Your search keyword '"Velia M. Fowler"' showing total 151 results

1. Recessive TMOD1 mutation causes childhood cardiomyopathy

Author

Catalina Vasilescu, Mert Colpan, Tiina H. Ojala, Tuula Manninen, Aino Mutka, Kaisa Ylänen, Otto Rahkonen, Tuija Poutanen, Laura Martelius, Reena Kumari, Helena Hinterding, Virginia Brilhante, Simo Ojanen, Pekka Lappalainen, Juha Koskenvuo, Christopher J. Carroll, Velia M. Fowler, Carol C. Gregorio, and Anu Suomalainen

Subjects

Biology (General), QH301-705.5

Abstract

Abstract Familial cardiomyopathy in pediatric stages is a poorly understood presentation of heart disease in children that is attributed to pathogenic mutations. Through exome sequencing, we report a homozygous variant in tropomodulin 1 (TMOD1; c.565C>T, p.R189W) in three individuals from two unrelated families with childhood-onset dilated and restrictive cardiomyopathy. To decipher the mechanism of pathogenicity of the R189W mutation in TMOD1, we utilized a wide array of methods, including protein analyses, biochemistry and cultured cardiomyocytes. Structural modeling revealed potential defects in the local folding of TMOD1R189W and its affinity for actin. Cardiomyocytes expressing GFP-TMOD1R189W demonstrated longer thin filaments than GFP-TMOD1wt-expressing cells, resulting in compromised filament length regulation. Furthermore, TMOD1R189W showed weakened activity in capping actin filament pointed ends, providing direct evidence for the variant’s effect on actin filament length regulation. Our data indicate that the p.R189W variant in TMOD1 has altered biochemical properties and reveals a unique mechanism for childhood-onset cardiomyopathy.

Published

2024

2. Proteomic and functional analyses of the periodic membrane skeleton in neurons

Author

Ruobo Zhou, Boran Han, Roberta Nowak, Yunzhe Lu, Evan Heller, Chenglong Xia, Athar H. Chishti, Velia M. Fowler, and Xiaowei Zhuang

Subjects

Science

Abstract

In neurons the membrane-associated periodic skeleton (MPS) consists of actin, spectrin, and associated molecules. Here the authors use proteomic analysis and super-resolution imaging to provide insight into the molecular composition and organization of the MPS, and its functions in axon-diameter regulation and neurite-neurite interactions.

Published

2022

3. Non-uniform distribution of myosin-mediated forces governs red blood cell membrane curvature through tension modulation.

Author

Haleh Alimohamadi, Alyson S Smith, Roberta B Nowak, Velia M Fowler, and Padmini Rangamani

Subjects

Biology (General), QH301-705.5

Abstract

The biconcave disk shape of the mammalian red blood cell (RBC) is unique to the RBC and is vital for its circulatory function. Due to the absence of a transcellular cytoskeleton, RBC shape is determined by the membrane skeleton, a network of actin filaments cross-linked by spectrin and attached to membrane proteins. While the physical properties of a uniformly distributed actin network interacting with the lipid bilayer membrane have been assumed to control RBC shape, recent experiments reveal that RBC biconcave shape also depends on the contractile activity of nonmuscle myosin IIA (NMIIA) motor proteins. Here, we use the classical Helfrich-Canham model for the RBC membrane to test the role of heterogeneous force distributions along the membrane and mimic the contractile activity of sparsely distributed NMIIA filaments. By incorporating this additional contribution to the Helfrich-Canham energy, we find that the RBC biconcave shape depends on the ratio of forces per unit volume in the dimple and rim regions of the RBC. Experimental measurements of NMIIA densities at the dimple and rim validate our prediction that (a) membrane forces must be non-uniform along the RBC membrane and (b) the force density must be larger in the dimple than the rim to produce the observed membrane curvatures. Furthermore, we predict that RBC membrane tension and the orientation of the applied forces play important roles in regulating this force-shape landscape. Our findings of heterogeneous force distributions on the plasma membrane for RBC shape maintenance may also have implications for shape maintenance in different cell types.

Published

2020

4. An interview with Velia M. Fowler, Department of Biological Sciences, University of Delaware, DE, USA

Author

Paul Trevorrow and Velia M. Fowler

Subjects

Structural Biology, Cell Biology

Published

2022

5. Proteomic and functional analyses of the periodic membrane skeleton in neurons

Author

Yunzhe Lu, Athar H. Chishti, Chenglong Xia, Xiaowei Zhuang, Velia M. Fowler, Ruobo Zhou, Roberta B. Nowak, Boran Han, and Evan Heller

Subjects

Proteomics, congenital, hereditary, and neonatal diseases and abnormalities, General Physics and Astronomy, Interactome, General Biochemistry, Genetics and Molecular Biology, Motor protein, Myosin, medicine, Spectrin, Axon, skin and connective tissue diseases, Actin, Ion channel, Neurons, Multidisciplinary, Cell adhesion molecule, Chemistry, Cell Membrane, nutritional and metabolic diseases, Membrane Proteins, General Chemistry, Actins, Axons, Cell biology, medicine.anatomical_structure, nervous system, Cell Adhesion Molecules

Abstract

Actin, spectrin, and associated molecules form a membrane-associated periodic skeleton (MPS) in neurons. The molecular composition and functions of the MPS remain incompletely understood. Here, using co-immunoprecipitation and mass spectrometry, we identified hundreds of potential candidate MPS-interacting proteins that span diverse functional categories. We examined representative proteins in several of these categories using super-resolution imaging, including previously unknown MPS structural components, as well as motor proteins, cell adhesion molecules, ion channels, and signaling proteins, and observed periodic distributions characteristic of the MPS along the neurites for ~20 proteins. Genetic perturbations of the MPS and its interacting proteins further suggested functional roles of the MPS in axon-axon and axon-dendrite interactions and in axon diameter regulation, and implicated the involvement of MPS interactions with cell adhesion molecules and non-muscle myosin in these roles. These results provide insights into the interactome of the MPS and suggest previously unknown functions of the MPS in neurons.

Published

2022

6. Nonmuscle Myosin IIA Regulates the Precise Alignment of Hexagonal Eye Lens Epithelial Cells During Fiber Cell Formation and Differentiation

Author

Sadia T. Islam, Catherine Cheng, Justin Parreno, and Velia M. Fowler

Subjects

General Medicine

Published

2023

7. Nanoscale dynamics of actin filaments in the red blood cell membrane skeleton

Author

Roberta B, Nowak, Haleh, Alimohamadi, Kersi, Pestonjamasp, Padmini, Rangamani, Velia M, Fowler, and Yap, Alpha

Subjects

Erythrocytes, 1.1 Normal biological development and functioning, Erythrocyte Membrane, Spectrin, macromolecular substances, Cell Biology, Biological Sciences, Medical and Health Sciences, Actins, Actin Cytoskeleton, Clinical Research, Underpinning research, Molecular Biology, Developmental Biology

Abstract

Red blood cell (RBC) shape and deformability are supported by a planar network of short actin filament (F-actin) nodes (∼37 nm length, 15-18 subunits) interconnected by long spectrin strands at the inner surface of the plasma membrane. Spectrin-F-actin network structure underlies quantitative modeling of forces controlling RBC shape, membrane curvature, and deformation, yet the nanoscale organization and dynamics of the F-actin nodes in situ are not well understood. We examined F-actin distribution and dynamics in RBCs using fluorescent-phalloidin labeling of F-actin imaged by multiple microscopy modalities. Total internal reflection fluorescence and Zeiss Airyscan confocal microscopy demonstrate that F-actin is concentrated in multiple brightly stained F-actin foci ∼200-300 nm apart interspersed with dimmer F-actin staining regions. Single molecule stochastic optical reconstruction microscopy imaging of Alexa 647-phalloidin-labeled F-actin and computational analysis also indicates an irregular, nonrandom distribution of F-actin nodes. Treatment of RBCs with latrunculin A and cytochalasin D indicates that F-actin foci distribution depends on actin polymerization, while live cell imaging reveals dynamic local motions of F-actin foci, with lateral movements, appearance and disappearance. Regulation of F-actin node distribution and dynamics via actin assembly/disassembly pathways and/or via local extension and retraction of spectrin strands may provide a new mechanism to control spectrin-F-actin network connectivity, RBC shape, and membrane deformability.

Published

2022

8. Megakaryocyte migration defects due to nonmuscle myosin IIA mutations underlie thrombocytopenia in MYH9-related disease

Author

Rong Liu, Kasturi Pal, James R. Sellers, Arit Ghosh, Velia M. Fowler, Neil Billington, and Roberta B. Nowak

Subjects

Mutation, Chemistry, Immunology, Cell migration, Chemotaxis, Cell Biology, Hematology, Platelets and Thrombopoiesis, medicine.disease_cause, Biochemistry, Phenotype, Cell biology, medicine.anatomical_structure, Megakaryocyte, Precursor cell, medicine, Platelet, Actin

Abstract

Megakaryocytes (MKs), the precursor cells for platelets, migrate from the endosteal niche of the bone marrow (BM) toward the vasculature, extending proplatelets into sinusoids, where circulating blood progressively fragments them into platelets. Nonmuscle myosin IIA (NMIIA) heavy chain gene (MYH9) mutations cause macrothrombocytopenia characterized by fewer platelets with larger sizes leading to clotting disorders termed myosin-9–related disorders (MYH9-RDs). MYH9-RD patient MKs have proplatelets with thicker and fewer branches that produce fewer and larger proplatelets, which is phenocopied in mouse Myh9-RD models. Defective proplatelet formation is considered to be the principal mechanism underlying the macrothrombocytopenia phenotype. However, MYH9-RD patient MKs may have other defects, as NMII interactions with actin filaments regulate physiological processes such as chemotaxis, cell migration, and adhesion. How MYH9-RD mutations affect MK migration and adhesion in BM or NMIIA activity and assembly prior to proplatelet production remain unanswered. NMIIA is the only NMII isoform expressed in mature MKs, permitting exploration of these questions without complicating effects of other NMII isoforms. Using mouse models of MYH9-RD (NMIIAR702C+/−GFP+/−, NMIIAD1424N+/−, and NMIIAE1841K+/−) and in vitro assays, we investigated MK distribution in BM, chemotaxis toward stromal-derived factor 1, NMIIA activity, and bipolar filament assembly. Results indicate that different MYH9-RD mutations suppressed MK migration in the BM without compromising bipolar filament formation but led to divergent adhesion phenotypes and NMIIA contractile activities depending on the mutation. We conclude that MYH9-RD mutations impair MK chemotaxis by multiple mechanisms to disrupt migration toward the vasculature, impairing proplatelet release and causing macrothrombocytopenia.

Published

2020

9. Erythroid differentiation in mouse erythroleukemia cells depends on Tmod3‐mediated regulation of actin filament assembly into the erythroblast membrane skeleton

Author

Arit Ghosh, Megan Coffin, Richard West, and Velia M. Fowler

Subjects

Erythroblasts, Spectrin, Biochemistry, Actin Cytoskeleton, Mice, Cell Line, Tumor, Genetics, Animals, Erythropoiesis, Leukemia, Erythroblastic, Acute, Protein Multimerization, Molecular Biology, Tropomodulin, Biotechnology

Abstract

Erythroid differentiation (ED) is a complex cellular process entailing morphologically distinct maturation stages of erythroblasts during terminal differentiation. Studies of actin filament (F-actin) assembly and organization during terminal ED have revealed essential roles for the F-actin pointed-end capping proteins, tropomodulins (Tmod1 and Tmod3). Tmods bind tropomyosins (Tpms), which enhance Tmod capping and F-actin stabilization. Tmods can also nucleate F-actin assembly, independent of Tpms. Tmod1 is present in the red blood cell (RBC) membrane skeleton, and deletion of Tmod1 in mice leads to a mild compensated anemia due to mis-regulated F-actin lengths and membrane instability. Tmod3 is not present in RBCs, and global deletion of Tmod3 leads to embryonic lethality in mice with impaired ED. To further decipher Tmod3's function during ED, we generated a Tmod3 knockout in a mouse erythroleukemia cell line (Mel ds19). Tmod3 knockout cells appeared normal prior to ED, but showed defects during progression of ED, characterized by a marked failure to reduce cell and nuclear size, reduced viability, and increased apoptosis. Tmod3 does not assemble with Tmod1 and Tpms into the Triton X-100 insoluble membrane skeleton during ED, and loss of Tmod3 had no effect on α1,β1-spectrin and protein 4.1R assembly into the membrane skeleton. However, F-actin, Tmod1 and Tpms failed to assemble into the membrane skeleton during ED in absence of Tmod3. We propose that Tmod3 nucleation of F-actin assembly promotes incorporation of Tmod1 and Tpms into membrane skeleton F-actin, and that this is integral to morphological maturation and cell survival during erythroid terminal differentiation.

