Neonatal rhesus monkeys as an animal model for rotavirus infection

AIM To establish a rotavirus(RV)-induced diarrhea model using RV SA11 in neonatal rhesus monkeys for the study of the pathogenic and immune mechanisms of RV infection and evaluation of candidate vaccines.METHODS Neonatal rhesus monkeys with an average age of 15-20 d and an average weight of 500 g ± 150 g received intragastric administration of varying doses of SA11 RV( 107 PFUs/mL, 106 PFUs/mL, or 105 PFUs/mL, 10 mL/animal) to determine whether the SA11 strain can effectively infect these animals by observing their clinical symptoms, fecal shedding of virus antigen by ELISA, distribution of RV antigen in the organs by immunofluorescence, variations of viral RNA load in the organs by qRT-PCR, histopathological changes in the small intestine by HE staining, and apoptosis of small intestinal epithelial cells by TUNEL assay.RESULTS The RV monkey model showed typical clinical diarrhea symptoms in the 108 PFUs SA11 group, where we observed diarrhea 1-4 d post infection(dpi) and viral antigen shed in the feces from 1-7 dpi. RV was found in jejunal epithelial cells. We observed a viral load of approximately 5.85 × 103 copies per 100 mg in the jejunum at 2 dpi, which was increased to 1.09 × 105 copies per 100 mg at 3 dpi. A relatively high viral load was also seen in mesenteric lymph nodes at 2 dpi and 3 dpi. The following histopathological changes were observed in the small intestine following intragastric administration of SA11 RV: vacuolization, edema, and atrophy. Apoptosis in the jejunal villus epithelium was also detectable at 3 dpi.CONCLUSION Our results indicate that we have successfully established a RV SA11 strain diarrhea model in neonatal rhesus monkeys. Future studies will elucidate the mechanisms underlying the pathogenesis of RV infection, and we will use the model to evaluate the protective effect of candidate vaccines.     

The woodchuck as an animal model for pathogenesis and therapy of chronic hepatitis B virus infection

INTRODUCTION Infection of adult humans with the hepatitis B virus (HBV) results characteristically in self-limited hepatic disease with recovery based on serological and clinical parameters. Progression to chronic HBV infection occurs infrequently in infe…     

Factor IX variants improve gene therapy efficacy for hemophilia B

Intramuscular injection of adeno-associated viral (AAV) vector to skeletal muscle of humans with hemophilia B is safe, but higher doses are required to achieve therapeutic factor IX (F.IX) levels. The efficacy of this approach is hampered by the retention of F.IX in muscle extracellular spaces and by the limiting capacity of muscle to synthesize fully active F.IX at high expression rates. To overcome these limitations, we constructed AAV vectors encoding F.IX variants for muscle- or liver-directed expression in hemophilia B mice. Circulating F.IX levels following intramuscular injection of AAV-F.IX-K5A/V10K, a variant with low-affinity to extracellular matrix, were 2-5 fold higher compared with wild-type (WT) F.IX, while the protein-specific activities remained similar. Expression of F.IX-R338A generated a protein with 2- or 6-fold higher specific activity than F.IX-WT following vector delivery to skeletal muscle or liver, respectively. F.IX-WT and variant forms provide effective hemostasis in vivo upon challenge by tail-clipping assay. Importantly, intramuscular injection of AAV-F.IX variants did not trigger antibody formation to F.IX in mice tolerant to F.IX-WT. These studies demonstrate that F.IX variants provide a promising strategy to improve the efficacy for a variety of gene-based therapies for hemophilia B.     

Preclinical animal models for hemophilia gene therapy: predictive value and limitations

Hemophilia A and B are excellent candidate disorders for the application of somatic cell gene therapy. One of the major advantages in the preclinical development of hemophilia gene therapy strategies has been the availability of several animal models for both hemophilia A and B. These models recapitulate many of the phenotypic aspects of human hemophilia and have proven to be very informative in exploring the efficacy and safety of gene therapy. Considerable progress has been made in the design of gene therapy protocols, and over the last 5 years it has been shown that long-term phenotypic correction, with sustained therapeutic levels of factor VIII (FVIII) and factor IX (FIX), can be attained in FVIII- and FIX-deficient mice and dogs using various viral vector-mediated gene therapy approaches. These animal models also have elucidated potential complications of gene therapy protocols, including acute vector-associated toxicities and the induction of neutralizing antibodies to the FVIII and FIX transgene products. Nevertheless, although the preclinical paradigm of hemophilic mouse followed by hemophilic dog studies has proven to be extremely helpful in evaluating the efficacy and safety of potential clinical gene therapy protocols, several limitations to these animal models still exist. This review presents a summary of the animal models available for hemophilia gene therapy, and highlights the various strengths and weaknesses of these models.     

