👤 Camillo Autore

Sudden arrhythmic death syndrome (SADS) refers to sudden cardiac death with structurally normal hearts at autopsy, most frequently attributed to inherited arrhythmia syndromes or concealed cardiomyopathies. Postmortem genetic testing may help identify underlying genetic causes. We aimed to investigate the yield of postmortem genetic testing in SADS cases by determining the prevalence of pathogenic or likely pathogenic variants in channelopathy- and cardiomyopathy-associated genes in autopsy-negative SADS victims. This systematic review and meta-analysis followed Preferred Reporting Items for Systematic Reviews and Meta-Analyses guidelines and was registered in PROSPERO (REGISTRATION: URL: https://www.crd.york.ac.uk/PROSPERO/; Unique identifier: CRD420251067244). PubMed and Embase were searched on June 4, 2025, for observational studies including individuals aged 1 to 50 years with SADS and negative or nonspecific findings at autopsy. Eligible studies reported postmortem genetic testing for channelopathy and cardiomyopathy genes. Pathogenic or likely pathogenic variant classification followed American College of Medical Genetics and Genomics criteria and ClinGen gene-disease associations. Pooled prevalence was estimated using random-effects models. A total of 45 studies involving 2498 SADS cases were included. Among 1697 SADS victims tested for both channelopathy and cardiomyopathy genes (33 studies), the pooled prevalence of pathogenic or likely pathogenic variants was 11.1% (95% CI, 4.1%-26.6%, Postmortem genetic testing identifies pathogenic or likely pathogenic variants in a significant subset of SADS cases, supporting its utility in postmortem evaluation. Show less

Approximately 95% of lymphoplasmacytic lymphomas (LPL) are IgM secreting and are characterized as Waldenstrom Macroglobulinemia (WM). Conversely, non-IgM secreting LPL are rare. As part of the 12th International Workshop on WM (IWWM-12), a consensus panel of experts was tasked to develop recommendations for the management and response assessment of non-IgM LPL. The panel considered that in view of available molecular, pathological and clinical data, non-IgM LPL should be considered as a separate sub-entity of LPL. The panel further recommended that the IWWM-2 consensus criteria used for IgM LPL (WM) treatment initiation, should also be used for non-IgM LPL and be independent of IgG or IgA paraprotein level unless symptomatic hyperviscosity is present. The panel agreed that based on current evidence, there is insufficient data to support a different clinical management for non-IgM vs IgM (WM) LPL. Moreover, the panel advised that patients with non-IgM LPL should be treated in a similar manner to patients with IgM LPL independent of MYD88 mutation status until more is known about its impact on treatment outcomes for non-IgM LPL patients. The panel therefore recommends the use of the IWWM-11 IgM LPL (WM) response criteria for cases of non-IgM LPL with a monoclonal IgA or IgG paraprotein component, but creating a specific panel to develop formal response criteria for this LPL subset was also recommended. Show less

MYBPC3 pathogenic variants are the most common cause of hypertrophic cardiomyopathy (HCM) and are associated with significant phenotypic heterogeneity. Despite their pathogenic potential, MYBPC3 founder variants persist within specific populations. This study investigates the MYBPC3 c.2309-2 A > G splice variant hypothesizing its founder origin in central Italy. The aim was to confirm the presence of a common haplotype, assess its molecular and clinical impact, and compare the phenotype with that of other MYBPC3 founder variants. Among the 5251 HCM patients recruited at eight Italian referral centers, 1108 probands (21.1%) were identified as carriers of pathogenic or likely pathogenic MYBPC3 variants, and among these, 11.6% carried the c.2309-2 A > G variant. Haplotype reconstruction using short tandem repeats and tag-SNPs revealed a unique 5.2 Mb haplotype segregating with the c.2309-2 A > G variant in all carriers. Age estimation suggested that the variant originated approximately 481 years ago, likely in the Lazio region with clustering in Rome. Clinically, carriers exhibited variable expressivity with age-and sex-dependent penetrance. Males showed earlier onset, higher penetrance and greater disease severity compared to females. RNA analysis showed the retention of both introns 23 and 24, and significantly reduced MYBPC3 expression consistent with haploinsufficiency. Comparative analysis with other MYBPC3 founder variants highlighted differences in phenotypic expression, particularly in left ventricular wall thickness and clinical outcomes. This study establishes c.2309-2 A > G as an Italian MYBPC3 founder mutation, enhancing the understanding of HCM genetics and regional founder effects. These findings emphasize the importance of targeted genetic screening and personalized management for MYBPC3 c.2309-2 A > G carriers. Show less

