Treatment of severe beta-thalassemia (patients) with myleran

Sickle cell disease: progress towards combination drug therapy

Dr. John Herrick described the first clinical case of sickle cell anaemia (SCA) in the United States in 1910. Subsequently, four decades later, Ingram and colleagues characterized the A to T substitution in DNA producing the GAG to GTG codon and replacement of glutamic acid with valine in the sixth position of the β^S -globin chain. The establishment of Comprehensive Sickle Cell Centers in the United States in the 1970s was an important milestone in the development of treatment strategies and describing the natural history of sickle cell disease (SCD) comprised of genotypes including homozygous haemoglobin SS (HbSS), HbSβ⁰ thalassaemia, HbSC and HbSβ⁺ thalassaemia, among others. Early drug studies demonstrating effective treatments of HbSS and HbSβ⁰ thalassaemia, stimulated clinical trials to develop disease-specific therapies to induce fetal haemoglobin due to its ability to block HbS polymerization. Subsequently, hydroxycarbamide proved efficacious in adults with SCA and was Food and Drug Administration (FDA)-approved in 1998. After two decades of hydroxycarbamide use for SCD, there continues to be limited clinical acceptance of this chemotherapy drug, providing the impetus for investigators and pharmaceutical companies to develop non-chemotherapy agents. Investigative efforts to determine the role of events downstream of deoxy-HbS polymerization, such as endothelial cell activation, cellular adhesion, chronic inflammation, intravascular haemolysis and nitric oxide scavenging, have expanded drug targets which reverse the pathophysiology of SCD. After two decades of slow progress in the field, since 2018 three new drugs were FDA-approved for SCA, but research efforts to develop treatments continue. Currently over 30 treatment intervention trials are in progress to investigate a wide range of agents acting by complementary mechanisms, providing the rationale for ushering in the age of effective and safe combination drug therapy for SCD. Parallel efforts to develop curative therapies using haematopoietic stem cell transplant and gene therapy provide individuals with SCD multiple treatment options. We will discuss progress made towards drug development and potential combination drug therapy for SCD with the standard of care hydroxycarbamide.

Sickle Hepatopathy

Sickle hepatopathy is an umbrella term describing various pattern of liver injury seen in patients with sickle cell disease. The disease is not uncommon in India; in terms of prevalence, India is second only to Sub-Saharan Africa where sickle cell disease is most prevalent. Hepatic involvement in sickle cell disease is not uncommon. Liver disease may result from viral hepatitis and iron overload due to multiple transfusions of blood products or due to disease activity causing varying changes in vasculature. The clinical spectrum of disease ranges from ischemic injury due to sickling of red blood cells in hepatic sinusoids, pigment gall stones, and acute/chronic sequestration syndromes. The sequestration syndromes are usually episodic and self-limiting requiring conservative management such as antibiotics and intravenous fluids or packed red cell transfusions. However, rarely these episodes may present with coagulopathy and encephalopathy like acute liver failure, which are life-threatening, requiring exchange transfusions or even liver transplantation. However, evidence for their benefits, optimal indications, and threshold to start exchange transfusion is limited. Similarly, there is paucity of the literature regarding the end point of exchange transfusion in this scenario. Liver transplantation may also be beneficial in end-stage liver disease. Hydroxyurea, the antitumor agent, which is popularly used to prevent life-threatening complications such as acute chest syndrome or stroke in these patients, has been used only sparingly in hepatic sequestrations. The purpose of this review is to provide insights into epidemiology of sickle cell disease in India and pathogenesis and classification of hepatobiliary involvement in sickle cell disease. Finally, various management options including exchange transfusion, liver transplantation, and hydroxyurea in hepatic sequestration syndromes will be discussed in brief.

