scholarly journals Infantile Pyknocytosis: End-Tidal CO, %Micro-R Measurements, Next-Generation Sequencing, and Transfusion Avoidance with Darbepoetin

2020 ◽  
Vol 5 (3) ◽  
pp. 1-8
Author(s):  
Timothy M. Bahr ◽  
Mari C. Knudsen ◽  
Michell Lozano-Chinga ◽  
Archana M. Agarwal ◽  
Jessica A. Meznarich ◽  
...  
Keyword(s):  
Next Generation Sequencing ◽  
Hemolytic Anemia ◽  
Clinical Course ◽  
Recombinant Erythropoietin ◽  
Next Generation ◽  
Good Outcome ◽  
End Tidal ◽  
Generation Sequencing

Infantile pyknocytosis is a rare, self-limited, hemolytic condition of unknown pathogenesis. It is diagnosed when a neonate with Coombs-negative hemolytic anemia has abundant pyknocytes and a characteristic clinical course after other hemolytic disorders has been excluded. Previous reports suggest that transfusions might be avoidable in this condition by administering recombinant erythropoietin. We cared for a patient with this disorder where we employed novel diagnostics and therapeutics. Despite these, and a good outcome free of transfusions, we continue to consider the condition to be idiopathic.

scholarly journals Dehydrated hereditary stomatocytosis with new missense mutations in PIEZO1 through the use of next-generation sequencing panel

2021 ◽  
Author(s):  
Sultan Aydin Koker ◽  
Tuba Karapınar ◽  
Paola BIANCHI ◽  
Yeşim Oymak ◽  
Elisa Fermo ◽  
...  
Keyword(s):  
Next Generation Sequencing ◽  
Missense Mutation ◽  
Hemolytic Anemia ◽  
Male Patient ◽  
Autoimmune Hemolytic Anemia ◽  
Missense Mutations ◽  
Next Generation ◽  
Targeted Next Generation Sequencing ◽  
Generation Sequencing

In this case study, we report an 11-year-old male patient who had jaundice, hepatosplenomegaly, and chronic mild congenital non-autoimmune hemolytic anemia. In our patient, a novel homozygous missense mutation in the PIEZO1 gene was detected using a gene-targeted Next-Generation Sequencing panel: c.3364G>A (p.Glu1122Lys), confirming the diagnosis of DHS.

scholarly journals Using a Next Generation Sequencing Panel to Discover the Obscure Causes of Hereditary Hemolytic Anemias

Blood ◽  
2016 ◽  
Vol 128 (22) ◽  
pp. 2433-2433 ◽  
Author(s):  
Archana M Agarwal ◽  
N. Scott Reading ◽  
Kimberly Frizzell ◽  
Wei Shen ◽  
Shelly Sorrells ◽  
...  
Keyword(s):  
Next Generation Sequencing ◽  
Hemolytic Anemia ◽  
Clinical Laboratory ◽  
Single Gene ◽  
Cytoskeletal Proteins ◽  
Next Generation ◽  
Pathogenic Variants ◽  
Late Morbidity ◽  
Next Generation Sequencing Ngs ◽  
Generation Sequencing

