Actin Isoforms Research Articles

Tropomyosin Isoforms Segregate into Distinct Clusters on Single Actin Filaments

Tropomyosins (Tpms) are rod-shaped proteins that interact head-to-tail to form a continuous polymer along both sides of most cellular actin filaments. Head-to-tail interaction between adjacent Tpm molecules and the formation of an overlap complex between them leads to the assembly of actin filaments with one type of Tpm isoform in time and space. Variations in the affinity of tropomyosin isoforms for different actin structures are proposed as a potential sorting mechanism. However, the detailed mechanisms of the spatio-temporal sorting of Tpms remain elusive. In this study, we investigated the early intermediates during actin–tropomyosin filament assembly, using a skeletal/cardiac Tpm isoform (Tpm1.1) and a cytoskeletal isoform (Tpm1.6) that differ only in the last 27 amino acids. We investigated how the muscle isoform Tpm1.1 and the cytoskeletal isoform Tpm1.6 nucleate domains on the actin filament, and tested whether (1) recruitment is affected by the actin isoform (muscle vs. cytoskeletal) and (2) whether there is specificity in recruiting the same isoform to a domain at these early stages. To address these questions, actin filaments were exposed to low concentrations of fluorescent tropomyosins in solution. The filaments were immobilized onto glass coverslips and the pattern of decoration was visualized by TIRF microscopy. We show that at the early assembly stage, tropomyosins formed multiple distinct fluorescent domains (here termed “cluster”) on the actin filaments. An automated image analysis algorithm was developed and validated to identify clusters and estimate the number of tropomyosins in each cluster. The analysis showed that tropomyosin isoform sorting onto an actin filament is unlikely to be driven by a preference for nucleating on the corresponding muscle or cytoskeletal actin isoforms, but rather is facilitated by a higher probability of incorporating the same tropomyosin isoforms into an early assembly intermediate. We showed that the 27 amino acids at the end of each tropomyosin seem to provide enough molecular information for the attachment of the same tropomyosin isoforms adjacent to each other on an actin filament. This results in the formation of homogeneous clusters composed of the same isoform rather than clusters with mixed isoforms.

Abstract We020: Myh9 plays a vital role in cardiac myofibroblast differentiation and is indispensable for cardiac repair after myocardial infarction

After myocardial infarction (MI), quiescent cardiac fibroblasts (CFs) are activated and differentiate into myofibroblasts featured by elevated expression of smooth muscle alpha-actin (SMαA, encoded by Acta2 ), which form contractile stress fibers. However, compared to the matrix formation function of cardiac myofibroblasts, much less is known about the role of their contraction in post-MI cardiac repair. In our previous study using mice lacking Acta2 in CFs, all other 5 actin isoforms were activated to compensate for the loss of Acta2 , suggesting the low feasibility of abolishing cardiac myofibroblast contraction through deleting actin genes. An alternative strategy through targeting myosin was explored. Our transcriptomic study identified Myh9 and Myh10 [encoding non-muscle myosin IIA (NM IIA) and NM IIB, respectively] as the dominant myosin isoforms in cardiac myofibroblasts. In vitro studies found that Myh9 knockout (KO) but not Myh10 KO significantly affected cardiac myofibroblast morphology, completely abolished the stress fiber formation and contractility of these cells, and reduced their proliferation and ability to stabilize the surrounding matrix. Mice lacking Myh9 in CFs have an increased post-MI cardiac rupture rate compared to WT mice regardless of sexes ( p =0.004 and 0.02 for male and female mice, respectively). In vitro and in vivo transcriptomic and proteomics analysis revealed disrupted expression of stress fiber and mesenchymal identity genes/proteins caused by Myh9 KO. Mechanistically, Myh9 KO led to an increased globular to filamentous (G/F) actin ratio. The altered actin dynamics likely trigger multiple epigenetic events, which together lead to significantly altered cardiac myofibroblast gene expression and activities beyond contraction.

