Jose Valdez scite author profile

Leiomodin 2 (Lmod2) is an actin-binding protein that has been implicated in the regulation of striated muscle thin filament assembly; its physiological function has yet to be studied. We found that knockout of Lmod2 in mice results in abnormally short thin filaments in the heart. We also discovered that Lmod2 functions to elongate thin filaments by promoting actin assembly and dynamics at thin filament pointed ends. Lmod2-KO mice die as juveniles with hearts displaying contractile dysfunction and ventricular chamber enlargement consistent with dilated cardiomyopathy. Lmod2-null cardiomyocytes produce less contractile force than wild type when plated on micropillar arrays. Introduction of GFP-Lmod2 via adeno-associated viral transduction elongates thin filaments and rescues structural and functional defects observed in Lmod2-KO mice, extending their lifespan to adulthood. Thus, to our knowledge, Lmod2 is the first identified mammalian protein that functions to elongate actin filaments in the heart; it is essential for cardiac thin filaments to reach a mature length and is required for efficient contractile force and proper heart function during development.actin-thin filaments | cardiomyopathy | cytoskeletal dynamics S triated muscle cells contain arrays of protein filaments assembled into contractile units that are nearly crystalline in structure. Efficient contraction at the molecular level is predicated upon accurate overlap of actin-containing thin and myosin-containing thick filaments. Therefore, proper control of filament assembly is absolutely critical.In striated muscle it is currently thought that the thin-filament pointed end capping protein tropomodulin (Tmod) is the predominant regulator of thin filament length, with Tmod1 being the sole isoform expressed in cardiomyocytes (1). Extensive in vitro work has revealed that Tmod1 uses two actin-and two tropomyosin-binding sites to associate with the end of the thin filament and to prevent addition or loss of actin monomers, thereby controlling length of the thin filament (2-7). Tmod1 is essential for life; Tmod1-KO mice are embryonic lethal because of cardiac defects (8-11).Identification of additional but structurally different members of the Tmod family of proteins, the leiomodins (Lmods), raises the possibility that thin filament lengths are not regulated solely by Tmod at thin filament pointed ends (12). Although there are three Lmod genes (Lmod1-3), Lmod2 and 3 are expressed in striated muscle with Lmod2 being the predominant isoform in cardiac muscle and Lmod3 the predominant isoform in skeletal muscle (12-16). The Lmods share ∼40% sequence identity at the protein level with the Tmods but do not contain a recognizable second tropomyosin-binding domain and have an additional C-terminal extension that includes a proline-rich region and an actin-binding Wiskott-Aldrich syndrome protein homology 2 (WH2) domain (12, 17). Lmod2 has been proposed to be the long-sought muscle actin filament nucleator because it robustly nucleates actin filament formation in ...

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A microfluidic platform for simultaneous quantification of oxygen-dependent viscosity and shear thinning in sickle cell blood

Valdez

Datta

Higgins

et al. 2019

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The pathology of sickle cell disease begins with the polymerization of intracellular hemoglobin under low oxygen tension, which leads to increased blood effective viscosity and vaso-occlusion. However, it has remained unclear how single-cell changes propagate up to the scale of bulk blood effective viscosity. Here, we use a custom microfluidic system to investigate how the increase in the stiffness of individual cells leads to an increase in the shear stress required for the same fluid strain in a suspension of softer cells. We characterize both the shear-rate dependence and the oxygen-tension dependence of the effective viscosity of sickle cell blood, and we assess the effect of the addition of increasing fractions of normal cells whose material properties are independent of oxygen tension, a scenario relevant to the treatment of sickle patients with blood transfusion. For untransfused sickle cell blood, we find an overall increase in effective viscosity at all oxygen tensions and shear rates along with an attenuation in the degree of shear-thinning achieved at the lowest oxygen tensions. We also find that in some cases, even a small fraction of transfused blood cells restores the shape of the shear-thinning relationship, though not the overall baseline effective viscosity. These results suggest that untransfused sickle cell blood will show the most extreme relative rheologic impairment in regions of high shear and that introducing even small fractions of normal blood cells may help retain some shear-thinning capability though without addressing a baseline relative increase in effective viscosity independent of shear.

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High-throughput assessment of hemoglobin polymer in single red blood cells from sickle cell patients under controlled oxygen tension

Caprio

Schonbrun

Gonçalves

et al. 2019

Proc. Natl. Acad. Sci. U.S.A.

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Sickle cell disease (SCD) is caused by a variant hemoglobin molecule that polymerizes inside red blood cells (RBCs) in reduced oxygen tension. Treatment development has been slow for this typically severe disease, but there is current optimism for curative gene transfer strategies to induce expression of fetal hemoglobin or other nonsickling hemoglobin isoforms. All SCD morbidity and mortality arise directly or indirectly from polymer formation in individual RBCs. Identifying patients at highest risk of complications and treatment candidates with the greatest curative potential therefore requires determining the amount of polymer in individual RBCs under controlled oxygen. Here, we report a semiquantitative measurement of hemoglobin polymer in single RBCs as a function of oxygen. The method takes advantage of the reduced oxygen affinity of hemoglobin polymer to infer polymer content for thousands of RBCs from their overall oxygen saturation. The method enables approaches for SCD treatment development and precision medicine.

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Bicontinuous Ion-Exchange Materials through Polymerization-Induced Microphase Separation

2020

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Polymerization-induced microphase separation has been used to prepare solid cross-linked monoliths containing bicontinuous and nanostructured polymer domains. We use this process to fabricate a monolith containing either a negatively or positively charged polyelectrolyte domain inside of the neutral styrene/divinylbenzene-derived matrix. First, the materials are made with a neutral pre-ionic polymer containing masked charged groups. The monoliths are then functionalized to a charged state by treatment with trimethylamine; small-angle X-ray scattering shows no significant morphological change in the microphase-separated structure upon postpolymerization modification. By exchanging dyes with the counterions in the material, we corroborated the continuity of the charged domains. Using ion-exchange capacity measurements, we estimate the number of accessible charges within the material based on macro-chain transfer agent molar mass and loading.

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Feature tracking microfluidic analysis reveals differential roles of viscosity and friction in sickle cell blood

et al. 2022

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Jose Valdez

Knockout of Lmod2 results in shorter thin filaments followed by dilated cardiomyopathy and juvenile lethality

A microfluidic platform for simultaneous quantification of oxygen-dependent viscosity and shear thinning in sickle cell blood

High-throughput assessment of hemoglobin polymer in single red blood cells from sickle cell patients under controlled oxygen tension

Bicontinuous Ion-Exchange Materials through Polymerization-Induced Microphase Separation

Feature tracking microfluidic analysis reveals differential roles of viscosity and friction in sickle cell blood

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