PROJECT SUMMARY. Protein kinases represent one of the largest gene families and regulate much of
biology. Kinase dysfunction is also associated with a plethora of diseases. Although the protein kinase gene
families have been mapped onto the kinome, the details of specificity and regulation are buried within each
family. These families include not only isoforms but also splice variants for many genes. Splice variants are not
represented the kinome, but enormously expand the complexity of signaling networks and specificity. Knockout
experiments tell us repeatedly that the isoforms and splice variants are functionally non-redundant, highlighting
that the assembly of highly specific complexes within cells and tissues is an essential feature of kinase
signaling. Increasingly we are also coming to appreciate the importance of these isoforms and splice variants
from disease phenotypes, which further highlights that biology is controlled by finely tuned regulatory networks.
cAMP-dependent protein kinase (PKA), expressed in every mammalian cell, regulates fundamental
biological processes that include metabolism, development/differentiation, memory, and immune
responsiveness. While the PKA Ca1 subunit has served in so many ways as the prototypical protein kinase,
surprisingly almost nothing is known about the Cß isoforms, which include multiple splice variants. While Ca1
is ubiquitous in all human cells, expression of the Cß isoforms is more tissue-specific, and disease phenotypes
suggest that they also are likely to be functionally non-redundant. Our goal here is to characterize three of the
Cß splice variants that differ only in their first exon. These Cß isoforms correlate with several diseases. Cß1
leads to cortisol producing adenomas in Cushing’s Disease, ablation of Cß2 in immune cells leads to immuno-
suppression, and increased Cß2 correlates with survival in prostate cancer patients and can cause Carney
Complex Disease (CNC) and thyroid tumors. This emphasizes the importance of Cß signaling and suggests
that our work will have important and previously unappreciated biological and disease relevance. Our
innovation lies in the fact that we can easily cross so many scales that extend from basic biochemistry and
atomic resolution of the molecules to their isoform-specific distribution in cells and tissues. We will use this
multi-scale approach to characterize the structure, function and regulation of three Cß isoforms. In parallel we
will map the tissue-specific localization of these isoforms in kidney, spleen, thymus and brain using isoform-
specific antibodies. Finally we will use a proteomic strategy to identify isoform-specific binding partners. Our
broad knowledge of PKA signaling, coupled with our deep understanding of the four functionally non-redundant
PKA holoenzymes, provides us with a unique opportunity to explore a wide swath of previously untapped
cAMP signaling space. Given the global importance of PKA signaling in all cells, the probability that the Cß
isoforms will have important physiological as well as disease relevance is high. Our studies will allow us to
move forward creatively with developing novel isoform-specific therapies.