Browsing by Author "Field, Loren J."

Now showing 1 - 10 of 24
  • Thumbnail Image
    Item
    2017 Riley Heart Center Symposium on Cardiac Development: Development and Repair of the Ventricular Wall
    (Springer Nature, 2018-08) Field, Loren J.; Shou, Weinian; Markham, Larry; Pediatrics, School of Medicine
  • Thumbnail Image
    Item
    Absence of cardiomyocyte differentiation following transplantation of adult cardiac-resident Sca-1+ cells into infarcted mouse hearts
    (American Heart Association, 2018-12-18) Soonpaa, Mark H.; Lafontant, Pascal J.; Reuter, Sean; Scherschel, John A.; Srour, Edward F.; Zaruba, Marc-Michael; Rubart-von der Lohe, Michael; Field, Loren J.; Medicine, School of Medicine
    Although several lines of evidence suggest that the glycosyl phosphatidylinositol-anchored cell surface protein Sca-1 marks cardiac-resident stem cells, a critical analysis of the literature raises some concerns regarding their cardiomyogenic potential.1 Here, isolated adult cardiac-resident Sca-1+ cells were engrafted into infarcted hearts and monitored for cardiomyogenic differentiation. Donor cells were prepared from ACT-EGFP; MHC-nLAC double-transgenic mice ([C57/Bl6J x DBA/2J]F1 genetic background; all procedures followed were in accordance with Institutional Guidelines). The ACT-EGFP transgene targets ubiquitous expression of an enhanced green fluorescent protein reporter, and the MHC-nLAC transgene targets cardiomyocyte-restricted expression of a nuclear-localized β-galactosidase reporter. Donor cell survival was monitored via EGFP fluorescence, while cardiomyogenic differentiation was monitored by reacting with the chromogenic β-galactosidase substrate 5-bromo-4-chloro-3-indolyl-β-D-galactoside (X-GAL), which gives rise to a blue product.2 Double-transgenic hearts were dispersed with Blendzyme and the resulting cells reacted with an APC-conjugated anti-Sca-1 antibody and a PE-conjugated cocktail of antibodies recognizing hematopoietic lineage markers.3 Sca-1+, EGFP+, lineage- cells were then isolated via fluorescence-activated cell sorting (FACS; characterization of the donor cells is provided in Figure 1A), and 100,000 cells were injected into the infarct border zone of non-transgenic [C57/Bl6J x DBA/2J]F1 mice immediately following permanent coronary artery occlusion.
  • Thumbnail Image
    Item
    Adult Bone Marrow–derived Cells Do Not Acquire Functional Attributes of Cardiomyocytes When Transplanted into Peri-infarct Myocardium
    (Elsevier, 2008-06-01) Scherschel, John A.; Soonpaa, Mark H.; Srour, Edward F.; Field, Loren J.; Rubart, Michael; Microbiology and Immunology, School of Medicine
    (BM) cells after being directly transplanted into the ischemically injured heart remains a controversial issue. In this study, we investigated the ability of transplanted BM cells to develop intracellular calcium ([Ca2+] i ) transients in response to membrane depolarization in situ. Low-density mononuclear (LDM) BM cells, c-kit-enriched (c-kitenr) BM cells, and highly enriched lin– c-kit+ BM cells were obtained from adult transgenic mice ubiquitously expressing enhanced green fluorescent protein (EGFP), and injected into peri-infarct myocardiums of nontransgenic mice. After 9–10 days the mice were killed, and the hearts were removed, perfused in Langendorff mode, loaded with the calcium-sensitive fluorophore rhod-2, and subjected to two-photon laser scanning fluorescence microscopy (TPLSM) to monitor action potential–induced [Ca2+] i transients in EGFP-expressing donor-derived cells and non-expressing host cardiomyocytes. Whereas spontaneous and electrically evoked [Ca2+] i transients were found to occur synchronously in host cardiomyocytes along the graft–host border and in areas remote from the infarct, they were absent in all of the >3,000 imaged BM-derived cells that were located in clusters throughout the infarct scar or peri-infarct zone. We conclude that engrafted BM-derived cells lack attributes of functioning cardiomyocytes, calling into question the concept that adult BM cells can give rise to substantive cardiomyocyte regeneration within the infarcted heart.
