Komparativní fenotypická studie vybraných forminových mutantů Arabidopsis / Comparative phenotypic study of selected Arabidopsis formin mutants

D'Agostino, Viktoria

January 2018

Actin filaments and microtubules are involved in cell development and morphogenesis. Plant Class II formins regulate both cytoskeletal polymers. However their function has not yet been fully described. This study examines effects of LOF mutations in Arabidopsis thaliana FH13 (AT5G58160) and FH14 (AT1G31810) genes on early root system development using a pharmacological approach. Since measuring root length of numerous mutant lines in multiple conditions is laborious and time consuming, this thesis also involves optimization of this process with the aim to establish a reliable method of fast visualisation and measurement of Arabidopsis seedlings in a time series in the laboratory. Furthermore, statistical analysis for a large amount of data gathered in multiple conditions had to be optimized. While no significant phenotype in terms of root length was found in fh13, fh14 and double fh13 fh14 LOF mutants under standard conditions, treatment with cytoskeletal drugs revealed possible changes in lateral root branching in an fh14 mutant. Nevertheless, specific function of FH13 and FH14 remains a question.

The Effect of Microenvironmental Cues on Adipocyte Cytoskeletal Remodeling

Anvari, Golnaz

January 2022

Obesity, a disease characterized by excess adipose tissue (AT), is a growing worldwide epidemic. The Centers for Disease Control and Prevention (CDC), in 2017-2018, reported the prevalence of obesity in adults in the United States was 42.4% . Obesity increases the risk for many other serious health conditions such as type 2 diabetes, cardiovascular diseases, stroke, and some cancers. In individuals with obesity, the hypertrophic expansion of adipocytes, the main cell type within AT, is not matched by new vessel formation, leading to AT hypoxia. As a result, hypoxia inducible factor-1⍺ (HIF-1⍺) accumulates in adipocytes inducing a transcriptional program that upregulates profibrotic genes and biosynthetic enzymes such as lysyl oxidase (LOX) synthesis. This excess synthesis and crosslinking of extracellular matrix (ECM) components cause AT fibrosis. Although fibrosis is a hallmark of obese AT, the role of fibroblasts, cells known to regulate fibrosis in other fibrosis-prone tissues, is not well studied. Adipocytes are mechanoresponsive and affected by different microenvironmental cues, including hypoxia and mechanical (un)loading. Yet, no study has focused on the role of the aforementioned factors on the adipocyte mechanical response, including actin cytoskeletal remodeling. This dissertation aims to develop an in vitro model of healthy/diseased AT to explore the effect of microenvironmental cues on adipocyte function and actin cytoskeletal remodeling. The first aim is to study (1) the crosstalk between fibroblasts and adipocytes in a co-culture model and (2) the effect of hypoxia on the ras homolog gene family member A (RhoA)/Rho-associated coiled-coil kinases (ROCK) mechanical pathway and actin cytoskeletal remodeling in adipocytes. We confirmed that hypoxia creates a diseased phenotype by inhibiting adipocyte maturation and inducing actin stress fiber formation facilitated by myocardin-related transcription factor A (MRTF-A/MKL1) nuclear translocation. The second aim explores the effects of mechanical unloading (simulated microgravity) on key adipocyte functions and actin cytoskeletal remodeling. This study demonstrated that mechanical unloading enhances adipocyte maturation via increased lipogenesis and lipolysis and cortical actin remodeling, which together further enhanced glucose uptake. However, disrupting cortical actin remodeling by using inhibitors or exposure to a high concentration of free fatty acids (FFAs) diminished enhanced adipocyte functions observed in simulated microgravity. Overall, the results of these studies support the importance of microenvironmental cues on adipocyte actin cytoskeletal remodeling. Therefore, targeting mechanical pathways that regulate actin cytoskeletal remodeling can be used to improve adipocyte function and AT metabolism and possibly treat related diseases such as type 2 diabetes and obesity. / Bioengineering

Bioengineering

Actin cytoskeletal

Adipocyte

Glucose uptake

Hypoxia

Lipid metabolism

Simulated microgravity

Identification of Novel Roles for the Survival Motor Neuron (Smn) Protein: Implications on Spinal Muscular Atrophy (SMA) Pathogenesis and Therapy