Abstract Hereditary hemolytic anemias are a heterogeneous group of disorders with consequences ranging from non-anemic hemolysis to severe life-threatening anemia. However, the late morbidity in patients without transfusions is often underappreciated because of erythropoietic compensatory stimulation inducing hematopoiesis by erythroferrone/hepcidin axis. Principal causes of hereditary hemolytic anemias are germline mutations of red cell cytoskeleton (e.g. hereditary spherocytosis and elliptocytosis/pyropoikilocytosis) or enzyme deficiencies (e.g. Glucose 6 phosphate dehydrogenase deficiency and pyruvate kinase deficiency). Routine morphological and biochemical analysis may be inconclusive and misleading particularly in transfusion-dependent infants and children. Molecular studies have not been extensively used to diagnose these disorders due to the complex genetic nature of these disorders, and multi-gene disorders. In these cases, patients may undergo multiple rounds of single gene testing, which can be very costly and time consuming. The advent of next generation sequencing (NGS) methods in the clinical laboratory has made diagnosing complex genetic disorders feasible. Our diagnostic panel includes 28 genes encoding cytoskeletal proteins and enzymes, and covers the complete coding region, splice site junctions, and, where appropriate, deep intronic or regulatory regions. Targeted gene capture and library construction for next-generation sequencing (NGS) was performed using Sure Select kit (Agilent Technologies, Santa Clara, USA). Prior to sequencing on the Illumina Next Seq, (Illumina Inc) instrument, indexed samples are quantified using qPCR and then pooled. Samples were sequenced using 2x150 paired end sequencing. We now report the first 68 patients evaluated using our NGS panel. The age of the patients ranged from newborn to 62 years. These patients presented with symptoms ranging from mild lifelong anemia to severe hemolytic anemia with extreme hyperbilirubinemia. Genetic variants were classified using the American College of Medical Genetics (ACMG) guidelines. We identified pathogenic variants in 11 patients and likely pathogenic variants in 12 others, the majority of these were novel. Many variants with unknown significance were also identified that could potentially contribute to disease. The most commonly mutated genes were SPTB and SPTA1, encoding spectrin subunits. Some complex interactions were uncovered i.e. SPTA1 mutations along with alpha LELY leading to hereditary pyropoikilocytosis; Spectrin variants along with Gilbert syndrome causing severe hyperbilirubinemia in neonates; and Spectrin variants in combination with PKLR and G6PD variants. Our results demonstrate that many patients with hemolytic anemia harbor complex combinations of known and novel mutations in RBC cytoskeleton/enzyme genes, but their clinical significance is further augmented by polymorphisms of UGT1A1 gene contributing to severe neonatal hyperbilirubinemia and its consequences. To conclude, next-generation sequencing provides a cost-effective and relatively rapid approach to molecular diagnosis, especially in instances where traditional testing failed. We have used this technology successfully to determine the molecular causes of hemolytic anemia in many cases with no prior family history. Disclosures Yaish: Octapharma: Other: Study investigator.

scholarly journals An extremely mild clinical course in a case with LAMB2-associated nephritis diagnosed with next-generation sequencing

2021 ◽  
Author(s):  
Koji Sakuraya ◽  
Kandai Nozu ◽  
Hitohiko Murakami ◽  
China Nagano ◽  
Tomoko Horinouchi ◽  
...  
Keyword(s):  
Next Generation Sequencing ◽  
Clinical Course ◽  
Next Generation ◽  
Generation Sequencing

scholarly journals Use of Next Generation Sequencing Panel for Routine Diagnosis of Hereditary Hemolytic Anemias

Blood ◽  
2018 ◽  
Vol 132 (Supplement 1) ◽  
pp. 2325-2325 ◽  
Author(s):  
Archana M Agarwal ◽  
Jay L Patel ◽  
Adam Clayton ◽  
Noel Scott Reading
Keyword(s):  
Genetic Counseling ◽  
Next Generation Sequencing ◽  
Hemolytic Anemia ◽  
Erythroid Cell ◽  
Red Cell ◽  
Next Generation ◽  
Novel Mutations ◽  
Ugt1a1 Gene ◽  
Rbc Membrane ◽  
Generation Sequencing

