Correction of phenotype in a thalassemia mouse model using a nonmyeloablative marrow transplantation regimen

A comprehensive review on the composition, biogenesis, purification, and multifunctional role of exosome as delivery vehicles for cancer therapy

All forms of life produce nanosized extracellular vesicles called exosomes, which are enclosed in lipid bilayer membranes. Exosomes engage in cell-to-cell communication and participate in a variety of physiological and pathological processes. Exosomes function via their bioactive components, which are delivered to target cells in the form of proteins, nucleic acids, and lipids. Exosomes function as drug delivery vehicles due to their unique properties of innate stability, low immunogenicity, biocompatibility, biodistribution, accumulation in desired tissues, low toxicity in normal tissues, and the stimulation of anti-cancer immune responses, and penetration capacity into distance organs. Exosomes mediate cellular communications by delivering various bioactive molecules including oncogenes, oncomiRs, proteins, specific DNA, messenger RNA (mRNA), microRNA (miRNA), small interfering RNA (siRNA), and circular RNA (circRNA). These bioactive substances can be transferred to change the transcriptome of target cells and influence tumor-related signaling pathways. After considering all of the available literature, in this review we discuss the biogenesis, composition, production, and purification of exosomes. We briefly review exosome isolation and purification techniques. We explore great-length exosomes as a mechanism for delivering a variety of substances, including proteins, nucleic acids, small chemicals, and chemotherapeutic drugs. We also talk about the benefits and drawbacks of exosomes. This review concludes with a discussion future perspective and challenges. We hope that this review will provide us a better understanding of the current state of nanomedicine and exosome applications in biomedicine.

Allogeneic bone marrow transplant in the absence of cytoreductive conditioning rescues mice with β-thalassemia major

β-thalassemia is a group of inherited blood disorders that result in defects in β-globin chain production. Cooley anemia (CA), or β-thalassemia major, is the most severe form of the disease and occurs when an individual has mutations in both copies of the adult β-globin gene. Patients with CA fail to make adult hemoglobin, exhibit ineffective erythropoiesis, experience severe anemia, and are transfusion dependent for life. Currently, allogeneic bone marrow transplantation (BMT) is the only cure; however, few patients have suitable donors for this procedure, which has significant morbidity and mortality. In this study, a novel humanized murine model of CA is rescued from lethal anemia by allogeneic BMT in the absence of cytoreductive conditioning. A single intravenous postnatal injection of allogeneic bone marrow results in stable, mixed hematopoietic chimerism. Five months after transplantation, donor cells accounted for approximately 90% of circulating erythrocytes and up to 15% of hematopoietic stem and progenitor cells. Transplanted mice are transfusion independent, have marked improvement of hematological indices, exhibit no growth retardation or signs of graft-versus-host disease, and are fertile. This study describes a method for the consistent engraftment of allogeneic donor hematopoietic cells that rescues a humanized mouse model of CA from lethal anemia, all in the absence of toxic cytoreductive conditioning.

Pretransplant immunosuppression followed by reduced-toxicity conditioning and stem cell transplantation in high-risk thalassemia: a safe approach to disease control

Patients with class 3 thalassemia with high-risk features for adverse events after high-dose chemotherapy with hematopoietic stem cell transplantation (HSCT) are difficult to treat, tending to either suffer serious toxicity or fail to establish stable graft function. We performed HSCT in 18 such patients age ≥7 years and hepatomegaly using a novel approach with pretransplant immunosuppression followed by a myeloablative reduced-toxicity conditioning regimen (fludarabine and i.v. busulfan [Flu-IV Bu]) and then HSCT. The median patient age was 14 years (range, 10 to 18 years). Before the Flu-IV Bu + antithymocyte globulin conditioning regimen, all patients received 1 to 2 cycles of pretransplant immunosuppression with fludarabine and dexamethasone. Thirteen patients received a related donor graft, and 5 received an unrelated donor graft. An initial prompt engraftment of donor cells with full donor chimerism was observed in all 18 patients, but 2 patients developed secondary mixed chimerism that necessitated withdrawal of immunosuppression to achieve full donor chimerism. Two patients (11%) had acute grade III-IV graft-versus-host disease, and 5 patients had limited chronic graft-versus-host disease. The only treatment-related mortality was from infection, and with a median follow-up of 42 months (range, 4 to 75), the 5-year overall survival and thalassemia-free survival were 89%. We conclude that this novel sequential immunoablative pretransplantation conditioning program is safe and effective for patients with high-risk class 3 thalassemia exhibiting additional comorbidities.

