includes a file browser that displays quality statistics, labels, and tags for each file. For many file types, the file browser provides a link to the UCSC Genome Browser where the data inside the file appears as a track. We imported test data sets from the labs of Stephen Quake (CIP2, Stanford) and Michael Snyder (CIP1, Stanford) into a test version of the database. We imported our first CIRM-funded dataset from the Kristin Baldwin lab (Scripps) into a firewall-protected production version of the database. We interviewed several additional labs, some of which may have data ready by the next reporting period, and have started building software in anticipation of their needs.
- This grant has enabled a plethora of activities in California Stem Cell Genomics. The Stanford Administrative Core for the Center of Excellence in Stem Cell Genomics (CESCG) has been established and is responsible for overseeing joint center activities, and the administration of center-initiated projects (CIP) 1 and 2, and several collaborative research projects (CRP). In the first year of the award the CESCG administration organized monthly telephone conference calls to share research progress and coordinate activities across the Center. On May 1, 2015 the CESCG held its first center-wide retreat in a one-day event at Clark Center on the campus of the Stanford Medical School. The two CIPs have made significant progress. CIP1 has generated a valuable resource of 38 induced pluripotent stem cell lines and established a reliable platform for high throughput derivation of human induced pluripotent stem cell-derived cardiomyocytes for use in downstream high throughput toxicity and drug pharmacology screening assays. CIP2 has completed the first human single cell brain analysis and is in the process of deriving a single cell pancreatic map. We have launched our collaborative research progress grant. Following on the receipt of applications in October 2014 and successful review in January 2015, the Administrative Core at Stanford has also issued subcontract awards for 3 CRPs managed by the CESCG from the Northern California site – two comprehensive project awards CRP-C2 to Daniel Geschwind of UCLA and CRP-C3 to Arnold Kriegstein of UCSF, and a regular project award CRP-R4 to Jeremy Sanford of UCSC. These activities will transform stem cell research in California and continue its preeminence in this area.
Critical to the long term success of the CIRM iPSC Initiative of generating and ensuring the availability of high quality disease-specific human IPSC lines is the establishment and successful operation of a biorepository with proven methods for quality control, safe storage and capabilities for worldwide distribution of high quality, highly-characterized iPSCs. Specifically the biorepository will be responsible for receipt, expansion, quality characterization, safe storage and distribution of human pluripotent stem cells generated by the CIRM stem cell initiative. This biobanking resource will ensure the availability of the highest quality hiPSC resources for researchers to use in disease modeling, target discovery and drug discovery and development for prevalent, genetically complex diseases.
The generation of induced pluripotent stem cells (iPSCs) from patients and subsequently, the ability to differentiate these iPSCs into disease-relevant cell types holds great promise in facilitating the “disease-in-a-dish” approach for studying our understanding of the pathological mechanisms of human disease. iPSCs have already proven to be a useful model for several monogenic diseases such as Parkinson’s, Fragile X Syndrome, Schizophrenia, Spinal Muscular Atrophy, and inherited metabolic diseases such as 1-antitrypsin deficiency, familial hypercholesterolemia, and glycogen storage disease. In addition, the differentiated cells obtained from iPSCs represent a renewable, disease-relevant cell model for high-throughput drug screening and toxicology/safety assessment which will ultimately lead to the successful development of new therapeutic agents. iPSCs also hold great hope for advancing the use of live cells as therapies for correcting the physiological manifestations caused by disease or injury.
- The California Institute for Regenerative Medicine (CIRM) Human Pluripotent Stem Cell Biorepository is operated by the Coriell Institute for Medical Research and is a critical component of the CIRM Human Stem Cell Initiative. The overall goal of this initiative is to generate, for world-wide use by non-profit and for-profit entities, high quality, disease-specific induced pluripotent stem cells (iPSCs). These cells are derived from existing tissues such as blood or skin, and are genetically manipulated in the laboratory to change into cells that resemble embryonic stem cells. iPSCs can be grown indefinitely in the Petri dish and have the remarkable capability to be converted into most of the major cell types in the body including neurons, heart cells, and liver cells. This ability makes iPSCs an exceptional resource for disease modeling as well as for drug screening. The expectation is that these cells will be a major benefit to the process for understanding prevalent, genetically complex diseases and in developing innovative therapeutics.
