Sensitive Replicate Real-Time Quantitative PCR of BCR-ABL Shows Deep Molecular Responses in Long-Term Post-Allogeneic Stem Cell Transplantation Chronic Myeloid Leukemia Patients.

Real-time quantitative PCR (RT-qPCR) is commonly used for follow-up of chronic myeloid leukemia (CML) patients treated with tyrosine kinase inhibitors, but its current sensitivity does not allow detection of very low BCR-ABL levels. Therefore RT-qPCR negativity is not synonymous with complete molecular response. Replicate RT-qPCR had shown increased sensitivity in tyrosine kinase inhibitor-treated patients and was, therefore, used here to evaluate whether RT-qPCR-negative post-allogeneic stem cell transplantation (SCT) patients harbor detectable disease. Samples from 12 patients were tested at 2 time points using 82 replicates of BCR-ABL RT-qPCR. One patient (38 months after SCT) had detectable transcripts at baseline and none at the follow-up test, done at a median of 107 months after SCT. This suggests cure from CML in the majority of allogeneic SCT patients who have no transcripts detectable by replicate RT-qPCR for BCR-ABL.

Droplet Digital PCR for BCR-ABL1 Monitoring in Diagnostic Routine: Ready to Start?

BCR-ABL1 mRNA levels represent the key molecular marker for the evaluation of minimal residual disease (MRD) in chronic myeloid leukemia (CML) patients and real-time quantitative PCR (RT-qPCR) is currently the standard method to monitor it. In the era of tyrosine kinase inhibitors (TKIs) discontinuation, droplet digital PCR (ddPCR) has emerged to provide a more precise detection of MRD. To hypothesize the use of ddPCR in clinical practice, we designed a multicentric study to evaluate the potential value of ddPCR in the diagnostic routine. Thirty-seven RNA samples from CML patients and five from healthy donors were analyzed using both ddPCR QXDxTMBCR-ABL %IS Kit and LabNet-approved RT-qPCR methodologies in three different Italian laboratories. Our results show that ddPCR has a good agreement with RT-qPCR, but it is more precise to quantify BCR-ABL1 transcript levels. Furthermore, we did not find differences between duplicate or quadruplicate analysis in terms of BCR-ABL1% IS values. Droplet digital PCR could be confidently introduced into the diagnostic routine as a complement to the RT-qPCR.

Alignment of Qx100/Qx200 Droplet Digital (Bio-Rad) and QuantStudio 3D (Thermofisher) Digital PCR for Quantification of BCR-ABL1 in Ph+ Chronic Myeloid Leukemia.

In recent years, the digital polymerase chain reaction has received increasing interest as it has emerged as a tool to provide more sensitive and accurate detection of minimal residual disease. In order to start the process of data alignment, we assessed the consistency of the BCR-ABL1 quantification results of the analysis of 16 RNA samples at different levels of disease. The results were obtained by two different laboratories that relied on The Qx100/Qx200 Droplet Digital PCR System (Bio-Rad) and Quant Studio 3D dPCR System (Thermofisher) platforms. We assessed the compatibility between the estimated values by linear regression, Bland-Altman bias-plot, and Mann-Whitney nonparametric test. The results confirmed the compatibility of the measures, allowing us tocompute an 'alignment factor' (AF), equal to 1.41, which was further validated by a different series of experiments. We conclude that the performed measurements by the two laboratories are comparable, and also equalized through the introduction of an alignment factor.

Monitoring Chronic Myeloid Leukemia: How Molecular Tools May Drive Therapeutic Approaches.