Hypertrophic cardiomyopathy (HCM) is a genetic cardiac muscle disease characterized by clinical and genetic heterogeneity. Genetic testing can reveal the presence of disease-causing variants in genes encoding sarcomere proteins. However, it yields inconclusive or negative results in 40-60% of HCM cases, owing to, among other causes, technical limitations such as the inability to detect pathogenic intronic variants. Therefore, we aimed to increase the diagnostic yield of molecular analysis for HCM by improving the Show less

Agarose gel-based conventional and real-time allele-specific polymerase chain reaction (AS-PCR) assays are currently used for sensitive detection and quantification of MYD88 L265P mutation. Visual inspection of an agarose gel can often be ambiguous. We propose a new allele-specific quantification PCR (AS-qPCR) assay, PlentiPlex™ MYD88 Waldenström lymphoma qPCR assay, that uses Intercalating Nucleic Acid (INA®) technology for increased affinity and specificity. This study compares PlentiPlex™ MYD88 Waldenström lymphoma qPCR assay with conventional AS-PCR. We included a total of 102 peripheral and bone marrow blood samples from 94 patients with a lymphoproliferative disorder. Droplet digital PCR (ddPCR) was used as a third method in case of discrepancy. A positive percent agreement of 100% (95% CI 0.92-1.0) and a negative percent agreement of 98% (95% CI 0.90-1.0) were found between the conventional AS-PCR and the AS-qPCR methods. Including the ddPCR results to validate the discrepant cases, the sensitivity and specificity of PlentiPlex™ MYD88 Waldenström lymphoma qPCR Assay were 1.0 (95% CI 0.97-1.0) and 1.0 (95% CI 0.96-1.0), respectively. Our data demonstrate that PlentiPlex™ MYD88 Waldenström lymphoma qPCR assay is a fast, highly sensitive, and specific method for the detection of MYD88 L265P compared with conventional AS-PCR. Show less

The role of genetic testing over the clinical and functional variables, including data from the cardiopulmonary exercise test (CPET), in the hypertrophic cardiomyopathy (HCM) risk stratification remains unclear. A retrospective genotype-phenotype correlation was performed to analyze possible differences between patients with and without likely pathogenic/pathogenic (LP/P) variants. A total of 371 HCM patients were screened at least for the main sarcomeric genes Show less

Hypertrophic cardiomyopathy (HCM) is mainly associated with myosin, heavy chain 7 (MYH7) and myosin binding protein C, cardiac (MYBPC3) mutations. In order to better explain the clinical and genetic heterogeneity in HCM patients, in this study, we implemented a target-next generation sequencing (NGS) assay. An Ion AmpliSeq™ Custom Panel for the enrichment of 19 genes, of which 9 of these did not encode thick/intermediate and thin myofilament (TTm) proteins and, among them, 3 responsible of HCM phenocopy, was created. Ninety-two DNA samples were analyzed by the Ion Personal Genome Machine: 73 DNA samples (training set), previously genotyped in some of the genes by Sanger sequencing, were used to optimize the NGS strategy, whereas 19 DNA samples (discovery set) allowed the evaluation of NGS performance. In the training set, we identified 72 out of 73 expected mutations and 15 additional mutations: the molecular diagnosis was achieved in one patient with a previously wild-type status and the pre-excitation syndrome was explained in another. In the discovery set, we identified 20 mutations, 5 of which were in genes encoding non-TTm proteins, increasing the diagnostic yield by approximately 20%: a single mutation in genes encoding non-TTm proteins was identified in 2 out of 3 borderline HCM patients, whereas co-occuring mutations in genes encoding TTm and galactosidase alpha (GLA) altered proteins were characterized in a male with HCM and multiorgan dysfunction. Our combined targeted NGS-Sanger sequencing-based strategy allowed the molecular diagnosis of HCM with greater efficiency than using the conventional (Sanger) sequencing alone. Mutant alleles encoding non-TTm proteins may aid in the complete understanding of the genetic and phenotypic heterogeneity of HCM: co-occuring mutations of genes encoding TTm and non-TTm proteins could explain the wide variability of the HCM phenotype, whereas mutations in genes encoding only the non-TTm proteins are identifiable in patients with a milder HCM status. Show less