The DIAPH3 linker specifies a β-actin network that maintains RhoA and Myosin-II at the cytokinetic furrow

Cytokinesis is the final step of the cell division cycle that leads to the formation of two new cells. Successful cytokinesis requires significant remodelling of the plasma membrane by spatially distinct β- and γ-actin networks. These networks are generated by the formin family of actin nucleators, DIAPH3 and DIAPH1 respectively. Here we show that β- and γ-actin perform specialized and non-redundant roles in cytokinesis and cannot substitute for one another. Expression of hybrid DIAPH1 and DIAPH3 proteins with altered actin isoform specificity relocalized cytokinetic actin isoform networks within the cell, causing cytokinetic failure. Consistent with this we show that β-actin networks, but not γ-actin networks, are required for the maintenance of non-muscle myosin II and RhoA at the cytokinetic furrow. These data suggest that independent and spatially distinct actin isoform networks form scaffolds of unique interactors that facilitate localized biochemical activities to ensure successful cell division.

Structural and functional mechanisms of actin isoforms.

Actin is a highly conserved and fundamental protein in eukaryotes and participates in a broad spectrum of cellular functions. Cells maintain a conserved ratio of actin isoforms, with muscle and non-muscle actins representing the main actin isoforms in muscle and non-muscle cells, respectively. Actin isoforms have specific and redundant functional roles and display different biochemistries, cellular localization, and interactions with myosins and actin-binding proteins. Understanding the specific roles of actin isoforms from the structural and functional perspective is crucial for elucidating the intricacies of cytoskeletal dynamics and regulation and their implications in health and disease. Here, we review how the structure contributes to the functional mechanisms of actin isoforms with a special emphasis on the questions of how post-translational modifications and disease-linked mutations affect actin isoforms biochemistry, function, and interaction with actin-binding proteins and myosin motors.

Imbalance between Actin Isoforms Contributes to Tumour Progression in Taxol-Resistant Triple-Negative Breast Cancer Cells.

The widespread occurrence of breast cancer and its propensity to develop drug resistance highlight the need for a comprehensive understanding of the molecular mechanisms involved. This study investigates the intricate pathways associated with secondary resistance to taxol in triple-negative breast cancer (TNBC) cells, with a particular focus on the changes observed in the cytoplasmic actin isoforms. By studying a taxol-resistant TNBC cell line, we revealed a shift between actin isoforms towards γ-actin predominance, accompanied by increased motility and invasive properties. This was associated with altered tubulin isotype expression and reorganisation of the microtubule system. In addition, we have shown that taxol-resistant TNBC cells underwent epithelial-to-mesenchymal transition (EMT), as evidenced by Twist1-mediated downregulation of E-cadherin expression and increased nuclear translocation of β-catenin. The RNA profiling analysis revealed that taxol-resistant cells exhibited significantly increased positive regulation of cell migration, hormone response, cell-substrate adhesion, and actin filament-based processes compared with naïve TNBC cells. Notably, taxol-resistant cells exhibited a reduced proliferation rate, which was associated with an increased invasiveness in vitro and in vivo, revealing a complex interplay between proliferative and metastatic potential. This study suggests that prolonged exposure to taxol and acquisition of taxol resistance may lead to pro-metastatic changes in the TNBC cell line.

IntAct: A nondisruptive internal tagging strategy to study the organization and function of actin isoforms.

Mammals have 6 highly conserved actin isoforms with nonredundant biological functions. The molecular basis of isoform specificity, however, remains elusive due to a lack of tools. Here, we describe the development of IntAct, an internal tagging strategy to study actin isoforms in fixed and living cells. We identified a residue pair in β-actin that permits tag integration and used knock-in cell lines to demonstrate that IntAct β-actin expression and filament incorporation is indistinguishable from wild type. Furthermore, IntAct β-actin remains associated with common actin-binding proteins (ABPs) and can be targeted in living cells. We demonstrate the usability of IntAct for actin isoform investigations by showing that actin isoform-specific distribution is maintained in human cells. Lastly, we observed a variant-dependent incorporation of tagged actin variants into yeast actin patches, cables, and cytokinetic rings demonstrating cross species applicability. Together, our data indicate that IntAct is a versatile tool to study actin isoform localization, dynamics, and molecular interactions.