More than 15 years ago, imatinib entered into the clinical practice as a "magic bullet"; from that point on, the prognosis of patients affected by chronic myeloid leukemia (CML) became comparable to that of aged-matched healthy subjects. The aims of treatment with tyrosine kinase inhibitors (TKIs) are for complete hematological response after 3 months of treatment, complete cytogenetic response after 6 months, and a reduction of the molecular disease of at least 3 logs after 12 months. Patients who do not reach their goal can switch to another TKI. Thus, the molecular monitoring of response is the main consideration of management of CML patients. Moreover, cases in deep and persistent molecular response can tempt the physician to interrupt treatment, and this "dream" is possible due to the quantitative PCR. After great international effort, today the BCR-ABL1 expression obtained in each laboratory is standardized and expressed as "international scale." This aim has been reached after the establishment of the EUTOS program (in Europe) and the LabNet network (in Italy), the platforms where biologists meet clinicians. In the field of quantitative PCR, the digital PCR is now a new and promising, sensitive and accurate tool. Some authors reported that digital PCR is able to better classify patients in precise "molecular classes," which could lead to a better identification of those cases that will benefit from the interruption of therapy. In addition, digital PCR can be used to identify a point mutation in the ABL1 domain, mutations that are often responsible for the TKI resistance. In the field of resistance, a prominent role is played by the NGS that enables identification of any mutation in ABL1 domain, even at sub-clonal levels. This manuscript reviews how the molecular tools can lead the management of CML patients, focusing on the more recent technical advances.

Philadelphia-positive lymphoblastic lymphoma: a case report and review of the literature.

Philadelphia positive acute lymphoblastic leukemia is well documented nowadays but very little is known about Philadelphia positive lymphoblastic lymphoma (LBL). Only two cases are available in literature and both of them died during treatment whereas the patient treated in our center is still alive 3 years after the initial diagnosis. A chemo-free regimen was used in induction with dasatinib plus steroids with local radiotherapy on the mass, and then the patient underwent bone marrow transplant. Philadelphia positive lymphoblastic lymphoma is a difficult diagnosis to make and the management of this extremely rare disease is very challenging.

CALR-positive myeloproliferative disorder in a patient with Ph-positive chronic myeloid leukemia in durable treatment-free remission: a case report.

Current diagnostic criteria for Philadelphia-negative myeloproliferative neoplasia (MPN) have been redefined by the discovery of Janus kinase 2 (JAK2), myeloproliferative leukemia (MPL) and calreticulin (CALR) genetic alterations. Only few cases of coexistence of CALR-mutated MPN and Philadelphia-positive chronic myeloid leukemia (CML) have been described so far. Here we report the case of a patient with CML diagnosed in 2001, treated with imatinib and pegylated interferon (IFN) frontline. She reached complete molecular remission (CMR) and discontinued imatinib, maintaining treatment free remission. Due to persistent thrombocytosis, we repeated bone marrow (BM) analysis and diagnosed CARL-mutated essential thrombocythemia (ET). A CALR-positive clone was found to be present since 2001, and was unaffected by imatinib treatment, possibly representing a molecular abnormality arising at stem cell level.

Microelectronic DNA chip for hereditary hyperferritinemia cataract syndrome, a model for large-scale analysis of disorders of iron metabolism.

Hereditary hyperferritinemia cataract syndrome (HHCS) is caused by mutations in the regulatory iron responsive element (IRE) in the 5'UTR of the L-ferritin transcript that reduce binding affinity to the iron regulatory proteins (IRPs) and lead to a constitutive upregulation of the protein in tissue and serum. Twenty-nine mutations have been reported within the L-ferritin (FTL) IRE sequence, 21 of which were available to us. In addition, we included in this study three new mutations. Thus, we analyzed 24 mutations spanning over a DNA stretch of 48 nucleotides, including four deletions 2-29 nucleotides long and 20 substitutions, seven of which were conservative transversions. With this unique experimental model we developed a microchip diagnostic platform for identifying known molecular defects in the L-ferritin IRE structure with a microelectronic array approach, which we optimized after studying the effects of various parameters. The system enables electronic deposition of biotinylated amplicons to selected pads. Under optimized conditions, no cross-hybridization was found, even for mutations that affected the same or adjacent nucleotide positions. The same cartridge could be serially hybridized with all the 24 reporter probe sets, which allowed correct genotyping right up until the end of the analysis. Extensive validation on 200 samples in a blinded fashion gave total concordance of results. This pilot study represents a first step toward developing a diagnostic microchip for large-scale analyses for epidemiological studies and screening of mutations associated with iron disorders.