Published

2022

10. MYH9‐related disease mutations cause abnormal red blood cell morphology through increased myosin‐actin binding at the membrane

Author

Roberta B. Nowak, Rémi Favier, Lydie Da Costa, Alyson S. Smith, Anastasiya Demenko, Velia M. Fowler, Kasturi Pal, Carlo Zaninetti, and Alessandro Pecci

Subjects

Male, Hearing Loss, Sensorineural, Erythrocytes, Abnormal, medicine.disease_cause, Article, Motor protein, 03 medical and health sciences, 0302 clinical medicine, Myosin, medicine, Humans, Gene, Actin, Mutation, Myosin Heavy Chains, medicine.diagnostic_test, Chemistry, Erythrocyte Membrane, Complete blood count, Hematology, Thrombocytopenia, Phenotype, Actins, Cell biology, Red blood cell, medicine.anatomical_structure, 030220 oncology & carcinogenesis, Female, 030215 immunology

Abstract

MYH9-related disease (MYH9-RD) is a rare, autosomal dominant disorder caused by mutations in MYH9, the gene encoding the actin-activated motor protein non-muscle myosin IIA (NMIIA). MYH9-RD patients suffer from bleeding syndromes, progressive kidney disease, deafness, and/or cataracts, but the impact of MYH9 mutations on other NMIIA-expressing tissues remains unknown. In human red blood cells (RBCs), NMIIA assembles into bipolar filaments and binds to actin filaments (F-actin) in the spectrin-F-actin membrane skeleton to control RBC biconcave disk shape and deformability. Here, we tested the effects of MYH9 mutations in different NMIIA domains (motor, coiled-coil rod, or non-helical tail) on RBC NMIIA function. We found that MYH9-RD does not cause clinically significant anemia and that patient RBCs have normal osmotic deformability as well as normal membrane skeleton composition and micron-scale distribution. However, analysis of complete blood count data and peripheral blood smears revealed reduced hemoglobin content and elongated shapes, respectively, of MYH9-RD RBCs. Patients with mutations in the NMIIA motor domain had the highest numbers of elongated RBCs. Patients with mutations in the motor domain also had elevated association of NMIIA with F-actin at the RBC membrane. Our findings support a central role for motor domain activity in NMIIA regulation of RBC shape and define a new sub-clinical phenotype of MYH9-RD.

Published

2019

11. Proteome-transcriptome analysis and proteome remodeling in mouse lens epithelium and fibers

Author

Larry L. David, Catherine Cheng, Deyou Zheng, Saima Limi, Phillip A. Wilmarth, Ales Cvekl, Yilin Zhao, and Velia M. Fowler

Subjects

Proteomics, 0301 basic medicine, Proteome, Gene Expression, Article, Transcriptome, Mice, 03 medical and health sciences, Cellular and Molecular Neuroscience, 0302 clinical medicine, Tandem Mass Spectrometry, Crystallin, Lens, Crystalline, Animals, RNA, Messenger, Fluorescent Antibody Technique, Indirect, Induced pluripotent stem cell, Chemistry, Gene Expression Profiling, Cell Differentiation, Epithelial Cells, Crystallins, Sensory Systems, Lens Fiber, Cell biology, Ophthalmology, 030104 developmental biology, Animals, Newborn, Fiber cell, Membrane protein, 030221 ophthalmology & optometry, Chromatography, Liquid, Transcription Factors

Abstract

Epithelial cells and differentiated fiber cells represent distinct compartments in the ocular lens. While previous studies have revealed proteins that are preferentially expressed in epithelial vs. fiber cells, a comprehensive proteomics library comparing the molecular compositions of epithelial vs. fiber cells is essential for understanding lens formation, function, disease and regenerative potential, and for efficient differentiation of pluripotent stem cells for modeling of lens development and pathology in vitro. To compare protein compositions between the lens epithelium and fibers, we employed tandem mass spectrometry (2D-LC/MS) analysis of microdissected mouse P0.5 lenses. Functional classifications of the top 525 identified proteins into gene ontology categories by molecular processes and subcellular localizations, were adapted for the lens. Expression levels of both epithelial and fiber proteomes were compared with whole lens proteome and mRNA levels using E14.5, E16.5, E18.5, and P0.5 RNA-Seq data sets. During this developmental time window, multiple complex biosynthetic and catabolic processes generate the molecular and structural foundation for lens transparency. As expected, crystallins showed a high correlation between their mRNA and protein levels. Comprehensive data analysis confirmed and/or predicted roles for transcription factors (TFs), RNA-binding proteins (e.g. Carhsp1), translational apparatus including ribosomal heterogeneity and initiation factors, microtubules, cytoskeletal [e.g. non-muscle myosin IIA heavy chain (Myh9) and βB2-spectrin (Sptbn2)] and membrane proteins in lens formation and maturation. Our data highlighted many proteins with unknown functions in the lens that were preferentially enriched in epithelium or fibers, setting the stage for future studies to further dissect the roles of these proteins in fiber cell differentiation vs. epithelial cell maintenance. In conclusion, the present proteomic datasets represent the first mouse lens epithelium and fiber cell proteomes, establish comparative analyses of protein and RNA-Seq data, and characterize the major proteome remodeling required to form the mature lens fiber cells.

Published

2019

12. Tropomodulins

Author

Arit Ghosh and Velia M. Fowler

Subjects

Actin Cytoskeleton, Microfilament Proteins, General Agricultural and Biological Sciences, General Biochemistry, Genetics and Molecular Biology, Actins, Tropomodulin

Abstract

Arit Ghosh and Velia Fowler introduce the structural features and functions of tropomodulins - actin-binding proteins that cap the slow-growing (pointed) ends of actin filaments.

Published

2021

13. Nanoscale organization of Actin Filaments in the Red Blood Cell Membrane Skeleton

Author

Haleh Alimohamadi, Pestonjamasp K, Roberta B. Nowak, Velia M. Fowler, and Padmini Rangamani

Subjects

Protein filament, Total internal reflection fluorescence microscope, Materials science, Membrane curvature, Confocal microscopy, law, Live cell imaging, Microscopy, Biophysics, Spectrin, macromolecular substances, Actin, law.invention

Abstract

Red blood cell (RBC) shape and deformability are supported by a planar network of short actin filament (F-actin) nodes interconnected by long spectrin molecules at the inner surface of the plasma membrane. Spectrin-F-actin network structure underlies quantitative modelling of forces controlling RBC shape, membrane curvature and deformation, yet the nanoscale organization of F-actin nodes in the networkin situis not understood. Here, we examined F-actin distribution in RBCs using fluorescent-phalloidin labeling of F-actin imaged by multiple microscopy modalities. Total internal reflection fluorescence (TIRF) and Zeiss Airyscan confocal microscopy demonstrate that F-actin is concentrated in multiple brightly stained F-actin foci ∼200-300 nm apart interspersed with dimmer F-actin staining regions. Live cell imaging reveals dynamic lateral movements, appearance and disappearance of F-actin foci. Single molecule STORM imaging and computational cluster analysis of experimental and synthetic data sets indicate that individual filaments are non-randomly distributed, with the majority as multiple filaments, and the remainder sparsely distributed as single filaments. These data indicate that F-actin nodes are non-uniformly distributed in the spectrin-F-actin network and necessitate reconsideration of current models of forces accounting for RBC shape and membrane deformability, predicated upon uniform distribution of F-actin nodes and associated proteins across the micron-scale RBC membrane.

Published

2021

14. Microstructural determinants of lens stiffness in rat versus guinea pig lenses

Author

Justin Parreno, Forbes Ke, Sandeep Aryal, Velia M. Fowler, and Abera K

Subjects

Flexibility (anatomy), Chemistry, Stiffness, Capsule, Presbyopia, medicine.disease, law.invention, Guinea pig, Lens (optics), medicine.anatomical_structure, Fiber cell, law, medicine, medicine.symptom, Nucleus, Biomedical engineering

Abstract

Proper ocular lens function requires lens biomechanical flexibility which is lost in presbyopia during aging. As increasing lens size has been shown previously to correlate with lens biomechanical stiffness in aging, we tested the hypothesis that whole lens size determines gross biomechanical stiffness. We used an allometric approach to evaluate this hypothesis by comparing lenses from three rodent species (mouse, rats and guinea pigs) of varying size. While rat lenses are larger and stiffer than mouse lenses, guinea pig lenses are even larger than rat lenses but are softer than the rat lens. This indicates that lens size is not a sole determinant of lens stiffness and disproves our hypothesis. Therefore, we investigated the scaling of lens microstructural features that could potentially explain the differences in biomechanical stiffness between rat and guinea pig lenses, including lens capsule thickness, epithelial cell area, fiber cell widths, suture organization, and nuclear size. Capsule thickness, epithelial cell area, and fiber cell widths scaled with lens size (i.e., greater in guinea pig lenses than rats), indicating that sizes of these features do not correlate with the stiffness of rat lenses, while suture organization was similar between rats and guinea pigs. However, we found that the hard rat lens nucleus occupies a greater fraction of the lens than the guinea pig lens nucleus, suggesting a role for nuclear size in determining whole lens stiffness. Therefore, while many features contribute to lens biomechanical properties, the size of the lens nucleus with respect to the size of the lens could be a major determinant of lens stiffness in rats versus guinea pigs.

Published

2021

15. Tropomyosin 3.1 Association With Actin Stress Fibers is Required for Lens Epithelial to Mesenchymal Transition

Author

Justin Parreno, Elizabeth H. Kwon, Velia M. Fowler, and Michael B. Amadeo

Subjects

0301 basic medicine, Gene isoform, Male, Stress fiber, Epithelial-Mesenchymal Transition, Cell Survival, Blotting, Western, Tropomyosin, Real-Time Polymerase Chain Reaction, Tropomyosin 3, law.invention, 03 medical and health sciences, Lens, Mice, Transforming Growth Factor beta2, 0302 clinical medicine, Confocal microscopy, law, Stress Fibers, Lens, Crystalline, Animals, Protein Isoforms, Epithelial–mesenchymal transition, RNA, Messenger, education, Actin, Mice, Knockout, education.field_of_study, Microscopy, Confocal, Chemistry, fibrosis, Epithelial Cells, General Medicine, Actins, Cell biology, Mice, Inbred C57BL, 030104 developmental biology, Cell culture, 030220 oncology & carcinogenesis, cataracts, Female, actin

Abstract

Purpose Epithelial to mesenchymal transition (EMT) is a cause of anterior and posterior subcapsular cataracts. Central to EMT is the formation of actin stress fibers. Selective targeting of actin stress fiber-associated tropomyosin (Tpm) in epithelial cells may be a means to prevent stress fiber formation and repress lens EMT. Methods We identified Tpm isoforms in mouse immortalized lens epithelial cells and epithelial and fiber cells from whole lenses by semi-quantitative reverse transcription-polymerase chain reaction (RT-PCR) followed Sanger sequencing. We focused on the role of one particular tropomyosin isoform, Tpm3.1, in EMT. To induce EMT, we treated cells or native lenses with TGFβ2. To test the function of Tpm3.1, we exposed cells or whole lenses to a Tpm3.1-specific chemical inhibitor, TR100, as well as investigated lenses from Tpm3.1 knockout mice. We examined stress fiber formation by confocal microscopy and assessed EMT progression by analysis of alpha-smooth muscle actin (αSMA) mRNA (real-time RT-PCR), and protein (Western immunoassay [WES]). Results Lens epithelial cells express eight Tpm isoforms. Cell culture studies showed that TGFβ2 treatment results in the upregulation of Tpm3.1, which associates with actin in stress fibers. TR100 prevents stress fiber formation and reduces αSMA in TGFβ2-treated cells. Using an ex vivo lens culture model, TGFβ2 treatment results in stress fiber formation at the basal regions of the epithelial cells. Genetic knockout of Tpm3.1 or treatment of lenses with TR100 prevents basal stress fiber formation and reduces epithelial αSMA levels. Conclusions Targeting specific stress fiber associated tropomyosin isoform, Tpm3.1, is a means to repress lens EMT.