Adaptive responses of the ileum of NOD mice to low-dose fluoride: A proteomic exploratory study.

Fluoride (F) has been employed worldwide to control dental caries. More recently, it has been suggested that the consumption of low doses of F in the drinking water may reduce blood glucose levels, introducing a new perspective for the use of F for the management of blood glucose. However, the exact mechanism by which F affects blood glucose levels remains largely unexplored. Given that the small gut plays a pivotal role in glucose homeostasis, the aim of this study was to investigate the proteomic changes induced by low doses of F in the ileum of female nonobese-diabetic (NOD) mice. Forty-two female NOD mice were divided into two groups based on the F concentration in their drinking water for 14 weeks: 0 (control) or 10 mgF/L. At the end of the experimental period, the ileum was collected for proteomic and Western blot analyses. Proteomic analysis indicated an increase in isoforms of actin, gastrotropin, several H2B histones, and enzymes involved in antioxidant processes, as well as a decrease in enzymes essential for energy metabolism. In summary, our data indicates an adaptive response of organism to preserve protein synthesis in the ileum, despite significant alterations in energy metabolism typically induced by F, therefore highlighting the safety of controlled fluoridation in water supplies.

An Update on Reported Variants in the Skeletal Muscle α‐Actin (ACTA1) Gene

The ACTA1 gene encodes skeletal muscle alpha‐actin, which forms the core of the sarcomeric thin filament in adult skeletal muscle. ACTA1 represents one of six highly conserved actin proteins that have all been associated with human disease. The first 15 pathogenic variants in ACTA1 were reported in 1999, which expanded to 177 in 2009. Here, we update on the now 607 total variants reported in LOVD, HGMD, and ClinVar, which includes 343 reported pathogenic/likely pathogenic (P/LP) variants. We also provide suggested ACTA1‐specific modifications to ACMG variant interpretation guidelines based on our analysis of known variants, gnomAD reports, and pathogenicity in other actin isoforms. Using these criteria, we report a total of 447 P/LP ACTA1 variants. From a clinical perspective, the number of reported ACTA1 disease phenotypes has grown from five to 20, albeit with some overlap. The vast majority (74%) of ACTA1 variants cause nemaline myopathy (NEM), but there are increasing numbers that cause cardiomyopathy and novel phenotypes such as distal myopathy. We highlight challenges associated with identifying genotype–phenotype correlations for ACTA1. Finally, we summarize key animal models and review the current state of preclinical treatments for ACTA1 disease. This update provides important resources and recommendations for the study and interpretation of ACTA1 variants.

Metalloproteomic Investigation of Hg-Binding Proteins in Renal Tissue of Rats Exposed to Mercury Chloride.

Results obtained from rat studies indicate that, even at low concentrations, mercurial species cause harmful effects on the kidneys, by inducing the nephrotic oxidative stress response. In the present work, Hg-associated proteins were identified as possible mercury-exposure biomarkers in rat kidneys exposed to low mercury chloride concentrations for 30 days (Hg-30) and 60 days (Hg-60), using metalloproteomic strategies. The renal proteomic profile was fractioned by two-dimensional electrophoresis and the mercury determinations in kidney samples, protein pellets and protein spots were performed using graphite furnace atomic absorption spectrometry. The characterization of Hg-associated protein spots and the analysis of differentially expressed proteins were performed by liquid chromatography, coupled with tandem mass spectrometry. Eleven Hg-associated protein spots with a concentration range of 79 ± 1 to 750 ± 9 mg kg-1 in the Hg-60 group were identified. The characterization and expression analyses allowed the identification of 53 proteins that were expressed only in the Hg-60 group, 13 "upregulated" proteins (p > 0.95) and 47 "downregulated" proteins (p < 0.05). Actin isoforms and hemoglobin subunits were identified in protein spots of the Hg-60 group, with mercury concentrations in the range of 138 to 750 mg kg-1, which qualifies these proteins as potential mercury-exposure biomarkers.