Liver expression of hepcidin and other iron genes in two mouse models of beta-thalassemia.

BACKGROUND AND OBJECTIVES: Homozygous beta-thalassemia patients may develop iron overload even if untransfused, due to inappropriately high intestinal iron absorption. Reduction of hepcidin synthesis has been reported both in patients and in animal models. We have measured liver hepcidin and other iron gene transcripts in two different mouse models of beta-thalassemia at different ages. DESIGN AND METHODS: Mice Hbb(th/th), characterized by spontaneous homozygous deletion of the major b1 globin gene were studied at 2 and 8 months. Mice Hbb(th/3+), characterized by the heterozygous deletion of b1 and b2 globin genes were studied at 4 and 10 months. Hematologic data were obtained and iron overload estimated by Perls' staining of the liver. Expression of liver hepcidin, Tfr2, Hjv, Fpn and Hfe RNA was assessed by real-time polymerase chain reaction. Levels of serum cytokines (interleukin-6, IL-1beta, IL-10, granulocyte-macrophage colony-stimulating factor) levels were assayed by enzyme-linked immunosorbent assay. RESULTS: Hemoglobin, hematocrit and mean corpuscular volume were significantly reduced in both beta-thalassemia models, more significantly in Hbb(th/3+), which have the greater, age-dependent, iron overload. Hepcidin RNA was not increased despite iron overload in both strains. Fpn RNA was increased and Tfr2 was decreased in older animals. Inflammatory cytokine levels were striking variable and unrelated to hepcidin levels. INTERPRETATION AND CONCLUSIONS: Although anemia is reported to inhibit hepcidin expression, normal hepcidin synthesis was maintained in both thalassemic models studied. However, hepcidin levels were inappropriate for the body iron, especially in Hbb(th/3+) 10-month-old animals. As we previously reported in wild type mice after parenteral iron overload, Tfr2 is reduced and Fpn RNA increased in thalassemic mice. Inflammatory cytokines did not play a major role in increasing hepcidin levels or in modifying iron homeostasis in this study.

Early BCR-ABL1 Reduction Is Predictive of Better Event-free Survival in Patients With Newly Diagnosed Chronic Myeloid Leukemia Treated With Any Tyrosine Kinase Inhibitor.

An early molecular response has a strong predictive value in chronic myeloid leukemia (CML). Recently, the halving time (velocity of early BCR-ABL1 transcript elimination) has been shown to represent an additional prognostic index. Our objective was the evaluation of the prognostic significance of the 3-month point in our population. We retrospectively collected BCR-ABL1 transcript data at different time points, events, and survival data of patients with CML treated at the Division of Hematology, San Luigi Hospital, University of Turin, Turin, Italy. Of 71 patients diagnosed from January 2005 to March 2015 in our center and treated with front-line tyrosine kinase inhibitors (imatinib, nilotinib and dasatinib), we selected those who had undergone a molecular evaluation at 3 months. The event-free survival (EFS) by the median follow-up time was the primary endpoint. The data from 50 patients with CML chronic phase were analyzed. Overall, 34 of the 50 patients (68%) had a transcript ≤ 10% at 3 months. Of those in the > 10% group, 63% had experienced an event compared with 12% in the ≤ 10% group by the median follow-up point (P < .001). The halving time threshold for discriminating between EFS was 17 days. None of the patients with a transcript > 10% at 3 months had a halving time of ≤ 17 days. Patients with BCR-ABL1 ≤ 10% and a halving time of ≤ 17 days had significantly better EFS than that of patients with BCR-ABL1 ≤ 10% and a halving time > 17 days and of patients with BCR-ABL1 > 10% (96% group 1 vs. 60% group 2 vs. 27% group 3; P < .001). Irrespective of the tyrosine kinase inhibitor used, the prognosis was significantly superior for patients with BCR-ABL1 ≤ 10% and halving time of ≤ 17 days. Our data revealed that the use of ABL1 as a control gene is reliable for the determination of the halving time in the clinical setting and highlight the importance of measuring the BCR-ABL1 transcript at CML diagnosis.