Published

2020

16. The Tudor-domain protein TDRD7, mutated in congenital cataract, controls the heat shock protein HSPB1 (HSP27) and lens fiber cell morphology

Author

Salma Al Saai, Catherine Cheng, Emily Paglione, Shaili Patel, Deepti Anand, Salil A. Lachke, Shinichiro Chuma, Xiaolu Xu, Mona Batish, Lisa Glazewski, Robert W. Mason, Archana D. Siddam, Carrie E. Barnum, Velia M. Fowler, Shawn W. Polson, Soma Dash, and Shuo Wei

Subjects

AcademicSubjects/SCI01140, Eye Diseases, Biology, Cell morphology, Cataract, 03 medical and health sciences, Mice, Xenopus laevis, 0302 clinical medicine, Downregulation and upregulation, Heat shock protein, Lens, Crystalline, Genetics, Animals, Humans, RNA, Messenger, Cytoskeleton, Eye Proteins, Molecular Biology, Genetics (clinical), Heat-Shock Proteins, 030304 developmental biology, Cell Nucleus, 0303 health sciences, Messenger RNA, RNA, General Medicine, Lens Fiber, Cell biology, Disease Models, Animal, Fiber cell, Ribonucleoproteins, Mutation, Microscopy, Electron, Scanning, General Article, 030217 neurology & neurosurgery, Molecular Chaperones

Abstract

Mutations of the RNA granule component TDRD7 (OMIM: 611258) cause pediatric cataract. We applied an integrated approach to uncover the molecular pathology of cataract in Tdrd7−/− mice. Early postnatal Tdrd7−/− animals precipitously develop cataract suggesting a global-level breakdown/misregulation of key cellular processes. High-throughput RNA sequencing integrated with iSyTE-bioinformatics analysis identified the molecular chaperone and cytoskeletal modulator, HSPB1, among high-priority downregulated candidates in Tdrd7−/− lens. A protein fluorescence two-dimensional difference in-gel electrophoresis (2D-DIGE)-coupled mass spectrometry screen also identified HSPB1 downregulation, offering independent support for its importance to Tdrd7−/− cataractogenesis. Lens fiber cells normally undergo nuclear degradation for transparency, posing a challenge: how is their cell morphology, also critical for transparency, controlled post-nuclear degradation? HSPB1 functions in cytoskeletal maintenance, and its reduction in Tdrd7−/− lens precedes cataract, suggesting cytoskeletal defects may contribute to Tdrd7−/− cataract. In agreement, scanning electron microscopy (SEM) revealed abnormal fiber cell morphology in Tdrd7−/− lenses. Further, abnormal phalloidin and wheat germ agglutinin (WGA) staining of Tdrd7−/− fiber cells, particularly those exhibiting nuclear degradation, reveals distinct regulatory mechanisms control F-actin cytoskeletal and/or membrane maintenance in post-organelle degradation maturation stage fiber cells. Indeed, RNA immunoprecipitation identified Hspb1 mRNA in wild-type lens lysate TDRD7-pulldowns, and single-molecule RNA imaging showed co-localization of TDRD7 protein with cytoplasmic Hspb1 mRNA in differentiating fiber cells, suggesting that TDRD7–ribonucleoprotein complexes may be involved in optimal buildup of key factors. Finally, Hspb1 knockdown in Xenopus causes eye/lens defects. Together, these data uncover TDRD7’s novel upstream role in elevation of stress-responsive chaperones for cytoskeletal maintenance in post-nuclear degradation lens fiber cells, perturbation of which causes early-onset cataracts.

Published

2020

17. The effects of mechanical strain on mouse eye lens capsule and cellular microstructure

Author

Catherine Cheng, Roberta B. Nowak, Justin Parreno, and Velia M. Fowler

Subjects

0301 basic medicine, Cell Physiology, Materials science, Lens Capsule, Crystalline, Biology, law.invention, Stress (mechanics), 03 medical and health sciences, 0302 clinical medicine, law, Confocal microscopy, medicine, Extracellular, Animals, Fiber, Eye lens, Cell Shape, Molecular Biology, 030304 developmental biology, 0303 health sciences, Strain (chemistry), Soft tissue, Capsule, Epithelial Cells, Articles, Cell Biology, Microstructure, Biomechanical Phenomena, Mice, Inbred C57BL, Lens (optics), 030104 developmental biology, medicine.anatomical_structure, Fiber cell, Lens (anatomy), 030221 ophthalmology & optometry, Stress, Mechanical, Deformation (engineering), Biomedical engineering

Abstract

The mouse eye lens was used as a model for multiscale transfer of loads. In the lens, compressive strain is distributed across specific lens tissue microstructures, including the extracellular capsule, as well as the epithelial and fiber cells. The removal of high loads resulted in complete recovery of most, but not all, microstructures., The understanding of multiscale load transfer within complex soft tissues is incomplete. The eye lens is ideal for multiscale mechanical studies because its principal function is to fine-focus light at different distances onto the retina via shape changes. The biomechanical function, resiliency, and intricate microstructure of the lens makes it an excellent nonconnective soft tissue model. We hypothesized that strain applied onto whole-lens tissue leads to deformation of specific microstructures and that this deformation is reversible following load removal. For this examination, mouse lenses were compressed by sequential application of increasing load. Using confocal microscopy and quantitative image analysis, we determined that axial strain ≥10% reduces capsule thickness, expands epithelial cell area, and separates fiber cell tips at the anterior region. At the equatorial region, strain ≥6% increases fiber cell widths. The effects of strain on lens epithelial cell area, capsule thickness, and fiber cell widths are reversible following the release from strain. However, the separation of fiber cell tips is irreversible at high loads. This irreversible separation between fiber cell tips leads to incomplete whole-lens resiliency. The lens is an accessible biomechanical model system that provides new insights on multiscale transfer of loads in soft tissues.

Published

2018

18. Tropomodulins and Leiomodins: Actin Pointed End Caps and Nucleators in Muscles

Author

Velia M. Fowler and Roberto Dominguez

Subjects

0301 basic medicine, Myofibril assembly, Muscles, Biophysics, Muscle Proteins, macromolecular substances, Biology, Tropomyosin, Sarcomere, Cell biology, Protein filament, 03 medical and health sciences, 030104 developmental biology, 0302 clinical medicine, Biochemistry, Biophysical Perspective, Animals, Humans, Myocyte, Spectrin, Cytoskeleton, 030217 neurology & neurosurgery, Actin, Tropomodulin

Abstract

Cytoskeletal structures characterized by actin filaments with uniform lengths, including the thin filaments of striated muscles and the spectrin-based membrane skeleton, use barbed and pointed-end capping proteins to control subunit addition/dissociation at filament ends. While several proteins cap the barbed end, tropomodulins (Tmods), a family of four closely related isoforms in vertebrates, are the only proteins known to specifically cap the pointed end. Tmods are ∼350 amino acids in length, and comprise alternating tropomyosin- and actin-binding sites (TMBS1, ABS1, TMBS2, and ABS2). Leiomodins (Lmods) are related in sequence to Tmods, but display important differences, including most notably the lack of TMBS2 and the presence of a C-terminal extension featuring a proline-rich domain and an actin-binding WASP-Homology 2 domain. The Lmod subfamily comprises three somewhat divergent isoforms expressed predominantly in muscle cells. Biochemically, Lmods differ from Tmods, acting as powerful nucleators of actin polymerization, not capping proteins. Structurally, Lmods and Tmods display crucial differences that correlate well with their different biochemical activities. Physiologically, loss of Lmods in striated muscle results in cardiomyopathy or nemaline myopathy, whereas complete loss of Tmods leads to failure of myofibril assembly and developmental defects. Yet, interpretation of some of the in vivo data has led to the idea that Tmods and Lmods are interchangeable or, at best, different variants of two subfamilies of pointed-end capping proteins. Here, we review and contrast the existing literature on Tmods and Lmods, and propose a model of Lmod function that attempts to reconcile the in vitro and in vivo data, whereby Lmods nucleate actin filaments that are subsequently capped by Tmods during sarcomere assembly, turnover, and repair.

Published

2017

19. The lens actin filament cytoskeleton: Diverse structures for complex functions

Author

Catherine Cheng, Roberta B. Nowak, and Velia M. Fowler

Subjects

0301 basic medicine, macromolecular substances, Article, 03 medical and health sciences, Cellular and Molecular Neuroscience, 0302 clinical medicine, Lens, Crystalline, Myosin, medicine, Animals, Humans, Actin-binding protein, Cytoskeleton, Actin, biology, Microfilament Proteins, Cell Differentiation, Epithelial Cells, Sensory Systems, Lens Fiber, Cell biology, Actin Cytoskeleton, Ophthalmology, 030104 developmental biology, medicine.anatomical_structure, Fiber cell, Lens (anatomy), biology.protein, Tropomodulin, 030217 neurology & neurosurgery

Abstract

The eye lens is a transparent and avascular organ in the front of the eye that is responsible for focusing light onto the retina in order to transmit a clear image. A monolayer of epithelial cells covers the anterior hemisphere of the lens, and the bulk of the lens is made up of elongated and differentiated fiber cells. Lens fiber cells are very long and thin cells that are supported by sophisticated cytoskeletal networks, including actin filaments at cell junctions and the spectrin-actin network of the membrane skeleton. In this review, we highlight the proteins that regulate the diverse actin filament networks in the lens and discuss how these actin cytoskeletal structures assemble and function in epithelial and fiber cells. We then discuss methods that have been used to study actin in the lens and unanswered questions that can be addressed with novel techniques.

Published

2017

20. TPM3.1 association with actin stress fibers is required for lens epithelial to mesenchymal transition

Author

Michael B. Amadeo, Velia M. Fowler, Elizabeth H. Kwon, and Justin Parreno

Subjects

Gene isoform, 0303 health sciences, Stress fiber, Chemistry, Tropomyosin, Cell biology, law.invention, 03 medical and health sciences, 0302 clinical medicine, Downregulation and upregulation, Cell culture, Confocal microscopy, law, Epithelial–mesenchymal transition, 030217 neurology & neurosurgery, Actin, 030304 developmental biology

Abstract

PurposeEpithelial to mesenchymal transition (EMT) is a cause of anterior and posterior subcapsular cataracts. Central to EMT is the formation of actin stress fibers. Targeting specific, stress fiber associated tropomyosin in epithelial cells may be a means to prevent stress fiber formation and repress lens EMT.MethodsWe identified Tpm isoforms in mouse immortalized lens epithelial cells and isolated whole lenses by semi-quantitative PCR followed Sanger sequencing. We focused on the role of one particular tropomyosin isoform, Tpm3.1, in EMT. To stimulate EMT, we cultured cells or native lenses in TGFβ2. To test the function of Tpm3.1, we exposed cells or whole lenses to a Tpm3.1-specific chemical inhibitor, TR100, as well as investigated lenses from Tpm3.1 knockout mice. We examined stress fiber formation by confocal microscopy and assessed EMT progression by αsma mRNA (qPCR) and protein (WES immunoassay) analysis.ResultsLens epithelial cells express eight tropomyosin isoforms. Cell culture studies showed that TGFβ2 treatment results in an upregulation of Tpm3.1, which associates with actin in stress fibers. TR100 prevents stress fiber formation and reduces αsma in TGFβ2 treated cells. We confirmed the role of Tpm3.1 in lens epithelial cells in the native lens ex vivo. Culture of whole lenses in the presence of TGFβ2 results in stress fiber formation at the basal regions of epithelial cells. Knockout of Tpm3.1 or treatment of lenses with TR100 prevents basal stress fiber formation and reduces epithelial αsma levels.ConclusionTargeting specific stress fiber associated tropomyosin isoform, Tpm3.1, is a means to represses lens EMT.

