Clinical and molecular analysis of a novel variant in heme oxygenase-1 deficiency: Unraveling its role in inflammation, heme metabolism, and pulmonary phenotype.

Heme oxygenase 1 (HO-1) is the pivotal catalyst for the primary and rate-determining step in heme catabolism, playing a crucial role in mitigating heme-induced oxidative damage. Pathogenic variants in the HMOX1 gene which encodes HO-1, are responsible for a severe, multisystem disease characterized by recurrent inflammatory episodes, organ failure, and an ultimately fatal course. Chronic hemolysis and abnormally low bilirubin levels are cardinal laboratory features of this disorder. In this study, we describe a patient with severe interstitial lung disease, frequent episodes of hyperinflammation non-responsive to immunosuppression, and fatal pulmonary hemorrhage. Employing exome sequencing, we identified two protein truncating variants in HMOX1, c.262_268delinsCC (p.Ala88Profs*51) and a previously unreported variant, c.55dupG (p.Glu19Glyfs*14). Functional analysis in patient-derived lymphoblastoid cells unveiled the complete absence of HO-1 protein expression and a marked reduction in cell viability upon exposure to hemin. These findings confirm the pathogenicity of the identified HMOX1 variants, further underscoring their association with severe pulmonary manifestations . This study describes the profound clinical consequences stemming from disruptions in redox metabolism.

Immediate cooling does not prevent the ex vivo hydrolysis of L-asparagine by asparaginase.

BACKGROUND: Monitoring of asparagine (ASN) during asparaginase (ASE) treatment directly links to the antileukemic effect of ASE but is challenging because of ASE-induced ex vivo hydrolysis of ASN. Assuming that ASE is not active at 4°C, immediate cooling of blood samples became the accepted method for ASN determination during ASE therapy. METHODS: To evaluate the effect of immediate sample cooling on the ex vivo hydrolysis of ASN by ASE the degradation of C4-ASN in whole blood, spiked with different ASE concentrations were analyzed HPLC-MS. C4-ASN and ASE were added either to blood at 4°C or to blood at 37°C, which was instantly cooled down to 4°C. RESULTS: Immediate cooling did not prevent the ex vivo hydrolysis of ASN by ASE. The rate of ASN degradation to aspartic acid depended on the amount of ASE, ASE preparation, and time. Spiked into blood at 4°C 100 U/L native E. coli ASE already immediately degraded 100% of C4-ASN, whereas 10 U/L reduced the amount of C4-ASN by 30%. Spiked into blood at 37°C, which was immediately cooled thereafter, 10 U/L native E. coli ASE hydrolyzed 60% of C4-ASN and 1 U/L between 5% and 10% of C4-ASN. Concentrations of aspartic acid increased in parallel with ASN degradation. In addition, the ex vivo hydrolysis also affected concentrations of glutamine and glutamic acid. CONCLUSIONS: Cooling of blood samples did not inactivate ASE. Thus, to evaluate the precise pharmacodynamics of ASE, alternative methods for effective ASE inactivation at the time of blood withdrawal are needed.