Abstract Hereditary hemolytic anemia (HHA) are a heterogeneous group of disorders due to germline mutations of the red cell cytoskeleton (e.g. hereditary spherocytosis (HS) and hereditary elliptocytosis/pyropoikilocytosis (HE/HPP)) or enzyme deficiencies (e.g. glucose 6 phosphate dehydrogenase deficiency (G6PD) and pyruvate kinase deficiency (PKD). Routine morphological and biochemical analysis may be inconclusive in neonates due to the physiological nature of erythroid cell maturation and can also be misleading in transfusion-dependent patients. Additionally, there has been increasing awareness of inherited red cell membrane disorders that are not easily identified by routine laboratory approaches. For example, clinically insignificant defects of RBC membrane genes (e.g. alpha LELY and alpha LEPRA in SPTA1), which can be present in the parents without significant hemolysis, may result in compound heterozygosity in the offspring, causing severe morbidity or even mortality due to significant hemolysis. Awareness of these low expression alleles is important for genetic counseling purposes. Molecular studies, although becoming more mainstream, have not been used extensively to diagnose these disorders. This is most likely due to the complex genetic nature of these disorders (e.g. large genes with multiple exons involved, and multi-gene disorders (i.e. hyperbilirubinemia due to HS as well as involvement of genes involved in bilirubin metabolism). The accessibility of next generation sequencing (NGS) methods in the clinical laboratory has made diagnosing complex genetic disorders feasible. Our current diagnostic panel includes 28 genes encoding cytoskeletal proteins and enzymes, and covers the complete coding region, splice site junctions, and, where appropriate, deep intronic or regulatory regions. Targeted gene capture and library construction for NGS are performed using a Sure Select kit (Agilent). Indexed samples are quantified using qPCR and then pooled prior to sequencing on the Illumina NextSeq or HiSeq instruments. Samples are sequenced using 150 bp paired-end sequencing. This panel includes genes responsible for RBC membrane defects, enzyme deficiencies, as well as bilirubin uridine diphosphate glucuronosyltransferase (UGT1A) genes that have a distinct role in hyperbilirubinemia. We now report the first 268 patients evaluated using our NGS panel between 2015-2018. These patients were evaluated using an Institutional Review Board Protocol (IRB - 00077285). The age of the patients ranged from newborn to 68 years. These patients presented with symptoms ranging from mild lifelong anemia to severe hemolytic anemia with extreme hyperbilirubinemia. Genetic variants were classified according to the American College of Medical Genetics (ACMG) guidelines. We identified pathogenic and likely pathogenic variants in 64/268 (24%) patients that were clearly responsible for the disease phenotype (e.g. moderate to severe hemolytic anemia). Approximately half of them were novel mutations. Moreover, 29/268 (11%) of patients were homozygous for a promoter polymorphism in the UGT1A1 gene A(TA)7TAA (UGT1A1*28), which may lead to reduced expression of the UGT1A1 gene and Gilbert's syndrome. Furthermore, 4/29 UGT1A1 polymorphism cases were associated with pathogenic spectrin mutations, likely increasing the severity of the clinical phenotype in these patients. Overall, the most commonly mutated genes were SPTB and SPTA1, encoding spectrin subunits, followed by PKLR and ANK1 (Table 1). Complex interactions between variants in the SPTA1 gene and the common alpha-LELY and alpha-LEPRA alleles were predicted to be associated with HPP and autosomal recessive HS in 12/64 patients. Furthermore, 23/268 (9%) patients had mutations that were predicted to cause moderate to severe anemia if inherited with another mutation, making them important for genetic counseling purposes (data not shown). Our results demonstrate that many patients with hemolytic anemia harbor complex combinations of known and novel mutations in RBC cytoskeleton/enzyme genes. Many variants of unknown significance were also identified that could potentially contribute to disease. To conclude, the use of NGS provides a cost-effective and comprehensive method to assist in the diagnosis of hemolytic anemias, especially in instances where complex gene-gene interactions are suspected. Disclosures No relevant conflicts of interest to declare.

FAS Mutations in Follicular Lymphoma Are Rare but Associated with Aggressive Clinical Behavior.

Blood ◽  
2009 ◽  
Vol 114 (22) ◽  
pp. 3967-3967
Author(s):  
Nathalie A. Johnson ◽  
Ryan Morin ◽  
Tesa Severson ◽  
Andrew J. Mungall ◽  
Yongjun Zhao ◽  
...  
Keyword(s):  
Next Generation Sequencing ◽  
Follicular Lymphoma ◽  
Research Funding ◽  
Sanger Sequencing ◽  
Clinical Course ◽  
Death Domain ◽  
Next Generation ◽  
Genomic Alterations ◽  
Aggressive Clinical Course ◽  
Generation Sequencing