- The Coriell CIRM iPSC Biorepository, located at the Buck Institute for Research on Aging in Novato, CA, is funded through a competitive grant award to Coriell from CIRM and is managed by Mr. Matt Self under the supervision of the Program Director, Dr. Steven Madore, Director of Molecular Biology at Coriell. The Biorepository will receive biospecimens consisting of peripheral blood mononuclear cells (PBMCs) and skin biopsies obtained from donors recruited by seven Tissue Collector grant awardees. These biospecimens will serve as the starting material for iPSC derivation by Cellular Dynamics, Inc (CDI). Under a contractual agreement with Coriell, CDI will expand each iPSC line to generate sufficient aliquots of high quality cryopreserved cells for distribution via the Coriell on-line catalogue. Aliquots of frozen cell lines and iPSCs will be stored in liquid nitrogen vapor in storage units at the Buck Institute with back-up aliquots stored in a safe off-site location.
- Renovation and construction of the Biorepository began at the Buck Institute in late January. The Biorepository Manger was hired March 1 and after installation of cryogenic storage vessels and alarm validation, the first biospecimens were received on April 30, 2014. Additionally, Coriell has developed a Clinical Information Management System (CIMS) for storing all clinical and demographic data associated with enrolled subjects. Tissue Collectors utilize CIMS via a web interface to upload and edit the subject demographic and clinical information that will ultimately be made available, along with the iPSCs, via Coriell’s on-line catalogue
- As of November 1 specimens representing a total of 725 unique individuals have been received at the Biorepository. These samples include PBMCs obtained from 550 unique individuals, skin biopsies from 72 unique individuals, and 103 primary dermal fibroblast cultures previously prepared in the laboratories of the CIRM Tissue Collectors. A total of 280 biospecimen samples have been delivered to CDI for the purpose of iPSC derivation. The Biorepository is anticipating delivery of the first batches of iPSCs for distribution in early 2015. These lines, along with the associated clinical data, will become available to scientists via the on-line Coriell catalogue. The CIRM Coriell iPSC Biorepository will ensure safe long-term storage and distribution of high quality iPSCs.
Induced pluripotent stem cells (iPSCs) have the potential to differentiate to nearly any cells of the body, thereby providing a new paradigm for studying normal and aberrant biological networks in nearly all stages of development. Donor-specific iPSCs and differentiated cells made from them can be used for basic and applied research, for developing better disease models, and for regenerative medicine involving novel cell therapies and tissue engineering platforms. When iPSCs are derived from a disease-carrying donor; the iPSC-derived differentiated cells may show the same disease phenotype as the donor, producing a very valuable cell type as a disease model. To facilitate wider access to large numbers of iPSCs in order to develop cures for polygenic diseases, we will use a an episomal reprogramming system to produce 3 well-characterized iPSC lines from each of 3,000 selected donors. These donors may express traits related to Alzheimer’s disease, autism spectrum disorders, autoimmune diseases, cardiovascular diseases, cerebral palsy, diabetes, or respiratory diseases. The footprint-free iPSCs will be derived from donor peripheral blood or skin biopsies. iPSCs made by this method have been thoroughly tested, routinely grown at large scale, and differentiated to produce cardiomyocytes, neurons, hepatocytes, and endothelial cells. The 9,000 iPSC lines developed in this proposal will be made widely available to stem cell researchers studying these often intractable diseases.
Induced pluripotent stem cells (iPSCs) offer great promise to the large number of Californians suffering from often intractable polygenic diseases such as Alzheimer’s disease, autism spectrum disorders, autoimmune and cardiovascular diseases, diabetes, and respiratory disease. iPSCs can be generated from numerous adult tissues, including blood or skin, in 4–5 weeks and then differentiated to almost any desired terminal cell type. When iPSCs are derived from a disease-carrying donor, the iPSC-derived differentiated cells may show the same disease phenotype as the donor. In these cases, the cells will be useful for understanding disease biology and for screening drug candidates, and California researchers will benefit from access to a large, genetically diverse iPSC bank. The goal of this project is to reprogram 3,000 tissue samples from patients who have been diagnosed with various complex diseases and from healthy controls. These tissue samples will be used to generate fully characterized, high-quality iPSC lines that will be banked and made readily available to researchers for basic and clinical research. These efforts will ultimately lead to better medicines and/or cellular therapies to treat afflicted Californians. As iPSC research progresses to commercial development and clinical applications, more and more California patients will benefit and a substantial number of new jobs will be created in the state.
