Prevalence of human pegivirus-1 and sequence variability of its E2 glycoprotein estimated from screening donors of fetal stem cell-containing material.

BACKGROUND: Human pegivirus-1 (HPgV-1) is a member of the Flaviviridae family whose genomic organization and mode of cellular entry is similar to that of hepatitis C virus (HCV). The E2 glycoprotein of HPgV-1 is the principle mediator in the virus-cell interaction and as such harbors most of HPgV-1's antigenic determinants. HPgV-1 persists in blood cell precursors which are increasingly used for cell therapy. METHODS: We studied HPgV-1 prevalence in a large cohort of females donating fetal tissues for clinical use. PCR was used for screening and estimation of viral load in viremic plasma and fetal samples. Sequence analysis was performed for portions of the 5'-untranslated and E2 regions of HPgV-1 purified from donor plasmas. Sequencing was followed by phylogenetic analysis. RESULTS: HPgV-1 was revealed in 13.7% of plasmas, 5.0% of fetal tissues, 5.4% of chorions, exceeding the prevalence of HCV in these types of samples. Transmission of HPgV-1 occurred in 25.8% of traceable mother-chorion-fetal tissues triads. For HPgV-1-positive donors, a high viral load in plasma appears to be a prerequisite for transmission. However, about one third of fetal samples acquired infection from non-viremic individuals. Sequencing of 5'-untranslated region placed most HPgV-1 samples to genotype 2a. At the same time, a portion of E2 sequence provided a much weaker support for this grouping apparently due to a higher variability. Polymorphisms were detected in important structural and antigenic motifs of E2. CONCLUSION: HPgV-1 is efficiently transmitted to fetus at early embryonic stages. A high variability in E2 may pose a risk of generation of pathogenic subtypes. Although HPgV-1 is considered benign and no longer tested mandatorily in blood banks, the virus may have adversary effects at target niches if delivered with infected graft upon cell transplantation. This argues for the necessity of HPgV-1 testing of cell samples aimed for clinical use.

Report on Liver Cell Transplantation Using Human Fetal Liver Cells.

In an era of organ shortage, human fetuses donated after medically indicated abortion could be considered a potential liver donor for hepatic cell isolation. We investigated transplantation of fetal liver cells as a strategy to support liver functionality in end-stage liver disease. Here, we report our protocol of human fetal liver cells (hFLC) isolation in fetuses from 17 to 22 gestational weeks, and our clinical procedure of hFLC transplantation through the splenic artery.

Human foetal brain tissue as quality control when developing stem cells towards cell replacement therapy for neurological diseases.

Human foetal brain tissue has been used in experimental and clinical trials to develop cell replacement therapy in neurodegenerative disorders such as Parkinson's disease and Huntington's disease. These pioneering clinical studies have shown proof of principle that cell replacement therapy can be effective and is worthwhile to develop as a therapeutic strategy for repairing the damaged brain. However, because of the limited availability of foetal brain material, and difficulties in producing standardized and quality-tested cell preparations from this source, there have been extensive efforts in investigating the potential use of alternative cell sources for generating a large number of transplantable, authentic neural progenitors and neurons. In this review, we highlight the value of using human foetal tissue as a reference material for quality control of acquired cell fate of in vitro generated neurons before and after transplantation.

Increased cell suspension concentration augments the survival rate of grafted tyrosine hydroxylase immunoreactive neurons.

The poor survival rate (5-20%) of grafted embryonic dopamine (DA) neurons is one of the primary factors preventing cell replacement from becoming a viable treatment for Parkinson's disease. Previous studies have demonstrated that graft volume impacts grafted DA neuron survival, indicating that transplant parameters influence survival rates. However, the effects of mesencephalic cell concentration on grafted DA neuron survival have not been investigated. The current study compares the survival rates of DA neurons in grafts of varying concentrations. Mesencephalic cell suspensions derived from E14 Fisher 344 rat pups were concentrated to 25,000, 50,000, 100,000 and 200,000 cells/microl and transplanted into two 0.5 microl sites in the 6-OHDA-denervated rat striatum. Animals were sacrificed 10 days and 6 weeks post-transplantation for histochemical analysis of striatal grafts. The absolute number of DA neurons per graft increased proportionally to the total number of cells transplanted. However, our results show that the 200,000 cells/microl group exhibited significantly higher survival rates (5.48+/-0.83%) compared to the 25,000 cells/microl (2.81+/-0.39%) and 50,000 cells/microl (3.36+/-0.51%) groups (p=0.02 and 0.03, respectively). Soma size of grafted DA neurons in the 200,000 cells/microl group was significantly larger than that of the 25,000 cells/microl (p<0.0001) and 50,000 cells/microl groups (p=0.004). In conclusion, increasing the concentration of mesencephalic cells prior to transplantation, augments the survival and functionality of grafted DA neurons. These data have the potential to identify optimal transplantation parameters that can be applied to procedures utilizing stem cells, neural progenitors, and primary mesencephalic cells.

