← Leaderboards
Michael Allen Riehle
University Of Arizona
$5,176,278
Attributed
$7,455,681
Total exposure
7
Grants
5
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 $907.4K · FY2008–25$1M$750K$500K$250K$0
'08
'09
'10
'11
'12
'13
'14
'15
'16
'17
'18
'19
'20
'21
'22
'23
'24
'25
Funding mix
By agency
NIH$7,455,681 · 7
By mechanism
R01$4,398,906 · 2
R56$2,208,839 · 3
R21$847,936 · 2
Top collaborators
- Shirley Luckhart7 shared
- Cecilia Giulivi2 shared
- David W Walker1 shared
Most similar at University Of Arizona
Same institution · by research overlap
- William R. Montfort$14,116,391
- Roger L Miesfeld$4,380,137
- Michael A Wells$4,688,753
- Joy J Winzerling$1,406,851
- A J Gandolfi$9,529,343
Others in their field
Top investigators on “Signal Transduction”
- Peter B. Gilbert · Fred Hutchinson Cancer Center$148,539,615
- David Heimbrook · Leidos Biomedical Research, Inc.$82,049,940
- Margaret Juliana McElrath · Fred Hutchinson Cancer Center$70,290,471
- Garret A Fitzgerald · University Of Pennsylvania$66,142,222
- Michael Barry Kastan · Duke University$64,512,357
- Randall J Bateman · Washington University$62,939,456
Research focus
Signal TransductionReproductionCulicidaeMalariaMidgutAnopheles GenusAffectPlasmodium FalciparumTransgenic OrganismsInfectionLongevityParasitesProductionInvertebratesPten GenePhysiologyTissuesImmunityInsulinPeptidesEngineeringVector MosquitoPlasmodiumPhysiological
Grant awards (17)
How to starve a parasite: Manipulating CoA biosynthesis to control Plasmodium development in the mosquito$616,676
R01 · FY2025 · AI · contact PI
How to starve a parasite: Manipulating CoA biosynthesis to control Plasmodium development in the mosquito$616,676
R01 · FY2024 · AI · contact PI
How to starve a parasite: Manipulating CoA biosynthesis to control Plasmodium development in the mosquito$622,463
R01 · FY2023 · AI · contact PI
Assessing the physiological roles of distinct insulin-like peptides in the mosquito Aedes aegypti$230,250
R21 · FY2020 · AI · contact PI
Assessing the physiological roles of distinct insulin-like peptides in the mosquito Aedes aegypti$191,875
R21 · FY2019 · AI · contact PI
Midgut mitochondrial function as a driver of resistance and fitness in mosquitoes$726,380
R56 · FY2018 · AI · contact PI
Improving Anopheline fitness and resistance through fat body insulin signaling$225,416
R21 · FY2017 · AI · contact PI
Midgut mitochondria as the key to fit, Plasmodium-resistant Anopheline mosquitoes$515,409
R56 · FY2016 · AI
Improving Anopheline fitness and resistance through fat body insulin signaling$200,395
R21 · FY2016 · AI · contact PI
Midgut mitochondria as the key to fit, Plasmodium-resistant Anopheline mosquitoes$191,563
R56 · FY2016 · AI
Harnessing midgut mitochondrial dynamics to enhance Anopheline mosquito fitness$775,487
R56 · FY2014 · AI
Insulin, IGF and Insulin Signaling: effects on Anopheles lifespan and immunity$500,540
R01 · FY2012 · AI · contact PI
Insulin, IGF and Insulin Signaling: effects on Anopheles lifespan and immunity$502,995
R01 · FY2011 · AI · contact PI
Insulin, IGF and Insulin Signaling: effects on Anopheles lifespan and immunity$506,849
R01 · FY2010 · AI · contact PI
Insulin, IGF and Insulin Signaling: effects on Anopheles lifespan and immunity$500,464
R01 · FY2009 · AI · contact PI
Insulin, IGF and Insulin Signaling: effects on Anopheles lifespan and immunity$20,510
R01 · FY2009 · AI · contact PI
Insulin, IGF and Insulin Signaling: effects on Anopheles lifespan and immunity$511,733
R01 · FY2008 · AI · contact PI