Lewis Tilney

Last updated
Lewis Tilney
Nationality U.S.
Alma mater
Awards
Scientific career
Fields Cell Biology
Institutions

Lewis G. Tilney is an American cell biologist and professor emeritus at the University of Pennsylvania. [1] He received his Ph.D. from Cornell University Medical School in 1964. [2] Tilney is known for studying the cytoskeleton of animal cells, specifically how different components affect the cytoskeleton's overall properties.

Contents

Research and publications

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Cornell University

Research interests

Tilney's research interests and primary research focus has been on the cytoskeleton of specific portions of animal cells. Through this research it was his goal to identify the cause behind certain properties of the cytoskeleton including length, distribution, and the location of each type of filament and microtubule. Some specific elements Tilney has investigated is the microvilli of intestinal epithelial cells, the actin tail of Listeria , the stereocilia of hair cells in the inner ear, and the bristles of Drosophila . [3]

Drosophila

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Drosophila

Tilney’s research in Drosophila focused on the actin filaments. He observed the cross-linking of adjacent filaments and using forked proteins and fascin investigated how the bundles formed. [4] He observed that in mutants, the aggregation of bundles did not occur which resulted in significantly smaller bundle sizes compared to the wild type. From this, he performed experiments using and removing cross-linking agents forked proteins and fascin to investigate each cross-linkers role in properly forming actin bundles. From his work, he reached the conclusions that forked proteins are used early in the process to aggregate smaller bundles into large ones and they also help the bundles come together. Forked proteins also help fascin entry into the bundles which allows the bundles to cross-link and align properly. [5] He conducted further experiments using antibodies specific to fascin and the forked proteins to show when they were present in actin formation. From this research, he was able to identify that fascin was present predominantly during bundle elongation whereas the forked proteins were present during bundle formation and consequently played a significant role in the shape and size of the actin bundles. Further, it was demonstrated the amount of actin polymerization was also limited by the area where actin had the ability to adhere to connector material. [6]

Toxoplasma gondii

Tilney also conducted research focused on Toxoplasma gondii and how its invasive stages acted in an actin-dependent fashion. To identify whether filaments form, Tilney induced actin polymerization on the anterior end of the parasite molecules using Jasplakinolide, an actin polymerization promoting and stabilizing molecule. Following the introduction of Jasplakinolide, it was observed that the actin-binding protein myosin connected to the newly formed polymer which confirmed its identity to be actin. This represented the first time that this actin polymerization had been observed in parasites. [7] Later research went on to show how protease inhibitors including cysteine and serine can modify the post-translational modifications in the processing of secretory proteins in the parasite. [8]

Awards and honors

Tilney was elected into the National Academy of Sciences for cellular and developmental biology in 1998. [3] He was elected alongside three other scientists in the field of cellular biology including Michael Levine, Lelio Orci, and Joan Ruderman. He was also awarded the Guggenheim Fellowship in 1975. This fellowship is awarded to those individuals who show excellent creativity in the sciences and produce scholarly work. It is awarded in the form of a grant that enables academic research. [9]

Related Research Articles

<span class="mw-page-title-main">Pseudopodia</span> False leg found on slime molds, archaea, protozoans, leukocytes and certain bacteria

A pseudopod or pseudopodium is a temporary arm-like projection of a eukaryotic cell membrane that is emerged in the direction of movement. Filled with cytoplasm, pseudopodia primarily consist of actin filaments and may also contain microtubules and intermediate filaments. Pseudopods are used for motility and ingestion. They are often found in amoebas.

<span class="mw-page-title-main">Cytoskeleton</span> Network of filamentous proteins that forms the internal framework of cells

The cytoskeleton is a complex, dynamic network of interlinking protein filaments present in the cytoplasm of all cells, including those of bacteria and archaea. In eukaryotes, it extends from the cell nucleus to the cell membrane and is composed of similar proteins in the various organisms. It is composed of three main components, microfilaments, intermediate filaments and microtubules, and these are all capable of rapid growth or disassembly dependent on the cell's requirements.