  • Thumbnail Image
    Item
    Cardiac engraftment of genetically-selected parthenogenetic stem cell-derived cardiomyocytes
    (Public Library of Science, 2015) Yang, Tao; Rubart, Michael; Soonpaa, Mark H.; Didié, Michael; Christalla, Peter; Zimmermann, Wolfram-Hubertus; Field, Loren J.; Department of Pediatrics, IU School of Medicine
    Parthenogenetic stem cells (PSCs) are a promising candidate donor for cell therapy applications. Similar to embryonic stem cells (ESCs) and induced pluripotent stem cells (iPSCs), PSCs exhibit self-renewing capacity and clonogenic proliferation in vitro. PSCs exhibit largely haploidentical genotype, and as such may constitute an attractive population for allogenic applications. In this study, PSCs isolated from transgenic mice carrying a cardiomyocyte-restricted reporter transgene to permit tracking of donor cells were genetically modified to carry a cardiomyocyte-restricted aminoglycoside phosphotransferase expression cassette (MHC-neor/pGK-hygror) to permit the generation of highly enriched cardiomyocyte cultures from spontaneously differentiating PSCs by simple selection with the neomycin analogue G148. Following engraftment into isogenic recipient hearts, the selected cardiomyocytes formed a functional syncytium with the host myocardium as evidenced by the presence of entrained intracellular calcium transients. These cells thus constitute a potential source of therapeutic donor cells.
  • Thumbnail Image
    Item
    Cardiac Troponin I-interacting Kinase impacts cardiomyocyte S-phase activity but not cardiomyocyte proliferation
    (American Heart Association, 2023) Reuter, Sean P.; Soonpaa, Mark H.; Field, Dorothy; Simpson, Ed; Rubart-von der Lohe, Michael; Lee, Han Kyu; Sridhar, Arthi; Ware, Stephanie M.; Green, Nick; Li, Xiaochun; Ofner, Susan; Marchuk, Douglas A.; Wollert, Kai C.; Field, Loren J.; Pediatrics, School of Medicine
    Background: Identifying genetic variants that affect the level of cell cycle reentry and establishing the degree of cell cycle progression in those variants could help guide development of therapeutic interventions aimed at effecting cardiac regeneration. We observed that C57Bl6/NCR (B6N) mice have a marked increase in cardiomyocyte S-phase activity after permanent coronary artery ligation compared with infarcted DBA/2J (D2J) mice. Methods: Cardiomyocyte cell cycle activity after infarction was monitored in D2J, (D2J×B6N)-F1, and (D2J×B6N)-F1×D2J backcross mice by means of bromodeoxyuridine or 5-ethynyl-2'-deoxyuridine incorporation using a nuclear-localized transgenic reporter to identify cardiomyocyte nuclei. Genome-wide quantitative trait locus analysis, fine scale genetic mapping, whole exome sequencing, and RNA sequencing analyses of the backcross mice were performed to identify the gene responsible for the elevated cardiomyocyte S-phase phenotype. Results: (D2J×B6N)-F1 mice exhibited a 14-fold increase in cardiomyocyte S-phase activity in ventricular regions remote from infarct scar compared with D2J mice (0.798±0.09% versus 0.056±0.004%; P<0.001). Quantitative trait locus analysis of (D2J×B6N)-F1×D2J backcross mice revealed that the gene responsible for differential S-phase activity was located on the distal arm of chromosome 3 (logarithm of the odds score=6.38; P<0.001). Additional genetic and molecular analyses identified 3 potential candidates. Of these, Tnni3k (troponin I-interacting kinase) is expressed in B6N hearts but not in D2J hearts. Transgenic expression of TNNI3K in a D2J genetic background results in elevated cardiomyocyte S-phase activity after injury. Cardiomyocyte S-phase activity in both Tnni3k-expressing and Tnni3k-nonexpressing mice results in the formation of polyploid nuclei. Conclusions: These data indicate that Tnni3k expression increases the level of cardiomyocyte S-phase activity after injury.