Published

2019

21. Non-uniform distribution of myosin-mediated forces governs red blood cell membrane curvature through tension modulation

Author

Velia M. Fowler, Alyson S. Smith, Roberta B. Nowak, Haleh Alimohamadi, Padmini Rangamani, and Elofsson, Arne

Subjects

0301 basic medicine, Erythrocytes, Bending, Phalloidine, Cell Membranes, Lipid Bilayers, Biochemistry, Mathematical Sciences, 0302 clinical medicine, Contractile Proteins, Membrane Technology, Spectrin, Glycophorins, Biology (General), Cytoskeleton, Lipid bilayer, Staining, Microscopy, Ecology, Chemistry, Physics, Classical Mechanics, Biological Sciences, Built Structures, Deformation, Membrane Staining, Actin Cytoskeleton, Cross-Linking Reagents, Membrane, Computational Theory and Mathematics, Membrane curvature, Modeling and Simulation, Physical Sciences, Engineering and Technology, Cellular Structures and Organelles, Research Article, Structural Engineering, QH301-705.5, Bioinformatics, 1.1 Normal biological development and functioning, Motor Proteins, Actin Motors, Myosins, Research and Analysis Methods, Stress, Membrane Structures, Fluorescence, Motor protein, 03 medical and health sciences, Cellular and Molecular Neuroscience, Molecular Motors, Underpinning research, Erythrocyte Deformability, Information and Computing Sciences, Genetics, Humans, Molecular Biology, Ecology, Evolution, Behavior and Systematics, Actin, Damage Mechanics, Myosin Heavy Chains, Rhodamines, Erythrocyte Membrane, Biology and Life Sciences, Proteins, Membrane Proteins, Cell Biology, Mechanical, Cytoskeletal Proteins, 030104 developmental biology, Microscopy, Fluorescence, Membrane protein, Specimen Preparation and Treatment, Biophysics, Stress, Mechanical, Generic health relevance, Membrane Characteristics, 030217 neurology & neurosurgery

Abstract

The biconcave disk shape of the mammalian red blood cell (RBC) is unique to the RBC and is vital for its circulatory function. Due to the absence of a transcellular cytoskeleton, RBC shape is determined by the membrane skeleton, a network of actin filaments cross-linked by spectrin and attached to membrane proteins. While the physical properties of a uniformly distributed actin network interacting with the lipid bilayer membrane have been assumed to control RBC shape, recent experiments reveal that RBC biconcave shape also depends on the contractile activity of nonmuscle myosin IIA (NMIIA) motor proteins. Here, we use the classical Helfrich-Canham model for the RBC membrane to test the role of heterogeneous force distributions along the membrane and mimic the contractile activity of sparsely distributed NMIIA filaments. By incorporating this additional contribution to the Helfrich-Canham energy, we find that the RBC biconcave shape depends on the ratio of forces per unit volume in the dimple and rim regions of the RBC. Experimental measurements of NMIIA densities at the dimple and rim validate our prediction that (a) membrane forces must be non-uniform along the RBC membrane and (b) the force density must be larger in the dimple than the rim to produce the observed membrane curvatures. Furthermore, we predict that RBC membrane tension and the orientation of the applied forces play important roles in regulating this force-shape landscape. Our findings of heterogeneous force distributions on the plasma membrane for RBC shape maintenance may also have implications for shape maintenance in different cell types., Author summary The spectrin-actin network of the membrane skeleton plays an important role in controlling specialized cell membrane morphology. In the paradigmatic red blood cell (RBC), where actin filaments are present exclusively in the membrane skeleton, recent experiments reveal that nonmuscle myosin IIA (NMIIA) motor contractility maintains the RBC biconcave disk shape. In this study, we have identified criteria for micron-scale distributions of NMIIA forces at the membrane required to maintain the biconcave disk shape of an RBC in the resting condition. Supported by experimental measurements of RBC NMIIA distribution, we showed that a heterogeneous force distribution with a larger force density at the dimple is able to capture the experimentally observed biconcave morphology of an RBC with better accuracy compared to previous models that did not consider the heterogeneity in the force distribution. Furthermore, we showed that the biconcave geometry of the RBC is closely regulated by the effective membrane tension and the direction of applied forces on the membrane. These findings can be generalized to any force-mediated membrane shape, providing insight into the role of actomyosin forces in prescribing and maintaining the morphology of different cell types.

Published

2019

22. Software-based measurement of thin filament lengths: an open-source GUI for Distributed Deconvolution analysis of fluorescence images

Author

Velia M. Fowler and David S. Gokhin

Subjects

0301 basic medicine, Physics, Histology, business.industry, Fluorescence, Sarcomere, Signal, Pathology and Forensic Medicine, 03 medical and health sciences, Length measurement, 030104 developmental biology, 0302 clinical medicine, Software, Optics, Line (geometry), Deconvolution, business, Myofibril, 030217 neurology & neurosurgery

Abstract

The periodically arranged thin filaments within the striated myofibrils of skeletal and cardiac muscle have precisely regulated lengths, which can change in response to developmental adaptations, pathophysiological states, and genetic perturbations. We have developed a user-friendly, open-source ImageJ plugin that provides a graphical user interface (GUI) for super-resolution measurement of thin filament lengths by applying Distributed Deconvolution (DDecon) analysis to periodic line scans collected from fluorescence images. In the workflow presented here, we demonstrate thin filament length measurement using a phalloidin-stained cryosection of mouse skeletal muscle. The DDecon plugin is also capable of measuring distances of any periodically localized fluorescent signal from the Z- or M-line, as well as distances between successive Z- or M-lines, providing a broadly applicable tool for quantitative analysis of muscle cytoarchitecture. These functionalities can also be used to analyse periodic fluorescence signals in nonmuscle cells.

Published

2016

23. Cytoskeletal Control of Erythroid Properties and Enucleation

Author

Velia M. Fowler

Subjects

Chemistry, Immunology, Enucleation, Cell Biology, Hematology, Cytoskeleton, Biochemistry, Cell biology

Published

2020

24. Red Blood Cell Curvature is Controlled by the Non-uniform Distribution of Myosin-Mediated Forces and Membrane Tension

Author

Alyson S. Smith, Haleh Alimohamadi, Velia M. Fowler, and Padmini Rangamani

Subjects

Red blood cell, Uniform distribution (continuous), medicine.anatomical_structure, Chemistry, Myosin, Biophysics, medicine, Curvature, Membrane tension

Published

2020

25. Multifunctional roles of Tropomodulin-3 in regulating actin dynamics

Author

Velia M. Fowler and Justin Parreno

Subjects

0301 basic medicine, Tropomodulin-3, biology, Chemistry, Biophysics, Cell migration, Review, macromolecular substances, Tropomyosin, Cell biology, Adherens junction, 03 medical and health sciences, 030104 developmental biology, Structural Biology, biology.protein, Lamellipodium, Cytoskeleton, Molecular Biology, Tropomodulin, Actin

Abstract

Tropomodulins (Tmods) are proteins that cap the slow growing (pointed) ends of actin filaments (F-actin). The basis for our current understanding of Tmod function comes from studies in cells with relatively stable and highly organized F-actin networks, leading to the view that Tmod capping functions principally to preserve F-actin stability. However, not only is Tmod capping dynamic, but it also can play major roles in regulating diverse cellular processes involving F-actin remodeling. Here, we highlight the multifunctional roles of Tmod with a focus on Tmod3. Like other Tmods, Tmod3 binds tropomyosin (Tpm) and actin, capping pure F-actin at submicromolar and Tpm-coated F-actin at nanomolar concentrations. Unlike other Tmods, Tmod3 can also bind actin monomers and its ability to bind actin is inhibited by phosphorylation of Tmod3 by Akt2. Tmod3 is ubiquitously expressed and present in a diverse array of cytoskeletal structures, including contractile structures such as sarcomere-like units of actomyosin stress fibers and in the F-actin network encompassing adherens junctions. Tmod3 participates in F-actin network remodeling in lamellipodia during cell migration, and in the assembly of specialized F-actin networks during exocytosis. Furthermore, Tmod3 is required for development, regulating F-actin mesh formation during meiosis I of mouse oocytes, erythroblast enucleation in definitive erythropoiesis, and megakaryocyte morphogenesis in the mouse fetal liver. Thus, Tmod3 plays vital roles in dynamic and stable F-actin networks in cell physiology and development, with further research required to delineate the mechanistic details of Tmod3 regulation in the aforementioned processes, or in other yet to be discovered processes.

Published

2018

26. Tropomyosin 3.5 protects F-actin networks required for tissue biomechanical properties

Author

Catherine Cheng, Roberta B. Nowak, Sondip K. Biswas, Michael B. Amadeo, Velia M. Fowler, and Woo-Kuen Lo

Subjects

Gene isoform, 0301 basic medicine, Cell, Tropomyosin, macromolecular substances, Actinin, Tropomyosin 3, law.invention, Mice, 03 medical and health sciences, In vivo, law, Lens, Crystalline, medicine, Animals, Spectrin, education, Actin, education.field_of_study, Mechanical load, biology, Chemistry, Cell Differentiation, Cell Biology, Actins, Lens Fiber, Lens (optics), medicine.anatomical_structure, 030104 developmental biology, Fimbrin, biology.protein, Biophysics, Tropomodulin, Research Article

Abstract

Tropomyosins (Tpms) stabilize F-actin and regulate interactions with other actin-binding proteins. The eye lens changes shape in order to fine focus light to transmit a clear image, and thus lens organ function is tied to its biomechanical properties, presenting an opportunity to study Tpm functions in tissue mechanics. The major mouse lens Tpm is Tpm3.5 (TM5NM5), a previously unstudied isoform. Decreased levels of Tpm3.5 lead to softer and less mechanically resilient lenses that are unable to resume their original shape after compression. While cell organization and morphology appear unaffected, Tmod1 dissociates from the membrane in Tpm3.5-deficient lens fiber cells resulting in reorganization of the spectrin-F-actin and α-actinin-F-actin networks at the membrane. These rearranged F-actin networks appear to be less able to support mechanical load and resilience leading to an overall change in tissue mechanical properties. This is the firstin vivoevidence that Tpm is essential for cell biomechanical stability in a load-bearing non-muscle tissue and indicates that Tpm3.5 protects mechanically stable, load-bearing F-actinin vivo.SummaryTropomyosin 3.5 stabilizes F-actin in eye lens fiber cells and promotes normal tissue biomechanical properties. Tpm3.5 deficiency leads to F-actin network rearrangements and decreased lens stiffness and resilience.

Published

2018

27. Thematic Minireview Series: The State of the Cytoskeleton in 2015

Author

Velia M. Fowler and Robert S. Fischer

Subjects

Microtubule cytoskeleton, Minireviews, macromolecular substances, Cell Biology, Biology, Actin cytoskeleton, Septin, Microtubules, Biochemistry, Actins, Biomechanical Phenomena, Cell biology, Prokaryotic cytoskeleton, Actin Cytoskeleton, Cytoskeletal Proteins, Tubulin, Microtubule, biology.protein, Animals, Humans, Cytoskeleton, Molecular Biology, Actin

Abstract

The study of cytoskeletal polymers has been an active area of research for more than 70 years. However, despite decades of pioneering work by some of the brightest scientists in biochemistry, cell biology, and physiology, many central questions regarding the polymers themselves are only now starting to be answered. For example, although it has long been appreciated that the actin cytoskeleton provides contractility and couples biochemical responses with mechanical stresses in cells, only recently have we begun to understand how the actin polymer itself responds to mechanical loads. Likewise, although it has long been appreciated that the microtubule cytoskeleton can be post-translationally modified, only recently have the enzymes responsible for these modifications been characterized, so that we can now begin to understand how these modifications alter the polymerization and regulation of microtubule structures. Even the septins in eukaryotes and the cytoskeletal polymers of prokaryotes have yielded new insights due to recent advances in microscopy techniques. In this thematic series of minireviews, these topics are covered by some of the very same scientists who generated these recent insights, thereby providing us with an overview of the State of the Cytoskeleton in 2015.