Molecular analysis of hemoglobinopathies in a large ethnic Hakka population in southern China

Thalassemia is an inherited autosomal recessive disorder with microcytic hypochromic anemia resulting from reduced or absent synthesis of 1 or more of the globin chains of hemoglobin. This study provided the insight into prevalence and molecular characterization of thalassemia in Hakka population. 14,524 unrelated subjects were included in our study from January 2015 to November 2017. All the subjects were detected by hematological analysis, hemoglobin electrophoresis analysis, and molecular diagnosis (gap-polymerase chain reaction and flow-through hybridization technology). Data analysis was used to compare allele frequencies between the Hakka populations. Seven thousand four hundred twenty-two cases of microcytosis were found. The percentage of microcytosis in Meizhou, Ganzhou, and Heyuan was 50.91% (6738/13,236), 51.27% (445/868), and 56.90% (239/420), respectively. A total of 5516 mutant chromosomes were identified, including 3775 α-thalassemia and 1741 β-thalassemia. --/αα was the most common α-thalassemia genotype, followed by -α/αα and -α/αα, accounted for 84.92% of α-thalassemia genotypes. Twelve kinds of mutations and 26 genotypes in β-thalassemia were found. IVS-II-654(C→T), CD41-42(-TCTT), -28(A→G), and CD17(A→T) alleles accounted for 92.65% of these mutations. IVS-II-654/N, CD41-42/N, -28/N, CD17/N genotypes accounted for 91.53% of β-thalassemia genotypes. 27 fetuses with at-risk pregnancies were subjected to prenatal diagnosis. Five fetuses were Bart's hydrops syndrome and 2 fetuses with β-thalassemia major. There were some differences in molecular characterization of thalassemia among Hakka people in different areas of southern China. Our results enriched the related information of thalassemia in the region, which provided valuable references for the prevention and control of thalassemia.

Natural Remedies for the Treatment of Beta-Thalassemia and Sickle Cell Anemia-Current Status and Perspectives in Fetal Hemoglobin Reactivation

For the treatment of β-thalassemia and sickle cell disease (SCD), pharmacological induction of fetal hemoglobin (HbF) production may be a promising approach. To date, numerous studies have been done on identifying the novel HbF-inducing agents and understanding the underlying mechanism for stimulating the HbF production. In this review, we have summarized the identified HbF-inducing agents by far. By examining the action mechanisms of the HbF-inducing agents, various studies have suggested that despite the ability of stimulating HbF production, the chemotherapeutic agents could not be practically applied for treating β-hemoglobinopathies, especially β-thalassemia, due to the their cytotoxicity and growth-inhibitory effect. Owing to this therapeutic obstacle, much effort has been put on identifying new HbF-inducing agents from the natural world with the combination of efficacy, safety, and ease of use. Therefore, this review aims to (i) reveal the novel screening platforms for identifying potential inducers with high efficiency and accuracy and to (ii) summarize the new identified natural remedies for stimulating HbF production. Hopefully, this review can provide a new insight into the current status and future perspectives in fetal hemoglobin reactivation for treating β-thalassaemia and SCD.

Emodin can induce K562 cells to erythroid differentiation and improve the expression of globin genes

In China, the traditional Chinese medicine "YiSui ShenXu Granule" has been used for treating β-thalassemia over 20 years and known to be effective in clinic. Several purified components from "YiSui ShenXu Granule" are tested in K562 cells to reveal its effect on globin expression and erythroid differentiation, and one of the purified components, emodin, was demonstrated to increase the expression of α-, ε-, γ-globin, CD235a, and CD71 in K562 cells. Moreover, the increase of their expression is emodin concentration-dependent. The mRNA and microRNA (miRNA) expression profiles are further analyzed and 417 mRNAs and 35 miRNAs with differential expression between untreated and emodin-treated K562 cells were identified. Among them, two mRNAs that encode known positive regulators of erythropoiesis, ALAS2, and c-KIT respectively, increased during emodin-induced K562 erythroid differentiation, meanwhile, two negative regulators, miR-221 and miR-222, decreased during this process. These results indicate that emodin can improve the expression of globin genes in K562 cells and also induce K562 cells to erythroid differentiation possibly through up-regulating ALAS2 and c-KIT and down-regulating miR-221 and miR-222.