Abstract Abstract 3967 Poster Board III-903 Background Follicular lymphoma (FL) is considered an indolent but incurable lymphoma. Treatment with cyclophosphamide, vincristine, prednisone and rituximab (CVP-R) provides complete or partial responses in most patients. The BCL2 translocation t(14;18) is present in 85% of the cases, but additional genomic alterations must occur to induce overt FL. We have sequenced the genome and transcriptome of a cytogenetically normal FL sample taken from a patient (pt 1) that had an unusually aggressive clinical course with the aim of identifying genomic alterations that could contribute to FL pathogenesis. We identified a mutation in FAS/CD95, a key component of the extrinsic apoptotic pathway. We hypothesized that FAS mutations may contribute to treatment resistance in FL by inhibiting apoptosis. This study investigates the prevalence and clinical outcome of patients with FL harbouring mutations in the exons coding for the functional “death domain” of the FAS gene. Methods The initial FL sample was subjected to cytogenetic analysis and whole genome tiling array comparative genomic hybridization followed by next-generation sequencing of the tumour genome and tumor transcriptome following the manufacturer's protocol (Illumina). FAS emerged as a potential candidate that could explain the unusually aggressive FL. We performed PCR amplification of exons 7,8,9 and the 3'UTR of the FAS gene with universal M13F(-21) and M13 primer extensions on pre-treatment FL samples derived from 214 patients including 33 diffuse large B cell lymphoma samples that had evolved from a prior FL (i.e. paired FL and DLBCL). PCR products were purified using AMPpure magnetic beads and bi-directionally sequenced using BigDye® Terminator v3.1 and an ABI 3730 XL sequencer. Analysis was performed using Mutation Surveyor. Mutations were considered present if they were observed in both forward and reverse reads. Results Patient 1 had a t(14;18) negative, grade 1 FL, that progressed rapidly despite CVP-R and second line chemotherapy but is now in complete remission following an allogeneic stem cell transplant. The FL immunophenotype was CD19+, CD10+, BCL2+, BCL6+ and lambda clonal. Minimal genomic gains and losses were observed by aCGH. After filtering known single nucleotide polymorphisms (SNPs), a total of 320 candidate novel protein-altering changes were identified (affecting 298 genes) in the tumor genome and transcriptome sequence data. Validation of the mutated genes by Sanger sequencing revealed a novel, somatic and coding mutation in FAS at genomic position chr10:90764005, changing C to T, resulting in a premature truncation of the protein. We then sequenced exons 7, 8, 9 and the 3'UTR of the FAS gene from 214 FL patients. Ten novel FAS mutations were detected, of these six were coding, three of which produced a truncated protein. Of the six coding mutations, two were observed in the transformed DLBCL sample. Coding mutations in FAS appeared to be associated with an aggressive clinical course (median time to progression=12 months for coding mutations (n=6) vs 34 months for non-coding or wild type (n=208), P=0.06). 2 of the 6 patients developed early transformation to DLBCL, 2 had treatment resistant FL that required allogeneic bone marrow transplant and 2 have already died due to progressive treatment refractory FL. Conclusion Next generation sequencing technology revealed novel somatic mutations in a cytogenetically normal FL sample, one of which was a mutation in the FAS gene. Sanger sequencing of a large cohort of FL samples revealed that 5% of cases harboured novel mutations in the death domain of FAS (2% coding, 3% non-coding). Coding mutations were rare but when present were associated with atypically aggressive disease. Disclosures: Connors: Roche Canada: Research Funding. Gascoyne:Roche Canada: Honoraria, Membership on an entity's Board of Directors or advisory committees, Research Funding.

The Clinical Utility Of Next-Generation Sequencing In The Diagnosis Of Hereditary Hemolytic Anemias

Blood ◽  
2013 ◽  
Vol 122 (21) ◽  
pp. 3421-3421
Author(s):  
Roberto H Nussenzveig ◽  
Nikhil Sangle ◽  
Robert D. Christensen ◽  
Mohamed E Salama ◽  
Josef Prchal ◽  
...  
Keyword(s):  
Next Generation Sequencing ◽  
Family History ◽  
Hemolytic Anemia ◽  
Molecular Diagnosis ◽  
Clinical Utility ◽  
Novel Mutation ◽  
Red Cell ◽  
The Novel ◽  
Next Generation ◽  
Generation Sequencing