  • Thumbnail Image
    Item
    Cardioprotection vs. regeneration: the case of extracellular vesicle-derived microRNAs
    (Springer, 2021-03-19) Wollert, Kai C.; Field, Loren J.; Pediatrics, School of Medicine
  • Thumbnail Image
    Item
    Cell Cycle–Mediated Cardiac Regeneration in the Mouse Heart
    (Springer, 2019) Eghbali, Arash; Dukes, Austin; Toischer, Karl; Hasenfuss, Gerd; Field, Loren J.; Medicine, School of Medicine
    Purpose of Review Many forms of heart disease result in the essentially irreversible loss of cardiomyocytes. The ability to promote cardiomyocyte renewal may be a promising approach to reverse injury in diseased hearts. The purpose of this review is to describe the impact of cardiomyocyte cell cycle activation on cardiac function and structure in several different models of myocardial disease. Recent Findings Transgenic mice expressing cyclin D2 (D2 mice) exhibit sustained cardiomyocyte renewal in the adult heart. Earlier studies demonstrated that D2 mice exhibited progressive myocardial regeneration in experimental models of myocardial infarction, and that cardiac function was normalized to values seen in sham-operated litter mates by 180 days post-injury. D2 mice also exhibited markedly improved atrial structure in a genetic model of atrial fibrosis. More recent studies revealed that D2 mice were remarkably resistant to heart failure induced by chronic elevated afterload as compared with their wild type (WT siblings), with a 6-fold increase in median survival as well as retention of relatively normal cardiac function. Finally, D2 mice exhibited a progressive recovery in cardiac function to normal levels and a concomitant reduction in adverse myocardial remodeling in an anthracycline cardiotoxicity model. Summary The studies reviewed here make a strong case for the potential utility of inducing cardiomyocyte renewal as a means to treat injured hearts. Several challenges which must be met to develop a viable therapeutic intervention based on these observations are discussed.
  • Thumbnail Image
    Item
    Cell-Cycle-Based Strategies to Drive Myocardial Repair
    (Springer, 2009-04-02) Zhu, Wuqiang; Hassink, Rutger J.; Rubart, Michael; Field, Loren J.; Pediatrics, School of Medicine
    Cardiomyocytes exhibit robust proliferative activity during development. After birth, cardiomyocyte proliferation is markedly reduced. Consequently, regenerative growth in the postnatal heart via cardiomyocyte proliferation (and, by inference, proliferation of stem-cell-derived cardiomyocytes) is limited and often insufficient to affect repair following injury. Here, we review studies wherein cardiomyocyte cell cycle proliferation was induced via targeted expression of cyclin D2 in postnatal hearts. Cyclin D2 expression resulted in a greater than 500-fold increase in cell cycle activity in transgenic mice as compared to their nontransgenic siblings. Induced cell cycle activity resulted in infarct regression and concomitant improvement in cardiac hemodynamics following coronary artery occlusion. These studies support the notion that cell-cycle-based strategies can be exploited to drive myocardial repair following injury.