Published

2015

28. Dynamic actin filaments control the mechanical behavior of the human red blood cell membrane

Author

David S. Gokhin, Alfonso de la Piedra, Roberta B. Nowak, Velia M. Fowler, Ionita Ghiran, and Joseph A. Khoory

Subjects

Erythrocytes, Arp2/3 complex, macromolecular substances, Microfilament, chemistry.chemical_compound, Actin remodeling of neurons, hemic and lymphatic diseases, Humans, Cytochalasin, Cytoskeleton, Molecular Biology, biology, Cell Membrane, Actin remodeling, Fluorescence recovery after photobleaching, hemic and immune systems, Cell Biology, Articles, Actin cytoskeleton, Actins, Cell biology, Biomechanical Phenomena, Actin Cytoskeleton, Osmotic Fragility, chemistry, biology.protein, Protein Multimerization, circulatory and respiratory physiology

Abstract

The short actin filaments in the spectrin-actin membrane skeleton of human red blood cells (RBCs) are capable of dynamic subunit exchange and mobility. Actin dynamics in RBCs regulates the biomechanical properties of the RBC membrane., Short, uniform-length actin filaments function as structural nodes in the spectrin-actin membrane skeleton to optimize the biomechanical properties of red blood cells (RBCs). Despite the widespread assumption that RBC actin filaments are not dynamic (i.e., do not exchange subunits with G-actin in the cytosol), this assumption has never been rigorously tested. Here we show that a subpopulation of human RBC actin filaments is indeed dynamic, based on rhodamine-actin incorporation into filaments in resealed ghosts and fluorescence recovery after photobleaching (FRAP) analysis of actin filament mobility in intact RBCs (∼25–30% of total filaments). Cytochalasin-D inhibition of barbed-end exchange reduces rhodamine-actin incorporation and partially attenuates FRAP recovery, indicating functional interaction between actin subunit turnover at the single-filament level and mobility at the membrane-skeleton level. Moreover, perturbation of RBC actin filament assembly/disassembly with latrunculin-A or jasplakinolide induces an approximately twofold increase or ∼60% decrease, respectively, in soluble actin, resulting in altered membrane deformability, as determined by alterations in RBC transit time in a microfluidic channel assay, as well as by abnormalities in spontaneous membrane oscillations (flickering). These experiments identify a heretofore-unrecognized but functionally important subpopulation of RBC actin filaments, whose properties and architecture directly control the biomechanical properties of the RBC membrane.

Published

2015

29. Tropomodulin Isoform-Specific Regulation of Dendrite Development and Synapse Formation

Author

Yanfang Rui, Velia M. Fowler, Kuai Yu, Omotola F. Omotade, H. Criss Hartzell, Wenliang Lei, and James Q. Zheng

Subjects

0301 basic medicine, Male, Myofilament, Dendritic spine, Synaptogenesis, Hippocampal formation, Hippocampus, Rats, Sprague-Dawley, 03 medical and health sciences, Pregnancy, Animals, Protein Isoforms, Cytoskeleton, Actin, Cells, Cultured, Research Articles, Neurons, biology, General Neuroscience, Dendrites, Actin cytoskeleton, Cell biology, Rats, 030104 developmental biology, Synapses, biology.protein, Female, Tropomodulin

Abstract

Neurons of the CNS elaborate highly branched dendritic arbors that host numerous dendritic spines, which serve as the postsynaptic platform for most excitatory synapses. The actin cytoskeleton plays an important role in dendrite development and spine formation, but the underlying mechanisms remain incompletely understood. Tropomodulins (Tmods) are a family of actin-binding proteins that cap the slow-growing (pointed) end of actin filaments, thereby regulating the stability, length, and architecture of complex actin networks in diverse cell types. Three members of the Tmod family, Tmod1, Tmod2, and Tmod3 are expressed in the vertebrate CNS, but their function in neuronal development is largely unknown. In this study, we present evidence that Tmod1 and Tmod2 exhibit distinct roles in regulating spine development and dendritic arborization, respectively. Using rat hippocampal tissues from both sexes, we find that Tmod1 and Tmod2 are expressed with distinct developmental profiles: Tmod2 is expressed early during hippocampal development, whereas Tmod1 expression coincides with synaptogenesis. We then show that knockdown of Tmod2, but not Tmod1, severely impairs dendritic branching. Both Tmod1 and Tmod2 are localized to a distinct subspine region where they regulate local F-actin stability. However, the knockdown of Tmod1, but not Tmod2, disrupts spine morphogenesis and impairs synapse formation. Collectively, these findings demonstrate that regulation of the actin cytoskeleton by different members of the Tmod family plays an important role in distinct aspects of dendrite and spine development.SIGNIFICANCE STATEMENTThe Tropomodulin family of molecules is best known for controlling the length and stability of actin myofilaments in skeletal muscles. While several Tropomodulin members are expressed in the brain, fundamental knowledge about their role in neuronal function is limited. In this study, we show the unique expression profile and subcellular distribution of Tmod1 and Tmod2 in hippocampal neurons. While both Tmod1 and Tmod2 regulate F-actin stability, we find that they exhibit isoform-specific roles in dendrite development and synapse formation: Tmod2 regulates dendritic arborization, whereas Tmod1 is required for spine development and synapse formation. These findings provide novel insight into the actin regulatory mechanisms underlying neuronal development, thereby shedding light on potential pathways disrupted in a number of neurological disorders.

Published

2017

30. HSPB7 is indispensable for heart development by modulating actin filament assembly

Author

Christopher T. Pappas, Velia M. Fowler, Tongbin Wu, Yongxin Mu, Xi Fang, Sylvia M. Evans, Ju Chen, Carol C. Gregorio, Julius Bogomolovas, Roberta B. Nowak, and Jennifer Veevers

Subjects

0301 basic medicine, Male, Organogenesis, HSP27 Heat-Shock Proteins, Arp2/3 complex, Muscle Proteins, Microfilament, Inbred C57BL, Cardiovascular, Protein filament, Actin remodeling of neurons, Mice, Congenital, 2.1 Biological and endogenous factors, Myocytes, Cardiac, Aetiology, Heart Defects, Mice, Knockout, Multidisciplinary, biology, actin polymerization, Heart, heart development, Biological Sciences, Cell biology, Actin Cytoskeleton, Heart Disease, Female, HSPB7, Cardiomyopathies, Cardiac, Tropomodulin, Heart Defects, Congenital, Sarcomeres, Knockout, thin filament assembly, macromolecular substances, 03 medical and health sciences, Nebulin, Animals, Actin, Myocytes, Myocardium, Actin remodeling, Mice, Inbred C57BL, Cytoskeletal Proteins, 030104 developmental biology, biology.protein, MDia1, sarcomere

Abstract

Small heat shock protein HSPB7 is highly expressed in the heart. Several mutations within HSPB7 are associated with dilated cardiomyopathy and heart failure in human patients. However, the precise role of HSPB7 in the heart is still unclear. In this study, we generated global as well as cardiac-specific HSPB7 KO mouse models and found that loss of HSPB7 globally or specifically in cardiomyocytes resulted in embryonic lethality before embryonic day 12.5. Using biochemical and cell culture assays, we identified HSPB7 as an actin filament length regulator that repressed actin polymerization by binding to monomeric actin. Consistent with HSPB7’s inhibitory effects on actin polymerization, HSPB7 KO mice had longer actin/thin filaments and developed abnormal actin filament bundles within sarcomeres that interconnected Z lines and were cross-linked by α-actinin. In addition, loss of HSPB7 resulted in up-regulation of Lmod2 expression and mislocalization of Tmod1. Furthermore, crossing HSPB7 null mice into an Lmod2 null background rescued the elongated thin filament phenotype of HSPB7 KOs, but double KO mice still exhibited formation of abnormal actin bundles and early embryonic lethality. These in vivo findings indicated that abnormal actin bundles, not elongated thin filament length, were the cause of embryonic lethality in HSPB7 KOs. Our findings showed an unsuspected and critical role for a specific small heat shock protein in directly modulating actin thin filament length in cardiac muscle by binding monomeric actin and limiting its availability for polymerization.

Published

2017

31. High-Resolution Fluorescence Microscope Imaging of Erythroblast Structure

Author

Alyson S, Smith, Roberta B, Nowak, and Velia M, Fowler

Subjects

Erythrocytes, Microscopy, Confocal, Erythroblasts, Fluorescent Antibody Technique, Bone Marrow Cells, Mice, Fetus, Liver, Microscopy, Fluorescence, Pregnancy, Image Processing, Computer-Assisted, Animals, Erythropoiesis, Female

Abstract

During erythropoiesis, erythroblasts undergo dramatic morphological changes to produce mature erythrocytes. Many unanswered questions regarding the molecular mechanisms behind these changes can be addressed with high-resolution fluorescence imaging. Immunofluoresence staining enables localization of specific molecules, organelles, and membrane components in intact cells at different phases of erythropoiesis. Confocal laser scanning microscopy can provide high-resolution, three-dimensional images of stained structures, which can be used to dissect the molecular mechanisms driving erythropoiesis. The sample preparation, staining procedure, imaging parameters, and image analysis methods used directly affect the quality of the confocal images and the amount and accuracy of information that they can provide. Here, we describe methods to dissect erythropoietic tissues from mice, to perform immunofluorescence staining and confocal imaging of various molecules, organelles and structures of interest in erythroblasts, and to present and quantitatively analyze the data obtained in these fluorescence images.

Published

2017

32. High-Resolution Fluorescence Microscope Imaging of Erythroblast Structure

Author

Velia M. Fowler, Alyson S. Smith, and Roberta B. Nowak

Subjects

0301 basic medicine, Fluorescence-lifetime imaging microscopy, medicine.diagnostic_test, Chemistry, Confocal, Immunofluorescence, Staining, law.invention, 03 medical and health sciences, 030104 developmental biology, Erythroblast, Confocal microscopy, law, medicine, Fluorescence microscope, Biophysics, Erythropoiesis

Abstract

During erythropoiesis, erythroblasts undergo dramatic morphological changes to produce mature erythrocytes. Many unanswered questions regarding the molecular mechanisms behind these changes can be addressed with high-resolution fluorescence imaging. Immunofluoresence staining enables localization of specific molecules, organelles, and membrane components in intact cells at different phases of erythropoiesis. Confocal laser scanning microscopy can provide high-resolution, three-dimensional images of stained structures, which can be used to dissect the molecular mechanisms driving erythropoiesis. The sample preparation, staining procedure, imaging parameters, and image analysis methods used directly affect the quality of the confocal images and the amount and accuracy of information that they can provide. Here, we describe methods to dissect erythropoietic tissues from mice, to perform immunofluorescence staining and confocal imaging of various molecules, organelles and structures of interest in erythroblasts, and to present and quantitatively analyze the data obtained in these fluorescence images.

Published

2017

33. Tropomodulin 1 controls erythroblast enucleation via regulation of F-actin in the enucleosome

Author

David S. Gokhin, Carla Casu, Lionel Blanc, Roberta B. Nowak, Julien Papoin, Velia M. Fowler, Stefano Rivella, and Jeffrey M. Lipton

Subjects

0301 basic medicine, Cell Nucleus Shape, Erythroblasts, Cellular differentiation, Immunology, Enucleation, macromolecular substances, Biochemistry, 03 medical and health sciences, Red Cells, Iron, and Erythropoiesis, Fetus, Erythroblast, Bone Marrow, hemic and lymphatic diseases, medicine, Animals, Protein Isoforms, Cytoskeleton, Actin, Cell Nucleus, Nonmuscle Myosin Type IIB, biology, Cell Polarity, hemic and immune systems, Cell Differentiation, Cell Biology, Hematology, Actins, Lamins, Cell biology, Mice, Inbred C57BL, Cell nucleus, 030104 developmental biology, medicine.anatomical_structure, Liver, Gene Knockdown Techniques, biology.protein, Tropomodulin, Lamin, circulatory and respiratory physiology

Abstract

Biogenesis of mammalian red blood cells requires nuclear expulsion by orthochromatic erythoblasts late in terminal differentiation (enucleation), but the mechanism is largely unexplained. Here, we employed high-resolution confocal microscopy to analyze nuclear morphology and F-actin rearrangements during the initiation, progression, and completion of mouse and human erythroblast enucleation in vivo. Mouse erythroblast nuclei acquire a dumbbell-shaped morphology during enucleation, whereas human bone marrow erythroblast nuclei unexpectedly retain their spherical morphology. These morphological differences are linked to differential expression of Lamin isoforms, with primary mouse erythroblasts expressing only Lamin B and primary human erythroblasts only Lamin A/C. We did not consistently identify a continuous F-actin ring at the cell surface constriction in mouse erythroblasts, nor at the membrane protein-sorting boundary in human erythroblasts, which do not have a constriction, arguing against a contractile ring-based nuclear expulsion mechanism. However, both mouse and human erythroblasts contain an F-actin structure at the rear of the translocating nucleus, enriched in tropomodulin 1 (Tmod1) and nonmuscle myosin IIB. We investigated Tmod1 function in mouse and human erythroblasts both in vivo and in vitro and found that absence of Tmod1 leads to enucleation defects in mouse fetal liver erythroblasts, and in CD34+ hematopoietic stem and progenitor cells, with increased F-actin in the structure at the rear of the nucleus. This novel structure, the "enucleosome," may mediate common cytoskeletal mechanisms underlying erythroblast enucleation, notwithstanding the morphological heterogeneity of enucleation across species.