Abstract Hereditary hemolytic anemia encompasses a diverse group of genetically and phenotypically heterogeneous disorders that are characterized by increased red cell destruction, with consequences ranging from relatively harmless to severe life-threatening anemia. Moreover, red cell hemolysis leads to increased production of bilirubin, a breakdown product of hemoglobin, which in neonates places them at risk for extreme jaundice and its consequences. Two of the more common genetic causes of hereditary hemolytic anemia, excluding hemoglobinopathies, can be attributed to defects in either the red cell cytoskeleton or enzyme deficiency (e.g. G6PD, PKLR). Morphological and biochemical diagnosis of hereditary hemolytic anemia due to defects in RBC cytoskeleton or enzyme deficiency is routinely performed in many laboratories. However, routine studies can be challenging, particularly in transfusion-dependent infants and children since these patients have mostly transfused RBCs. Molecular diagnosis has also been challenging not only due to molecular heterogeneity but also due to the number and size of the genes involved. We developed a novel, high-throughput, sensitive sequencing assay for diagnosis of the molecular causes of the two major types of hereditary hemolytic anemia described above. Our diagnostic panel includes 25 genes encoding cytoskeletal proteins and enzymes, and covers the complete coding region, splice site junctions, and, where appropriate, deep intronic or regulatory regions. Targeted gene capture and library construction for next-generation sequencing (NGS) was performed using HaloPlex as described by the manufacturer (Agilent Technologies, Santa Clara, CA). One hundred base-pair paired-end sequencing was done on a HiSeq 2000 system (Illumina, San Diego, CA). Bioinformatic analysis was based on an “in house” pipeline using standard open-source software. A total of 19 patients with unexplained hemolytic anemia, and 30 normal controls were tested in our assay. Mutations in the appropriate genes were identified in 17/19 patients, many of these being novel. All identified mutations were confirmed by Sanger sequencing. In silico prediction of the impact resulting from the novel mutations was performed using two web-based software packages, Sift and Polyphen. Where possible, inheritance of pathogenic mutations was determined in immediate relatives. One of the cases we investigated involved a neonate with unexplained jaundice and subsequent, significantly compensated, anemia without family history of a hemolytic disorder. Routine studies were suggestive for hereditary spherocytosis due to the presence of microspherocytes on the proband’s blood film, increased osmotic fragility, and decreased eosin-5-maleimide stained red cells. Two pathogenic mutations, in compound heterozygosity, were identified in the SPTA1 gene (α-spectrin). A previously reported mutation αLEPRA, known to be associated with recessive spectrin-deficient HS, and a novel mutation in intron 45 +1 (c.6530+1G>A) disrupting the consensus splice site. Screening of other relevant genes failed to reveal additional mutations. Studies of his parents revealed both to be heterozygous carriers with the asymptomatic mother harboring the αLEPRA mutation and the asymptomatic father harboring the novel mutation. Our results demonstrate the clinical utility of this assay for molecular diagnosis and genetic counseling for parents at risk of having affected children. Next-generation sequencing provides a cost-effective and rapid approach to molecular diagnosis, especially in cases where traditional testing has failed. We have used this technology successfully to determine the molecular causes of hemolytic anemia in several cases with no family history. Furthermore, we have validated its clinical utility in neonates risk for hyperbillirubinemia, as well as, in patients with transfusion dependent hemolytic anemia. Disclosures: No relevant conflicts of interest to declare.

Development Of a Comprehensive Rapid Next-Generation Sequencing Assay For The Diagnosis Of Inherited Hemolytic Anemia

Blood ◽  
2013 ◽  
Vol 122 (21) ◽  
pp. 949-949
Author(s):  
Amber Hogart Begtrup ◽  
Neha Dagaonkar ◽  
Suvarnamala Pushkaran ◽  
Katie M. Giger ◽  
Ammar Husami ◽  
...  
Keyword(s):  
Next Generation Sequencing ◽  
Hemolytic Anemia ◽  
Base Pair ◽  
Nonsense Mutation ◽  
Missense Variant ◽  
Next Generation ◽  
Protein Coding ◽  
Initial Validation ◽  
Insight Into ◽  
Generation Sequencing

