“The laminins are transforming cell biology. For millions of years, Nature has developed laminins for cell adhesion and for providing outside-in signals that support phenotypes and cell survival. By using biologically relevant laminins in cell culture matrices one can create proper cell culture niches for better science and clinical translation.”
- Dr. Karl Tryggvasson
The role of extracellular proteins for cells and organs
Tissues contain both cells and extracellular space and the latter consists of a macromolecule network, the extracellular matrix. The extracellular matrix closest to cells is called the basal lamina, which is thin, flexible sheets of a specialized matrix composed in large of laminins, entactin, perlecan and collagen IV. It underlies all epithelial sheets and tubes, surrounds individual fat cells, muscle cells and Schwann cells or it can, as in the kidney glomerulus, lie between two individual cell layers.
The role of the basal lamina is more than simple structural and filtering roles. The basal lamina determines cell polarity, influences cell metabolism, organizes proteins in the adjacent plasma membranes, serves as a route for cell migration and promotes cell survival, proliferation, and differentiation. The basal lamina and in particular the laminins affect the adjacent cells while at the same time being synthesized and secreted by the very same cells that are associated with it. This is a classic case of inside out and outside in signaling.
The most abundant proteins of the basal lamina are the laminins. Laminins are large glycoproteins with and, and chain and are highly conserved through different species. A simple organism like a Hydra has only one laminin, expressed by its endoderm needed for its ectoderm to produce collagen, together forming the basal lamina between the two cell layers. Through evolution at least 16 identified laminin isoforms with distinct functions are present in the human body. The laminins are the only tissue-specific proteins in the basal lamina. Pluripotent stem cells in the inner cell mass of the blastocysts express laminin-521/511 during embryonic development, skeletal muscle cells are surrounded by laminin-211 and endothelial cells secrete laminin-411/511.
Laminins are mainly thought to mediate their effects through the integrin receptors, but these gigantic proteins can also exert signaling through non-integrin signaling receptors and have shown to have many types of growth factor-like properties. As four different laminins can bind to one single integrin receptor and have four different effects on cells, all binding sites of the laminin molecules are important and the whole protein is needed for the correct function of the cells.
Professor Karl Tryggvason
2013- Tanato Professor of Diabetes Research, Duke-NUS, Singapore
1994- Professor at Division of Matrix Biology, Karolinska Institutet, Stockholm
1975 MD, University of Oulu, Finland
1977 Ph.D., Medicine, University of Oulu, Finland
Icelandic Science Foundation, award
Kaitera Prize, Finland, 1995;
Anders Jahre Prize in Medicine, Oslo, Norway, 1998;
Honorary Professor, Beijing Medical University, 1999;
Homer -Smith Award, American Society of Nephrology, 2000;
Honorary Doctor, University of Iceland, 2001;
Louis -Jeantet Prize in Medicine, Geneva, Switzerland, 2002;
Nils Alwall Prize, International Society of Blood Purification, 2009.
Co-founder, BioStratum Inc, USA, 1994;
Co-founder, NephroGenex Inc, USA, 2007;
Founder, BioLamina AB, Sweden, 2008;
Co -founder, ScaraTech Medical AB, Sweden, 2011.
Invited Speaker to well over 150 international conferences mostly around extracellular matrices and nephrology. Keynote speaker in numerous conferences. Supervised over 42 Ph.D. theses. Over 306 articles, many of them in top-tier publications like Nature, Science, and Cell. With over 26 000 citations, one of the most cited scientists at the Karolinska Institute. H-Index 82. 75 review articles and book chapters. Over 30 patents.
The BioLamina foundation
BioLamina is built on a solid scientific foundation and our products are based on research performed by Professor Karl Tryggvason, a world leader in the field of basal lamina (basement membrane) research. He is interested in knowing about the roles of the basal lamina in normal biology and development, its role in human diseases how its proteins such as laminins can find applications. Having cloned most of the human laminin chains, his experience, methods, and know-how for production and purification of complex matrix proteins are unparalleled.
This knowledge has been transferred to BioLamina as a direct consequence of requests of scientists around the world to test the various unique human recombinant laminins in their laboratories for answering specific research questions. Due to a large number of requests, it became obvious that it was impossible for a research laboratory to fulfill the human recombinant laminin need of the world’s research community. Therefore, Karl co-founded BioLamina with his son Dr. Kristian Tryggvason in 2008 since he believes these tools are a necessity for biologically relevant cell biology research and applications.
Karl is a native of Iceland, which has formed the basis of his personality. Raised on an island with darkness half of the year and with an average temperature just above freezing both winter and summer makes people stubborn, strong and ready to take on any challenge. Ambitious as he is, he left Iceland already after high school to study medicine. Only a year after he got fascinated about science and started working on his Ph.D. on extracellular proteins.
Medicine was rapidly left behind when solving scientific problems became his passion. However, the doctor in him has always coupled his scientific questions with medical problems. He has, for instance, solved the genetic causes of two kidney diseases, one type of muscular dystrophy and a severe skin blistering disease. His studies on kidney diseases helped him elucidate how the kidney filter functions. Dr. Tryggvason has stayed faithful to the extracellular matrix, but since it affects almost all organs and tissues, he has opened several new fields of research. The reason for this is partly curiosity and serendipity, but also the ability to connect the dots and not discard odd results, but use them as a stepping stone to solving novel problems.
Part of Dr. Tryggvason’s success in science is the ability to see the big picture while at the same time be very detail-oriented. Everything he does, he does well and demands that of others. With his research group of hungry and talented scientists, he has always been at the forefront of using new techniques that have given him an edge to solving novel problems.