Cytosolic actin isoforms form networks with different rheological properties that indicate specific biological function

The implications of the existence of different actins expressed in epithelial cells for network mechanics and dynamics is investigated by microrheology and confocal imaging. γ-actin predominately found in the apical cortex forms stiffer networks compared to β-actin, which is preferentially organized in stress fibers. We attribute this to selective interactions with Mg2+-ions interconnecting the filaments’ N-termini. Bundling propensity of the isoforms is different in the presence of Mg2+-ions, while crosslinkers such as α-actinin, fascin, and heavy meromyosin alter the mechanical response independent of the isoform. In the presence of myosin, β-actin networks show a large number of small contraction foci, while γ-actin displays larger but fewer foci indicative of a stronger interaction with myosin motors. We infer that subtle changes in the amino acid sequence of actin isoforms lead to alterations of the mechanical properties on the network level with potential implications for specific biological functions.

Actin Isoform Composition and Binding Factors Fine-Tune Regulatory Impact of Mical Enzymes

Actin Isoform Composition and Binding Factors Fine-Tune Regulatory Impact of Mical Enzymes

Purification of modified mammalian actin isoforms for in vitro reconstitution assays

In vitro reconstitution assays using purified actin have greatly improved our understanding of cytoskeletal dynamics and their regulation by actin-binding proteins. However, early purification methods consisted of harsh conditions to obtain pure actin and often did not include correct maturation and obligate modification of the isolated actin monomers. Novel insights into the folding requirements and N-terminal processing of actin as well as a better understanding of the interaction of actin with monomer sequestering proteins such as DNaseI, profilin and gelsolin, led to the development of more gentle approaches to obtain pure recombinant actin isoforms with known obligate modifications. This review summarizes the approaches that can be employed to isolate natively folded endogenous and recombinant actin from tissues and cells. We further emphasize the use and limitations of each method and describe how these methods can be implemented to study actin PTMs, disease-related actin mutations and novel actin-like proteins.

Molecular mechanisms of inorganic-phosphate release from the core and barbed end of actin filaments.

The release of inorganic phosphate (Pi) from actin filaments constitutes a key step in their regulated turnover, which is fundamental to many cellular functions. The mechanisms underlying Pi release from the core and barbed end of actin filaments remain unclear. Here, using human and bovine actin isoforms, we combine cryo-EM with molecular-dynamics simulations and in vitro reconstitution to demonstrate how actin releases Pi through a 'molecular backdoor'. While constantly open at the barbed end, the backdoor is predominantly closed in filament-core subunits and opens only transiently through concerted amino acid rearrangements. This explains why Pi escapes rapidly from the filament end but slowly from internal subunits. In a nemaline-myopathy-associated actin variant, the backdoor is predominantly open in filament-core subunits, resulting in accelerated Pi release and filaments with drastically shortened ADP-Pi caps. Our results provide the molecular basis for Pi release from actin and exemplify how a disease-linked mutation distorts the nucleotide-state distribution and atomic structure of the filament.

Actin polymerization and depolymerization in developing vertebrates.

Development is a complex process that occurs throughout the life cycle. F-actin, a major component of the cytoskeleton, is essential for the morphogenesis of tissues and organs during development. F-actin is formed by the polymerization of G-actin, and the dynamic balance of polymerization and depolymerization ensures proper cellular function. Disruption of this balance results in various abnormalities and defects or even embryonic lethality. Here, we reviewed recent findings on the structure of G-actin and F-actin and the polymerization of G-actin to F-actin. We also focused on the functions of actin isoforms and the underlying mechanisms of actin polymerization/depolymerization in cellular and organic morphogenesis during development. This information will extend our understanding of the role of actin polymerization in the physiologic or pathologic processes during development and may open new avenues for developing therapeutics for embryonic developmental abnormalities or tissue regeneration.

