Hereditary predisposition to malignant myeloid hemopathies: Caution in use of saliva and guideline based on our experience.

Background: Predisposition to myeloid malignancies is a field at the border of hematology and genetics. Knowledge in this domain has so rapidly increased that WHO defined in 2016 the new "Myeloid Neoplasms with Germline Predisposition" category of tumors. High throughput sequencing is frequently performed in tumors either for diagnosis or prognosis, but this approach may identify potential germline variants that have to be confirmed on non-infiltrated tissues. Method: In this study, we systematically compared NGS data from genetic analysis performed on all sample types (bone marrow, blood, saliva, skin fibroblasts and hair follicles) in 29 patients, and 44 of their relatives (blood and saliva). Results: We showed that saliva was usable for relatives, but only for 24% (7/29) of our patients. Most of patients' saliva were either "non-contributive" (14/29 i.e., 48% because clearly or probably infiltrated) or "inconclusive" (8/29 corresponding to 28%). Conclusion: The recommendations for the use of saliva we present here focus on the importance of collecting saliva during remission when possible. Moreover, we propose hair follicles as an alternative to skin biopsy, that remains the gold standard especially in case of allogenic hematopoietic stem cells transplantation. Technological progresses have revolutionized the diagnosis of predisposition to solid or hematological malignancies, and it is very likely that new techniques will help to manage the familial predisposition in the future.

Clinical management of molecular alterations identified by high throughput sequencing in patients with advanced solid tumors in treatment failure: Real-world data from a French hospital.

Background: In the context of personalized medicine, screening patients to identify targetable molecular alterations is essential for therapeutic decisions such as inclusion in clinical trials, early access to therapies, or compassionate treatment. The objective of this study was to determine the real-world impact of routine incorporation of FoundationOne analysis in cancers with a poor prognosis and limited treatment options, or in those progressing after at least one course of standard therapy. Methods: A FoundationOneCDx panel for solid tumor or liquid biopsy samples was offered to 204 eligible patients. Results: Samples from 150 patients were processed for genomic testing, with a data acquisition success rate of 93%. The analysis identified 2419 gene alterations, with a median of 11 alterations per tumor (range, 0-86). The most common or likely pathogenic variants were on TP53, TERT, PI3KCA, CDKN2A/B, KRAS, CCDN1, FGF19, FGF3, and SMAD4. The median tumor mutation burden was three mutations/Mb (range, 0-117) in 143 patients with available data. Of 150 patients with known or likely pathogenic actionable alterations, 13 (8.6%) received matched targeted therapy. Sixty-nine patients underwent Molecular Tumor Board, which resulted in recommendations in 60 cases. Treatment with genotype-directed therapy had no impact on overall survival (13 months vs. 14 months; p = 0.95; hazard ratio = 1.04 (95% confidence interval, 0.48-2.26)]. Conclusions: This study highlights that an organized center with a Multidisciplinary Molecular Tumor Board and an NGS screening system can obtain satisfactory results comparable with those of large centers for including patients in clinical trials.

GM2 gangliosidosis AB variant: first case of late onset and review of the literature.

AB variant is the rarest form of GM2 gangliosidosis, neurodegenerative diseases caused by lysosomal accumulation of GM2 gangliosides. Less than thirty cases are referenced in the literature, and to date, no late-onset form has been described. Our proband is a 22-year-old male with spinocerebellar ataxia and lower limbs motor deficiency. His symptoms started at the age of 10. A genetic analysis revealed two mutations in the GM2A gene encoding the GM2 activator protein (GM2-AP), an essential co-factor of hexosaminidase A. Both mutations, GM2A:c.79A > T:p.Lys27* and GM2A:c.415C > T:p.Pro139Ser, were inherited respectively from his father and his mother. The nonsense mutation was predicted to be likely pathogenic, but the missense mutation was of unknown significance. To establish the pathogenicity of this variant, we studied GM2 accumulation and GM2A gene expression. Electron microscopy and immunofluorescence performed on patient's fibroblasts did not reveal any lysosomal accumulation of GM2. There was also no difference in GM2A gene expression using RT-qPCR, and both mutations were found on cDNA Sanger sequencing. Measurement of plasma gangliosides by liquid-phase chromatography-tandem mass spectrometry showed an accumulation of GM2 in our patient's plasma at 83.5 nmol/L, and a GM2/GM3 ratio at 0.066 (median of negative control at 30.2 nmol/L [19.7-46.8] and 0.019 respectively). Therefore, the association of both p.Lys27* and p.Pro169Ser mutations leads to a GM2-AP functional deficiency. Whereas the first mutation is more likely to be linked with infantile form of GM2 gangliosidosis, the hypomorphic p.Pro169Ser variant may be the first associated with a late-onset form of AB variant.

New structural variations responsible for Charcot-Marie-Tooth disease: The first two large KIF5A deletions detected by CovCopCan software.

Next-generation sequencing (NGS) allows the detection of mutations in inherited genetic diseases, like the Charcot-Marie-Tooth disease (CMT) which is the most common hereditary peripheral neuropathy. The majority of mutations detected by NGS are single nucleotide variants (SNVs) or small indels, while structural variants (SVs) are often underdiagnosed. PMP22 was the first gene described as being involved in CMT via a SV of duplication type. To date, more than 90 genes are known to be involved in CMT, with mainly SNVs and short indels described. Herein targeted NGS and the CovCopCan bioinformatic tool were used in two unrelated families, both presenting with typical CMT symptoms with pyramidal involvement. We have discovered two large SVs in KIF5A, a gene known to cause axonal forms of CMT (CMT2) in which no SVs have yet been described. In the first family, the patient presented with a large deletion of 12 kb in KIF5A from Chr12:57,956,278 to Chr12:57,968,335 including exons 2-15, that could lead to mutation c.(130-943_c.1717-533del), p.(Gly44_Leu572del). In the second family, two cases presented with a large deletion of 3 kb in KIF5A from Chr12:57,974,133 to Chr12:57,977,210 including exons 24-28, that could lead to mutation c.(2539-605_*36 + 211del), p.(Leu847_Ser1032delins33). In addition, bioinformatic sequence analysis revealed that a NAHR (Non-Allelic-Homologous-Recombination) mechanism, such as those in the PMP22 duplication, could be responsible for one of the KIF5A SVs and could potentially be present in a number of other patients. This study reveals that large KIF5A deletions can cause CMT2 and highlights the importance of analyzing not only the SNVs but also the SVs during diagnosis of neuropathies.