Bowerman, Melissa

18 April 2012

Spinal muscular atrophy (SMA) is the leading genetic cause of death of young children. It is an autosomal recessive disease caused by the mutation and/or the deletion within the ubiquitously expressed survival motor neuron 1 (SMN1) gene. SMA pathology is characterized by spinal cord motor neuron degeneration, neuromuscular junction (NMJ) defects and muscular atrophy. Upon disease onset, SMA patients progressively become paralyzed and in the most severe cases, they die due to respiratory complications. Over the years, it has become clear that SMN is a multi-functional protein with important roles in small nuclear ribonucleoprotein (snRNP) assembly, RNA metabolism, axonal outgrowth and pathfinding, mRNA transport as well as in the functional development of NMJs, skeletal muscle and cardiac muscle. However, it remains unclear which of these functions, and the respective perturbed molecular pathways, dictate SMA pathogenesis. Here, we have established Smn-depleted PC12 cells and an intermediate SMA mouse model to characterize a role for Smn in the regulation of actin cytoskeleton dynamics. We find that Smn depletion results in the increased expression of profilin IIa and active RhoA (RhoA-GTP) as well as the decreased expression of plastin 3 and Cdc42. Importantly, the inhibition of rho-kinase (ROCK), a direct downstream regulator of RhoA, significantly increased the lifespan of SMA mice and shows beneficial potential as a therapeutic strategy for SMA. In an addition, we have uncovered a muscle- and motor neuron-independent role for SMN in the regulation of pancreatic development and glucose metabolism in SMA mice and type 1 SMA patients. This finding highlights the importance of combining a glucose tolerance assessment of SMA patients with their existing clinical care management. Thus, our work has uncovered two novel and equally important roles for the SMN protein, both of which contribute significantly to SMA pathogenesis.

spinal muscular atrophy

survival motor neuron protein

actin cytoskeletal dynamics

Rho GTPases

motor neuron

skeletal muscle

neuromuscular junctions

Rho-kinase inhibitors

glucose metabolism

pancreatic islet

profilin

plastin 3

Identification of Novel Roles for the Survival Motor Neuron (Smn) Protein: Implications on Spinal Muscular Atrophy (SMA) Pathogenesis and Therapy

Bowerman, Melissa

18 April 2012

Spinal muscular atrophy (SMA) is the leading genetic cause of death of young children. It is an autosomal recessive disease caused by the mutation and/or the deletion within the ubiquitously expressed survival motor neuron 1 (SMN1) gene. SMA pathology is characterized by spinal cord motor neuron degeneration, neuromuscular junction (NMJ) defects and muscular atrophy. Upon disease onset, SMA patients progressively become paralyzed and in the most severe cases, they die due to respiratory complications. Over the years, it has become clear that SMN is a multi-functional protein with important roles in small nuclear ribonucleoprotein (snRNP) assembly, RNA metabolism, axonal outgrowth and pathfinding, mRNA transport as well as in the functional development of NMJs, skeletal muscle and cardiac muscle. However, it remains unclear which of these functions, and the respective perturbed molecular pathways, dictate SMA pathogenesis. Here, we have established Smn-depleted PC12 cells and an intermediate SMA mouse model to characterize a role for Smn in the regulation of actin cytoskeleton dynamics. We find that Smn depletion results in the increased expression of profilin IIa and active RhoA (RhoA-GTP) as well as the decreased expression of plastin 3 and Cdc42. Importantly, the inhibition of rho-kinase (ROCK), a direct downstream regulator of RhoA, significantly increased the lifespan of SMA mice and shows beneficial potential as a therapeutic strategy for SMA. In an addition, we have uncovered a muscle- and motor neuron-independent role for SMN in the regulation of pancreatic development and glucose metabolism in SMA mice and type 1 SMA patients. This finding highlights the importance of combining a glucose tolerance assessment of SMA patients with their existing clinical care management. Thus, our work has uncovered two novel and equally important roles for the SMN protein, both of which contribute significantly to SMA pathogenesis.

spinal muscular atrophy

survival motor neuron protein

actin cytoskeletal dynamics

Rho GTPases

motor neuron

skeletal muscle

neuromuscular junctions

Rho-kinase inhibitors

glucose metabolism

pancreatic islet

profilin

plastin 3

Identification of Novel Roles for the Survival Motor Neuron (Smn) Protein: Implications on Spinal Muscular Atrophy (SMA) Pathogenesis and Therapy

