Proteolytic Processing of HCN2 and Co-assembly with HCN4 in the Generation of Cardiac Pacemaker Channels

Ye, Bin; Nerbonne, Jeanne M.

doi:10.1074/jbc.m109.007583

Cited by 24 publications

(21 citation statements)

References 32 publications

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“…In the presence of PNGaseF, the HCN2 band is completely shifted to ϳ90 kDa, suggesting that cardiac HCN2 channels are fully N-glycosylated in vivo. These molecular masses are consistent with a nonproteolyzed form of HCN2, as has been reported for rat and human ventricles (17,36,46,57,59).…”

Section: Hcn2 Channels Undergo N-glycosylation In Native Cardiacsupporting

confidence: 65%

Evolutionary emergence of N-glycosylation as a variable promoter of HCN channel surface expression

Hegle

Nazzari

Roth

et al. 2010

American Journal of Physiology-Cell Physiology

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Hegle AP, Nazzari H, Roth A, Angoli D, Accili EA. Evolutionary emergence of N-glycosylation as a variable promoter of HCN channel surface expression. Am J Physiol Cell Physiol 298: C1066 -C1076, 2010. First published February 3, 2010 doi:10.1152/ajpcell.00389.2009.-All four mammalian hyperpolarization-activated cyclic nucleotide-modulated (HCN) channel isoforms have been shown to undergo N-linked glycosylation in the brain. With the mouse HCN2 isoform as a prototype, HCN channels have further been suggested to require N-glycosylation for function, a provocative finding that would make them unique in the voltage-gated potassium channel superfamily. Here, we show that both the HCN1 and HCN2 isoforms are also predominantly N-glycosylated in the embryonic heart, where they are found in significant amounts and where HCN-mediated currents are known to regulate beating frequency. Surprisingly, we find that N-glycosylation is not required for HCN2 function, although its cell surface expression is highly dependent on the presence of N-glycans. Comparatively, disruption of N-glycosylation only modestly impacts cell surface expression of HCN1 and leaves permeation and gating functions almost unchanged. This difference between HCN1 and HCN2 is consistent with evolutionary trajectories that diverged in an isoform-specific manner after gene duplication from a common HCN ancestor that lacked N-glycosylation and was able to localize efficiently to the cell surface. ion channels; hyperpolarization-activated cyclic nucleotide-modulated channel-mediated current; N-linked glycosylation; embryonic heart; molecular evolution AN OUTSTANDING QUESTION in hyperpolarization-activated cyclic nucleotide-modulated (HCN) channel biology, and indeed in the biology of most intrinsic proteins of the plasma membrane, is how expression at the cell surface is regulated to affect functional heterogeneity in health and pathological states. The number of HCN channels on the cell surface is a critical determinant of beating frequency in cardiac conduction tissue. HCN isoforms and HCN-mediated currents (I h ) are upregulated in the embryonic and neonatal ventricle (24,45,53,56), in the neonatal sinoatrial node (1), and in beating embryonic stem cells during development in culture (27,36,40,41). However, the factors that determine HCN channel supply at the cell surface during cardiac development have been studied in only a limited fashion.An important determinant of plasma membrane expression of intrinsic membrane proteins is N-linked glycosylation, which promotes proper folding, stability, and oligomeric assembly in the endoplasmic reticulum (ER) and facilitates transport and targeting to the plasma membrane (14, 15). HCN1 and HCN2 are extensively N-glycosylated in mouse brain (31,39,58) and contain only one Asn-X-Ser/Thr consensus sequon for N-glycosylation in the S5 linker, close to the channel pore (Fig.

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Section: Hcn2 Channels Undergo N-glycosylation In Native Cardiacsupporting

confidence: 65%

Evolutionary emergence of N-glycosylation as a variable promoter of HCN channel surface expression

Hegle

Nazzari

Roth

et al. 2010

American Journal of Physiology-Cell Physiology

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“…Insufficiency of Simple Autoinhibition Model Based on V 1/2 Assessment Consequences for HCN channel modulation from truncations of the C-terminal region are likely to have physiological relevance, since C-terminal truncations have been identified in human patients with cardiac sinus node defects (Schulze-Bahr et al 2003;Schweizer et al 2010) and even in myocardial tissues of healthy mice (Ye and Nerbonne 2009). Thus, it is essential to generate a cohesive biophysical theory of how the molecular structure can determine kinetic properties.…”

Section: Discussionmentioning

confidence: 99%

HCN Channel C-Terminal Region Speeds Activation Rates Independently of Autoinhibition

