Actin Dynamics in Aspergillus nidulans

Quintanilla, Laura

03 October 2013

Actin is a major cytoskeletal protein required for the polarized growth of filamentous fungi. Recent studies have characterized the dynamics of actin polymers in growing Neurospora crassa and identified the presence of actin patches, cables and rings. In Aspergillus nidulans actin patch and ring dynamics have been documented using fluorescent proteins tagged to actin. However, fluorescently tagged actin does not reveal the presence of actin cables. Recently, the Lifeact construct has been used to label all three actin structures in fungi. Lifeact is a 17 amino acid peptide derived from the Saccharomyces cerevisiae actin binding protein Abp140p. To better understand actin dynamics in living cells, A. nidulans was transformed with the Lifeact reporter construct. Lifeact expressing strains grew and developed as wild-type. Lifeact labeled actin localized to three different organizational patterns in mature hyphae: a sub-apical collar of endocytic actin patches that was located approximately 2µm from the apex, an apical actin array, and a sub-apical actin web. The apical actin array (AAA – Apical Actin Array) was present in the apices of forty percent of hyphae observed (n=100). The sub-apical actin web (SAW – Sub-apical Actin Web) was present in fifty percent of hyphae observed and was located at an average of 18.46 µm from the apex. It was hypothesized that this network of actin cables was associated with branch and septation site selection or associated with branch and septa formation. An alternative hypothesis was that the SAW acted as a diffusion barrier for nuclei. It was determined that the SAW was neither associated with branch or septa site selection or formation, nor did it act as a barrier for nuclei. It was observed that the AAA can retract and form the SAW. It was hypothesized that this change in actin dynamics could be connected to the faster growth rates reported for mature hyphae. Measurements of individual hyphae containing the AAA or SAW revealed that hyphae with SAWs grow 1.67 times faster than hyphae with AAAs. This data supports the hypothesis that the presence of the SAW is associated with faster rates of growth. An accumulation of circular vesicles was also observed posterior to the SAW and are believed to be woronin bodies. The identity of the circular structures was not confirmed, but the retraction of the AAA to form the SAW may act as a mechanism to transport apically formed woronin bodies to distal regions of the cell. The SAW may also act as a barrier to maintain woronin bodies in sub-apical regions of the hyphae. The Lifeact actin reporter gave clear and defined labeling of filamentous actin in A. nidulans without disturbing natural development. The use of Lifeact allowed for novel insights into actin cable dynamics present in the apical and sub-apical regions of hyphae, branch formation, and septa formation.

Lifeact

actin dynamics

Assessing the Roles of Striatin Orthologs in Fungal Morphogenesis, Sexual Development and Pathogenicity

Wang, Chih-Li

2011 August 1900

Striatin family proteins contain a caveolin binding domain, a coiled-coil motif, a calmodulin binding domain, and a WD-repeat domain. Homologs of striatin protein have been However, our knowledge of the function and the molecular mechanism of fungal striatin homologs is limited. Based on the conserved sequences of functional domains, I hypothesized that the fungal striatin orthologs also act as scaffolding proteins that are functionally conserved among fungal species and involved in multiple types of development in the diverse kingdom Mycota. I used reverse genetic strategies to study the function of the Aspergillus nidulans striatin ortholog (strA) and the Colletotrichum graminicola striatin ortholog (str1). In assays of sexual development, the strA deletion strain (ΔstrA) produces fewer ascospores with smaller cleistothecia, while the str1 deletion strain (Δstr1) is defective in perithecia development. The ΔstrA phenotypes indicate that StrA is associated with ascosporogenesis in cleistothecia. Both ΔstrA and Δstr1 are reduced in radial growth and in conidia production. The Δstr1 strain is also altered in its spiral growth pattern and morphology of conidia and hyphopodia, but it produces appressoria similar to wild type. The pairing of nitrate non-utilizing mutants demonstrates that Str1 is required for hyphal fusion. In pathogenicity, Δstr1 is less virulent in maize anthracnose leaf blight and stalk rot. The phenotypes of Δstr1 are complemented by the Fusarium verticillioides striatin ortholog (fsr1), indicating that Fsr1 and Str1 are functionally conserved. Over-expression of StrA reveals its positive role in conidiation and the sexual production. StrA::eGFP localizes mainly to the endoplasmic reticulum. After comparing the results from these two species and other studied fungal species, I suggest that fungal striatins are involved in five types of development including hyphal growth, hyphal fusion, conidiation, sexual development, and virulence, and propose a model of fungal striatin protein interactions to account for these diverse phenotypes.

Fungal striatin

Aspergillus nidulans

StrA

Colletotrichum graminicola

Str1

Sexual development

Virulence

Hyphal fusion

Conidiation

Hyphal growth

Lifeact

Actin

<i>Cauliflower mosaic virus</i> Inclusion Body Formation: The Where, The How and The Why

Alers-Velazquez, Roberto M.

January 2020

No description available.

Molecular Biology

Virology

LifeAct

Latrunculin B

GFP250

Liquid-liquid phase separation

Nonmembranous organelles

Pararetrovirus

Particle tracking

qPCR

DAS-ELISA

CaMV

P6

inclusion bodies

Talin

symptom formation

temperature