Sequencing of sarcomere protein genes in patients fulfilling the clinical diagnostic criteria for hypertrophic cardiomyopathy (HCM) identifies a disease-causing mutation in 35% to 60% of cases. Age at diagnosis and family history may increase the yield of mutations screening. In order to assess whether Next-Generation Sequencing (NGS) may fulfil the molecular diagnostic needs in HCM, we included 17 HCM-related genes in a sequencing panel run on PGM IonTorrent. We selected 70 HCM patients, 35 with early (≤25 years) and 35 with late (≥65 years) diagnosis of disease onset. All samples had a 98.6% average of target regions, with coverage higher than 20× (mean coverage 620×). We identified 41 different mutations (seven of them novel) in nine genes: MYBPC3 (17/41 = 41%); MYH7 (10/41 = 24%); TNNT2, CAV3 and MYH6 (3/41 = 7.5% each); TNNI3 (2/41 = 5%); GLA, MYL2, and MYL3 (1/41=2.5% each). Mutation detection rate was 30/35 (85.7%) in early-onset and 8/35 (22.9%) in late-onset HCM patients, respectively (p < 0.0001). The overall detection rate for patients with positive family history was 84%, and 90.5% in patients with early disease onset. In our study NGS revealed higher mutations yield in patients with early onset and with a family history of HCM. Appropriate patient selection can increase the yield of genetic testing and make diagnostic testing cost-effective. Show less

End-stage hypertrophic cardiomyopathy (ES-HC) has an ominous prognosis. Whether genotype can influence ES-HC occurrence is unresolved. We assessed the spectrum and clinical correlates of HC-associated mutations in a large multicenter cohort with end-stage ES-HC. Sequencing analysis of 8 sarcomere genes (MYH7, MYBPC3, TNNI3, TNNT2, TPM1, MYL2, MYL3, and ACTC1) and 2 metabolic genes (PRKAG2 and LAMP2) was performed in 156 ES-HC patients with left ventricular (LV) ejection fraction (EF) <50%. A comparison among mutated and negative ES-HC patients and a reference cohort of 181 HC patients with preserved LVEF was performed. Overall, 131 mutations (36 novel) were identified in 104 ES-HC patients (67%) predominantly affecting MYH7 and MYBPC3 (80%). Complex genotypes with double or triple mutations were present in 13% compared with 5% of the reference cohort (p = 0.013). The distribution of mutations was otherwise indistinguishable in the 2 groups. Among ES-HC patients, those presenting at first evaluation before the age of 20 had a 30% prevalence of complex genotypes compared with 19% and 21% in the subgroups aged 20 to 59 and ≥60 years (p = 0.003). MYBPC3 mutation carriers with ES-HC were older than patients with MYH7, other single mutations, or multiple mutations (median 41 vs 16, 26, and 28 years, p ≤0.001). Outcome of ES-HC patients was severe irrespective of genotype. In conclusion, the ES phase of HC is associated with a variable genetic substrate, not distinguishable from that of patients with HC and preserved EF, except for a higher frequency of complex genotypes with double or triple mutations of sarcomere genes. Show less

Hypertrophic cardiomyopathy (HCM) is the most common genetic cardiac disease. Fourteen sarcomeric and sarcomere-related genes have been implicated in HCM etiology, those encoding β-myosin heavy chain (MYH7) and cardiac myosin binding protein C (MYBPC3) reported as the most frequently mutated: in fact, these account for around 50% of all cases related to sarcomeric gene mutations, which are collectively responsible for approximately 70% of all HCM cases. Here, we used denaturing high-performance liquid chromatography followed by bidirectional sequencing to screen the coding regions of MYH7 and MYBPC3 in a cohort (n = 125) of Italian patients presenting with HCM. We found 6 MHY7 mutations in 9/125 patients and 18 MYBPC3 mutations in 19/125 patients. Of the three novel MYH7 mutations found, two were missense, and one was a silent mutation; of the eight novel MYBPC3 mutations, one was a substitution, three were stop codons, and four were missense mutations. Thus, our cohort of Italian HCM patients did not harbor the high frequency of mutations usually found in MYH7 and MYBPC3. This finding, coupled to the clinical diversity of our cohort, emphasizes the complexity of HCM and the need for more inclusive investigative approaches in order to fully understand the pathogenesis of this disease. Show less