FK228 Analogues Induce Fetal Hemoglobin in Human Erythroid Progenitors

Fetal hemoglobin (HbF) improves the clinical severity of sickle cell disease (SCD), therefore, research to identify HbF-inducing agents for treatment purposes is desirable. The focus of our study is to investigate the ability of FK228 analogues to induce HbF using a novel KU812 dual-luciferase reporter system. Molecular modeling studies showed that the structure of twenty FK228 analogues with isosteric substitutions did not disturb the global structure of the molecule. Using the dual-luciferase system, a subgroup of FK228 analogues was shown to be inducers of HbF at nanomolar concentrations. To determine the physiological relevance of these compounds, studies in primary erythroid progenitors confirmed that JMA26 and JMA33 activated HbF synthesis at levels comparable to FK228 with low cellular toxicity. These data support our lead compounds as potential therapeutic agents for further development in the treatment of SCD.

Molecular pharmacological basis of the YiSui ShenXu Granule in beta-thalassemia therapy

OBJECTIVES

To study the molecular pharmacological basis of the YiSui ShenXu Granule, a complex prescription of the Chinese traditional medicine used to treat beta-thalassemia.

METHODS

Real-time quantitative PCR method had been applied to analyze the genes expression: gamma-globin, Ckit, EpoR, Spi, FKLF, GATA1 and GATA2 in K562 cell treated and untreated with this complex prescription and its each single herbal medicine.

RESULTS

The results showed that this complex prescription increased the gamma-globin, EpoR, Spi and FKLF expression and decreased the Ckit, GATA1 and GATA2 expression. And all single herbal medicines of this complex prescription could change some of those gene expressions, but not the same as the complex prescription. Even that, this study results indicated that the YiSui ShenXu Granule has its molecular pharmacological basis in treating beta-thalassemia.

A cell stress signaling model of fetal hemoglobin induction: what doesn't kill red blood cells may make them stronger

A major goal of hemoglobinopathy research is to develop treatments that correct the underlying molecular defects responsible for sickle cell disease and beta-thalassemia. One approach to achieving this goal is the pharmacologic induction of fetal hemoglobin (HbF). This strategy is capable of inhibiting the polymerization of sickle hemoglobin and correcting the globin chain imbalance of beta-thalassemia. Despite this promise, none of the currently available HbF-inducing agents exhibit the combination of efficacy, safety, and convenience of use that would make them applicable to most patients. The recent success of targeted drug therapies for malignant diseases suggests that this approach could be effective for developing optimal HbF-inducing agents. A first step in applying this approach is the identification of specific molecular targets. However, while >70 HbF-inducing agents have been described, neither molecular mechanisms nor target molecules have been definitively verified for any of these compounds. To help focus investigation in this area, we have reviewed known HbF-inducing agents and their proposed mechanisms of action. We find that in many cases, current models inadequately explain key experimental results. By integrating features of the erythropoietic stress model of HbF induction with data from recent intracellular signaling experiments, we have developed a new model that has the potential to explain several findings that are inconsistent with previous models and to unify most HbF-inducing agents under a common mechanism: cell stress signaling. If correct, this or related models could lead to new opportunities for development of targeted therapies for the beta-hemoglobinopathies.

Understanding mechanisms of gamma-globin gene regulation to develop strategies for pharmacological fetal hemoglobin induction

The developmental regulation of gamma-globin gene expression has shaped research efforts to establish therapeutic modalities for individuals affected with sickle cell disease (SCD). Fetal hemoglobin (Hb F) synthesis is high at birth, followed by a decline to adult levels by 10 months of age. The expression of gamma-globin is controlled by a developmentally regulated transcriptional program that is recapitulated during normal erythropoiesis in the adult bone marrow. It is known that naturally occurring mutations in the gamma-gene promoters cause persistent Hb F synthesis after birth, which ameliorates symptoms in SCD by inhibiting hemoglobin S polymerization and vaso-occlusion. Several pharmacological agents have been identified over the past 2 decades that reactivate gamma-gene transcription through different cellular systems. We will review the progress made in our understanding of molecular mechanisms that control gamma-globin expression and insights gained from Hb F-inducing agents that act through signal transduction pathways.