A factor IX-deficient mouse model for hemophilia B gene therapy

We have generated a mouse where the clotting factor IX (FIX) gene has been disrupted by homologous recombination. The FIX nullizygous (−/−) mouse was devoid of factor IX antigen in plasma. Consistent with the bleeding disorder, the factor IX coagulant activities for wild-type (+/+), heterozygous (+/−), and homozygous (−/−) mice were 92%, 53%, and <5%, respectively, in activated partial thromboplastin time assays. Plasma factor IX activity in the deficient mice (−/−) was restored by introducing wild-type murine FIX gene via adenoviral vectors. Thus, these factor IX-deficient mice provide a useful animal model for gene therapy studies of hemophilia B.     

Immune implications of gene therapy for hemophilia

Similar to any novel treatment strategy for hemophilia, gene therapy faces the question of the risk of formation of inhibitory antibodies to the therapeutic factor VIII or factor IX protein. Activation of CD4 (+) or CD8 (+) T cells could lead to antibody formation or cytotoxic T lymphocyte responses to transgene-expressing cells. Preclinical studies in animal models of hemophilia A and B with different mutations in the dysfunctional gene shed light on the risk for such immune responses and point toward strategies to avoid immune activation or even promote tolerance induction. The impacts of variables such as choice and design of gene transfer vector, underlying gene mutation, route of vector administration, and transient immune suppression are discussed. Maintenance of immunological hyporesponsiveness to the therapeutic gene product is critical for successful gene therapy. Recent studies provide evidence for tolerance induction to coagulation factor antigens by viral hepatic or neonatal in vivo gene transfer, by in utero gene delivery, and by oral or nasal administration of protein or peptides.     

Clinical gene transfer studies for hemophilia B

Hemophilia B, a deficiency of functional factor IX (FIX), has been extensively explored as a model for gene transfer. Two U.S. Food and Drug Administration-approved clinical studies for hemophilia B have been undertaken, both using adeno-associated viral vectors (AAV). AAV vectors have tropism for liver, muscle, central nervous system, and the respiratory tract; both skeletal muscle and liver have been used as target tissues in the hemophilia B studies. In both studies, proof of principle was first established in the hemophilia B dog model, with long-term expression of canine FIX at therapeutic levels achieved before clinical studies were initiated. In the AAV-FIX muscle trial, vector was introduced into skeletal muscle of the upper and lower extremities of eight human patients by direct intramuscular injection. Muscle biopsies taken 2 to 10 months postinjection demonstrated gene transfer and expression (by Southern blot and immunofluorescence, respectively) in all patients, but circulating FIX levels were generally not >1%, and escalation of dose to levels that proved therapeutic in animals was thwarted by feasibility issues regarding the number of injections required. Nevertheless, the study demonstrated that parenteral injection of AAV-FIX was safe at the doses tested, and could result in long-term expression of the transgene. Moreover, the general characteristics of transduction of human muscle were similar to those observed in other animal models. The safety and efficacy data established in the first trial formed the basis for a second trial in which AAV-FIX is administered systemically to target the liver. The liver study is currently ongoing, with six patients enrolled to date.     