Published

2017

34. EphA2 and ephrin-A5 are not a receptor-ligand pair in the ocular lens

Author

Catherine Cheng, Velia M. Fowler, and Xiaohua Gong

Subjects

0301 basic medicine, animal structures, genetic structures, Biology, Article, law.invention, 03 medical and health sciences, Cellular and Molecular Neuroscience, Mice, 0302 clinical medicine, Imaging, Three-Dimensional, law, Lens, Crystalline, medicine, Ephrin, Animals, Microscopy, Confocal, Receptor, EphA2, Erythropoietin-producing hepatocellular (Eph) receptor, Anatomy, Ephrin-A5, Sensory Systems, Epithelium, Lens Fiber, eye diseases, Cell biology, Lens (optics), Mice, Inbred C57BL, Ophthalmology, 030104 developmental biology, medicine.anatomical_structure, Fiber cell, embryonic structures, Models, Animal, 030221 ophthalmology & optometry, Ephrin A5, sense organs, Signal transduction, Protein Binding, Signal Transduction

Abstract

Eph-ephrin bidirectional signaling is essential for eye lens transparency in humans and mice. Our previous studies in mouse lenses demonstrate that ephrin-A5 is mainly expressed in the anterior epithelium, where it is required for maintaining the anterior epithelial monolayer. In contrast, EphA2 is localized in equatorial epithelial and fiber cells where it is essential for equatorial epithelial and fiber cell organization and hexagonal cell shape. Immunostaining of lens epithelial and fiber cells reveals that EphA2 and ephrin-A5 are also co-expressed in anterior fiber cell tips, equatorial epithelial cells and newly formed lens fibers, although they are not precisely colocalized. Due to this complex expression pattern and the promiscuous interactions between Eph receptors and ephrin ligands, as well as their complex bidirectional signaling pathways, cataracts in ephrin-A5(-/-) or EphA2(-/-) lenses may arise from loss of function or abnormal signaling mechanisms. To test whether abnormal signaling mechanisms may play a role in cataractogenesis in ephrin-A5(-/-) or EphA2(-/-) lenses, we generated EphA2 and ephrin-A5 double knockout (DKO) mice. We compared the phenotypes of EphA2(-/-) and ephrin-A5(-/-) lenses to that of DKO lenses. DKO lenses displayed an additive lens phenotype that was not significantly different from the two single KO lens phenotypes. Similar to ephrin-A5(-/-) lenses, DKO lenses had abnormal anterior epithelial cells leading to a large mass of epithelial cells that invade into the underlying fiber cell layer, directly resulting in anterior cataracts in ephrin-A5(-/-) and DKO lenses. Yet, similar to EphA2(-/-) lenses, DKO lenses also had abnormal packing of equatorial epithelial cells with disorganized meridional rows, lack of a lens fulcrum and disrupted fiber cells. The DKO lens phenotype rules out abnormal signaling by EphA2 in ephrin-A5(-/-) lenses or by ephrin-A5 in EphA2(-/-) lenses as possible cataract mechanisms. Thus, these results indicate that EphA2 and ephrin-A5 do not form a lens receptor-ligand pair, and that EphA2 and ephrin-A5 have other binding partners in the lens to help align differentiating equatorial epithelial cells or maintain the anterior epithelium, respectively.

Published

2017

35. Functional effects of mutations in the tropomyosin-binding sites of tropomodulin1 and tropomodulin3

Author

Sawako Yamashiro, Velia M. Fowler, Raymond A. Lewis, and David S. Gokhin

Subjects

biology, Cell Biology, Plasma protein binding, Actin cytoskeleton, Tropomyosin, Molecular biology, Tropomyosin binding, Structural Biology, biology.protein, Biophysics, Latrunculin, Binding site, Tropomodulin, Actin

Abstract

Tropomodulins (Tmods) interact with tropomyosins (TMs) via two TM-binding sites and cap the pointed ends of TM-coated actin filaments. To study the functional interplay between TM binding and TM-actin filament capping by Tmods, we introduced disabling mutations into the first, second, or both TM-binding sites of full-length Tmod1 (Tmod1-L27G, Tmod1-I131D, and Tmod1-L27G/I131D, respectively) and full-length Tmod3 (Tmod3-L29G, Tmod3-L134D, and Tmod3-L29G/L134D, respectively). Tmod1 and Tmod3 showed somewhat different TM-binding site utilization, but nearly all TM binding was abolished in Tmod1-L27G/I131D and Tmod3-L29G/L134D. Disruption of Tmod-TM binding had a modest effect on Tmod1's ability and no effect on Tmod3's ability to stabilize TM-actin pointed ends against latrunculin A-induced depolymerization. However, disruption of Tmod-TM binding did significantly impair the ability of Tmod3 to reduce elongation rates at pointed ends with α/βTM, albeit less so with TM5NM1, and not at all with TM5b. For Tmod1, disruption of Tmod-TM binding only slightly impaired its ability to reduce elongation rates with α/βTM and TM5NM1, but not at all with TM5b. Thus, Tmod-TM binding has a greater influence on Tmods' ability to inhibit subunit association as compared to dissociation from TM-actin pointed ends, particularly for α/βTM, with Tmod3's activity being more dependent on TM binding than Tmod1's activity. Nevertheless, disruption of Tmod1-TM binding precluded Tmod1 targeting to thin filament pointed ends in cardiac myocytes, suggesting that the functional effects of Tmod-TM binding on TM-coated actin filament capping can be significantly modulated by the in vivo conformation of the pointed end or other factors in the intracellular environment.

Published

2014

36. Calpain-mediated proteolysis of tropomodulin isoforms leads to thin filament elongation in dystrophic skeletal muscle

Author

Velia M. Fowler, Alessandra Sacco, Matthew T. Tierney, Zhenhua Sui, and David S. Gokhin

Subjects

Duchenne muscular dystrophy, Muscle Proteins, macromolecular substances, Actinin, Mice, Nebulin, medicine, Animals, Muscular dystrophy, Muscle, Skeletal, Molecular Biology, Cytoskeleton, Soleus muscle, biology, Calpain, Skeletal muscle, Articles, Cell Biology, musculoskeletal system, medicine.disease, Actin cytoskeleton, Molecular biology, Actins, Protein Structure, Tertiary, Cell biology, Muscular Dystrophy, Duchenne, Actin Cytoskeleton, Disease Models, Animal, medicine.anatomical_structure, Proteolysis, Mice, Inbred mdx, biology.protein, Tropomodulin

Abstract

Calpain-mediated proteolysis of the thin filament pointed-end–capping protein tropomodulin results in actin subunit association onto pointed ends and increased thin filament lengths in two different murine models of Duchenne muscular dystrophy. This mechanism affects different skeletal muscles in a use- and disease severity–dependent manner., Duchenne muscular dystrophy (DMD) induces sarcolemmal mechanical instability and rupture, hyperactivity of intracellular calpains, and proteolytic breakdown of muscle structural proteins. Here we identify the two sarcomeric tropomodulin (Tmod) isoforms, Tmod1 and Tmod4, as novel proteolytic targets of m-calpain, with Tmod1 exhibiting ∼10-fold greater sensitivity to calpain-mediated cleavage than Tmod4 in situ. In mdx mice, increased m-calpain levels in dystrophic soleus muscle are associated with loss of Tmod1 from the thin filament pointed ends, resulting in ∼11% increase in thin filament lengths. In mdx/mTR mice, a more severe model of DMD, Tmod1 disappears from the thin filament pointed ends in both tibialis anterior (TA) and soleus muscles, whereas Tmod4 additionally disappears from soleus muscle, resulting in thin filament length increases of ∼10 and ∼12% in TA and soleus muscles, respectively. In both mdx and mdx/mTR mice, both TA and soleus muscles exhibit normal localization of α-actinin, the nebulin M1M2M3 domain, Tmod3, and cytoplasmic γ-actin, indicating that m-calpain does not cause wholesale proteolysis of other sarcomeric and actin cytoskeletal proteins in dystrophic skeletal muscle. These results implicate Tmod proteolysis and resultant thin filament length misspecification as novel mechanisms that may contribute to DMD pathology, affecting muscles in a use- and disease severity–dependent manner.

Published

2014

37. Tropomodulin3-null mice are embryonic lethal with anemia due to impaired erythroid terminal differentiation in the fetal liver

Author

Amittha Wickrema, Nancy Kim, Roberta B. Nowak, Velia M. Fowler, Jie Li, Xiuli An, Hui Liu, Zhenhua Sui, and Andrea Bacconi

Subjects

Male, Erythroblasts, Immunology, Enucleation, Apoptosis, macromolecular substances, Biochemistry, Mice, Red Cells, Iron, and Erythropoiesis, Erythroblast, hemic and lymphatic diseases, Animals, Erythropoiesis, Progenitor cell, Erythroid Precursor Cells, Mice, Knockout, biology, Inside BLOOD, Cell Cycle, Gene Expression Regulation, Developmental, Actin remodeling, hemic and immune systems, Cell Biology, Hematology, Cell cycle, Cell biology, Liver, biology.protein, Female, Tropomodulin, Gene Deletion, circulatory and respiratory physiology

Abstract

Tropomodulin (Tmod) is a protein that binds and caps the pointed ends of actin filaments in erythroid and nonerythoid cell types. Targeted deletion of mouse tropomodulin3 (Tmod3) leads to embryonic lethality at E14.5-E18.5, with anemia due to defects in definitive erythropoiesis in the fetal liver. Erythroid burst-forming unit and colony-forming unit numbers are greatly reduced, indicating defects in progenitor populations. Flow cytometry of fetal liver erythroblasts shows that late-stage populations are also decreased, including reduced percentages of enucleated cells. Annexin V staining indicates increased apoptosis of Tmod3(-/-) erythroblasts, and cell-cycle analysis reveals that there are more Ter119(hi) cells in S-phase in Tmod3(-/-) embryos. Notably, enucleating Tmod3(-/-) erythroblasts are still in the process of proliferation, suggesting impaired cell-cycle exit during terminal differentiation. Tmod3(-/-) late erythroblasts often exhibit multilobular nuclear morphologies and aberrant F-actin assembly during enucleation. Furthermore, native erythroblastic island formation was impaired in Tmod3(-/-) fetal livers, with Tmod3 required in both erythroblasts and macrophages. In conclusion, disruption of Tmod3 leads to impaired definitive erythropoiesis due to reduced progenitors, impaired erythroblastic island formation, and defective erythroblast cell-cycle progression and enucleation. Tmod3-mediated actin remodeling may be required for erythroblast-macrophage adhesion, coordination of cell cycle with differentiation, and F-actin assembly and remodeling during erythroblast enucleation.

Published

2014

38. A two-segment model for thin filament architecture in skeletal muscle

Author

Velia M. Fowler and David S. Gokhin

Subjects

Myofilament, Actin remodeling, macromolecular substances, Cell Biology, Anatomy, Actinin, Biology, Actin cytoskeleton, Microfilament, Protein filament, Nebulin, Biophysics, biology.protein, CapZ Actin Capping Protein, Molecular Biology

Abstract

Correct specification of myofilament length is essential for efficient skeletal muscle contraction. The length of thin actin filaments can be explained by a novel 'two-segment' model, wherein the thin filaments consist of two concatenated segments, which are of either constant or variable length. This is in contrast to the classic 'nebulin ruler' model, which postulates that thin filaments are uniform structures, the lengths of which are dictated by nebulin. The two-segment model implicates position-specific microregulation of actin dynamics as a general principle underlying actin filament length and stability.