Abstract Hereditary hemolytic anemia is caused by defects in hemoglobin, in the red blood cell (RBC) cytoskeleton proteins, or by deficiencies in RBC enzymes. RBC cytoskeletal disorders include hereditary spherocytosis (HS), elliptocytosis (HE), pyropoikilocytosis (HPP), and stomatocytosis (HSt), which are typically inherited as autosomal dominant disorders but can also present as recessive forms, frequently severe. The RBC enzymopathies, such as glucose-6-phosphate dehydrogenase (G6PD) and pyruvate kinase (PK) deficiency, are X-linked or recessively inherited disorders causing hemolytic anemia. Although rare, congenital dyserythropoietic anemias (CDA) are inherited red cell lineage disorders which occasionally, especially CDA-II, can be misdiagnosed as HS. Diagnosis of an inherited hemolytic anemia not due to a hemoglobin disorder is based upon morphology of the RBCs, functional analysis of the RBCs through ektacytometry or osmotic fragility, and enzymatic assays. The diagnosis of severely affected patients is complicated by transfusion dependence. Diagnosis based on genetic mutations is attractive, especially in transfused patients, and provides additional insight into the mechanisms of disease. Despite these advantages, genetic diagnoses have been limited by expense and long turn-around times for clinical results. To address these issues, we have developed a rapid comprehensive clinical next-generation sequencing-based assay that evaluates 27 genes with published disease-causing mutations for RBC cytoskeletal disorders, enzymopathies, and CDAs. The protein-coding exons plus 25 bases of exon/intron junction as well as promoter sequences with known relationship to clinical phenotypes were included in the design. Genomic DNA was digested with a panel of 8 restriction enzymes and oligonucleotide probes were used to enrich the target regions. Enriched samples were then sequenced on an Illumina MiSeq benchtop sequencer with 150 base pair, paired-end reads. Enrichment and sequencing were completed within 48 hours. Sequencing reads were aligned to the human genome reference sequence and analysis of coverage and variants was completed using NextGENe software. Initial validation included 5 affected probands, 1 affected sibling of a proband, 4 parental samples, and 2 unrelated control individuals with no history of hemolytic anemia. Overall, > 99% of all nucleotides in the regions of interest had at least 20X sequencing coverage. Our assay confirmed a previously identified maternally inherited nonsense mutation, Y1089X, and a paternally inherited A970D missense variant in SPTA1 in a patient (SPCA) with severe HS. The A970D SPTA1 missense change was also seen in two unaffected parents and an unaffected control, further validating that this missense variant alone does not cause dominant HS. The common SPTA1 allele, αLELY was seen in the clinically unaffected mother of SPCA, but was not found in the affected child, suggesting that this allele must be inherited in trans with a pathologic SPTA1 mutation to have clinical effect. Analysis of additional probands revealed both dominant and recessive forms of HS due to mutations in ANK1. Patient AAHS2 presented with typical dominant HS, and was found to have a novel ANK1 frameshift mutation, c.3464delG. Patient HEEM presented with severe transfusion-dependent anemia and was found to have one reported ANK1 missense mutation, T1075I (ankyrin Tubarao) in the spectrin-binding domain, and one novel nonsense mutation, Y735X. In addition, we identified novel amino acid changes in the newly identified dehydrated HSt gene PIEZO1. HEGR, a patient with hemolytic anemia, splenomegaly and portal vein thrombosis in infancy was found to have a novel 6 base pair insertion at R1462 in PIEZO1. Thal1 was previously diagnosed with dominant β-thalassemia, however had a more severe presentation than expected. We found a PIEZO1missense mutation R2302H in Thal1 that likely explains the severe phenotype. The initial validation of this comprehensive sequencing assay has demonstrated that this is a robust and rapid diagnostic tool for patients with severe hereditary hemolytic anemia. Simultaneous investigation of the key protein-coding genes involved in proper RBC function and survival, provides new insight into the variable phenotypes of patients with hemolytic anemia and ultimately will improve the management of patients with severe disease. Disclosures: No relevant conflicts of interest to declare.

