← Leaderboards
Xiaorong Lin
University Of Georgia
$11,480,457
Attributed
$15,110,909
Total exposure
12
Grants
9
Lead (contact PI)
Attributed= this PI's even-split share of every grant they're on (the fair, additive number). Exposure = full size of all those grants.
Funding over time
peak $3.4M · FY2010–25$5M$3.8M$2.5M$1.3M$0
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Funding mix
By agency
NIH$15,110,909 · 12
By mechanism
R01$11,441,651 · 3
R21$3,669,258 · 9
Top collaborators
- Damian J Krysan6 shared
- James Jing Cai2 shared
- Richard Brian Meagher2 shared
- Matthew S Sachs2 shared
Most similar at University Of Georgia
Same institution · by research overlap
- Richard Brian Meagher$7,686,733
- Sarah Anne Hamer$790,450
- Dan Geller$16,667
- Evan M White$16,667
Others in their field
Top investigators on “Cryptococcus”
- Joseph Heitman · Duke University$34,222,654
- Arturo Casadevall · Johns Hopkins University$33,951,910
- Hiten D Madhani · University Of California, San Francisco$24,815,163
- Maurizio Del Poeta · Northport Va Medical Center$22,300,489
- Tamara L Doering · Washington University$20,134,929
- David R Boulware · University Of Minnesota$17,618,664
Research focus
CryptococcusCryptococcus NeoformansMolecularMutantFungusInfectionVirulenceFutureYeastsPathogenesisCellsGeneticBaseMutationIn VitroCessation Of LifeTranscription FactorGenesPathway InteractionsResponsePhenotypeOverexpressionMouse ModelPathogen
Grant awards (38)
Genetic and mechanistic analysis of carbon dioxide tolerance in Cryptococcus pathogenesis$2,811,266
R01 · FY2025 · AI
Cryptococcal vaccine development based on strong immunity induced by morphological strains$577,493
R01 · FY2025 · AI · contact PI
Genetic and mechanistic analysis of carbon dioxide tolerance in Cryptococcus pathogenesis$630,827
R01 · FY2024 · AI
Cryptococcal vaccine development based on strong immunity induced by morphological strains$577,663
R01 · FY2024 · AI · contact PI
Define the molecular bases for cryptococcal adaptation to host conditions by the RAM pathway$226,500
R21 · FY2024 · AI · contact PI
Develop and Assess mRNA Lipid Nanoparticle Vaccines Against Cryptococcosis$217,673
R21 · FY2024 · AI · contact PI
Investigating a signaling molecule that cooperates with quorum sensing to induce biofilm formation in C. neoformans$188,750
R21 · FY2024 · AI · contact PI
Genetic and mechanistic analysis of carbon dioxide tolerance in Cryptococcus pathogenesis$630,827
R01 · FY2023 · AI
Defining the genetic network governing cryptococcal morphological transition$471,846
R01 · FY2023 · AI · contact PI
Investigating a signaling molecule that cooperates with quorum sensing to induce biofilm formation in C. neoformans$226,500
R21 · FY2023 · AI · contact PI
Define the molecular bases for cryptococcal adaptation to host conditions by the RAM pathway$188,750
R21 · FY2023 · AI · contact PI
Develop and Assess mRNA Lipid Nanoparticle Vaccines Against Cryptococcosis$166,248
R21 · FY2023 · AI · contact PI
Genetic and mechanistic analysis of carbon dioxide tolerance in Cryptococcus pathogenesis$663,532
R01 · FY2022 · AI
Genetic and mechanistic analysis of carbon dioxide tolerance in Cryptococcus pathogenesis$678,567
R01 · FY2021 · AI
Defining the genetic network governing cryptococcal morphological transition$471,846
R01 · FY2021 · AI · contact PI
Systematic investigation of GPI-anchored mannoproteins in Cryptococcus neoformans$226,500
R21 · FY2021 · AI · contact PI
Genetic and mechanistic analysis of carbon dioxide tolerance in Cryptococcus pathogenesis$683,782
R01 · FY2020 · AI
Defining the genetic network governing cryptococcal morphological transition$471,846
R01 · FY2020 · AI · contact PI
Systematic investigation of GPI-anchored mannoproteins in Cryptococcus neoformans$188,750
R21 · FY2020 · AI · contact PI
Defining the genetic network governing cryptococcal morphological transition$462,396
R01 · FY2019 · AI · contact PI
Determining genetic signatures of the cryptococcal response to Zoloft by an integrated approach combining transcriptome, translatome and genetic screens$178,677
R21 · FY2019 · AI
Defining the genetic network governing cryptococcal morphological transition$462,396
R01 · FY2018 · AI · contact PI
Meiosis In Cryptococcal Infection$257,990
R21 · FY2018 · AI · contact PI
Determining genetic signatures of the cryptococcal response to Zoloft by an integrated approach combining transcriptome, translatome and genetic screens$216,133
R21 · FY2018 · AI
Meiosis In Cryptococcal Infection$239,317
R21 · FY2017 · AI · contact PI
MADS-box transcriptional regulation of dimorphic transition in Penicillium marneffei$167,061
R21 · FY2017 · AI
Meiosis in cryptococcal infection$1
R21 · FY2017 · AI · contact PI
The link between dimorphism and virulence in Cryptococcus$294,740
R01 · FY2016 · AI · contact PI
MADS-box transcriptional regulation of dimorphic transition in Penicillium marneffei$216,312
R21 · FY2016 · AI
The link between dimorphism and virulence in Cryptococcus$69,726
R01 · FY2016 · AI · contact PI
The link between dimorphism and virulence in Cryptococcus$362,322
R01 · FY2015 · AI · contact PI
The link between dimorphism and virulence in Cryptococcus$422,322
R01 · FY2014 · AI · contact PI
Investigate the multifunctional adhesins in Cryptococcus$177,793
R21 · FY2014 · AI · contact PI
The link between dimorphism and virulence in Cryptococcus$340,582
R01 · FY2013 · AI · contact PI
Investigate the multifunctional adhesins in Cryptococcus$193,089
R21 · FY2013 · AI · contact PI
The link between dimorphism and virulence in Cryptococcus$357,672
R01 · FY2012 · AI · contact PI
Genetic regulation of invasive hyphal growth of Aspergillus fumigatus$177,303
R21 · FY2011 · AI · contact PI
Genetic regulation of invasive hyphal growth of Aspergillus fumigatus$215,911
R21 · FY2010 · AI · contact PI