Letter regarding "The usefulness of the genetic panel in the classification and refinement of diagnostic accuracy of Mexican patients with Marfan syndrome and other connective tissue disorders".

Dear Editor, We have read the article "The usefulness of the genetic panel in the classification and refinement of diagnostic accuracy of Mexican patients with Marfan syndrome and other connective tissue disorders", recently published in your esteemed journal. We are a team dedicated to diagnosing, approaching, and managing patients with connective tissue disorders, particularly hypermobile spectrum disorders (HSD) and Ehlers-Danlos syndromes (EDS). We appreciate the research group's effort to address the complexity of connective tissue disorders using a multi-panel genetic approach and their analysis of genotype-phenotype associations in a cohort of Mexican patients. However, we would like to express our concern regarding two specific points that we consider crucial for the comprehensive understanding and management of these disorders. Read more in the PDF.

3MC syndrome: molecular findings in previously reported and milder patients expand the natural history and phenotypic spectrum.

The 3MC syndromes types 1-3 (MIM#257920, 265050 and 248340, respectively) are rare autosomal recessive genetic disorders caused by pathogenic variants in genes encoding the lectin complement pathway. Patients with 3MC syndrome have a distinctive facial phenotype including hypertelorism, highly arched eyebrows and ptosis. A significant number of patients have bilateral cleft lip and palate and they often exhibit genitourinary and skeletal anomalies. A clinical clue to 3MC syndrome is the presence of a characteristic caudal appendage. Genetic variants in MASP1, COLEC11 and COLEC10 genes have been identified as the causation of this syndrome, yet relatively few patients have been described so far. We consolidate and expand current knowledge of phenotypic features and molecular diagnosis of 3MC syndrome by describing the clinical and molecular findings in five patients. This includes follow-up of two brothers whose clinical phenotypes were first reported by Crisponi et al in 1999. Our study contributes to the evolving clinical and molecular spectrum of 3MC syndrome.

MYC Promotes Bone Marrow Stem Cell Dysfunction in Fanconi Anemia.

Bone marrow failure (BMF) in Fanconi anemia (FA) patients results from dysfunctional hematopoietic stem and progenitor cells (HSPCs). To identify determinants of BMF, we performed single-cell transcriptome profiling of primary HSPCs from FA patients. In addition to overexpression of p53 and TGF-ß pathway genes, we identified high levels of MYC expression. We correspondingly observed coexistence of distinct HSPC subpopulations expressing high levels of TP53 or MYC in FA bone marrow (BM). Inhibiting MYC expression with the BET bromodomain inhibitor (+)-JQ1 reduced the clonogenic potential of FA patient HSPCs but rescued physiological and genotoxic stress in HSPCs from FA mice, showing that MYC promotes proliferation while increasing DNA damage. MYC-high HSPCs showed significant downregulation of cell adhesion genes, consistent with enhanced egress of FA HSPCs from bone marrow to peripheral blood. We speculate that MYC overexpression impairs HSPC function in FA patients and contributes to exhaustion in FA bone marrow.

[Quinolones. Nowadays perspectives and mechanisms of resistance]. / Quinolonas. Perspectivas actuales y mecanismos de resistencia.

Quinolones are a family of synthetic broad-spectrum antimicrobial drugs whose target is the synthesis of DNA. They directly inhibit DNA replication by interacting with two enzymes; DNA gyrase and topoisomerase IV. They have been widely used for the treatment of several community and hospital acquired infections, in the food processing industry and in the agricultural field, making the increasing incidence of quinolone resistance a frequent problem associated with constant exposition to diverse microorganisms. Resistance may be achieved by three non-exclusive mechanisms; through chromosomic mutations in the Quinolone Resistance-Determining Regions of DNA gyrase and topoisomerase IV, by reducing the intracytoplasmic concentrations of quinolones actively or passively and by Plasmid-Mediated Quinolones-Resistance genes, [Qnr determinant genes of resistance to quinolones, variant gene of the aminoglycoside acetyltransferase (AAC(6')-Ib-c)] and encoding genes of efflux pumps (qepA and oqxAB)]. The future of quinolones is uncertain, however, meanwhile they continue to be used in an irrational way, increasing resistance to quinolones should remain as an area of primary priority for research.

Quinolonas: Perspectivas actuales y mecanismos de resistencia / Quinolones: Nowadays perspectives and mechanisms of resistance

Quinolones are a family of synthetic broad-spectrum antimicrobial drugs whose target is the synthesis of DNA. They directly inhibit DNA replication by interacting with two enzymes; DNA gyrase and topoisomerase IV. They have been widely used for the treatment of several community and hospital acquired infections, in the food processing industry and in the agricultural field, making the increasing incidence of quinolone resistance a frequent problem associated with constant exposition to diverse microorganisms. Resistance may be achieved by three non-exclusive mechanisms; through chromosomic mutations in the Quinolone Resistance-Determining Regions of DNA gyrase and topoisomerase IV, by reducing the intracytoplasmic concentrations of quinolones actively or passively and by Plasmid-Mediated Quinolones-Resistance genes, [Qnr determinant genes of resistance to quinolones, variant gene of the aminoglycoside acetyltransferase (AAC(6')-Ib-c)] and encoding genes of efflux pumps (qepA and oqxAB)]. The future of quinolones is uncertain, however, meanwhile they continue to be used in an irrational way, increasing resistance to quinolones should remain as an area of primary priority for research.

Las quinolonas son un grupo de antimicrobianos sintéticos de amplio espectro, cuyo objetivo es la síntesis del ADN. Inhiben directamente su replicación al interactuar con dos enzimas; ADN girasa y topoisomerasa IV. Se han utilizado ampliamente para el tratamiento de infecciones intra y extra-hospitalarias, en el campo de la agricultura y en el procesamiento de alimentos, lo que hace que el incremento de resistencia a quinolonas sea un problema cada vez más frecuente, asociado a la constante exposición de diversos microorganismos. La resistencia puede alcanzarse mediante tres mecanismos no excluyentes entre sí; a través de mutaciones cromosómicas en genes codificantes que afectan las regiones determinantes de resistencia a quinolonas de ADN girasa y topoisomerasa IV, al reducir las concentraciones intracitoplásmicas de quinolonas de manera activa o pasiva y por genes de resistencia a quinolonas mediados por plásmidos [genes de resistencia a quinolonas determinates de qnr, gen variante de la aminoglucósido acetil transferasa (AAC(6’)-lb-cr) y genes codificadores de bombas de eflujo (qepAy oqxAB)]. El futuro de las quinolonas es incierto; sin embargo, mientras continúen empleándose para el manejo de infecciones en el ser humano, el incremento de resistencia a quinolonas debe permanecer como un área de importancia primaria para la investigación.