Adeno-associated virus-mediated gene transfer for hemophilia B

Hemophilia is the bleeding diathesis caused by mutations in the gene encoding factor VIII (hemophilia A) or factor IX (hemophilia B). Currently, the disease is treated by intravenous infusion of the missing purified clotting factor. The goal of gene transfer for treating hemophilia is to achieve sustained expression of factor VIII or factor IX at levels high enough to improve the symptoms of the disease. Hemophilia has proven to be an attractive model for those interested in gene transfer, and multiple gene-transfer strategies are currently being investigated for the hemophilias. The most promising preclinical studies have been with adeno-associated viral vectors (AAV); introduction of AAV vectors expressing factor IX into skeletal muscle or liver in hemophilic dogs has resulted in the long-term expression of factor IX at levels that are adequate to improve disease symptoms. Efforts to translate these findings into the clinical arena have proceeded slowly because of the lack of prior clinical experience with parenteral administration of AAV. In a staged approach, AAV-factor IX (AAV-F.IX) was first administered at doses of up to 1.8 x 10(12) vector genomes/kg (vg/kg) into the skeletal muscles of men with hemophilia B. This trial established the safety of parenteral administration and also showed that general characteristics of AAV transduction were similar in mice, dogs, and humans. In an ongoing trial, AAV-F.IX is being administered into the hepatic circulation of men with severe hemophilia B. The goal of these studies is to identify a safe dose that reliably yields circulating levels of factor IX >2% of normal levels in all subjects. This goal has already been achieved in the hemophilia B dog model; the ongoing study will determine whether a similar result can be achieved in humans with hemophilia B.     

Current status of gene therapy for hemophilia

The hemophilias are an attractive model for gene therapy because their clinical manifestations are attributable to the lack of a single protein that circulates in minute amounts in the plasma. Sustained therapeutic expression of factors VIII and IX has been achieved in preclinical studies using a wide range of gene transfer technologies targeted at different tissues. This achievement has led to six different phase I/II clinical trials that resulted in limited efficacy but minimal toxicity. Recombinant adeno-associated viral vectors appear most promising for hemophilia gene therapy; however, this review summarizes all the major gene therapy approaches used and outlines the future challenges.     

An update on gene therapy for hemophilia

More than two thirds of the world's hemophiliacs currently face a drastically shortened life of pain and disability because they do not have access to safe factor concentrates, as these products are highly expensive and in limited supply. For these individuals, gene therapy remains an important avenue of hope because of its potential for a durable cure following a single therapeutic manipulation. The results of recent hemophilia gene clinical trials are encouraging, although they have failed to demonstrate sustained correction of the bleeding diathesis. Although many obstacles still remain, continuing technologic improvements have resulted in impressive advances in this field, which bodes well for patients with hemophilia and other genetic disorders.     

Self-complementary adeno-associated viral vectors for gene therapy of hemophilia B: progress and challenges

Therapies currently used for hemophilia involve injection of protein concentrates that are expensive, invasive and associated with side effects such as development of neutralizing antibodies (inhibitors) that diminish therapeutic efficacy. Gene transfer is an attractive alternative to circumvent these issues. However, until now, clinical trials using gene therapy to treat hemophilia have failed to demonstrate sustained efficacy, although a vector based on a self-complementary adeno-associated virus has recently shown promise. This article will briefly outline a novel gene-transfer approach using self-complementary adeno-associated viral vectors using hemophilia B as a target disorder. This approach is currently being evaluated in the clinic. We will provide an overview of the development of self-complementary adeno-associated virus vectors as well as preclinical and clinical data with this vector system.     

Sustained correction of bleeding disorder in hemophilia B mice by gene therapy

Mice generated by disrupting the clotting factor IX gene exhibit severe bleeding disorder and closely resemble the phenotype seen in hemophilia B patients. Here we demonstrate that a single intraportal injection of a recombinant adeno-associated virus (AAV) vector encoding canine factor IX cDNA under the control of a liver-specific enhancer/promoter leads to a long-term and complete correction of the bleeding disorder. High level expression of up to 15-20 microgram/ml of canine factor IX was detected in the plasma of mice injected with 5.6 x 10(11) particles of an AAV vector for >5 months. The activated partial thromboplastin time of the treated mice was fully corrected to higher than normal levels. Liver-specific expression of canine factor IX was confirmed by immunofluorescence staining, and secreted factor IX protein was identified in the mouse plasma by Western blotting. All treated mice survived the tail clip test without difficulty. Thus, a single intraportal injection of a recombinant adeno-associated virus vector expressing factor IX successfully cured the bleeding disorder of hemophilia B mice, proving the feasibility of using AAV-based vectors for liver-targeted gene therapy of genetic diseases.     