#5919 PATIENT-SPECIFIC HUMAN INDUCED PLURIPOTENT STEM CELL (HIPSC)-DERIVED PODOCYTES

Abstract Background and Aims Podocytes typically represent a distinct morphology with long, interdigitating primary and secondary foot processes wrapping around glomerular capillaries forming the filtration unit of the kidney. In glomerular diseases like genetic focal segmental glomerulosclerosis (FSGS), podocyte alterations are often related to dysfunction of the glomerular filtration barrier and the development of proteinuria. Genetic mutations in podocyte relevant genes, important for foot process or actin cytoskeleton dynamics, are known to induce severe podocyte injury. Analysis of podocyte alterations ex vivo is limited because of their inability to proliferate due to their terminal differentiated state and limited access to primary podocytes. Instead, immortalized podocytes regained proliferation capacity by insertion of a thermosensitive SV40 large T antigen and are useful for many research questions. However, these podocytes usually do not express all podocyte marker and foot process development is often restricted. Since we aim to characterize personalized podocytes from patients suffering from genetic FSGS ex vivo, we generated podocytes from dermal fibroblasts via reprogramming into hiPSCs and subsequent differentiation into hiPSC-derived podocytes keeping the patients’ genetic background. Method Dermal fibroblasts were outgrown from a skin punch biopsy from a patient or a healthy donor and subsequently reprogrammed into hiPSCs by electroporation of the common OKSM plasmids and finally differentiated into podocytes. Cells were characterized phenotypically regarding morphology and marker expression using RNA bulk sequencing, western blot, qPCR and immunofluorescence staining. Potential functional alterations of diseased podocytes regarding actin cytoskeleton were assessed by actin polymerization assay. Results Patient-specific podocytes could be generated ex vivo by reprogramming dermal fibroblasts into hiPSCs and subsequently differentiating them into mature podocytes representing the patients’ background. During this process, cell morphology changed from spindle-like fibroblasts to small and round hiPSCs growing in colonies and representing a high nuclei-to body ratio as well as high proliferation rate. During differentiation, hiPSCs were induced into intermediate mesoderm, resulting in increased cell size and decreased proliferation rate terminating in 300 nm large star-shaped podocytes developing a distinct network of long primary and secondary foot processes. Patient-derived hiPSC-podocytes with a mutation in the INF2 gene lacked filamentous actin and only develop a limited number of only short foot processes compared to hiPSC-podocytes derived from a healthy control donor. Moreover, expression of actin cytoskeleton associated genes like SYNPO, ACTN4 and CD2AP was decreased while other actin isoforms, cortactin and the GTPase RhoA were increased in diseased patient-specific podocytes. Actin polymerization assay showed that polymerization process itself was not altered in healthy and diseased hiPSC-podocytes. Conclusion Analysis of patient-specific podocytes is possible ex vivo via differentiation of hiPSCs, generated from patients’ dermal fibroblasts by episomal reprogramming, into hiPSC-derived podocytes, with the potential to study alterations of disease-specific mutations regarding phenotypical and functional behavior in a personalized manner. The use of hiPSCs bypasses the limitation of restricted podocyte cell number and has the advantage of maintaining the patients’ genetic background at podocyte cell level. This enables future large-scale experiments regarding intercell-cell communication and interaction in glomerular three-dimensional co-cultures or via treatment with therapeutic substances or stress factors.

Smooth Muscle-Alpha Actin R149C Pathogenic Variant Downregulates Integrin Recruitment at Cell-Matrix Adhesions and Decreases Cellular Contractility.