  • Thumbnail Image
    Item
    Complex Arrhythmia Syndrome in a Knock-In Mouse Model Carrier of the N98S Calm1 Mutation
    (American Heart Association, 2020) Tsai, Wen-Chin; Guo, Shuai; Olaopa, Michael A.; Field, Loren J.; Yang, Jin; Shen, Changyu; Chang, Ching-Pin; Chen, Peng-Sheng; Rubart, Michael; Medicine, School of Medicine
    Background: Calmodulin mutations are associated with arrhythmia syndromes in humans. Exome sequencing previously identified a de novo mutation in CALM1 resulting in a p.N98S substitution in a patient with sinus bradycardia and stress-induced bidirectional ventricular ectopy. The objectives of the present study were to determine if mice carrying the N98S mutation knocked into Calm1 replicate the human arrhythmia phenotype and to examine arrhythmia mechanisms. Methods: Mouse lines heterozygous for the Calm1N98S allele (Calm1N98S/+) were generated using CRISPR/Cas9 technology. Adult mutant mice and their wildtype littermates (Calm1+/+) underwent electrocardiographic monitoring. Ventricular de- and repolarization was assessed in isolated hearts using optical voltage mapping. Action potentials and whole-cell currents and [Ca2+]i, as well, were measured in single ventricular myocytes using the patch-clamp technique and fluorescence microscopy, respectively. The microelectrode technique was used for in situ membrane voltage monitoring of ventricular conduction fibers. Results: Two biologically independent knock-in mouse lines heterozygous for the Calm1N98S allele were generated. Calm1N98S/+ mice of either sex and line exhibited sinus bradycardia, QTc interval prolongation, and catecholaminergic bidirectional ventricular tachycardia. Male mutant mice also showed QRS widening. Pharmacological blockade and activation of β-adrenergic receptors rescued and exacerbated, respectively, the long-QT phenotype of Calm1N98S/+ mice. Optical and electric assessment of membrane potential in isolated hearts and single left ventricular myocytes, respectively, revealed β-adrenergically induced delay of repolarization. β-Adrenergic stimulation increased peak density, slowed inactivation, and left-shifted the activation curve of ICa.L significantly more in Calm1N98S/+ versus Calm1+/+ ventricular myocytes, increasing late ICa.L in the former. Rapidly paced Calm1N98S/+ ventricular myocytes showed increased propensity to delayed afterdepolarization-induced triggered activity, whereas in situ His-Purkinje fibers exhibited increased susceptibility for pause-dependent early afterdepolarizations. Epicardial mapping of Calm1N98S/+ hearts showed that both reentry and focal mechanisms contribute to arrhythmogenesis. Conclusions: Heterozygosity for the Calm1N98S mutation is causative of an arrhythmia syndrome characterized by sinus bradycardia, QRS widening, adrenergically mediated QTc interval prolongation, and bidirectional ventricular tachycardia. β-Adrenergically induced ICa.L dysregulation contributes to the long-QT phenotype. Pause-dependent early afterdepolarizations and tachycardia-induced delayed afterdepolarizations originating in the His-Purkinje network and ventricular myocytes, respectively, constitute potential sources of arrhythmia in Calm1N98S/+ hearts.
  • Thumbnail Image
    Item
    Dishevelled-associated activator of morphogenesis 1 (Daam1) is required for heart morphogenesis
    (2011-01) Li, Deqiang; Hallett, Mark A.; Zhu, Wuqiang; Rubart, Michael; Liu, Ying; Yang, Zhenyun; Chen, Hanying; Haneline, Laura S.; Chan, Rebecca J.; Schwartz, Robert J.; Field, Loren J.; Atkinson, Simon J.; Shou, Weinian
    Dishevelled-associated activator of morphogenesis 1 (Daam1), a member of the formin protein family, plays an important role in regulating the actin cytoskeleton via mediation of linear actin assembly. Previous functional studies of Daam1 in lower species suggest its essential role in Drosophila trachea formation and Xenopus gastrulation. However, its in vivo physiological function in mammalian systems is largely unknown. We have generated Daam1-deficient mice via gene-trap technology and found that Daam1 is highly expressed in developing murine organs, including the heart. Daam1-deficient mice exhibit embryonic and neonatal lethality and suffer multiple cardiac defects, including ventricular noncompaction, double outlet right ventricles and ventricular septal defects. In vivo genetic rescue experiments further confirm that the lethality of Daam1-deficient mice results from the inherent cardiac abnormalities. In-depth analyses have revealed that Daam1 is important for regulating filamentous actin assembly and organization, and consequently for cytoskeletal function in cardiomyocytes, which contributes to proper heart morphogenesis. Daam1 is also found to be important for proper cytoskeletal architecture and functionalities in embryonic fibroblasts. Biochemical analyses indicate that Daam1 does not regulate cytoskeletal organization through RhoA, Rac1 or Cdc42. Our study highlights a crucial role for Daam1 in regulating the actin cytoskeleton and tissue morphogenesis.