Published

2013

39. Stabilization of F-actin by tropomyosin isoforms regulates the morphology and mechanical behavior of red blood cells

Author

David S. Gokhin, Zhenhua Sui, Xinhua Guo, Velia M. Fowler, Xiuli An, and Roberta B. Nowak

Subjects

0301 basic medicine, Gene isoform, Male, Morphology (linguistics), Erythrocytes, macromolecular substances, Tropomyosin, Polymerization, 03 medical and health sciences, Mice, 0302 clinical medicine, hemic and lymphatic diseases, Glycophorin, Animals, Protein Isoforms, Molecular Biology, Band 3, Actin, Cytoskeleton, Mice, Knockout, biology, hemic and immune systems, Cell Biology, Articles, Skeleton (computer programming), Molecular biology, Actins, 3. Good health, Cell biology, Actin Cytoskeleton, 030104 developmental biology, Membrane, 030220 oncology & carcinogenesis, biology.protein, Protein Binding

Abstract

The absence of Tpm3.1 in red blood cells (RBCs) induces a compensatory increase in Tpm1.9 and abnormally stable F-actin in the membrane skeleton, with reduced association of Band 3 and glycophorin A, leading to a compensated hemolytic anemia with abnormal RBC shapes and mechanical properties., The short F-actins in the red blood cell (RBC) membrane skeleton are coated along their lengths by an equimolar combination of two tropomyosin isoforms, Tpm1.9 and Tpm3.1. We hypothesized that tropomyosin’s ability to stabilize F-actin regulates RBC morphology and mechanical properties. To test this, we examined mice with a targeted deletion in alternatively spliced exon 9d of Tpm3 (Tpm3/9d–/–), which leads to absence of Tpm3.1 in RBCs along with a compensatory increase in Tpm1.9 of sufficient magnitude to maintain normal total tropomyosin content. The isoform switch from Tpm1.9/Tpm3.1 to exclusively Tpm1.9 does not affect membrane skeleton composition but causes RBC F-actins to become hyperstable, based on decreased vulnerability to latrunculin-A–induced depolymerization. Unexpectedly, this isoform switch also leads to decreased association of Band 3 and glycophorin A with the membrane skeleton, suggesting that tropomyosin isoforms regulate the strength of F-actin-to-membrane linkages. Tpm3/9d–/– mice display a mild compensated anemia, in which RBCs have spherocytic morphology with increased osmotic fragility, reduced membrane deformability, and increased membrane stability. We conclude that RBC tropomyosin isoforms directly influence RBC physiology by regulating 1) the stability of the short F-actins in the membrane skeleton and 2) the strength of linkages between the membrane skeleton and transmembrane glycoproteins.

Published

2016

40. Tropomodulin 1 Regulation of Actin Is Required for the Formation of Large Paddle Protrusions Between Mature Lens Fiber Cells

Author

Velia M. Fowler, Roberta B. Nowak, Sondip K. Biswas, Paul G. FitzGerald, Catherine Cheng, and Woo-Kuen Lo

Subjects

0301 basic medicine, Cytoskeleton organization, DNA Mutational Analysis, Inbred C57BL, Ophthalmology & Optometry, Medical and Health Sciences, Cell membrane, Lens, Mice, Scanning, Cells, Cultured, Mice, Knockout, Microscopy, actinin, Cultured, paddles, biology, Cell Differentiation, Anatomy, Biological Sciences, eye, Lens Fiber, Actin Cytoskeleton, medicine.anatomical_structure, Lens (anatomy), Tropomodulin, Cells, Knockout, macromolecular substances, Electron, Cataract, 03 medical and health sciences, Lens, Crystalline, medicine, Animals, Actin, Crystalline, Animal, DNA, Actin cytoskeleton, Actins, Mice, Inbred C57BL, Disease Models, Animal, 030104 developmental biology, spectrin, Fimbrin, Disease Models, Mutation, Microscopy, Electron, Scanning, Biophysics, biology.protein, interdigitations

Abstract

Author(s): Cheng, Catherine; Nowak, Roberta B; Biswas, Sondip K; Lo, Woo-Kuen; FitzGerald, Paul G; Fowler, Velia M | Abstract: PurposeTo elucidate the proteins required for specialized small interlocking protrusions and large paddle domains at lens fiber cell tricellular junctions (vertices), we developed a novel method to immunostain single lens fibers and studied changes in cell morphology due to loss of tropomodulin 1 (Tmod1), an F-actin pointed end-capping protein.MethodsWe investigated F-actin and F-actin-binding protein localization in interdigitations of Tmod1+/+ and Tmod1-/- single mature lens fibers.ResultsF-actin-rich small protrusions and large paddles were present along cell vertices of Tmod1+/+ mature fibers. In contrast, Tmod1-/- mature fiber cells lack normal paddle domains, while small protrusions were unaffected. In Tmod1+/+ mature fibers, Tmod1, β2-spectrin, and α-actinin are localized in large puncta in valleys between paddles; but in Tmod1-/- mature fibers, β2-spectrin was dispersed while α-actinin was redistributed at the base of small protrusions and rudimentary paddles. Fimbrin and Arp3 (actin-related protein 3) were located in puncta at the base of small protrusions, while N-cadherin and ezrin outlined the cell membrane in both Tmod1+/+ and Tmod1-/- mature fibers.ConclusionsThese results suggest that distinct F-actin organizations are present in small protrusions versus large paddles. Formation and/or maintenance of large paddle domains depends on a β2-spectrin-actin network stabilized by Tmod1. α-Actinin-crosslinked F-actin bundles are enhanced in absence of Tmod1, indicating altered cytoskeleton organization. Formation of small protrusions is likely facilitated by Arp3-branched and fimbrin-bundled F-actin networks, which do not depend on Tmod1. This is the first work to reveal the F-actin-associated proteins required for the formation of paddles between lens fibers.

Published

2016

41. Sequential Application of Glass Coverslips to Assess the Compressive Stiffness of the Mouse Lens: Strain and Morphometric Analyses

Author

David S. Gokhin, Velia M. Fowler, Catherine Cheng, and Roberta B. Nowak

Subjects

0301 basic medicine, Aging, genetic structures, General Chemical Engineering, Mouse Lens, Strain (injury), Optical power, General Biochemistry, Genetics and Molecular Biology, law.invention, 03 medical and health sciences, Mice, law, Lens, Crystalline, medicine, Animals, Process (anatomy), General Immunology and Microbiology, business.industry, General Neuroscience, Ciliary Body, Stiffness, Accommodation, Ocular, Anatomy, Presbyopia, medicine.disease, Lens (optics), Cellular Biology, 030104 developmental biology, sense organs, medicine.symptom, business, Accommodation, Biomedical engineering

Abstract

The eye lens is a transparent organ that refracts and focuses light to form a clear image on the retina. In humans, ciliary muscles contract to deform the lens, leading to an increase in the lens' optical power to focus on nearby objects, a process known as accommodation. Age-related changes in lens stiffness have been linked to presbyopia, a reduction in the lens' ability to accommodate, and, by extension, the need for reading glasses. Even though mouse lenses do not accommodate or develop presbyopia, mouse models can provide an invaluable genetic tool for understanding lens pathologies, and the accelerated aging observed in mice enables the study of age-related changes in the lens. This protocol demonstrates a simple, precise, and cost-effective method for determining mouse lens stiffness, using glass coverslips to apply sequentially increasing compressive loads onto the lens. Representative data confirm that mouse lenses become stiffer with age, like human lenses. This method is highly reproducible and can potentially be scaled up to mechanically test lenses from larger animals.

Published

2016

42. Feisty filaments: actin dynamics in the red blood cell membrane skeleton

Author

Velia M. Fowler and David S. Gokhin

Subjects

0301 basic medicine, Erythrocytes, Chemistry, Extramural, Actin filament organization, Erythrocyte Membrane, Plasmodium falciparum, macromolecular substances, Hematology, Skeleton (computer programming), Article, Actins, 03 medical and health sciences, Red blood cell, 030104 developmental biology, medicine.anatomical_structure, Membrane, Actin dynamics, Biophysics, medicine, Humans

Abstract

This article discusses recent advances and unsolved questions in our understanding of actin filament organization and dynamics in the red blood cell (RBC) membrane skeleton, a two-dimensional quasi-hexagonal network consisting of (α1β1)2-spectrin tetramers interconnecting short actin filament-based junctional complexes.In contrast to the long-held view that RBC actin filaments are static structures that do not exchange subunits with the cytosol, RBC actin filaments are dynamic structures that undergo subunit exchange and turnover, as evidenced by monomer incorporation experiments with rhodamine-actin and filament disruption experiments with actin-targeting drugs. The malaria-causing parasite, Plasmodium falciparum, co-opts RBC actin dynamics to construct aberrantly branched actin filament networks. Even though RBC actin filaments are dynamic, RBC actin filament lengths are highly uniform (∼37 nm). RBC actin filament lengths are thought to be stabilized by the capping proteins, tropomodulin-1 and αβ-adducin, as well as the side-binding protein tropomyosin, present in an equimolar combination of two isoforms, TM5b (Tpm1.9) and TM5NM1 (Tpm3.1).New evidence indicates that RBC actin filaments are not simply passive cytolinkers, but rather dynamic structures whose assembly and disassembly play important roles in RBC membrane function.

Published

2016

43. Thin-filament length correlates with fiber type in human skeletal muscle

Author

David S. Gokhin, Sarah A. Lewis, Darryl D. D'Lima, Nancy Kim, Velia M. Fowler, and Heinz R. Hoenecke

Subjects

Sarcomeres, Myofilament, Physiology, Fluorescent Antibody Technique, Muscle Proteins, Muscle Cell Biology and Cell Motility, macromolecular substances, Sarcomere, Pectoralis Muscles, Nebulin, Myofibrils, Myosin, medicine, Humans, Cells, Cultured, Myosin Heavy Chains, biology, Microfilament Proteins, Skeletal muscle, Cell Biology, Deltoid Muscle, Actin cytoskeleton, Actin Cytoskeleton, Crystallography, medicine.anatomical_structure, Biophysics, biology.protein, Myofibril, Tropomodulin

Abstract

Force production in skeletal muscle is proportional to the amount of overlap between the thin and thick filaments, which, in turn, depends on their lengths. Both thin- and thick-filament lengths are precisely regulated and uniform within a myofibril. While thick-filament lengths are essentially constant across muscles and species (∼1.65 μm), thin-filament lengths are highly variable both across species and across muscles of a single species. Here, we used a high-resolution immunofluorescence and image analysis technique (distributed deconvolution) to directly test the hypothesis that thin-filament lengths vary across human muscles. Using deltoid and pectoralis major muscle biopsies, we identified thin-filament lengths that ranged from 1.19 ± 0.08 to 1.37 ± 0.04 μm, based on tropomodulin localization with respect to the Z-line. Tropomodulin localized from 0.28 to 0.47 μm further from the Z-line than the NH2-terminus of nebulin in the various biopsies, indicating that human thin filaments have nebulin-free, pointed-end extensions that comprise up to 34% of total thin-filament length. Furthermore, thin-filament length was negatively correlated with the percentage of type 2X myosin heavy chain within the biopsy and shorter in type 2X myosin heavy chain-positive fibers, establishing the existence of a relationship between thin-filament lengths and fiber types in human muscle. Together, these data challenge the widely held assumption that human thin-filament lengths are constant. Our results also have broad relevance to musculoskeletal modeling, surgical reattachment of muscles, and orthopedic rehabilitation.

Published

2012

44. Tropomodulins are negative regulators of neurite outgrowth

Author

Velia M. Fowler, Robert S. Fischer, Leif Dehmelt, Shelley Halpain, and Thomas Fath

Subjects

Histology, Neurite, Growth Cones, Hippocampus, Article, Pathology and Forensic Medicine, Mice, Cell Line, Tumor, Neurites, Animals, Pseudopodia, Cytoskeleton, Growth cone, Cells, Cultured, Neurons, biology, Cell Biology, General Medicine, Actin cytoskeleton, N2a cell, Actins, Rats, Cell biology, Actin Cytoskeleton, biology.protein, Lamellipodium, Tropomodulin

Abstract

Regulation of the actin cytoskeleton is critical for neurite formation. Tropomodulins (Tmods) regulate polymerization at actin filament pointed ends. Previous experiments using a mouse model deficient for the neuron specific isoform Tmod2 suggested a role for Tmods in neuronal function by impacting processes underlying learning and memory. However, the role of Tmods in neuronal function on the cellular level remains unknown. Immunofluorescence localization of the neuronal isoforms Tmod1 and Tmod2 in cultured rat primary hippocampal neurons revealed that Tmod1 is enriched along the proximal part of F-actin bundles in lamellipodia of spreading cells and in growth cones of extending neurites, while Tmod2 appears largely cytoplasmic. Functional analysis of these Tmod isoforms in a mouse neuroblastoma N2a cell line showed that knockdown of Tmod2 resulted in a significant increase in the number of neurite-forming cells and in neurite length. While N2a cells compensated for Tmod2 knockdown by increasing Tmod1 levels, over-expression of exogenous Tmod1 had no effect on neurite outgrowth. Moreover, knockdown of Tmod1 increased the number of neurites formed per cell, without effect on the number of neurite-forming cells or neurite length. Taken together, these results indicate that Tmod1 and Tmod2 have mechanistically distinct inhibitory roles in neurite formation, likely mediated via different effects on F-actin dynamics and via differential localizations during early neuritogenesis.

