Abstract

Hyperpolarization-activated nonselective cation channels (HCNs), also known as pacemaker channels, play a crucial role in producing rhythmic firing in electrically excitable cells such as heart cells and neurons. Their activity is modulated by cyclic AMP, which binds directly to the principal channel subunits to alter the channel gating. This cAMP effect is known to be centrally important in regulation of the heartbeat, regulation of the sleeping versus waking patterns apparent in EEG, and no doubt in many other cellular processes. We are primarily interested in the molecular mechanisms responsible for HCN gating. The HCN's are members of the 6TM voltage-gated channel family, with similarities both to voltage-gated IC (Ky) channels and to cyclic nucleotide gated (CNG) channels. These two channel classes share a common architecture but apparently use different mechanisms for their principal gating. How do HCN's work? Their voltage-dependence is reversed from that of normal Ky gating and there are some mechanistic similarities to both the Ky and CNG gating. Furthermore, a cyclic nucleotide binding domain (like that in CNG's) has important but subtle effects on gating. We will use a sea urchin HCN, with more substantial effects of cAMP, as a route to understanding the mammalian channels. Our first goal is to produce a kinetic description of the HCN currents that will serve as a basis for understanding their role in cellular electrophysiology and pacemaking behavior. We will incorporate the effect of both voltage and cAMP; in doing so, we will also test specific molecular mechanisms. Second, we will investigate the mechanisms of gating, using cysteine mutagenesis, metal binding, and chemical modification to test where the gates are and specifically if the gating induced by cAMP and by voltage arises from two separate mechanisms. This is particularly interesting because we have already found that the pharmacology of the channel is highly dependent on gating. Finally, we will test specific kinetic and physical mechanisms by which cAMP (and the cyclic nucleotide binding domain) alter gating of the channel.

  Funding Agency

Agency
National Institute of Health (NIH)
Institute
National Heart, Lung, and Blood Institute (NHLBI)
Type
Research Project (R01)
Project #
5R01HL070320-04
Application #
6871975
Study Section
Molecular, Cellular and Developmental Neurosciences 2 (MDCN)
Program Officer
Lathrop, David A
Project Start
2002-04-01
Project End
2007-02-14
Budget Start
2005-04-01
Budget End
2007-02-14
Support Year
4
Fiscal Year
2005
Total Cost
$387,000
Indirect Cost

  Institution

Name
Harvard University
Department
Biology
Type
Schools of Medicine
DUNS #
047006379
City
Boston
State
MA
Country
United States
Zip Code
02115

  Publications

Kwan, Daniel C H; Prole, David L; Yellen, Gary (2012) Structural changes during HCN channel gating defined by high affinity metal bridges. J Gen Physiol 140:279-91
Ryu, Sujung; Yellen, Gary (2012) Charge movement in gating-locked HCN channels reveals weak coupling of voltage sensors and gate. J Gen Physiol 140:469-79
Prole, David L; Yellen, Gary (2006) Reversal of HCN channel voltage dependence via bridging of the S4-S5 linker and Post-S6. J Gen Physiol 128:273-82
Proenza, Catherine; Yellen, Gary (2006) Distinct populations of HCN pacemaker channels produce voltage-dependent and voltage-independent currents. J Gen Physiol 127:183-90
Dekker, John P; Yellen, Gary (2006) Cooperative gating between single HCN pacemaker channels. J Gen Physiol 128:561-7
Shin, Ki Soon; Maertens, Chantal; Proenza, Catherine et al. (2004) Inactivation in HCN channels results from reclosure of the activation gate: desensitization to voltage. Neuron 41:737-44
Rothberg, Brad S; Shin, Ki Soon; Yellen, Gary (2003) Movements near the gate of a hyperpolarization-activated cation channel. J Gen Physiol 122:501-10