Bowerman, Melissa

January 2012

Spinal muscular atrophy (SMA) is the leading genetic cause of death of young children. It is an autosomal recessive disease caused by the mutation and/or the deletion within the ubiquitously expressed survival motor neuron 1 (SMN1) gene. SMA pathology is characterized by spinal cord motor neuron degeneration, neuromuscular junction (NMJ) defects and muscular atrophy. Upon disease onset, SMA patients progressively become paralyzed and in the most severe cases, they die due to respiratory complications. Over the years, it has become clear that SMN is a multi-functional protein with important roles in small nuclear ribonucleoprotein (snRNP) assembly, RNA metabolism, axonal outgrowth and pathfinding, mRNA transport as well as in the functional development of NMJs, skeletal muscle and cardiac muscle. However, it remains unclear which of these functions, and the respective perturbed molecular pathways, dictate SMA pathogenesis. Here, we have established Smn-depleted PC12 cells and an intermediate SMA mouse model to characterize a role for Smn in the regulation of actin cytoskeleton dynamics. We find that Smn depletion results in the increased expression of profilin IIa and active RhoA (RhoA-GTP) as well as the decreased expression of plastin 3 and Cdc42. Importantly, the inhibition of rho-kinase (ROCK), a direct downstream regulator of RhoA, significantly increased the lifespan of SMA mice and shows beneficial potential as a therapeutic strategy for SMA. In an addition, we have uncovered a muscle- and motor neuron-independent role for SMN in the regulation of pancreatic development and glucose metabolism in SMA mice and type 1 SMA patients. This finding highlights the importance of combining a glucose tolerance assessment of SMA patients with their existing clinical care management. Thus, our work has uncovered two novel and equally important roles for the SMN protein, both of which contribute significantly to SMA pathogenesis.

spinal muscular atrophy

survival motor neuron protein

actin cytoskeletal dynamics

Rho GTPases

motor neuron

skeletal muscle

neuromuscular junctions

Rho-kinase inhibitors

glucose metabolism

pancreatic islet

profilin

plastin 3

THE MEMBRANE BLOCK TO POLYSPERMY IN MAMMALIAN EGGS; ANALYSES OF CALCIUM SIGNALING AND ACTIN DYNAMICS DURING FERTILIZATION

Nicole Leigh Branca (15353446)

27 April 2023

<p>    </p> <p>When mammalian eggs are fertilized, they undergo an egg-to-embryo transition during which different egg activation events take place. Egg activation events include the establishment of blocks to polyspermy, which prevent multiple sperm from fertilizing an egg. One of these blocks to polyspermy occurs at the level of the egg plasma membrane (the membrane block to polyspermy). Previous work in our lab provides evidence that the mammalian membrane block to polyspermy is mediated by sperm-induced calcium signaling and the egg’s actomyosin cytoskeleton (McAvey et al., 2002). This thesis research builds upon this foundation, testing hypotheses about two specific effector molecules, one involved in calcium signaling and one with the actin cytoskeleton, and also developing the use of an actin probe for live-cell imaging, with the goal of imaging actin dynamics in eggs undergoing fertilization. Specifically, we examined the calcium effector molecule Ca2+/Calmodulin-dependent-protein kinase IIg (<strong>CaMKII</strong>g), based on previous studies showing that CaMKII plays a role in the membrane block (Gardner et al., 2007) and that the g isoform of CaMKII is necessary and sufficient for eggs to complete meiosis (Backs et al., 2010). We tested the hypothesis that CaMKIIg would mediate the membrane block to polyspermy but found that egg activation driven by expression of a constitutively active form of CaMKIIg was not sufficient to establish the membrane block. Our studies of the actin cytoskeleton focused on the Arp2/3 complex as a candidate. We tested the hypothesis that Arp2/3, which mediates actin filament branching, was involved in membrane block establishment, building on the finding that disruption of actin with the drug cytochalasin D impairs the membrane block (McAvey et al., 2022). These studies used the Arp2/3 inhibitor CK666, predicting that we would see increased sperm incorporation in CK666-treated eggs. However, an assay of sperm incorporation over time indicated that Arp2/3 may not play a significant role in the membrane block to polyspermy, although follow-up studies will be beneficial. Lastly, the actin probe SiR- Actin was assessed for use on oocytes undergoing live-cell imaging during meiosis I and II. Oocytes were treated with differing concentrations of SiR-Actin and live cell imaged while maturing through meiosis I or completing meiosis II. Higher doses and longer exposure to SiR- Actin caused abnormalities in oocytes during meiosis I but not in eggs completing meiosis II. Together, this work sets the stage of a range of future studies into the mammalian membrane block to polyspermy. </p>

Reproduction

Membrane Block to Polyspermy

mammalian fertilization

ARP2/3 complex

CaMKII y

Calcium signaling

actin cytoskeletal dynamics

Oocyte Meiosis

SiR-Actin

actin probes

Live cell imaging analysis