<span class="mw-page-title-main">Microfilament</span> Filament in the cytoplasm of eukaryotic cells

Microfilaments, also called actin filaments, are protein filaments in the cytoplasm of eukaryotic cells that form part of the cytoskeleton. They are primarily composed of polymers of actin, but are modified by and interact with numerous other proteins in the cell. Microfilaments are usually about 7 nm in diameter and made up of two strands of actin. Microfilament functions include cytokinesis, amoeboid movement, cell motility, changes in cell shape, endocytosis and exocytosis, cell contractility, and mechanical stability. Microfilaments are flexible and relatively strong, resisting buckling by multi-piconewton compressive forces and filament fracture by nanonewton tensile forces. In inducing cell motility, one end of the actin filament elongates while the other end contracts, presumably by myosin II molecular motors. Additionally, they function as part of actomyosin-driven contractile molecular motors, wherein the thin filaments serve as tensile platforms for myosin's ATP-dependent pulling action in muscle contraction and pseudopod advancement. Microfilaments have a tough, flexible framework which helps the cell in movement.

<span class="mw-page-title-main">Actin</span> Family of proteins

Actin is a family of globular multi-functional proteins that form microfilaments in the cytoskeleton, and the thin filaments in muscle fibrils. It is found in essentially all eukaryotic cells, where it may be present at a concentration of over 100 μM; its mass is roughly 42 kDa, with a diameter of 4 to 7 nm.

<span class="mw-page-title-main">Myosin</span> Superfamily of motor proteins

Myosins are a superfamily of motor proteins best known for their roles in muscle contraction and in a wide range of other motility processes in eukaryotes. They are ATP-dependent and responsible for actin-based motility.

<span class="mw-page-title-main">Profilin</span>

Profilin is an actin-binding protein involved in the dynamic turnover and reconstruction of the actin cytoskeleton. It is found in most eukaryotic organisms. Profilin is important for spatially and temporally controlled growth of actin microfilaments, which is an essential process in cellular locomotion and cell shape changes. This restructuring of the actin cytoskeleton is essential for processes such as organ development, wound healing, and the hunting down of infectious intruders by cells of the immune system.

<span class="mw-page-title-main">Growth cone</span> Large actin extension of a developing neurite seeking its synaptic target

A growth cone is a large actin-supported extension of a developing or regenerating neurite seeking its synaptic target. It is the growth cone that drives axon growth. Their existence was originally proposed by Spanish histologist Santiago Ramón y Cajal based upon stationary images he observed under the microscope. He first described the growth cone based on fixed cells as "a concentration of protoplasm of conical form, endowed with amoeboid movements". Growth cones are situated on the tips of neurites, either dendrites or axons, of the nerve cell. The sensory, motor, integrative, and adaptive functions of growing axons and dendrites are all contained within this specialized structure.

<span class="mw-page-title-main">Filopodia</span> Actin projections on the leading edge of lamellipodia of migrating cells

Filopodia are slender cytoplasmic projections that extend beyond the leading edge of lamellipodia in migrating cells. Within the lamellipodium, actin ribs are known as microspikes, and when they extend beyond the lamellipodia, they're known as filopodia. They contain microfilaments cross-linked into bundles by actin-bundling proteins, such as fascin and fimbrin. Filopodia form focal adhesions with the substratum, linking them to the cell surface. Many types of migrating cells display filopodia, which are thought to be involved in both sensation of chemotropic cues, and resulting changes in directed locomotion.

<span class="mw-page-title-main">Cell cortex</span> Layer on the inner face of a cell membrane

The cell cortex, also known as the actin cortex, cortical cytoskeleton or actomyosin cortex, is a specialized layer of cytoplasmic proteins on the inner face of the cell membrane. It functions as a modulator of membrane behavior and cell surface properties. In most eukaryotic cells lacking a cell wall, the cortex is an actin-rich network consisting of F-actin filaments, myosin motors, and actin-binding proteins. The actomyosin cortex is attached to the cell membrane via membrane-anchoring proteins called ERM proteins that plays a central role in cell shape control. The protein constituents of the cortex undergo rapid turnover, making the cortex both mechanically rigid and highly plastic, two properties essential to its function. In most cases, the cortex is in the range of 100 to 1000 nanometers thick.