Thoracic aortic aneurysm is found in patients with ACTA2 pathogenic variants. ACTA2 missense variants are associated with impaired aortic smooth muscle cell (SMC) contraction. This study tested the hypothesis that the Acta2R149C/+ variant alters actin isoform expression and decreases integrin recruitment, thus, reducing aortic contractility. Stress relaxation measurements in thoracic aortic rings showed two functional regimes with a reduction of stress relaxation in the aorta from Acta2R149C/+ mice at low tension, but not at high tension values. Contractile responses to phenylephrine and potassium chloride were 50% lower in Acta2R149C/+ mice than in wild-type (WT) mice. Additionally, SMC were immunofluorescently labeled for specific proteins and imaged by confocal or total internal reflection fluorescence microscopy. The quantification of protein fluorescence of Acta2R149C/+ SMC showed a downregulation in smooth muscle α-actin (SMα-actin) and a compensatory upregulation of smooth muscle γ-actin (SMγ-actin) compared to WT cells. These results suggest that downregulation of SMα-actin leads to reduced SMC contractility, while upregulation of SMγ-actin may lead to increased SMC stiffness. Decreased α5β1 and α2β1 integrin recruitment at cell-matrix adhesions further reduce the ability of mutant cells to participate in cell-matrix crosstalk. Collectively, the results suggest that mutant Acta2R149C/+ aortic SMC have reduced contractility and interaction with the matrix, which are potential long-term contributing factors to thoracic aortic aneurysms.

Purification of Human β- and γ-actin from Budding Yeast.

Biochemical studies of human actin and its binding partners rely heavily on abundant and easily purified a-actin from skeletal muscle. Therefore, muscle actin has been used to evaluate and determine the activities of most actin regulatory proteins and there is an underlying concern that these proteins perform differently with actin present in non-muscle cells. To provide easily accessible and relatively abundant sources of human β- or γ-actin (i.e., cytoplasmic actins), we developed Saccharomyces cerevisiae strains that express each as their sole source of actin. Both β- or γ-actin purified in this system polymerize and interact with various binding partners, including profilin, mDia1 (formin), fascin, and thymosin-β4 (Tβ4). Notably, Tβ4 and profilin bind to β- or γ-actin with higher affinity than to a-actin, emphasizing the value of testing actin ligands with specific actin isoforms. These reagents will make specific isoforms of actin more accessible for future studies of actin regulation.

Novel ACTA1 Mutation in a Family with Congenital Myopathy and Variably-penetrant Cardiomyopathy (P6-8.008)

<h3>Objective:</h3> To describe characteristics of a family with congenital myopathy, variably-penetrant dilated cardiomyopathy, and a novel, likely pathogenic variant in <i>ACTA1</i>, c.81C&gt;A (p.Asp27Glu). <h3>Background:</h3> <i>ACTA1</i> encodes skeletal muscle alpha-actin, the primary actin isoform in human skeletal muscle, also expressed to a lesser degree in cardiac muscle. Mutations in <i>ACTA1</i> are common in patients with congenital myopathies; however, associated cardiomyopathy is rare. <h3>Design/Methods:</h3> Retrospective chart review of the proband and 3 family members. <h3>Results:</h3> The proband was a 47-year-old Caucasian male of Ukrainian heritage. His mother (73), sister (40), and nephew (18) were similarly affected. All were hypotonic at birth, had delayed motor milestones, and presented with high-arched palate, elongated facies, and mild-moderate axial and proximal-predominant weakness. The proband had dilated cardiomyopathy with congestive heart failure and intraventricular conduction delay, his sister had dilated cardiomyopathy with left anterior fascicular block, his nephew had left ventricular dilatation with preserved function and normal conduction, and his mother had atrial fibrillation without structural heart disease. Biceps brachii biopsy in the proband demonstrated congenital fiber-type disproportion (CFTD), in addition to rare nemaline rods on electron microscopy. Next-generation sequencing identified a novel, likely pathogenic variant in <i>ACTA1</i>, c.81C&gt;A (p.Asp27Glu), segregating in affected family members. This missense variant is not present in population databases and affects a highly conserved amino acid. In silico models predicted a deleterious effect on protein structure and function (PolyPhen-2: probably damaging; SIFT: 0.0; MutationTaster: disease-causing). <h3>Conclusions:</h3> This family expands the genotypic and phenotypic spectrum of <i>ACTA1-</i>related myopathies. The novel missense variant c.81C&gt;A (p.Asp27Glu) associates with autosomal dominant congenital myopathy, CFTD, and variable, non-age-dependent penetrance of cardiac structural abnormalities along the spectrum of left ventricular dilatation and systolic dysfunction. Dilated cardiomyopathy and CFTD are rare in both isolation and combination in <i>ACTA1</i>-related myopathies. We emphasize that early cardiac surveillance is important in patients with <i>ACTA1-</i>related myopathies. <b>Disclosure:</b> Dr. Putko has nothing to disclose. Dr. Schmitt has nothing to disclose. Dr. Oudit has nothing to disclose. Dr. Phan has nothing to disclose. Dr. Beecher has nothing to disclose.

