U.S. Department of Health and Human Services
Gregory Germino

 Contact Info

Tel: 301-496-5877
Email: germinogg@mail.nih.gov

 Select Experience

  • Senior InvestigatorKidney Diseases Branch, NIDDK, NIH2009–Present
  • Adjunct Professor of MedicineJohns Hopkins University School of Medicine2009–Present
  • Professor of Medicine Division of Nephrology, Johns Hopkins University School of Medicine2003–2009
  • Affiliate MemberMcKusick-Nathans Institute of Genetic Medicine, Johns Hopkins University School of Medicine2002–2009
  • Joint AppointmentDepartment of Molecular Biology and Genetics, Johns Hopkins University School of Medicine2001–2009
  • Associate Professor of MedicineDivision of Nephrology, Johns Hopkins University School of Medicine1997–2003
  • Assistant Professor of MedicineDivision of Nephrology, Johns Hopkins University School of Medicine1992–1997
  • Associate Research ScientistInstructor and Assistant Professor, Yale University School of Medicine1988–1992
  • Research Post-Doctoral FellowNuffield Department of Medicine, Oxford University1987–1988
  • Clinical Post-Doctoral FellowNephrology, Yale University School of Medicine1986–1987
  • Internal Medicine ResidencyYale–New Haven Hospital1983–1986
  • M.D.University of Chicago Pritzker School of Medicine1983
  • B.S.Loyola University of Chicago1979

 Related Links


Gregory G. Germino, M.D.

Deputy Director, Office of the Director​
Section Chief, Polycystic Kidney Disease Laboratory, Kidney Diseases Branch

Specialties: Molecular Biology/Biochemistry, Genetics/Genomics, Nephrology​​​​​

Gregory G. Germino, M.D.

Section Chief, Polycystic Kidney Disease LaboratoryKidney Diseases Branch
Deputy Director, Office of the Director
Deputy Director, Office of the Deputy Director
  • Cell Biology/Cell Signaling
  • Genetics/Genomics
  • Molecular Biology/Biochemistry
  • Nephrology
  • Systems Biology
Research Summary/In Plain Language

Research Summary

Research Goal

The ultimate goal is to determine the mechanisms and factors that establish and maintain tubular diameter, to understand the pathobiology of PKD, and to use this information to find a therapy for PKD.​

Current Research

The function of the kidney critically depends on the proper structure of its tubule system, yet regulation of tubular diameter is a poorly understood phenomenon.  Cystic diseases of the kidney offer unique opportunities to study these processes.  My research focuses on the molecular basis of renal cystic disease and renal tubular morphogenesis.

Autosomal dominant polycystic kidney disease (ADPKD) affects approximately 1/1000 Americans.  Cysts arise at all stages of life, and gradually expand to replace normal renal parenchyma.  This process results in end stage kidney failure (ESKF) in approximately half by the 6th decade, accounting for approximately 5 percent of all cases of ESKF.  Autosomal recessive polycystic kidney disease (ARPKD) is rare (1/20,000) but often more severe.  Therapies for both  are limited to managing the complications.  We have, however, made great progress in understanding their pathobiology and the role of the normal PKD gene products in regulating tubular morphology.

Mutations in either of two genes, PKD1 and PKD2, cause all forms of ADPKD.  Mutations appear to compromise gene function, and much data implicate a molecular recessive model as responsible for initiating cyst growth.  PKD1 and PKD2 encode components of a receptor-channel complex that likely has ciliary and non-ciliary functions.  Using orthologous mouse models, we have demonstrated unsuspected, complex development-stage specific consequences of Pkd1 inactivation that are linked to metabolic pathways.  These models also have been used to show that PKD genes are essential for proper form and function of multiple other organs.  We are pursuing several parallel lines of inquiry regarding the relationship between PKD proteins, cellular metabolism, matrix, and planar cell polarity pathways.

ARPKD is a second interest.  We identified the gene mutated in this disorder, PKHD1, and have shown that it likely encodes a very large membrane-associated protein that undergoes Notch-like proteolytic processing.  We have developed a series of mouse lines and cell culture systems to model the disease and study the protein, and we have shown genetic interaction between the PKD1 and PKHD1 loci.  Current efforts are focused on determining its function in kidney and liver development.

Applying our Research

PKD is one of the most common, serious mendelian disorders of man and causes 4-5 percent of all end stage kidney disease in the United States. Affected individuals also suffer from other complications such as hypertension, cyst infections, abdominal pain, and have an increased risk of intracranial aneurysms. Present management is focused on treating symptoms. Understanding the mechanisms of disease will allow us to develop safe and effective treatments.

Need for Further Study

While the PKD gene products polycystin 1 (PC1) and polycystin 2 (PC2) are essential for establishing and maintaining normal tubule structure, we do not know how they do this. Several lines of evidence suggest that they function as a receptor-channel complex, but what they sense and signal is poorly understood. Though numerous pathways have been reported to be dysregulated in cystic epithelia, it is unclear how these link back to the function of the PC1/PC2 complex, which pathways are dysregulated at the earliest stages of cyst formation, and which are altered as secondary consequence of cystic dilations. We also do not understand why cysts form immediately after gene inactivation in young mice but take months to arise in older animals. What factors preserve tubular structure during this interval, and what triggers the subsequent failure? Understanding these processes is important not only from a pathobiological standpoint, but also to design more specific therapies. We also need better tools for assessing the progression of disease so we can better evaluate the effectiveness of clinical interventions.