- First year progress on grant ID1-06557, " Generation and Characterization of High-Quality, Footprint-Free Human Induced Pluripotent Stem Cell (iPSC) Lines From 3000 Donors to Investigate Multigenic Disease" has met all agreed-upon milestones. In particular, Cellular Dynamics International (CDI) has taken lease to approximately 5000 square feet of lab space at the Buck Institute for Research on Aging in Novato, CA. The majority of this space is located within the new CIRM-funded Stem Cell Research Building at the Buck Institute and was extensively reconfigured to meet the specific needs of this grant. All equipment, including tissue culture safety cabinets and incubators, liquid-handling robotics, and QC instrumentation have been installed and qualified. A total of 16 scientists have been hired and trained (13 in Production and 3 in Quality) and more than 20 Standard Operating Procedures (SOPs) have been developed and approved specifically for this project. These SOPs serve to govern the daily activities of the Production and Quality staff and help ensure consistency and quality throughout the iPSC derivation and characterization process. In addition, a Laboratory Information Management System (LIMS) had to be developed to handle the large amount of data generated by this project and to track all samples from start to finish. The first and most important phase of this LIMS project has been completed; additional functionalities will likely be added to the LIMS during the next year, but completion of phase 1 will allow us to enter full production mode on schedule in the first quarter of year 2. Procedures for the shipping, infectious disease testing, and processing of donor samples were successfully implemented with the seven Tissue Collectors. To date, over 700 samples have been received from these Tissue Collectors and derivation of the first 50 patient-derived iPSC lines has been completed on schedule. These cells have been banked in the Coriell BioRepository, also located at the Buck Institute. The first Distribution Banks will be available for commercial release during year 2.
Many mental disorders are closely associated with problems that occur during brain development in early life. For instance, by 2 years of age, autistic children have larger brains than normal kids, likely due to, at least in part, excess production of neurons and support cells, the building blocks of the nervous system. In autistic brains, how neurons grow various thread-like processes also shows some abnormalities. The cause of autism is complex and likely involves many genetic factors. These developmental defects are also associated with mental disorders caused by single-gene mutations, such as Rett syndrome and fragile X syndrome, the most common form of inherited mental retardation, whose clinical features overlap with autism. However, what causes the developmental defects in brains of children with different mental disorders is largely unknown. In recent years, an exciting new regulatory pathway was discovered that may well contribute to the etiology of mental disorders. The major player in this novel pathway is a class of tiny molecules 21
California is the most populated state in the US and has a large number of patients suffering from various mental disorders. The proposed studies in this grant application will contribute to the mission of developing novel avenues through stem cell research for the diagnosis, prevention and treatment of mental disorders
- Human stem cells, both embryonic and induced pluripotent stem cells, offer exciting opportunities for cell-based therapies in injured or diseased human brains or spinal cords. The clinical efficacy of grafted progenitor cells critically depends on their ability to migrate to the appropriate sites in the adult central nervous system without unwanted proliferation and tumor formation. However, little is known about the cellular behavior of human neural progenitor cells derived from human stem cells or how their proliferation and migration are coordinated. During this reporting period, we continued to study human neural progenitor cells derived from human stem cells, a cell culture system established during the prior reporting period. We focused on microRNAs, a class of small, noncoding RNAs of ~21–23 nucleotides that regulate gene expression at the posttranscriptional level. These small RNAs mostly destabilize target mRNAs or suppress their translation by binding to complementary sequences in the 3' untranslated regions (3'UTRs). Our results obtained during this reporting period indicate that some microRNAs have very interesting functions in human neural progenitors, both in in vitro cell culture system and when transplanted into mouse brains. These new findings may have important implications for stem cell based therapies for neurodegenerative diseases or brain/spinal cord injuries.