Results 11 to 20 of about 29,858 (265)

Conidial fungi from the semiarid Caatinga biome of Brazil: a new species of Pseudoacrodictys

Mycotaxon, 2014
Patricia Oliveira Fiúza, Luis Fernando Pascholati Gusmão, Rafael F Castaneda-Ruiz   +2 more
exaly   +2 more sources

Some new conidial fungi from Cuba

Mycotaxon, 1996
Rafael F. Castañeda-Ruíz, Masatoshi Saikawa, Gl. Hennebert   +2 more
openalex   +3 more sources

The guanine nucleotide exchange factor RIC8 regulates conidial germination through Gα proteins in Neurospora crassa. [PDF]

, 2012
Heterotrimeric G protein signaling is essential for normal hyphal growth in the filamentous fungus Neurospora crassa. We have previously demonstrated that the non-receptor guanine nucleotide exchange factor RIC8 acts upstream of the Gα proteins GNA-1 and
Borkovich, Katherine A, Cabrera, Ilva E, Cox, Murray P, Eaton, Carla J, Servin, Jacqueline A, Wright, Sara J   +5 more
core   +11 more sources

The Entomopathogenic Fungus Beauveria bassiana Employs Autophagy as a Persistence and Recovery Mechanism during Conidial Dormancy

mBio, 2023
Many filamentous fungi develop a conidiation process as an essential mechanism for their dispersal and survival in natural ecosystems. However, the mechanisms underlying conidial persistence in environments are still not fully understood. Here, we report
Jin-Li Ding, Hai-Yan Lin, Jia Hou, Ming-Guang Feng, Sheng-Hua Ying   +4 more
doaj   +1 more source

Cuticular Lipids as a First Barrier Defending Ixodid Ticks against Fungal Infection

Journal of Fungi, 2022
The chemical composition of tick cuticles acts as a barrier to pathogens and may limit infection by entomopathogenic fungi. This study characterized the cuticular neutral lipids (NL) and hydrocarbons (HCs) of four ixodid ticks that are widely distributed
Cárita S. Ribeiro-Silva, Elen R. Muniz, Valesca H. Lima, Cíntia C. Bernardo, Walquíria Arruda, Rosane N. Castro, Patrícia S. Gôlo, Isabele C. Angelo, Éverton K. K. Fernandes   +8 more
doaj   +1 more source

Microcyle Conidiation in Filamentous Fungi [PDF]

Mycobiology, 2014
The typical life cycle of filamentous fungi commonly involves asexual sporulation after vegetative growth in response to environmental factors. The production of asexual spores is critical in the life cycle of most filamentous fungi. Normally, conidia are produced from vegetative hyphae (termed mycelia).
Jung, Boknam, Kim, Soyeon, Lee, Jungkwan
openaire   +2 more sources

A Simple and Low-Cost Strategy to Improve Conidial Yield and Stress Resistance of Trichoderma guizhouense through Optimizing Illumination Conditions

Journal of Fungi, 2022
Light is perceived by photoreceptors in fungi and further integrated into the stress-activated MAPK HOG pathway, and thereby potentially activates the expression of genes for stress responses.
Yifan Li, Xiya Meng, Degang Guo, Jia Gao, Qiwei Huang, Jian Zhang, Reinhard Fischer, Qirong Shen, Zhenzhong Yu   +8 more
doaj   +1 more source

Conidial and Conidiogenous Cell Development in the Fungi Imperfecti

Nishi Nihon Hifuka, 1978
Garry T. Cole
openalex   +2 more sources

HapX, an Indispensable bZIP Transcription Factor for Iron Acquisition, Regulates Infection Initiation by Orchestrating Conidial Oleic Acid Homeostasis and Cytomembrane Functionality in Mycopathogen Beauveria bassiana

mSystems, 2020
In pathogenic filamentous fungi, conidial germination not only is fundamental for propagation in the environment but is also a critical step of infection.
Yue-Jin Peng, Jia-Jia Wang, Hai-Yan Lin, Jin-Li Ding, Ming-Guang Feng, Sheng-Hua Ying   +5 more
doaj   +1 more source

The novel spore-specific regulator SscA controls Aspergillus conidiogenesis

mBio, 2023
A major group of fungi produces asexual spores (conidia) for dissemination and propagation and, in pathogenic fungi, for infection. Despite the critical role of conidia, the underlying mechanism of spore formation, integrity, and viability is not fully ...
Ye-Eun Son, Jae-Hyuk Yu, Hee-Soo Park
doaj   +1 more source