Correction of murine β-thalassemia after minimal lentiviral gene transfer and homeostatic in vivo erythroid expansion

A challenge for gene therapy of genetic diseases is to maintain corrected cell populations in subjects undergoing transplantation in cases in which the corrected cells do not have intrinsic selective advantage over nontransduced cells. For inherited hematopoietic disorders, limitations include inefficient transduction of stem cell pools, the requirement for toxic myelosuppression, and a lack of optimal methods for cell selection after transduction. Here, we have designed a lentiviral vector that encodes human β-globin and a truncated erythropoietin receptor, both under erythroid-specific transcriptional control. This truncated receptor confers enhanced sensitivity to erythropoietin and a benign course in human carriers. Transplantation of marrow transduced with the vector into syngenic thalassemic mice, which have elevated plasma erythropoietin levels, resulted in long-term correction of the disease even at low ratios of transduced/untransduced cells. Amplification of the red over the white blood cell lineages was self-controlled and averaged ∼ 100-fold instead of ∼ 5-fold for β-globin expression alone. There was no detectable amplification of white blood cells or alteration of hematopoietic homeostasis. Notwithstanding legitimate safety concerns in the context of randomly integrating vectors, this approach may prove especially valuable in combination with targeted integration or in situ homologous recombination/repair and may lower the required level of pretransplantation myelosuppression.

Nonengraftment haploidentical cellular immunotherapy for refractory malignancies: tumor responses without chimerism

Allogeneic bone marrow transplantation relies on immunosuppression, which controls graft-versus-host disease (GVHD) and allows engraftment at the expense of diminished graft versus-tumor (GVT) activity. Advances in hematologic transplantation have prompted the development of effective, less-toxic regimens that attempt to balance GVH and GVT immunoreactions. We analyzed the safety and efficacy of haploidentical transplantation in a Phase I/II nonimmunosuppressive, nonmyeloablative setting. A total of 41 patients with relapsed refractory cancer received 100 cGy of total body irradiation (TBI), along with an infusion of 1 x 10(6) to 2 x 10(8) CD3+ cells/kg; 29 patients received the highest dose. A postinfusional cellular graft rejection syndrome resembling engraftment syndrome was noted at the 2 highest CD3+ infusion cohorts. There were 26 patients with hematologic malignancies with 14 responses, 9 of which were major. Two of 6 patients with lymphoma remained free of disease at 76 months and 82 months, respectively; there were 5 durable complete responses and 4 partial responses in 13 patients with acute myelogenous leukemia (AML). All responses occurred outside of donor chimerism. TBI at 100 cGy followed by HLA-haploidentical immunotherapy is a biologically active therapy for patients with refractory AML and lymphoma. Possible mechanisms contributing to its effectiveness include initial GVT kill, breaking of host tolerance to tumor through cross-reactive alloreactive responses, persistent nondetectable microchimerism, or some combination of these.

Reduced intensity and non-myeloablative allogeneic stem cell transplantation in children and adolescents with malignant and non-malignant diseases

Allogeneic hematopoietic stem cell transplant (AlloSCT) from related or unrelated histocompatible donors has been well established as potentially curative therapy for children and adolescents with selected malignant and non-malignant diseases. In the malignant setting non-myeloablative (NMA)/reduced intensity (RI)-AlloSCT eradicates malignant cells through a graft versus malignancy effect provided by alloreactive donor T-lymphocytes and/or natural killer cells. In patients with non-malignant diseases NMA/RI AlloSCT provides enough immunosuppression to promote engraftment and correct underlying genetic defects. In children, myeloablative AlloSCT is not only associated with acute short-term toxicities but also long-term late complications such as growth retardation, infertility, and secondary malignancies. NMA/RI-AlloSCT in children may be associated with reduction in use of blood products, risk of infections, transplant-related mortality, and length of hospitalization. Despite the success of RI-AlloSCT in adults, large prospective and/or randomized multicenter studies are necessary in children and adolescent recipients to define the appropriate patient population, optimal conditioning regimens, cost-benefits, survival and differences in short-term and long-term effects compared to conventional myeloablative conditioning.