The Novel PIEZO1 Mutation p.L2023V Is Causal for Hereditary Xerocytosis Resulting in Delayed Channel Inactivation and a Dehydrated Red Blood Cell Phenotype

Blood ◽  
2014 ◽  
Vol 124 (21) ◽  
pp. 741-741
Author(s):  
Mary A Risinger ◽  
Edyta Glogowska ◽  
Amber Hogart Begtrup ◽  
Neha Dagaonkar ◽  
Satheesh Chonat ◽  
...  
Keyword(s):  
Next Generation Sequencing ◽  
Blood Cell ◽  
Hemolytic Anemia ◽  
Red Blood Cell ◽  
Band 3 ◽  
Next Generation ◽  
Wild Type ◽  
Channel Inactivation ◽  
Cellular Dehydration ◽  
Generation Sequencing

Abstract The regulation of cell volume is important for the maintenance of integrity in all cells and is especially critical for the highly specialized red blood cell (RBC) which must withstand pressure changes within the vasculature and remain deformable to traverse small vessels. Disorders that interfere with volume homeostasis result in the premature destruction of RBCs. One protein that appears to play a prominent role in RBC hydration is the recently described nonselective cation channel PIEZO1 which is involved in mechanotransduction. Mutations of PIEZO1 have been associated with an autosomal dominant form of hereditary hemolytic anemia (HHA) characterized by RBC dehydration known as hereditary xerocytosis (HX) (Zarychanski et al., Blood 2012;120:1908). There is evidence that PIEZO1 may also be responsible for a channel activity that participates in the dehydration of sickle cells which exacerbates sickling and vaso-occlusive events in patients with Sickle Cell Disease (reviewed in Gallagher, Curr Opin Hematol 2013, 20:201). Using a Next-Generation sequencing panel containing 27 hemolytic anemia associated genes, we identified and characterized a novel PIEZO1 mutation p.L2023V which results in delayed channel inactivation and a dehydrated RBC phenotype. This single amino acid substitution at a highly conserved site was detected in the heterozygous state in a 15 year old Caucasian young man (CQ15) with chronic hemolysis well compensated with reticulocytosis, along with heterozygosity for the SLC4A1 p.E40K mutation known as band 3 Montefiore. Hematologic characteristics included macrocytosis, elevated MCHC, and a smear showing occasional stomatocytes. Several family members also had hemolysis and jaundice and were given a diagnosis of hereditary pyropoikilocytosis prior to our evaluation. The L2023V mutation was considered possibly damaging by the PolyPhen-2 algorithm with a score of 0.777. The mother was heterozygous for the PIEZO1 L2023V mutation while the father carried the band 3 Montefiore mutation. Ektacytometry was used to evaluate RBC deformability; the mother's RBCs had a profile of classic xerocytosis with decreased Omin and Ohyp, the father had a very mild spherocytosis profile, while the patient's RBCs had mixed ektacytometry characteristics with decreased Ohyp and an intermediate Omin (Figure 1A). Intracellular cation values determined by flame emission spectroscopy for CQ15 and his mother demonstrated K+ loss. The mutation p.L2023V is located at a site predicted to be at the border between membrane and cytoplasm in the carboxy terminal part of the protein, similar to the previously described p.R2456H mutation in a kindred with HX (Zarychanski et al., 2012). To enable detailed physiologic study of the L2023V mutation, we prepared an HEK293 cell line with a stable, single copy integrant of the variant with an inducible promoter. Whole cell patch clamp studies were performed on HEK293 cells expressing wild type PIEZO1 and PIEZO1 L2023V. Traces of mechanically activated currents were recorded from the cells and were normalized to peak current (Figure 1B). The inactivation time constant tau (in ms) was determined from mono-exponential fits for wild type and mutant PIEZO1 channels. The difference in average inactivation time between wild type PIEZO1 and PIEZO1 L2023V was highly significant (Student's t-test; p<0.0001) and is predicted to lead to cellular dehydration. Patients often present with a complex clinical picture and laboratory results and may have combinations of potentially damaging genetic variants identified by Next-Generation sequencing. The examination of clinical, laboratory, and genetic data from family members and, in some cases, in vitro studies are required to clarify the relative contribution of these variants and to arrive at an accurate diagnosis. The data presented here further our understanding of the role of PIEZO1 in RBCs and its potential pathological contribution in HHAs with associated cellular dehydration and may facilitate the future development of therapeutic targets for treatment of these conditions. Figure 1 Figure 1. Disclosures No relevant conflicts of interest to declare.

Sign in / Sign up

Export Citation Format

Share Document