Effect of fetal hemoglobin-stimulating medicines on the interaction of DNA and protein of important erythroid regulatory elements

β-Thalassemia is the most common single gene disorder in the world, which is caused by the imbalance between α-globin chain and β-globin chain synthesis. Several medicines, such as 5-azacytidine, hydroxyurea, cytarabine, vinblatine, butyrate, and myleran, have been shown to be able to reactivate γ-globin chain synthesis during the adult stage, and some of them (5-azacytidine, hydroxyurea, myleran, and butyrate) have been used clinically to treat thalas semia and sickle cell disease. Much research efforts are focusing on the determination of the underlying mechanisms of medicine action. In this experiment, as an effort to probe the underlying mechanism of medicine action, we used ligation-mediated polymerase chain reaction and in vivo footprinting methods to study the DNA-protein interaction at critical erythroid regulatory elements after hydroxyurea or myleran administration to mice. Our results showed that the patterns of in vivo footprints at both the hypersensitive site 2 of the locus control region and the β-globin gene promoter were changed after medicine treatment. We proposed based on these results that the medicines' administration might result in a change in the interaction between trans-acting factors and cis-acting elements at these regions. These changes might influence the assembly of the transcription complex and, lastly, influence the expression of the β-globin gene.Key words: hydroxyurea, in vivo footprinting, ligation-mediated PCR, LCR, β-globin.

Prospects of chimeric RNA-DNA oligonucleotides in gene therapy

A strategy called targeted gene repair was developed to facilitate the process of gene therapy using a chimeric RNA-DNA oligonucleotide. Experiments demonstrated the feasibility of using the chimeric oligonucleotide to introduce point conversion in genes in vitro and in vivo. However, barriers exist in the low and/or inconstant frequency of gene repair. To overcome this difficulty, three main aspects should be considered. One is designing a more effective structure of the oligonucleotide. Trials have included lengthening the homologous region, displacing the mismatch on the chimeric strand and inventing a novel thioate-modified single-stranded DNA, which was demonstrated to be more active than the primary chimera in cell-free extracts. The second aspect is optimizing the delivery system. Producing synthetic carriers for efficient and specific transfection is demanding, especially for treatment in vivo where targeting is difficult. The third and most important aspect lies in the elucidation of the mechanism of the strategy. Investigation of the mechanism of strand exchange between the oligonucleotide molecule and double-stranded DNA in prokaryotes may greatly help to understand the mechanism of gene repair in eukaryotes. The development of this strategy holds great potential for the treatment of genetic defects and other purposes.

Targeted correction of the point mutations of beta-thalassemia and targeted mutagenesis of the nucleotide associated with HPFH by RNA/DNA oligonucleotides: potential for beta-thalassemia gene therapy

An RNA/DNA chimeric oligonucleotide was found to be effective in the targeted correction of point mutations in Escherichia coli, plant, and mammalian genomes. This strategy, named chimeraplasty, has the potential for gene therapy of many genetic diseases caused by point mutations. beta-Thalassemia is a very common human genetic disease and in most cases it is caused by point mutations. To test whether the chimeraplasty can be used to correct the point mutations responsible for beta-thalassemia, we introduced one mutated beta-globin gene, betaE, into MEL cells and successfully corrected the point mutation of the betaE gene with the highest correction efficiency of 1.9%. Furthermore, a targeted -202 C-->G mutation of the Ggamma-globin gene, which is associated with the elevated Ggamma-globin gene expression in the adult stage, was introduced into HeLa and CMK cells by an RNA/DNA oligonucleotide. These results indicated that the chimeraplasty has potential for human beta-thalassemia gene therapy.

Pharmacological therapy

Collectively sickle cell disease and beta-thalassaemia are the most commonly inherited single-gene defects world-wide and were the first group of diseases for which DNA-based detection strategies were utilized. Although genotypically distinct, these two groups of diseases exhibit several common clinical features: moderate-to-severe haemolytic anaemia, acute and progressive tissue damage, disease- or treatment-related organ failure and premature death. Within the last two decades, a striking improvement in life expectancy in the two patient populations has been observed, by dint of primary and secondary prevention strategies. However, apart from bone marrow transplantation, a generally applicable, specific and non-toxic form of treatment remains unavailable for these disorders. Nonetheless, a greater appreciation of the developmental control of human globin gene expression coupled with observations of the effects of certain classes of agents to 'reverse' erythroid cellular phenotype in in vitro and animal models have led to pharmacological trials to obtain meaningful increases in haemoglobin F production in patients affected by these two severe beta-globin disorders. Contemporary understanding of the quantitative relationship between the abnormal molecules in the red cells (aggregates of sickle haemoglobin) in the sickle cell syndromes and aggregated alpha-globin polypeptides in the beta-thalassemia syndromes, and the extent of the red cell and/or organ involvement, has now enabled investigators to predict how much inhibition of these intracellular pathogenic processes might be necessary to achieve partial or total abrogation of disease manifestations. The results of the Multicenter Study of Hydroxyurea and other controlled trials now bear out these predictions.