<span class="mw-page-title-main">Protein filament</span> Long chain of protein monomers

In biology, a protein filament is a long chain of protein monomers, such as those found in hair, muscle, or in flagella. Protein filaments form together to make the cytoskeleton of the cell. They are often bundled together to provide support, strength, and rigidity to the cell. When the filaments are packed up together, they are able to form three different cellular parts. The three major classes of protein filaments that make up the cytoskeleton include: actin filaments, microtubules and intermediate filaments.

<span class="mw-page-title-main">Ena/Vasp homology proteins</span>

ENA/VASP homology proteins or EVH proteins are a family of closely related proteins involved in cell motility in vertebrate and invertebrate animals. EVH proteins are modular proteins that are involved in actin polymerization, as well as interactions with other proteins. Within the cell, Ena/VASP proteins are found at the leading edge of Lamellipodia and at the tips of filopodia. Ena, the founding member of the family was discovered in a drosophila genetic screen for mutations that act as dominant suppressors of the abl non receptor tyrosine kinase. Invertebrate animals have one Ena homologue, whereas mammals have three, named Mena, VASP, and Evl.

<span class="mw-page-title-main">Fascin</span> Actin bundling protein

Fascin is an actin bundling protein.

<span class="mw-page-title-main">Prokaryotic cytoskeleton</span> Structural filaments in prokaryotes

The prokaryotic cytoskeleton is the collective name for all structural filaments in prokaryotes. It was once thought that prokaryotic cells did not possess cytoskeletons, but advances in visualization technology and structure determination led to the discovery of filaments in these cells in the early 1990s. Not only have analogues for all major cytoskeletal proteins in eukaryotes been found in prokaryotes, cytoskeletal proteins with no known eukaryotic homologues have also been discovered. Cytoskeletal elements play essential roles in cell division, protection, shape determination, and polarity determination in various prokaryotes.

<span class="mw-page-title-main">ANLN</span> Mammalian protein found in Homo sapiens

Anillin is a conserved protein implicated in cytoskeletal dynamics during cellularization and cytokinesis. The ANLN gene in humans and the scraps gene in Drosophila encode Anillin. In 1989, anillin was first isolated in embryos of Drosophila melanogaster. It was identified as an F-actin binding protein. Six years later, the anillin gene was cloned from cDNA originating from a Drosophila ovary. Staining with anti-anillin antibody showed the anillin localizes to the nucleus during interphase and to the contractile ring during cytokinesis. These observations agree with further research that found anillin in high concentrations near the cleavage furrow coinciding with RhoA, a key regulator of contractile ring formation.

<span class="mw-page-title-main">Stress fiber</span> Contractile actin bundles found in non-muscle cells

Stress fibers are contractile actin bundles found in non-muscle cells. They are composed of actin (microfilaments) and non-muscle myosin II (NMMII), and also contain various crosslinking proteins, such as α-actinin, to form a highly regulated actomyosin structure within non-muscle cells. Stress fibers have been shown to play an important role in cellular contractility, providing force for a number of functions such as cell adhesion, migration and morphogenesis.

<span class="mw-page-title-main">Toll-like receptor 11</span>

Toll-like receptor 11 (TLR11) is a protein that in mice and rats is encoded by the gene TLR11, whereas in humans it is represented by a pseudogene. TLR11 belongs to the toll-like receptor (TLR) family and the interleukin-1 receptor/toll-like receptor superfamily. In mice, TLR11 has been shown to recognise (bacterial) flagellin and (eukaryotic) profilin present on certain microbes, it helps propagate a host immune response. TLR11 plays a fundamental role in both the innate and adaptive immune responses, through the activation of Tumor necrosis factor-alpha, the Interleukin 12 (IL-12) response, and Interferon-gamma (IFN-gamma) secretion. TLR11 mounts an immune response to multiple microbes, including Toxoplasma gondii, Salmonella species, and uropathogenic E. coli, and likely many other species due to the highly conserved nature of flagellin and profilin.

<span class="mw-page-title-main">Rho-associated protein kinase</span>

Rho-associated protein kinase (ROCK) is a kinase belonging to the AGC family of serine-threonine specific protein kinases. It is involved mainly in regulating the shape and movement of cells by acting on the cytoskeleton.

