Lawrence Rizzolo, PhD, FARVO
Professor Emeritus of Surgery (Gross Anatomy)Cards
About
Titles
Professor Emeritus of Surgery (Gross Anatomy)
Biography
Dr. Rizzolo received his Ph.D. in biochemistry from Duke University in 1977. He received postdoctoral training in biochemistry at Harvard Medical School and in cell biology at the New York University School of Medicine. He received further training in pedagogy and curriculum development at the Harvard-Macy Institute and is a Gallup-Certified strengths coach. Rizzolo joined the Yale faculty in 1993 where he has served as the Director of Medical Sciences for the Section of Anatomy, and Course Director of Human Anatomy and Development. He developed “Anatomy Clinic”, an online guide for training clinical students that is used worldwide. Rizzolo holds joint appointments in the Department of Ophthalmology and Visual Science and the Yale Stem Cell Center. His current research focuses on stem cell approaches to studying retinal degenerations, such as age-related macular degeneration. He is a Fellow of the Association for Research in Vision and Ophthalmology, and serves on the editorial boards of Anatomical Sciences Education and Molecular Vision. Rizzolo was the liaison between the American Association of Anatomists and the Anatomical Society of Ireland and Great Britain. He currently advises the Peking Union Medical College on curricular development.
Departments & Organizations
- Rizzolo Lab
- Surgery
- Yale Stem Cell Center
- Yale Ventures
Education & Training
- Research Associate
- New York University, Cell Biology (1985)
- Research Fellow
- Harvard University, Biochemistry (1981)
- PhD
- Duke University (1977)
Research
Overview
Biomedical Research
The retinal pigment epithelium (RPE) plays a central role in retinal physiology by forming the outer blood-retinal barrier and supporting the function of the photoreceptors. Many retinopathies involve a disruption of the epithelium's interactions with the neural retina or its uncontrolled proliferation. Surgical interventions limit the progression of disease, but fail to restore function. Although encouraging progress has been made with RPE transplantation, its effectiveness is limited to the earliest stages of disease when patients would be reluctant to have surgery. Our goal is to expand that window of opportunity by understanding the interactions of the RPE with its neighbors, the choroid and the neural portion of the retina. Our early studies with chick RPE demonstrated that: 1) As the neural retina matures, it secretes factors that induce the RPE to form the outer blood-retinal barrier by decreasing the permeability of RPE junctions. 2) At the RPE/neural retina interface, extracellular matrix or cell-cell interactions regulate the distribution of certain integrins. These integrins are redistributed when the neural retina and its extracellular matrix mature. 3) Initially, diffusible factors produced by the neural retina maintain the apical polarity of the Na,K-ATPase. These retinal factors differ from those that decrease the permeability of the monolayer, and may act indirectly through effects on the structure of the apical microvilli. 4) Gene array studies demonstrate that 40% of the RPE transcriptome changes in parallel with retinal development. Retinal secretions regulate many of these changes.
Our current research asks whether the chick studies are relevant to human biology. Surprisingly, we found that the tight junctions of human RPE differ significantly from those of non-primate vertebrates -- surprising because tight junctions serve a conserved function. Tight junctions are an integral part of any blood-tissue barrier, because they regulate diffusion across the paracellular spaces of an epithelial monolayer. Tight junctions form a network of anastomosing strands that encircles each cell and binds it to its neighbors in the monolayer. They regulate the permeability and selectivity of the paracellular path and are matched with the ion channels and transporters that regulate the transcellular movement of solutes. Claudins are a family of at least 24 proteins that determine the properties of tight junctions and each epithelium expresses a subset that reflects the physiology of the organ. Human RPE expresses a different set of claudins that non-primate vertebrates which implies differences in retinal physiology.
In both cultures of human fetal RPE (hfRPE) and human embryonic stem cell (hESC)-derived RPE, we found that we could make the barrier function more in vivo-like by using a serum free medium that we call SFM-1. Studies of the transcriptome demonstrate that SFM-1 affects many genes and that adaptation of the cultures to SFM-1 furthers the maturation of hESC-RPE. This was demonstrated in two cells, H1 and H9. Examining function and the transcriptome leads us to believe that even after SFM-1, hESC-RPE remains less mature than hfRPE isolated from 16 week-gestation fetal eyes. The study identifies 25 marker genes that can be used to monitor the maturation of RPE that we predict will occur when hESC-RPE is co-cultured with hESC-derived retinal precursors (RPC).
To test this hypothesis, RPE and RPC need to be culture in the same media. It appears that SFM-1 furthers the maturation of RPC so that co-culture is feasible. We have found that a scaffold of gelatin decorated with glycoproteins provides a way to culture RPC as a flat sheet that can be layered atop a sheet of RPE. Preliminary data indicate that gene expression is altered in both the RPE and RPC layers following co-culture.
I believe this co-culture model will provide a superior platform to explore the efficacy of drugs that might treat retinal degenerations or improve the efficacy of transplantation. Further, the model itself may prove to be a suitable tissue for transplantation into patients with advanced retinal degeneration.