Hepatic expression of hemochromatosis genes in two mouse strains after phlebotomy and iron overload.

BACKGROUND AND OBJECTIVES: Iron homeostasis is tightly regulated in mammals according to the needs of erythropoiesis and the iron stores present. This regulation is disrupted in hereditary hemochromatosis (HH), a genetic disorder characterized by increased intestinal iron absorption, leading to iron overload. The genes coding for HFE, transferrin receptor 2 (TFR2), ferroportin (SLC40A1 or FPN1), hepcidin (HEPC) and hemojuvelin (HJV or RGMC) are responsible for different types of genetic iron overload. All these genes are highly expressed in the liver and their protein products are likely components of a single hepcidin-related pathway. In order to gain insights into the molecular relationship among the HH proteins we evaluated the hepatic expression of HH genes in conditions of iron restriction or overload. DESIGN AND METHODS: Data were obtained after phlebotomy, to activate the erythroid regulators and following parenteral iron dextran loading, to activate the store regulators, in two mice strains (C57BL/6 and DBA/2). HH genes and proteins expression were analyzed by quantitative real time polymerase chain reaction and by Western blotting, respectively. RESULTS: Hepc RNA was reduced after phlebotomy and increased in iron overload. A statistically significant reduction of hepatic Fpn1 RNA expression was observed after phlebotomy; this effect was more evident in the DBA/2 strain. Fpn1 increased in C57BL/6 mice, but not in the DBA/2 ones in parenteral iron loading. Fpn1 protein did not change substantially in either condition. Hfe, Rgmc and Tfr2 expression was not influenced by phlebotomy. In parenteral iron overload, Tfr2 gene and protein expression decreased concomitant to the increase in Hepc, while Hfe RNA remained constant. INTERPRETATION AND CONCLUSIONS: Our results indicate that regulation of hepatic Fpn1 differs from that reported for duodenal Fpn1. Furthermore, taken the differences in gene expression in dietary overload (increased Hfe but not Tfr2), distinct roles are suggested for Hfe and Tfr2 in Hepc activation.

Homozygosity for transferrin receptor-2 Y250X mutation induces early iron overload.

Two Italian subjects, aged three and sixteen years, presented with early iron overload as shown by increased serum iron indices and hepatic iron concentration. They both carried the Y250X mutation of the TFR2 gene in the homozygous state. We suggest that transferrin receptor-2 is important in maintaining iron balance in the first decades of life.

Genetic and clinical heterogeneity of ferroportin disease.

Ferroportin is encoded by the SLC40A1 gene and mediates iron export from cells by interacting with hepcidin. SLC40A1 gene mutations are associated with an autosomal type of genetic iron overload described as haemochromatosis type 4, or HFE4 (Online Mendelian Inheritance in Man number 606069), or ferroportin disease. We report three families with this condition caused by novel SLC40A1 mutations. Denaturing high-performance liquid chromatography was employed to scan for the SLC40A1 gene. A D181V (A846T) mutation in exon 6 of the ferroportin gene was detected in the affected members of an Italian family and shown to have a de novo origin in a maternal germinal line. This mutation was associated with both parenchymal and reticuloendothelial iron overload in the liver, and with reduced urinary hepcidin excretion. A G80V (G543T) mutation in exon 3 was found in the affected members of an Italian family with autosomal hyperferritinaemia,. Finally, a G267D (G1104A) mutation was identified in exon 7 in a family of Chinese descent whose members presented with isolated hyperferritinaemia. Ferroportin disease represents a protean genetic condition in which the different SLC40A1 mutations appear to be responsible for phenotypic variability. This condition should be considered not only in families with autosomal iron overload or hyperferritinaemia, but also in cases of unexplained hyperferritinaemia.