Effect of hydroxyurea on the frequency of painful crises in sickle cell anemia. Investigators of the Multicenter Study of Hydroxyurea in Sickle Cell Anemia

BACKGROUND

In a previous open-label study of hydroxyurea therapy, the synthesis of fetal hemoglobin increased in most patients with sickle cell anemia, with only mild myelotoxicity. By inhibiting sickling, increased levels of fetal hemoglobin might decrease the frequency of painful crises.

METHODS

In a double-blind, randomized clinical trial, we tested the efficacy of hydroxyurea in reducing the frequency of painful crises in adults with a history of three or more such crises per year. The trial was stopped after a mean follow-up of 21 months.

RESULTS

Among 148 men and 151 women studied at 21 clinics, the 152 patients assigned to hydroxyurea treatment had lower annual rates of crises than the 147 patients given placebo (median, 2.5 vs. 4.5 crises per year, P < 0.001). The median times to the first crisis (3.0 vs. 1.5 months, P = 0.01) and the second crisis (8.8 vs. 4.6 months, P < 0.001) were longer with hydroxyurea treatment. Fewer patients assigned to hydroxyurea had chest syndrome (25 vs. 51, P < 0.001), and fewer underwent transfusions (48 vs. 73, P = 0.001). At the end of the study, the doses of hydroxyurea ranged from 0 to 35 mg per kilogram of body weight per day. Treatment with hydroxyurea did not cause any important adverse effects.

CONCLUSIONS

Hydroxyurea therapy can ameliorate the clinical course of sickle cell anemia in some adults with three or more painful crises per year. Maximal tolerated doses of hydroxyurea may not be necessary to achieve a therapeutic effect. The beneficial effects of hydroxyurea do not become manifest for several months, and its use must be carefully monitored. The long-term safety of hydroxyurea in patients with sickle cell anemia is uncertain.

Sickle cell disease pathophysiology

The primary pathophysiological event in the erythrocytes of individuals with the various sickle syndromes is the intracellular aggregation or polymerization of sickle haemoglobin (HbS). The extent of polymerization is determined by the intracellular haemoglobin composition (% HbS and % HbS A, A2 and F), concentration (MCHC and % of dense cells) and oxygen saturation, as well as minor factors such as intracellular pH and DPG concentration. Intracellular HbS polymerization leads to a marked decrease in the flexibility or rheological properties of the sickle erythrocytes and obstruction in various microcirculatory beds, as well as chronic anaemia. Other abnormalities in the properties of the sickle erythrocytes, including membrane abnormalities, changes in ion fluxes and volume and endothelial adhesion, result from acute and chronic oxygen-linked polymerization events and may, in turn, modify polymerization. However, within a good approximation, many aspects of sickle cell disease pathophysiology--for example variations in anaemia among the different sickle syndromes--can be explained in terms of differences in polymerization tendency. Thus, the effects of alpha-thalassaemia can be explained with reference to changes in MCHC and syndromes with high HbF are understandable in terms of the sparing effect of HbF on polymerization. Recent therapeutic approaches to sickle cell disease focus on attempts to reduce intracellular HbS polymerization by altering the haemoglobin molecules, erythrocyte properties, or the distribution of intracellular haemoglobin species. The last, through pharmacological elevation of HbF, has become the central focus of much laboratory and clinical research in recent years. Agents such as hydroxyurea (with or without recombinant erythropoietin) and butyrate compounds elevate HbF (and reduce HbS) in a majority of sickle erythrocytes, thus decreasing intracellular polymerization. Current prospective protocols are designed to see if these changes cause clinical improvement at acceptable doses. Other treatment strategies, including bone marrow transplantation and possible gene replacement therapies, are also under active clinical or laboratory investigation.