2015

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Hyperpolarization- and cyclic nucleotide-activated (HCN) channels contribute to rhythmic oscillations in excitable cells. They possess an intrinsic autoinhibition with a hyperpolarized V 1/2, which can be relieved by cAMP binding to the cyclic nucleotide binding (CNB) fold in the C-terminal region or by deletion of the CNB fold. We questioned whether V 1/2 shifts caused by altering the autoinhibitory CNB fold would be accompanied by parallel changes in activation rates. We used two-electrode voltage clamp on Xenopus oocytes to compare wildtype (WT) HCN2, a constitutively autoinhibited point mutant incapable of cAMP binding (HCN2 R591E), and derivatives with various C-terminal truncations. Activation V 1/2 and deactivation t 1/2 measurements confirmed that a truncated channel lacking the helix αC of the CNB fold (ΔαC) had autoinhibition comparable to HCN2 R591E; however, ΔαC activated approximately two-fold slower than HCN2 R591E over a 60-mV range of hyperpolarizations. A channel with a more drastic truncation deleting the entire CNB fold (ΔCNB) had similar V 1/2 values to HCN2 WT with endogenous cAMP bound, confirming autoinhibition relief, yet it surprisingly activated slower than the autoinhibited HCN2 R591E. Whereas CNB fold truncation slowed down voltage-dependent reaction steps, the voltage-independent closed-open equilibrium subject to autoinhibition in HCN2 was not rate-limiting. Chemically inhibiting formation of the endogenous lipid PIP2 hyperpolarized the V 1/2 of HCN2 WT but did not slow down activation to match ΔCNB rates. Our findings suggest a "quickening conformation" mechanism, requiring a full-length CNB that ensures fast rates for voltage-dependent steps during activation regardless of potentiation by cAMP or PIP2.

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“…3) (22,28,41,45,67,69,71,80,84). Comparison of transcripts from all four hyperpolarization-activated cation channels showed that expression of HCN1 and HCN4 were highest, although there were significant levels of HCN2 and HCN3 (Fig.…”

Section: Resultsmentioning

confidence: 99%

Expression and distribution of voltage-gated ion channels in ferret sinoatrial node

Brahmajothi

Morales

Campbell

et al. 2010

Physiological Genomics

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Brahmajothi MV, Morales MJ, Campbell DL, Steenbergen C, Strauss HC. Expression and distribution of voltage-gated ion channels in ferret sinoatrial node. Physiol Genomics 42A: 131-140, 2010. First published August 3, 2010 doi:10.1152/physiolgenomics.00049.2010.-Spontaneous diastolic depolarization in the sinoatrial (SA) node enables it to serve as pacemaker of the heart. The variable cell morphology within the SA node predicts that ion channel expression would be heterogeneous and different from that in the atrium. To evaluate ion channel heterogeneity within the SA node, we used fluorescent in situ hybridization to examine ion channel expression in the ferret SA node region and atrial appendage. SA nodal cells were distinguished from surrounding cardiac myocytes by expression of the slow (SA node) and cardiac (surrounding tissue) forms of troponin I. Nerve cells in the sections were identified by detection of GAP-43 and cytoskeletal middle neurofilament. Transcript expression was characterized for the 4 hyperpolarization-activated cation channels, 6 voltage-gated Na ϩ channels, 3 voltage-gated Ca 2ϩ channels, 24 voltagegated K ϩ channel ␣-subunits, and 3 ancillary subunits. To ensure that transcript expression was representative of protein expression, immunofluorescence was used to verify localization patterns of voltagedependent K ϩ channels. Colocalizations were performed to observe any preferential patterns. Some overlapping and nonoverlapping binding patterns were observed. Measurement of different cation channel transcripts showed heterogeneous expression with many different patterns of expression, attesting to the complexity of electrical activity in the SA node. This study provides insight into the possible role ion channel heterogeneity plays in SA node pacemaker activity. gene expression; sodium channels; potassium channels; voltage-gated calcium channels; L-type calcium channels; T-type calcium channels; cyclic nucleotide gated cation channels PRIMARY PACEMAKER CELLS in the central region of the sinoatrial (SA) node undergo spontaneous diastolic depolarization, which ultimately triggers the action potential (AP) upstroke. The excitatory AP wave front subsequently spreads through adjacent areas of the perinodal region to the crista terminalis and atrium. Repolarization of the pacemaker cells allows the cycle to repeat. This inherent cyclic behavior enables the SA node to serve as the normal pacemaker of the heart (7,12,14,26,57).In the central nodal and adjacent perinodal cells, the ionic basis of spontaneous diastolic depolarization and different phases of the AP have been attributed to many currents (7,8,14,27,36,37,42,47,61,68,77). Studies conducted on different mammalian species identified a hyperpolarizationactivated nonselective cation current (I f ), two calcium currents [I Ca,L (L-type) and I Ca,T (T-type)], a sodium current (I Na ), and at least four voltage-dependent potassium currents [ultrarapid (I Kur ), rapid (I Kr ), and slow (I Ks ) delayed rectifier currents and transient outward curre...

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Proteolytic Processing of HCN2 and Co-assembly with HCN4 in the Generation of Cardiac Pacemaker Channels

Cited by 24 publications

References 32 publications

Evolutionary emergence of N-glycosylation as a variable promoter of HCN channel surface expression

Evolutionary emergence of N-glycosylation as a variable promoter of HCN channel surface expression

HCN Channel C-Terminal Region Speeds Activation Rates Independently of Autoinhibition

Expression and distribution of voltage-gated ion channels in ferret sinoatrial node

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