Cryptococcus neoformans: historical curiosity to modern pathogen D Srikanta, FH Santiago‐Tirado, TL Doering Yeast 31 (2), 47-60, 2014 | 208 | 2014 |
Trojan horse transit contributes to blood-brain barrier crossing of a eukaryotic pathogen FH Santiago-Tirado, MD Onken, JA Cooper, RS Klein, TL Doering MBio 8 (1), 10.1128/mbio. 02183-16, 2017 | 181 | 2017 |
Membrane-trafficking sorting hubs: cooperation between PI4P and small GTPases at the trans-Golgi network FH Santiago-Tirado, A Bretscher Trends in cell biology 21 (9), 515-525, 2011 | 132 | 2011 |
PI4P and Rab inputs collaborate in myosin-V-dependent transport of secretory compartments in yeast FH Santiago-Tirado, A Legesse-Miller, D Schott, A Bretscher Developmental cell 20 (1), 47-59, 2011 | 116 | 2011 |
Active segregation of yeast mitochondria by Myo2 is essential and mediated by Mmr1 and Ypt11 I Chernyakov, F Santiago-Tirado, A Bretscher Current Biology 23 (18), 1818-1824, 2013 | 65 | 2013 |
A Single Protein S-acyl Transferase Acts through Diverse Substrates to Determine Cryptococcal Morphology, Stress Tolerance, and Pathogenic Outcome FH Santiago-Tirado, T Peng, M Yang, HC Hang, TL Doering PLoS Pathog 11 (5), e1004908, 2015 | 63 | 2015 |
False friends: Phagocytes as Trojan horses in microbial brain infections. FH Santiago-Tirado, TL Doering PLoS pathogens 13 (12), e1006680, 2017 | 54 | 2017 |
Computational analysis reveals a key regulator of cryptococcal virulence and determinant of host response SR Gish, EJ Maier, BC Haynes, FH Santiago-Tirado, DL Srikanta, CZ Ma, ... MBio 7 (2), 10.1128/mbio. 00313-16, 2016 | 45 | 2016 |
Trojan horse transit contributes to blood-brain barrier crossing of a eukaryotic pathogen. mBio 8: e02183-16 FH Santiago-Tirado, MD Onken, JA Cooper, RS Klein, TL Doering | 34 | 2017 |
Yeast formin Bni1p has multiple localization regions that function in polarized growth and spindle orientation W Liu, FH Santiago-Tirado, A Bretscher Molecular biology of the cell 23 (3), 412-422, 2012 | 28 | 2012 |
Pbx proteins in Cryptococcus neoformans cell wall remodeling and capsule assembly P Kumar, C Heiss, FH Santiago-Tirado, I Black, P Azadi, TL Doering Eukaryotic cell 13 (5), 560-571, 2014 | 26 | 2014 |
Regulated phosphorylation of budding yeast's essential myosin V heavy chain, Myo2p A Legesse-Miller, S Zhang, FH Santiago-Tirado, CK Van Pelt, A Bretscher Molecular biology of the cell 17 (4), 1812-1821, 2006 | 19 | 2006 |
An atypical ABC transporter is involved in antifungal resistance and host interactions in the pathogenic fungus Cryptococcus neoformans CJ Winski, Y Qian, S Mobashery, FH Santiago-Tirado Mbio 13 (4), e01539-22, 2022 | 17 | 2022 |
The catheterized bladder environment promotes Efg1- and Als1-dependent Candida albicans infection AA La Bella, MJ Andersen, NC Gervais, JJ Molina, A Molesan, ... Science Advances 9 (9), eade7689, 2023 | 14* | 2023 |
All about that fat: Lipid modification of proteins in Cryptococcus neoformans FH Santiago-Tirado, TL Doering Journal of Microbiology 54 (3), 212-222, 2016 | 13 | 2016 |
Development and applications of a CRISPR activation system for facile genetic overexpression in Candida albicans NC Gervais, AA La Bella, LF Wensing, J Sharma, V Acquaviva, M Best, ... G3 13 (2), jkac301, 2023 | 11 | 2023 |
Fungal mechanisms of intracellular survival: what can we learn from bacterial pathogens? PV Stuckey, FH Santiago-Tirado Infection and Immunity 91 (9), e00434-22, 2023 | 5 | 2023 |
An In Vitro Brain Endothelial Model for Studies of Cryptococcal Transmigration into the Central Nervous System FH Santiago‐Tirado, RS Klein, TL Doering Current protocols in microbiology 53 (1), e78, 2019 | 5 | 2019 |
Real-time visualization of phagosomal pH manipulation by Cryptococcus neoformans in an immune signal-dependent way EJ Santiago-Burgos, PV Stuckey, FH Santiago-Tirado Frontiers in Cellular and Infection Microbiology 12, 967486, 2022 | 4 | 2022 |
Advanced genetic techniques in fungal pathogen research RL Ross, FH Santiago-Tirado mSphere, e00643-23, 2024 | 1 | 2024 |