Reduced intensity stem cell transplantation for treatment of class 3 Lucarelli severe thalassemia patients

Bone marrow transplantation is the only therapeutic option that can potentially eliminate thalassemic disease. Early results indicated that children in Class 3 Lucarelli had a much worse outcome because of high nonrejection mortality and high rejection rate. In the present study, reduced intensity stem cell transplantation (RIT) was performed in eight Class 3 Lucarelli patients conditioned by busulfan, fludarabine, and antilymphpcute globulin. One of the eight patients additionally received thiotepa, and total lymphoid irradiation (TLI), while one only received TLI. All patients received hydroxyurea 20 mg/kg/day daily >/=3 months before RIT. Peripheral blood stem cell (PBSCs) were given to a target number of CD34(+) cells more than 5 x 10(6) cells/kg of recipient weight. Seven patients received T cell nondepleted PBSCs from matched siblings while one patient received purified CD34(+) cells from two HLA antigen mismatched maternal PBSCs. The graft-versus-host disease (GvHD) prophylaxis included cyclosporine or tacrolimus and mycophenolate mofetil. Initially, an engraftment of donor cells was observed in all eight patients, but subsequently only six of eight patients had stable full donor engraftment. There were no deaths or Grade 3-4 acute GvHD in our patients. The present study lends support that the regimens described here produced minimal toxicity and resulted in stable full donor engraftment in the majority of the severe Class 3 Lucarelli thalassemia patients.

Reduced intensity allogeneic umbilical cord blood transplantation in children and adolescent recipients with malignant and non-malignant diseases

There is a significant amount of morbidity and mortality following myeloablative umbilical cord blood transplantation (UCBT). Reduced intensity (RI) conditioning offers an alternative to myeloablative conditioning before UCBT. We investigated RI-UCBT in 21 children and adolescents with malignant (n=14), and non-malignant diseases (n=7). RI conditioning consisted of fludarabine (150-180 mg/m2) with either busulfan (< or = 8 mg/kg)+rabbit antithymocyte globulin (R-ATG; n=16) or cyclophosphamide+R-ATG+/-etoposide (n=5). Human leukocyte antigen match: 4/6 (n=13), 5/6 (n=5) and 6/6 (n=3). The median total nucleated cell and CD34+ cell dose per kilogram were 3.58 x 10(7) and 2.54 x 10(5), respectively. The median time for neutrophil and platelet engraftment was 17.5 and 52 days, respectively. There were six primary graft failures (chronic myelogenous leukemia (CML), beta-thalassemia, hemophagocytic lymphohistiocytosis (HLH) and myelodysplastic syndrome (MDS)). The probability of developing grade II to grade IV acute graft-versus-host disease (GVHD) and chronic GVHD was 28.6 and 16.7%, respectively. Incidence of transplant-related mortality (TRM) was 14%. The 5 years overall survival (OS) in all patients was 59.8%. The 5 years OS for patients with average versus poor-risk malignancy was 77.8 versus 22.2% (P=0.03). RI-UCBT may result in graft failure in specific high-risk chemo-naïve patients (CML, beta-thalassemia, HLH and MDS), but in more heavily pretreated pediatric and adolescent recipients results in rapid engraftment and may be associated with decreased severe GVHD and TRM.

Long-term correction of beta-thalassemia with minimal cellular requirement and transplantation modalities

Determination of minimal criteria, pre-transplantation regimens, and infusion modalities for effective and reproducible bone marrow (BM) therapy in beta-thalassemia is of fundamental importance for clinical application. In this study, using repopulation assays, we first established the minimal proportion of normal BM stem cells that would result in therapeutic benefit in this red blood cell (RBC) disorder. Eight groups of stable chimeric hemizygous beta-thalassemic (hemi-betathal) mice (10-89%) were systematically subjected to cellular, molecular, and patho-physiologic analyses for approximately 2 years. In the chimeric hemi-betathal groups containing 19-24% normal donor cells, all RBC parameters and consequent erythropoiesis were significantly improved. Mice in the 24% chimeric group and above had marked reduction in organ pathology including iron deposits, and survived to a normal lifespan. Altogether, these results established that a range of 19-24% normal BM cells is sufficient for long-term significant correction of the hemi-betathal phenotype. We also determined concomitantly the minimal myelosuppression radiation doses, the number of cells to be infused, and the number of infusions required in order to attain this therapeutic range in hemi-betathal mice. Importantly, with prior minimal myelosuppression with 1 or 2 Gy, and using cell doses of 40 or 60 millions, 100% of the recipients were successfully engrafted at therapeutic levels, provided the cells were administered in two doses. This study has therefore determined the therapeutic chimeric level as 19-24% of normal cells, and has also defined the minimal transplantation modalities necessary for the stable and successful correction of the hemi-betathal phenotype.

