Distinct roles of HF-1b/Sp4 in ventricular and neural crest cells lineages affect cardiac conduction system development.

The heterogeneous cell types of the cardiac conduction system are responsible for coordinating and maintaining rhythmic contractions of the heart. While it has been shown that the cells of the conduction system are derived from myocytes, additional cell types, including neural crest cells, may play a role in the development and maturation of these specialized cell lineages. Previous work has shown that the expression of the hf-1b gene is required for specification of the cardiac conduction system. Using Cre-Lox technology, we conditionally mutated the hf-1b gene in the ventricular and the neural crest cell lineages. Cx40 immunohistochemistry on HF-1b tissue-restricted knockouts revealed a requirement for HF-1b in the cardiomyogenic lineage. Electrophysiological studies identified a second requirement for HF-1b in the neural crest-derived cells. Absence of HF-1b in the neural crest led to atrial and atrioventricular dysfunction resulting from deficiencies in the neurotrophin receptor trkC. Therefore, in this study, we document that a single transcription factor, HF-1b, acts through two separate cell types to direct distinct functions of the cardiac conduction system.

Small proline-rich protein 1A is a gp130 pathway- and stress-inducible cardioprotective protein.

The interleukin-6 cytokines, acting via gp130 receptor pathways, play a pivotal role in the reduction of cardiac injury induced by mechanical stress or ischemia and in promoting subsequent adaptive remodeling of the heart. We have now identified the small proline-rich repeat proteins (SPRR) 1A and 2A as downstream targets of gp130 signaling that are strongly induced in cardiomyocytes responding to biomechanical/ischemic stress. Upregulation of SPRR1A and 2A was markedly reduced in the gp130 cardiomyocyte-restricted knockout mice. In cardiomyocytes, MEK1/2 inhibitors prevented SPRR1A upregulation by gp130 cytokines. Furthermore, binding of NF-IL6 (C/EBPbeta) and c-Jun to the SPRR1A promoter was observed after CT-1 stimulation. Histological analysis revealed that SPRR1A induction after mechanical stress of pressure overload was restricted to myocytes surrounding piecemeal necrotic lesions. A similar expression pattern was found in postinfarcted rat hearts. Both in vitro and in vivo ectopic overexpression of SPRR1A protected cardiomyocytes against ischemic injury. Thus, this study identifies SPRR1A as a novel stress-inducible downstream mediator of gp130 cytokines in cardiomyocytes and documents its cardioprotective effect against ischemic stress.

Defects in cardiac conduction system lineages and malignant arrhythmias: developmental pathways and disease.

To unravel the complex disease phenotype of heart failure, we are utilizing an integrative approach employing genomics, physiology, and mouse genetics to identify nodal pathways for specific physiological end points such as myocyte stretch activation responses, contractility and electrical conduction. A new class of genetic pathways for cardiac sudden death and associated arrhythmias has been based on transcription factors that control conduction system lineages, including HF1b/SP4 and NKX2.5. Previous studies have established that HF1b plays a critical role in conduction system lineage formation and the loss of HF1b leads to a confused electrophysiological identity in Purkinje and ventricular cell lineages, resulting in cardiac sudden death and marked tachy and brady arrhythmias. Utilizing Hf1b and Nkx2.5 floxed alleles, we now have identified the primary pathways which link these transcription factors with cardiac arrythmogenesis. Mice which harbour a neural crest restricted knockout of HF1b display marked arrhythmogenesis and conduction system defects, implicating neural crest cues in conduction system development and disease. Mice which harbour a ventricular-restricted knockout of Nkx2.5 display completely normal conduction at birth, but a hypoplastic atrioventricular (AV) node. During maturation, progressive complete heart block ensues, associated with a selective dropout of distal AV nodal cell lineages at the boundaries of the penetrating His bundle. Single cell analyses examining individual nodal cells within AV node of ventricular restricted Nkx2.5 knockout mice clearly document a cell autonomous requirement for NKX2.5 within AV nodal lineages per se. Micro-electrophysiological AV nodal mapping indicates a selective conduction defect at the boundary of the distal AV node and His bundle. HF1b and NKX2.5 reflect new cardiac cell non-autonomous and autonomous pathways for conduction system lineage defects and associated cardiac arrythmogenesis.