about
Loss-of-function DNA sequence variant in the CLCNKA chloride channel implicates the cardio-renal axis in interindividual heart failure risk variationG protein-coupled receptor kinase 2 ablation in cardiac myocytes before or after myocardial infarction prevents heart failure.Deep mRNA sequencing for in vivo functional analysis of cardiac transcriptional regulators: application to Galphaq.Cardiac signaling genes exhibit unexpected sequence diversity in sporadic cardiomyopathy, revealing HSPB7 polymorphisms associated with diseaseMicroRNA-133a protects against myocardial fibrosis and modulates electrical repolarization without affecting hypertrophy in pressure-overloaded adult heartsEpigenetic coordination of embryonic heart transcription by dynamically regulated long noncoding RNAsCommon variants in HSPB7 and FRMD4B associated with advanced heart failureMitochondrial genome linearization is a causative factor for cardiomyopathy in mice and Drosophila.A novel strategy to increase the proliferative potential of adult human β-cells while maintaining their differentiated phenotype.Mitochondrial reprogramming induced by CaMKIIδ mediates hypertrophy decompensationCytosolic accumulation of small nucleolar RNAs (snoRNAs) is dynamically regulated by NADPH oxidaseDeep sequencing of cardiac microRNA-mRNA interactomes in clinical and experimental cardiomyopathy.A human 3' miR-499 mutation alters cardiac mRNA targeting and function.Interdependence of Parkin-Mediated Mitophagy and Mitochondrial Fission in Adult Mouse Hearts.Postnatal β-cell maturation is associated with islet-specific microRNA changes induced by nutrient shifts at weaning.Chronic Contractile Dysfunction without Hypertrophy Does Not Provoke a Compensatory Transcriptional Response in Mouse Hearts.Changes of Ovarian microRNA Profile in Long-Living Ames Dwarf Mice during AgingCardiac Disease Status Dictates Functional mRNA Targeting Profiles of Individual MicroRNAs.Epitranscriptional orchestration of genetic reprogramming is an emergent property of stress-regulated cardiac microRNAs.Parkin-mediated mitophagy directs perinatal cardiac metabolic maturation in miceA nucleus-targeted alternately spliced Nix/Bnip3L protein isoform modifies nuclear factor κB (NFκB)-mediated cardiac transcription.Common miR-590 Variant rs6971711 Present Only in African Americans Reduces miR-590 BiogenesisEndoplasmic reticulum-mitochondria crosstalk in NIX-mediated murine cell deathEpitranscriptional regulation of cardiovascular development and disease.Cardiac miR-133a overexpression prevents early cardiac fibrosis in diabetesTranscriptome analysis in heart failure.Widespread Down-Regulation of Cardiac Mitochondrial and Sarcomeric Genes in Patients With Sepsis.RISC RNA sequencing for context-specific identification of in vivo microRNA targets.RhoA protects the mouse heart against ischemia/reperfusion injuryMicroRNA-155 tunes both the threshold and extent of NK cell activation via targeting of multiple signaling pathways.MARF and Opa1 control mitochondrial and cardiac function in Drosophila.Menage a Trois: intimate relationship among a microRNA, long noncoding RNA, and mRNA.Ovarian transcriptome associated with reproductive senescence in the long-living Ames dwarf mice.TNF receptor-activated factor 2 mediates cardiac protection through noncanonical NF-κB signaling.A balancing act in cardiac hypertrophy.Modulation of subsets of cardiac B lymphocytes improves cardiac function after acute injuryImmunomodulatory role of non-neuronal cholinergic signaling in myocardial injury
P50
Q24625036-F0375861-774B-41CF-A0FC-F91825B1312FQ30487539-23A48537-6A76-4258-96B8-1667F53D7ACFQ33548600-A2A48834-333E-4984-A7E0-0DB3C315E466Q33559617-8321D523-27B6-4209-9B03-011CFAE0C50AQ33580704-A6BD72EB-038F-49AD-89A5-B616813C6D72Q34082965-3E30EA25-FC89-4B71-8499-94CD1E21BF35Q34096292-2763D020-1DDF-47C4-9103-C6357EF97A66Q34399661-1D222050-2ABC-4982-BC99-DD74E6855E7BQ34776341-3D255AE6-A050-4424-9187-958D2AF5ABFBQ35132584-318C79AE-3C1F-4600-B1F5-8ED02C66C442Q35561116-2BBE0E48-1958-443B-962A-D00A7769AF19Q35593966-067F9D73-F0D4-4B38-AAA4-C3742B8DD489Q35873898-BB53A8F9-4E64-4ECD-B90D-702C42A9B2FFQ35908527-9042D840-E2F1-4A8B-9D55-62E594257520Q36059303-62309130-210C-41E1-8B13-E90CBE0F05D6Q36064578-8D6E3EF2-B540-4680-A066-BA4CBDC3C8ABQ36238604-60195AB8-299B-4566-80F5-6324CB6FA87BQ36378208-873D16A8-BA4B-4AD1-AB98-83DFBC9EDBAEQ36438608-A057BC51-8A8A-4973-8199-012D90BAC877Q36561435-FE2F37F4-9D00-45FB-A844-BC011EEF93ABQ36890525-CDC50D8C-0A48-43FB-A5E8-B49E0BD3437AQ36917391-708D16E1-9135-4CF3-8587-070C4722BB98Q37036070-31268493-DFE1-4B85-B14B-4C744CA189B5Q38272573-40B86AB5-089C-4B95-AE63-085061386BA8Q38281695-C6E68B68-E028-4D19-9505-75A97F9DC85AQ38800655-DE8773F5-998F-4C51-913F-44A82BA50FABQ40379824-3DA5EF35-05B0-47C8-869D-A730A80B12C3Q41835167-A90D832C-C282-464E-859B-94C2541F80FFQ42014677-3C730569-188C-4EF8-9D12-0A39B1788996Q42028128-8A8EE9D9-9F23-4BE5-8CA1-B68D935E7F8FQ42136255-7AEA586D-09E8-4A3C-AC89-B91F395C9855Q42873479-DDFCF9A9-7260-420C-AF6C-D871EEB082ADQ48541084-B27FC9B2-FA59-4B2A-B305-ED18B6F5D8FBQ50130549-49A0F59B-0459-4250-B2F6-B2CAB0D82CE5Q53913069-B4B99370-A3E3-4833-AC82-83A10A947934Q89014006-0E47822D-FF03-451B-9F21-01A805794D51Q92511086-16F8DEB3-5A61-46CA-98B2-E1340D585ED3
P50
description
hulumtues
@sq
onderzoeker
@nl
researcher
@en
հետազոտող
@hy
name
Scot J Matkovich
@ast
Scot J Matkovich
@en
Scot J Matkovich
@es
Scot J Matkovich
@sl
type
label
Scot J Matkovich
@ast
Scot J Matkovich
@en
Scot J Matkovich
@es
Scot J Matkovich
@sl
prefLabel
Scot J Matkovich
@ast
Scot J Matkovich
@en
Scot J Matkovich
@es
Scot J Matkovich
@sl
P1053
B-9077-2009
P106
P21
P31
P3829
P496
0000-0002-7398-6857