Hemochromatosis due to mutations in transferrin receptor 2.

A rare recessive disorder which leads to iron overload and severe clinical complications similar to those reported in HFE-related hemochromatosis has been delineated and sometimes called hemochromatosis type 3. The gene responsible is Transferrin Receptor 2 (TFR2), which maps to chromosome 7q22. The TFR2 gene presents a significative homology to transferrin receptor (TFRC) gene, encodes for a transmembrane protein with a large extracellular domain, is able to bind transferrin, even if with lower affinity than TFRC. The TFR2 function is still unclear. The transcript does not contain IRE elements and is not modified by the cellular iron status. At variance with TFRC, interactions between TFR2 and HFE do not occur, at least in their soluble forms. TFR2 is spliced in two alternative forms, alfa and beta. The alfa form is strongly expressed in the liver. The beta form, codified from a start site in exon 4 of the alpha, has a low and ubiquitous expression. Using anti-TFR2 monoclonal antibodies we have confirmed expression of the protein in the liver but also in duodenal epithelial cells, and studied the protein functional behaviour in cell lines, in response to iron addition, iron deprivation and olo-transferrin exposure. Our results suggest a regulatory role of TFR2 in iron metabolism. Five TFR2 homozygous mutations have been documented in HFE3 patients: a nonsense mutation (Y250X); a C insertion that causes a frameshift and a premature stop codon (E60X); a missense mutation (M172K); a 12 basepair deletion in exon 16, that causes 4 aminoacid loss (AVAQ 594-597del) in the extracellular domain of TFR2; a missense mutation in exon 17 (Q690P). The mutation analysis supports the hypothesis that all are private mutations. The pathogenetic role of TFR2 in hemochromatosis has been recently further demonstrated through the targeted expression of the Y250X human mutation in mice, which develop sings of iron overload identical to the human disease. Although the rarity of TFR2 mutations limits their usefulness in diagnostic/screening programs, their study can contribute to a better understanding of the protein function.

Analysis of HFE and TFR2 mutations in selected blood donors with biochemical parameters of iron overload.

BACKGROUND AND OBJECTIVES: Hereditary hemochromatosis is a recessive condition characterized by iron accumulation in several organs, followed by organ damage and failure. The disorder is prevalently due to C282Y and H63D mutations in the HFE gene, but additional HFE and TFR2 mutations have been reported. Early iron overload may be assessed by biochemical parameters such as increased transferrin saturation and serum ferritin. DESIGN AND METHODS: Taking advantage of the collection of 178 DNA samples selected for increased transferrin saturation (>50% in males and >45% in females) from a previous large scale screening of Italian blood donors, we simultaneously assessed the presence of 14 hemochromatosis-associated molecular defects (11 of HFE and 3 of TFR2) by a reverse hybridization-based strip assay. RESULTS: In the series studied the overall C282Y allele frequency was 9% and that of the H63D and S65C was 22.2% and 1.4%, respectively. One rare HFE allele (E168Q), but no TFR2 mutation was detected. When checked at a second examination, transferrin saturation was significantly higher in C282Y homozygotes, H63D/ C282Y compound heterozygotes and H63D homozygotes as compared to wild-type subjects (p<0.05). INTERPRETATION AND CONCLUSIONS: Our results confirm previous findings on C282Y and H63D mutations in Italy, show that the C282Y allele frequency is enriched in samples selected for altered iron parameters, and that a few rare genotypes are present in Northern Italy. None of the known TFR2 mutations was identified in this series confirming the preliminary indication of their rare occurrence. Subjects with hemochromatosis-associated genotypes show a persistently higher mean transferrin saturation than do those with wild type genotypes.

Clinical and pathologic findings in hemochromatosis type 3 due to a novel mutation in transferrin receptor 2 gene.