<span class="mw-page-title-main">Arp2/3 complex</span> Macromolecular complex

Arp2/3 complex is a seven-subunit protein complex that plays a major role in the regulation of the actin cytoskeleton. It is a major component of the actin cytoskeleton and is found in most actin cytoskeleton-containing eukaryotic cells. Two of its subunits, the Actin-Related Proteins ARP2 and ARP3, closely resemble the structure of monomeric actin and serve as nucleation sites for new actin filaments. The complex binds to the sides of existing ("mother") filaments and initiates growth of a new ("daughter") filament at a distinctive 70 degree angle from the mother. Branched actin networks are created as a result of this nucleation of new filaments. The regulation of rearrangements of the actin cytoskeleton is important for processes like cell locomotion, phagocytosis, and intracellular motility of lipid vesicles.

Paracytophagy is the cellular process whereby a cell engulfs a protrusion which extends from a neighboring cell. This protrusion may contain material which is actively transferred between the cells. The process of paracytophagy was first described as a crucial step during cell-to-cell spread of the intracellular bacterial pathogen Listeria monocytogenes, and is also commonly observed in Shigella flexneri. Paracytophagy allows these intracellular pathogens to spread directly from cell to cell, thus escaping immune detection and destruction. Studies of this process have contributed significantly to our understanding of the role of the actin cytoskeleton in eukaryotic cells.

Edwin W. Taylor is an adjunct professor of cell and developmental biology at Northwestern University. He was elected to the National Academy of Sciences in 2001. Taylor received a BA in physics and chemistry from the University of Toronto in 1952; an MSc in physical chemistry from McMaster University in 1955, and a PhD in biophysics from the University of Chicago in 1957. In 2001 Taylor was elected to the National Academy of Scineces in Cellular and Developmental Biology and Biochemistry.

References

  1. "Lewis Tilney | Department Of Biology". Live-Sas-Bio.Pantheon.Sas.Upenn.Edu, 2020, https://live-sas-bio.pantheon.sas.upenn.edu/people/lewis-tilney .
  2. "Faculty | Biomedical Graduate Studies | Perelman School Of Medicine At The University Of Pennsylvania". Med.Upenn.Edu, 2020, https://www.med.upenn.edu/apps/ faculty/index.php/g20000320/p4380899
  3. 1 2 "Lewis Tilney". Nasonline.Org, 2020, http://www.nasonline.org/member-directory/m embers/3005869.html.
  4. Guild, Gregory M.; Shaw, Michael K.; Vranich, Kelly A.; Connelly, Patricia S.; Tilney, Lewis G. (1998). "Why Are Two Different Cross-linkers Necessary for Actin Bundle Formation in Vivo and What Does Each Cross-link Contribute?". Journal of Cell Biology. 143 (1): 121–133. doi: 10.1083/jcb.143.1.121 . PMC   2132811 . PMID   9763425.
  5. Tilney, L G et al. "Actin Filaments And Microtubules Play Different Roles During Bristle Elongation In Drosophila". Journal Of Cell Science, vol 113, no. 7, 2000, pp. 1255-1265.
  6. Tilney, Lewis G.; Connelly, Patricia S.; Vranich, Kelly A.; Shaw, Michael K.; Guild, Gregory M. (2000). "Regulation of Actin Filament Cross-linking and Bundle Shape in Drosophila Bristles". The Journal of Cell Biology. 148 (1): 87–99. doi: 10.1083/jcb.148.1.87 . PMC   3207148 . PMID   10629220.
  7. Shaw, M. K.; Tilney, L. G. (1999). "Induction of an acrosomal process in Toxoplasma gondii: Visualization of actin filaments in a protozoan parasite". Proceedings of the National Academy of Sciences. 96 (16): 9095–9099. Bibcode:1999PNAS...96.9095S. doi: 10.1073/pnas.96.16.9095 . PMC   17738 . PMID   10430901.
  8. Shaw, Michael K.; Roos, David S.; Tilney, Lewis G. (2002). "Cysteine and serine protease inhibitors block intracellular development and disrupt the secretory pathway of Toxoplasma gondii". Microbes and Infection. 4 (2): 119–132. doi:10.1016/s1286-4579(01)01520-9. PMID   11880042.
  9. "John Simon Guggenheim Foundation | About The Fellowship". Gf.Org, 2020, https://www.gf.org/about/fellowship/ .