Novel adeno-associated viruses from rhesus monkeys as vectors for human gene therapy

Tissues from rhesus monkeys were screened by PCR for the presence of sequences homologous to known adeno-associated virus (AAV) serotypes 1-6. DNA spanning entire rep-cap ORFs from two novel AAVs, called AAV7 and AAV8, were isolated. Sequence comparisons among these and previously described AAVs revealed the greatest divergence in capsid proteins. AAV7 and AAV8 were not neutralized by heterologous antisera raised to the other serotypes. Neutralizing antibodies to AAV7 and AAV8 were rare in human serum and, when present, were low in activity. Vectors formed with capsids from AAV7 and AAV8 were generated by using rep and inverted terminal repeats (ITRs) from AAV2 and were compared with similarly constructed vectors made from capsids of AAV1, AAV2, and AAV5. Murine models of skeletal muscle and liver-directed gene transfer were used to evaluate relative vector performance. AAV7 vectors demonstrated efficiencies of transgene expression in skeletal muscle equivalent to that observed with AAV1, the most efficient known serotype for this application. In liver, transgene expression was 10- to 100-fold higher with AAV8 than observed with other serotypes. This improved efficiency correlated with increased persistence of vector DNA and higher number of transduced hepatocytes. The efficiency of AAV8 vector for liver-directed gene transfer of factor IX was not impacted by preimmunization with the other AAV serotypes. Vectors based on these novel, nonhuman primate AAVs should be considered for human gene therapy because of low reactivity to antibodies directed to human AAVs and because gene transfer efficiency in muscle was similar to that obtained with the best known serotype, whereas, in liver, gene transfer was substantially higher than previously described.     

Nonviral gene therapy approaches to hemophilia

The goal of hemophilia gene therapy is to obtain long-term therapeutic levels of factor VIII (FVIII) or factor IX (FIX) without stimulating an immune response against the transgene product or the vector. The success of gene therapy is largely dependent on the development of appropriate gene delivery vectors. Both viral vectors and nonviral vectors have been considered for the development of hemophilia gene therapy. In general, viral vectors are far more efficient than nonviral gene delivery approaches and resulted in long-term therapeutic levels of FVIII or FIX in preclinical animal models. However, there are several reasons why a nonviral treatment would still be desirable, particularly because some viral vectors are associated with inflammatory reactions, that render transgene expression transient, or with an increased risk of insertional oncogenesis when random integrating vectors are used. Nonviral vectors may obviate some of these concerns. Since nonviral vectors are typically assembled in cell-free systems from well-defined components, they have significant manufacturing advantages over viral vectors. The continued development of improved nonviral gene delivery approaches offers new perspectives for gene therapy of chronic diseases including hemophilia.     

Coagulation factors with improved properties for hemophilia gene therapy

Hemophilias A and B are X-linked bleeding disorders that result in a qualitative or quantitative deficiency in coagulation factors VIII (FVIII) and IX (FIX), respectively. Affected patients experience significant morbidity as a result of repeated joint hemorrhages and subsequent arthropathy, and there is increased mortality related to life-threatening bleeding events. The mainstay of therapy is episodic or prophylactic infusions of plasma-derived or recombinant FVIII or FIX. However, gene transfer holds the promise of maintaining plasma levels of FVIII or FIX high enough to prevent the development of joint disease and reduce the risk of life-threatening bleeds or possibly even achieving normal plasma levels. Human gene therapy trials thus far have fallen short of this goal. This review summarizes the inherent limitations in expression of recombinant FVIII and the bioengineering strategies that are currently being explored for constructing novel recombinant FVIII molecules that have improved function. Current strategies for FVIII include increasing mRNA levels, improving secretion efficiency, increasing the rate of thrombin activation, stabilization of the activated form of FVIII, and strategies to prolong FVIII half-life in plasma by disrupting FVIII interaction with its clearance receptors. Strategies to improve the function of FIX include increasing the mRNA levels, reducing interaction with collagen IV, and increasing the specific activity. These novel molecules partnered with advances in gene transfer vector design and delivery may ultimately achieve persistent expression of FVIII and FIX, leading to an effective long-term treatment strategy for the hemophilias.     