Published

2011

45. Mitochondrial Regulation Is Essential for Erythroid Nuclear Clearance

Author

Raymond Liang, Miao Lin, Saghi Ghaffari, Geoffrey D. Girnun, Vijay Menon, Roberta B. Nowak, and Velia M. Fowler

Subjects

Chemistry, Mitochondrial disease, Immunology, Cell, Enucleation, Cell Biology, Hematology, Mitochondrion, medicine.disease, Biochemistry, Cell biology, Cell nucleus, medicine.anatomical_structure, Erythroblast, Anaerobic glycolysis, hemic and lymphatic diseases, Organelle, medicine

Abstract

The terminal steps of red blood cell (RBC) generation involve an extensive cellular remodeling. This encompasses alterations of cellular content through five erythroblast stages that result in the expulsion of the nucleus (enucleation) followed by loss of mitochondria and all other organelles, and a transition to anaerobic glycolysis. Whether there is any link between the erythroid removal of the nucleus and the function of any other organelle including mitochondria remains unknown. Here we show that mitochondria are essential for nuclear clearance. We first demonstrate through high-throughput single-cell imaging and confocal microscopy that as mouse bone marrow erythroblasts mature (Gate 3: TER119+,CD44low, FSClow), mitochondria migrate to one end of the cell, aggregate and trail behind the nucleus as it extrudes from the cell, a prerequisite for enucleation to complete. We further show that mitochondrial localization behind the nucleus has similar kinetics as nuclear polarization. This process is also conserved in mouse fetal liver erythroid cells as well as in primary human CD34+-derived erythroblasts in culture. Notably, kinesin inhibition disrupts mitochondrial motility and localization and reduces significantly erythroblast enucleation rate in the absence of any impact on dynein or tubulin. These results suggest that mitochondria function as necessary chaperones during erythroblast enucleation. Furthermore, mitochondrial activity distinguishes erythroblasts on the verge of enucleation from others at the same erythroblast stage (Gate 3). We show that active mitochondrial respiration facilitates nuclear condensation and is required for nuclear extrusion. To our surprise however, metabolite profiling revealed that late-stage erythroblasts sustain mitochondrial metabolism and subsequent enucleation primarily through extracellular pyruvate but independently of glucose oxidation or anapleorotic reactions of amino acids. 13C-labeled metabolite tracing also confirmed pyruvate incorporation into mitochondria while glycolysis was minimal in orthochromatic erythroblasts. Thus, we provide evidence for the first time of a link between erythroid enucleation and mitochondrial metabolism. The process described establishes a model of mitochondrial compartmentalization within the cell for providing essential metabolites in a precise spatial and temporal manner. These findings are likely to improve the in vitro production of RBC and might be relevant to anemias of congenital mitochondrial disorders and aging. Disclosures No relevant conflicts of interest to declare.

Published

2018

46. Tropomodulin 1-null mice have a mild spherocytic elliptocytosis with appearance of Tropomodulin 3 in red blood cells and disruption of the membrane skeleton

Author

Velia M. Fowler, Nancy Kim, Sandra Larkin, Luanne L. Peters, John H. Hartwig, Roberta B. Nowak, Jeannette Moyer, and Frans A. Kuypers

Subjects

Tropomodulin-3, Erythrocytes, Hereditary elliptocytosis, Immunology, Erythrocytes, Abnormal, macromolecular substances, Microfilament, Biochemistry, Gene Knockout Techniques, Mice, Elliptocytosis, Cytosol, medicine, Animals, Spectrin, Cytoskeleton, biology, EPB41, Anemia, Cell Biology, Hematology, medicine.disease, Actins, Cell biology, Actin Cytoskeleton, Osmotic Fragility, biology.protein, Tropomodulin

Abstract

The short actin filaments in the red blood cell (RBC) membrane skeleton are capped at their pointed ends by tropomodulin 1 (Tmod1) and coated with tropomyosin (TM) along their length. Tmod1-TM control of actin filament length is hypothesized to regulate spectrin-actin lattice organization and membrane stability. We used a Tmod1 knockout mouse to investigate the in vivo role of Tmod1 in the RBC membrane skeleton. Western blots of Tmod1-null RBCs confirm the absence of Tmod1 and show the presence of Tmod3, which is normally not present in RBCs. Tmod3 is present at only one-fifth levels of Tmod1 present on wild-type membranes, but levels of actin, TMs, adducins, and other membrane skeleton proteins remain unchanged. Electron microscopy shows that actin filament lengths are more variable with spectrin-actin lattices displaying abnormally large and more variable pore sizes. Tmod1-null mice display a mild anemia with features resembling hereditary spherocytic elliptocytosis, including decreased RBC mean corpuscular volume, cellular dehydration, increased osmotic fragility, reduced deformability, and heterogeneity in osmotic ektacytometry. Insufficient capping of actin filaments by Tmod3 may allow greater actin dynamics at pointed ends, resulting in filament length redistribution, leading to irregular and attenuated spectrin-actin lattice connectivity, and concomitant RBC membrane instability.

Published

2010

47. Mammalian Tropomodulins Nucleate Actin Polymerization via Their Actin Monomer Binding and Filament Pointed End-capping Activities*

Author

Sawako Yamashiro, Velia M. Fowler, Kaye D. Speicher, and David W. Speicher

Subjects

Arp2/3 complex, macromolecular substances, Biochemistry, Protein Structure, Secondary, Mice, Actin remodeling of neurons, Animals, Protein Isoforms, Actin-binding protein, Molecular Biology, biology, Actin monomer binding, Actin remodeling, Cell Biology, Actin cytoskeleton, Actins, Protein Structure, Tertiary, Cell biology, Actin Cytoskeleton, Mutagenesis, biology.protein, Rabbits, MDia1, Chickens, Tropomodulin

Abstract

Many actin-binding proteins have been shown to possess multiple activities to regulate filament dynamics. Tropomodulins (Tmod1–4) are a conserved family of actin filament pointed end-capping proteins. Our previous work has demonstrated that Tmod3 binds to monomeric actin in addition to capping pointed ends. Here, we show a novel actin-nucleating activity in mammalian Tmods. Comparison of Tmod isoforms revealed that Tmod1–3 but not Tmod4 nucleate actin filament assembly. All Tmods bind to monomeric actin, and Tmod3 forms a 1:1 complex with actin. By truncation and mutagenesis studies, we demonstrated that the second α-helix in the N-terminal domain of Tmod3 is essential for actin monomer binding. Chemical cross-linking and LC-MS/MS further indicated that residues in this second α-helix interact with actin subdomain 2, whereas Tmod3 N-terminal domain peptides distal to this α-helix interact with actin subdomain 1. Mutagenesis of Leu-73 to Asp, which disrupts the second α-helix of Tmod3, decreases both its actin monomer-binding and -nucleating activities. On the other hand, point mutations of residues in the C-terminal leucine-rich repeat domain of Tmod3 (Lys-317 in the fifth leucine-rich repeat β-sheet and Lys-344 or Arg-345/Arg-346 in the C-terminal α6-helix) significantly reduced pointed end-capping and nucleation without altering actin monomer binding. Taken together, our data indicate that Tmod3 binds actin monomers over an extended interface and that nucleating activity depends on actin monomer binding and pointed end-capping activities, contributed by N- and C-terminal domains of Tmod3, respectively. Tmod3 nucleation of actin assembly may regulate the cytoskeleton in dynamic cellular contexts.

Published

2010

48. Mitochondrial Regulation is Essential for Erythroid Nuclear Removal

Author

Saghi Ghaffari, Vijay Menon, Velia M. Fowler, Miao Lin, Raymond Liang, Roberta B. Nowak, Boris M. Hartmann, and Geoffrey D. Girnun

Subjects

0301 basic medicine, 03 medical and health sciences, Cancer Research, 030104 developmental biology, Chemistry, Genetics, Cell Biology, Hematology, Molecular Biology

Published

2018

49. Tropomodulin1 is required for membrane skeleton organization and hexagonal geometry of fiber cells in the mouse lens

Author

Velia M. Fowler, Robert S. Fischer, Rebecca K. Zoltoski, Jerome R. Kuszak, and Roberta B. Nowak

Subjects

Aging, genetic structures, Tropomyosin, macromolecular substances, Article, Cell membrane, Mice, 03 medical and health sciences, 0302 clinical medicine, Lens, Crystalline, medicine, Animals, Spectrin, Fiber, Cell Shape, Research Articles, Actin, 030304 developmental biology, Mice, Knockout, 0303 health sciences, biology, Cell Membrane, Microfilament Proteins, Epithelial Cells, Cell Biology, Actin cytoskeleton, Cell biology, Actin Cytoskeleton, Membrane, medicine.anatomical_structure, Fiber cell, biology.protein, Carrier Proteins, Tropomodulin, 030217 neurology & neurosurgery

Abstract

The spectrin–actin network is disrupted in Tmod1 mutants, disturbing fiber cell morphology, and disordering lens cell organization., Hexagonal packing geometry is a hallmark of close-packed epithelial cells in metazoans. Here, we used fiber cells of the vertebrate eye lens as a model system to determine how the membrane skeleton controls hexagonal packing of post-mitotic cells. The membrane skeleton consists of spectrin tetramers linked to actin filaments (F-actin), which are capped by tropomodulin1 (Tmod1) and stabilized by tropomyosin (TM). In mouse lenses lacking Tmod1, initial fiber cell morphogenesis is normal, but fiber cell hexagonal shapes and packing geometry are not maintained as fiber cells mature. Absence of Tmod1 leads to decreased γTM levels, loss of F-actin from membranes, and disrupted distribution of β2-spectrin along fiber cell membranes. Regular interlocking membrane protrusions on fiber cells are replaced by irregularly spaced and misshapen protrusions. We conclude that Tmod1 and γTM regulation of F-actin stability on fiber cell membranes is critical for the long-range connectivity of the spectrin–actin network, which functions to maintain regular fiber cell hexagonal morphology and packing geometry.

Published

2009

50. A Nebulin Ruler Does Not Dictate Thin Filament Lengths

Author

Velia M. Fowler, Angelica Castillo, Ryan Littlefield, Kimberly P. Littlefield, and Roberta B. Nowak

Subjects

Male, Myofibril assembly, Biophysics, Fluorescent Antibody Technique, Muscle Proteins, macromolecular substances, Sarcomere, Nebulin, Myofibrils, Myosin, Animals, Actin, biology, Muscle, Molecular Motors, and Cell Motility, Actins, Muscle, Striated, Crystallography, biology.protein, Female, Titin, Rabbits, Myofibril, Chickens, Tropomodulin

Abstract

To generate force, striated muscle requires overlap between uniform-length actin and myosin filaments. The hypothesis that a nebulin ruler mechanism specifies thin filament lengths by targeting where tropomodulin (Tmod) caps the slow-growing, pointed end has not been rigorously tested. Using fluorescent microscopy and quantitative image analysis, we found that nebulin extended 1.01–1.03 μm from the Z-line, but Tmod localized 1.13–1.31 μm from the Z-line, in seven different rabbit skeletal muscles. Because nebulin does not extend to the thin filament pointed ends, it can neither target Tmod capping nor specify thin filament lengths. We found instead a strong correspondence between thin filament lengths and titin isoform sizes for each muscle. Our results suggest the existence of a mechanism whereby nebulin specifies the minimum thin filament length and sarcomere length regulates and coordinates pointed-end dynamics to maintain the relative overlap of the thin and thick filaments during myofibril assembly.

Published

2009