Murine and math models for the level of stable mixed chimerism to cure beta-thalassemia by nonmyeloablative bone marrow transplantation

Stable mixed chimeric stem cell transplantation in hemoglobinopathies exploits shorter erythroid survival in hemolytic anemias, providing normal donor red blood cells with a competitive survival advantage. This study examined the level of stable mixed chimerism necessary for complete hematological cure of the thalassemic phenotype, using a nonmyeloablative busulfan chemotherapeutic preparation. Thalassemic mice transplanted from congenic wild-type donors developed partial mixed chimerism. Hematologic cure required >80% donor red blood cells and only >13% donor white blood cells. Murine and human transplant results were compared with a math model for survival advantage of donor peripheral blood cells produced by steady-state chimeric marrow.

Developmental changes in integrated ultrasound backscatter from embryonic blood in vivo in mice at high US frequency

Mouse blood imaged using high-frequency ultrasound (US) is more echogenic in embryos than in adults. Studying changes in blood echogenicity in embryos may be of fundamental interest in studies on the genetic regulation of normal and abnormal blood development in mutant mice. Embryonic red blood cells (RBCs) are large and nucleated in midgestation but decrease in size and become enucleated as they mature. We therefore hypothesised that these structural alterations are responsible for variations in echogenicity of embryonic blood with gestational age and development. The objective of the current study was to quantify these structural changes in echogenicity (echo brightness) and apparent integrated backscatter (AIB) from embryonic blood at high US frequencies in vivo in mice. Results from anaesthetised pregnant mice studied using transcutaneous US showed that echogenicity of embryonic blood in the heart, aorta and umbilical cord and AIB within the heart chambers peaked at embryonic day (ED) 13.5 and then decreased progressively toward term. Between EDs 13.5 and 17.5 (near term), RBC mean cell volume decreased from 133 to 109 fL, haematocrit increased from 12 to 34%, and the percentage of nucleated RBCs decreased from 59 to 2%. Relative to younger ages, RBC nuclei at ED 13.5 were small and dense (pyknotic) which may have contributed to the peak in echogenicity and AIB at this age. To calculate the AIB, radiofrequency (RF) signals with centre frequencies of 28 MHz and 35 MHz were integrated over the 16- to 35-MHz and 21- to 42-MHz frequency range, respectively. At 28 MHz, mean apparent integrated backscatter of blood in the embryonic heart increased significantly from 0.0023 +/- 0.0004 Sr.cm(-1) (mean +/- SEM) at ED 12.5 to peak at 0.0037 +/- 0.0005 Sr.cm(-1) at ED 13.5. The mean AIB then decreased progressively with advancing gestation to 0.0002 +/- 0.0001 Sr.cm(-1) at ED 17.5. At 35 MHz, the mean AIB changed similarly with gestational age, except that values were lower than at 28 MHz at all ages. Higher attenuation of US at 35 MHz than at 28 MHz in tissue likely accounted for the lower AIB of blood insonified at 35 MHz. We speculate that developmental changes in red cell morphology are responsible for the observed changes in echogenicity and AIB of embryonic blood with gestational age in mice.

Murine marrow cellularity and the concept of stem cell competition: geographic and quantitative determinants in stem cell biology

In unperturbed mice, the marrow cell numbers correlate with the stem cell numbers. High levels of long-term marrow engraftment are obtained with infusion of high levels of marrow cells in untreated mice. To address the issue of stem cell competition vs 'opening space', knowledge of total murine marrow cellularity and distribution of stem and progenitor cells are necessary. We determined these parameters in different mouse strains. Total cellularity in BALB/c mice was 530+/-20 million cells; stable from 8 weeks to 1 year of age. C57BL/6J mice had 466+/-48 million marrow cells. Using these data, theoretical models of infused marrow (40 million cells) replacing or adding to host marrow give chimerism values of 7.5 and 7.0%, respectively; the observed 8-week engraftment of 40 million male BALB/c marrow cells into female hosts (72 mice) gave a value of 6.91+/-0.4%. This indicates that syngeneic engraftment is determined by stem cell competition. Our studies demonstrate that most marrow cells, progenitors and engraftable stem cells are in the spine. There was increased concentration of progenitors in the spine. Total marrow harvest for stem cell purification and other experimental purposes was both mouse and cost efficient with over a four-fold decrease in animal use and a financial saving.