NOD-scid mouse as an experimental animal model for cysticercosis

The major three species of human taeniid cestodes, Taenia solium, T. saginata and T. saginata asiatica (= T. asiatica) which require humans as the definitive host are still not rare in developing countries. Among these, T. solium is the most serious with medical and economic importance. Neurocysticercosis (NCC) in humans is now recognized as the major cause of neurologic disease in the world. As these human taeniid cestodes obligatory require domestic animals such as swine, cattle and swine as the major intermediate host animals respectively, it is not easy to analyze the basic research in these domestic animals. In this brief review, we introduce experimental animal model for these three species in order to obtain fully developed metacestode stage in severe combined immunodeficiency (scid) mice. Non-obese diabetic scid (NOD-scid) mice are expected to be a satisfactory animal model and to have advantages for analysis by several view points of developmental biology with gene expression throughout development, antigenic homology of cyst fluid of these three species, evaluation of drug efficacy or metacestocidal drug designs, confirmation of unknown taeniid gravid segments for identification based on the morphology and DNA analysis of metacestodes. The animal model is not only available for human Taenia spp but can also be applied to other taeniid cestodes of economic importance or in veterinary parasitology.     

Preclinical gene therapy studies for hemophilia using adenoviral vectors

Hemophilia A and B are hereditary coagulation defects resulting from a deficiency of factor VIII (FVIII) and factor IX (FIX), respectively. Introducing a functional FVIII or FIX gene could potentially provide a cure for these bleeding disorders. Adenoviral vectors have been used as tools to introduce potentially therapeutic genes into mammalian cells and are by far the most efficient vectors for hepatic gene delivery. Long-term expression of both FVIII and FIX has been achieved in preclinical (hemophilic) mouse models using adenoviral vectors. Therapeutic levels of FVIII and FIX also have been achieved in hemophilic dogs using adenoviral vectors and in some cases expression was long-term. The performance of earlier generation adenoviral vectors, which retained residual viral genes, was compromised by potent acute and chronic inflammatory responses that contributed to significant toxicity and morbidity and short-term expression of FVIII and FIX. The development of improved adenoviral vectors devoid of viral genes (gutless or high-capacity adenoviral vectors) was therefore warranted, which led to a significant reduction in acute and chronic toxicity and more prolonged expression of FVIII and FIX. Strategies aimed at making these vectors safer and less immunogenic and their implications for hemophilia gene therapy are discussed in this review.     

Permanent phenotypic correction of hemophilia B in immunocompetent mice by prenatal gene therapy

Hemophilia B, also known as Christmas disease, arises from mutations in the factor IX (F9) gene. Its treatment in humans, by recombinant protein substitution, is expensive, thus limiting its application to intermittent treatment in bleeding episodes and prophylaxis during surgery; development of inhibitory antibodies is an associated hazard. This study demonstrates permanent therapeutic correction of his disease without development of immune reactions by introduction of an HIV-based lentiviral vector encoding the human factor IX protein into the fetal circulation of immunocompetent hemophiliac and normal outbred mice. Plasma factor IX antigen remained at around 9%, 13%, and 16% of normal in the 3 hemophilia B mice, respectively, until the last measurement at 14 months. Substantial improvement in blood coagulability as measured by coagulation assay was seen in all 3 mice and they rapidly stopped bleeding after venipuncture. No humoral or cellular immunity against the protein, elevation of serum liver enzymes, or vector spread to the germline or maternal circulation were detected.     

The putative factor IX gene promoter in hemophilia B Leyden

Hemophilia B Leyden is characterized by low levels of factor IX antigen and activity before the age of 15, whereas after puberty factor IX levels rise at a rate of about 5% per year. A single base substitution (-A----T) at position -20 was identified in the putative promoter of the gene cloned from a patient with hemophilia B Leyden. This nucleotide change was confirmed in a second patient from the same pedigree and was also found in a patient from a second Dutch pedigree with the same hemophilic phenotype. The results indicate that the two Dutch kindreds are related and point to the functional significance of the -20 position for the expression of the human factor IX gene.