Educational Research
The international community of medical educators struggles with how to decompress an overcrowded curriculum. The questions have become what to teach, when to teach it and how to teach it in less time. The problem is especially acute for anatomy. Even though the classical anatomy course is a large component of medical school, residency programs believe their residents come ill-prepared. Further, the pool of qualified instructors is shrinking. To address these issues of content, efficiency and instructors, I investigated what students need, how they learn and how instructors teach. I call the resulting method “Clinically-Engaged Anatomy”. Clinically-engaged anatomy engages students in professional behaviors to learn the anatomy that prepares them for clerkships. Students learn how to draw inferences from skillful observation to form testable hypotheses, test them and teach others about the process. The coursework requires students to develop the teamwork skills that characterize modern medical practice. The clinical cases that drive the curriculum are cases commonly encountered in Yale affiliated hospitals. Students study the anatomy that underlies the patient’s history, physical exam, imaging studies and medical or surgical resolution. The cadaver becomes a simulated patient whereby anatomy is explored by performing surgical procedures. This approach fosters integration of anatomy with clinical training and has attracted large numbers of clinic faculty to participate. Despite a 30% reduction in course hours, we demonstrated that students recall more when they enter clerkships. Clinically-engaged anatomy merges advanced web resources with laboratory dissection. My “Anatomy Clinic” website attracts more than 17,000 non-Yale page viewings per year from around the world and is used in Great Britain for their “Basic Training Programme for Anatomy Professionals”. The anesthesiology and otolaryngology residency training programs adapted these methods to their laboratory sessions. Therefore, clinically engaged anatomy has identified important anatomy to teach, conveys that knowledge effectively in less time, and attracts a large number of faculty who would not participate in the old course.
Current research asks how the new Medical School Curriculum impacts student outcomes in the new anatomy course. All of the basic science courses were integrated with the aim to shortened courses by reducing redundancy, leveraging integration to teach more efficiently, and using innovation.Ongoing projects focus on the effectiveness of new innovations and whether integration has achieved its goals.
A second project investigates how clinical students incorporate interactive computer activities into their daily work and how that information might guide curricular development.
- We use fetal and stem cell-derived culture models of human retinal pigment epithelium RPE to study mechanisms of retinal degeneration and examine putative therapeutic agents.
- We are investigating the role of autophagy in young and aged RPE, and how changes in autophagy might relate to age-related macular degeneration.
- We use embryonic stem cells to study the interactions of retinal and RPE progenetors with the goal of developing superior engineered tissues for drug testing and transplantation.
- We are investigating how the new Medical School Curriculum impacts the anatomy course. Pedagogical innovation and integration with other courses are being used to deliver a shortened, yet more effective anatomy course.
Medical Research Interests
Academic Achievements & Community Involvement
News & Links
Media
- The different domains of the RPE plasma membrane are revealed by fluorescent labeling of the microvilli (Na,K-ATPase, red) and basolateral membranes (spectrin, green). In most epithelia, these proteins colocalize in the basolateral membrane, but in RPE most of the ATPase localizes in the microvilli.
- Two essential features of the RPE are its polarity and barrier properties. The RPE is polarized, because it separates the neural retina from the fenestrated capillaries in the choroid. The apical membrane of RPE interacts with the photoreceptors; the basal membrane interacts with the choroid. Like other epithelia, the apical and basolateral membranes have different protein compositions that enable each to interact with different environments. The barrier properties are regulated by two components. Transepithelial transport through the cells is regulated by plasma membrane pumps and transporters. Passive diffusion through the paracellular spaces is regulated by the strands of tight junctions that encircle each cell. Tight junctions are semi-selective, which means some solutes cross them more readily than others. By regulating both the transcellular and paracellular pathways, the RPE regulates the ionic composition of the subretinal space. For review see: Wilt SD, Rizzolo LJ: Unique aspects of the blood-brain barrier. In Tight Junctions, Ed. M. Cereijido and J.M. Anderson, CRC Press., 2001. Rizzolo LJ: Polarity and the Development of the Outer Blood-Retinal Barrier. Histol. Histopath. 12:1057-1067, 1997. Rizzolo, L.J. (2007) Development and role of tight junctions in the retinal pigment epithelium, Int. Rev. Cytol. 258:195-234.
- In contrast to neurons, epithelial polarity is not inherent in the cell but is induced by the environment. The environment of the RPE changes dramatically as the neural retina and the choriocapillaris differentiate. Just as the polarity of RPE changes during development, the intercellular junctions that bind neighboring RPE cells also mature gradually. These junctions retard diffusion across the RPE through the paracellular spaces. In many epithelia these junctions are relatively leaky, but in the RPE they must be tight to form a blood-retinal barrier. Our studies indicate that this plasticity of the membranes and junctions depends upon interactions with the neural retina. For reviews see: Wilt SD, Rizzolo LJ: Unique aspects of the blood-brain barrier. In Tight Junctions, Ed. M. Cereijido and J.M. Anderson, CRC Press 2001. Rizzolo LJ: Polarity and the Development of the Outer Blood-Retinal Barrier. Histol. Histopath. 12:1057-1067, 1997.
- RPE tight junctions labeled en face with actin (green) and ZO-1 (red).
News
- September 30, 2016
Students teaching students
- April 25, 2016
Embryonic stem cells and diseases of the retina
- April 25, 2016
Longest-running show on Cedar Street ends after more than 60 years
- December 30, 2014Source: Medicine@Yale
Yale Stem Cell Research Boosted By State