BACKGROUND & AIMS: Although most patients with hereditary hemochromatosis are homozygous for a single mutation of the HFE gene on chromosome 6p, accumulating evidence indicates that the disease is genetically heterogeneous. Type 3 hemochromatosis, recently described in 4 families, is linked to mutations of the gene encoding transferrin receptor 2 on chromosome 7q22. Here we report data from a family carrying a new mutation of the transferrin receptor 2 gene. METHODS: Detailed clinical and histopathologic documentation was available for most family members. The entire coding sequence and exon/intron boundaries of the transferrin receptor 2 gene were analyzed by direct sequencing. RESULTS: A 12-nucleotide deletion in exon 16, causing the loss of 4 amino acids (AVAQ 594-597 del), was detected at the homozygous state in the 3 patients with histologically proven iron overload. The deletion segregated with the disease within the family and was not found in 100 healthy controls. Some clinical and pathologic characteristics, such as low penetrance in the premenopausal woman, and early iron deposition in periportal hepatocytes resembled those of classic, HFE-related hemochromatosis. CONCLUSIONS: Our data support the role of the transferrin receptor 2 gene in hemochromatosis type 3 as well as its critical involvement in the maintenance of iron homeostasis in humans.

Screening hepcidin for mutations in juvenile hemochromatosis: identification of a new mutation (C70R).

Juvenile or type 2 hemochromatosis (JH) is a genetic disease caused by increased intestinal iron absorption that leads to early massive iron overload. The main form of the disease is caused by mutations in a still unknown gene on chromosome 1q. Recently, we recognized a second type of JH with clinical features identical to the 1q-linked form, caused by mutations in the gene encoding hepcidin (HEPC). Hepcidin is a hepatic antimicrobial-like peptide whose role in iron homeostasis was first defined in animal models; deficiency of hepcidin in mice leads to iron overload, whereas its hepatic overexpression in transgenic animals causes iron deficiency. To define the prevalence of HEPC mutations in JH we screened the HEPC gene for mutation in 21 unrelated JH subjects. We identified a new mutation (C70R), which affects 1 of the 8 conserved cysteines that form the disulfide bonds and are critical for the stability of the polypeptide.

Growth hormone (GH)-induced reconstitution of CD8+ CD28+ T lymphocytes in a rare case of severe lymphopenia associated with Juvenile Haemochromatosis and Turner's syndrome.

This paper describes a rare case of Turner's syndrome associated with Juvenile Haemochromatosis and severe lymphopenia, followed-up for a period of 5 years. Because of the indication for treatment with growth hormone (GH), this case was observed as a model to analyse the effects of GH on growth, iron mobilization and lymphocyte reconstitution. For this purpose, a serial study of the T lymphocyte subpopulations CD4+, CD8+, CD8+ CD28+ and CD8+ CD28- was performed by immunophenotyping during the follow-up period. Besides the impact of both phlebotomy treatment and GH on the rapid growth and mobilization of 20.8 g of iron in 136 weeks, the most relevant observation was the finding of a significant expansion of CD8+ T lymphocytes expressing the costimulatory marker CD28 in the setting of the severe lymphopenia. These findings constitute new clinical evidence supporting the notion that the GH/IGF-1 system has an important role on the maintenance of T cell homeostasis in vivo, and that GH may be regarded as a putative therapeutic agent in T lymphocyte reconstitution.

Juvenile hemochromatosis HJV-related revealed by cardiogenic shock.

Hemochromatosis is a heterogeneous genetic disease. Juvenile hemochromatosis is a severe rare recessive autosomal disease. Herein, we report a consanguineous family linked to a mutation in the recently identified HJV gene. A refractory cardiogenic shock had revealed hemochromatosis in the proband, a 26-year-old woman, and led to the death by heart failure. Regular phlebotomies in her young sister, which was also affected, had allowed to prevent the severe complications of the disease. These two affected subjects presented an identical homozygous haplotype at the 1q21 chromosome region and a missense homozygous mutation at the HJV gene (Arg288 > Trp). This observation underlines the importance of HJV genetic testing, by complete screening of the gene, in young patients with abnormal iron parameters and hypogonadism and/or cardiac symptoms to prevent death from cardiac complications.