Four ciliate-specific expansion events occurred during actin gene family evolution of eukaryotes

Actin gene family is a divergent and ancient eukaryotic cellular cytoskeletal gene family, and participates in many essential cellular processes. Ciliated protists offer us an excellent opportunity to investigate gene family evolution, since their gene families evolved faster in ciliates than in other eukaryotes. Nonetheless, actin gene family is well studied in few model ciliate species but little is known about its evolutionary patterns in ciliates. Here, we analyzed the evolutionary pattern of eukaryotic actin gene family based on genomes/transcriptomes of 36 species covering ten ciliate classes, as well as those of nine non-ciliate eukaryotic species. Results showed: (1) Except for conventional actins and actin-related proteins (Arps) shared by various eukaryotes, at least four ciliate-specific subfamilies occurred during evolution of actin gene family. Expansions of Act2 and ArpC were supposed to have happened in the ciliate common ancestor, while expansions of ActI and ActII may have occurred in the ancestor of Armophorea, Muranotrichea, and Spirotrichea. (2) The number of actin isoforms varied greatly among ciliate species. Environmental adaptability, whole genome duplication (WGD) or segmental duplication events, distinct spatial and temporal patterns of expression might play driving forces for the variation of isoform numbers. (3) The ‘birth and death’ model of evolution could explain the evolution of actin gene family in ciliates. And actin genes have been generally under strong negative selection to maintain protein structures and physiological functions. Collectively, we provided meaningful information for understanding the evolution of eukaryotic actin gene family.

Structure and function of Plasmodium actin II in the parasite mosquito stages.

Actins are filament-forming, highly-conserved proteins in eukaryotes. They are involved in essential processes in the cytoplasm and also have nuclear functions. Malaria parasites (Plasmodium spp.) have two actin isoforms that differ from each other and from canonical actins in structure and filament-forming properties. Actin I has an essential role in motility and is fairly well characterized. The structure and function of actin II are not as well understood, but mutational analyses have revealed two essential functions in male gametogenesis and in the oocyst. Here, we present expression analysis, high-resolution filament structures, and biochemical characterization of Plasmodium actin II. We confirm expression in male gametocytes and zygotes and show that actin II is associated with the nucleus in both stages in filament-like structures. Unlike actin I, actin II readily forms long filaments in vitro, and near-atomic structures in the presence or absence of jasplakinolide reveal very similar structures. Small but significant differences compared to other actins in the openness and twist, the active site, the D-loop, and the plug region contribute to filament stability. The function of actin II was investigated through mutational analysis, suggesting that long and stable filaments are necessary for male gametogenesis, while a second function in the oocyst stage also requires fine-tuned regulation by methylation of histidine 73. Actin II polymerizes via the classical nucleation-elongation mechanism and has a critical concentration of ~0.1 μM at the steady-state, like actin I and canonical actins. Similarly to actin I, dimers are a stable form of actin II at equilibrium.