Towards a definition of recovery of function.

In this review we consider recovery of function after spinal cord injury, and, in particular, recovery improved following intraspinal cellular transplants. Some recovery occurs spontaneously and this can be especially dramatic in neonates, supporting the notion that developing and adult spinal cord respond differently to injury. Recovery can be improved in both neonates and adults by appropriate cellular transplants into the injury site. We describe several functional tests used in animals with spinal lesions and transplants. We compare the effects of transplants of fetal tissue and genetically modified fibroblasts into neonatal and adult injury sites on recovery of motor and sensorimotor function. Fetal tissue transplants support greater recovery and elicit more regeneration in neonates than in adults. Transplants of fibroblasts modified to produce neurotrophic factors however support both recovery and axonal growth even in adults. The contribution of the transplant to recovery is shown by the loss of function that follows a second lesion just rostral to the original lesion/transplant site. The effect of the re-lesion indicates that the recovery is mediated by the presence of the transplant but the way in which transplants act to promote recovery may include a number of mechanisms, including regeneration and sprouting, neuroprotection, and modifications of organization of spared CNS structures.

[Results and outlooks of using cell technologies in the treatment of neurological diseases]. / Itogi i perspektivy ispol'zovaniia kletochnykh tekhnologii v lechenii nevrologicheskikh zabolevanii.

An attempt was undertaken in the last decade of the 20th century to use a principally new approach to the treatment of neurological diseases--cell therapy. Main efforts were focused on developing a method related with replacement of neurons dying in neurodegenerative pathology, primarily, in Parkinson disease (PD). Outlined below are the key elements of the technology:--ensuring, in experiment, of a prolonged therapeutic effect in transplantation, to the affected part, first of embryonic neurons of the animal of the same species (allografting) and then of homologous embryonic neurons of man (heterografting);--obtaining, standardization and preparation (for transplantation) of embryonic nervous tissue of man; transplantation of embryonic nervous tissue of man to the brain of patient and evaluation, in situ, of the functional activity of its neurons; and evaluation of the therapeutic effect of grafting. Cell suspension of meseencephalon of 6-9 week human fetus containing around 10% of differentiating dopaminergic neurons was used for grafting in PD. Embryonic dopaminergic neurons, administered stereotactically into the striatum of patient, established synaptic links with neurons of the recipient, which was accompanied by the onset of synthesis and reverse uptake of dopamine (DA) as well as by the onset of spontaneous and stimulated release of DA. Neurografting ensured a temporary improvement of the condition in a part of PD patients but did not cure them. Moreover, such positive therapeutic effect was registered only in patients with the akineticorigid but not trembling variation of the disease. Hence, although there was a certain progress in clinical neurografting, the approach cannot be now recommended for introduction in neurology and neurosurgery. The limited therapeutic effect of the treatment method is primarily explained by a low rate of survival of transplanted dopaminergic neurons and, consequently, by the persisting DA deficit in patient's body. Therefore, the outlooks for perfecting the cell technology are related with increasing the survival rate of implanted dopaminergic neurons and with stimulating the innervation of target neurons in patient's striatum as well as with using the neural (glia) and non-neural (fibroblasts, myoblasts) cells with modified gene and stem cells. Finally, despite a certain progress of advancing the cell technology in neurology the approach still needs more research, which would enable further clinical trials.

Cloning and stem cells: processes, politics, and policy.

The creation of good science policy requires an understanding of the scientific technologic processes as well as an appreciation of the "politicization process" and contemporary politics. This article encompasses a review of nuclear transfer and stem cell technologies and advances against a backdrop of the politicization of science. The combination of these forces has rendered it almost impossible to develop true consensus on what any national policy regarding nuclear transfer should look like. Careful consideration of the multidimensional nature of these technologies and the myriad of social, economic, and cultural factors they will impact demands, however, that, at the very least, a national dialogue be instituted in an effort to frame good policy pertaining to nuclear transfer and stem cell research.

The pros and cons of human therapeutic cloning in the public debate.

Few issues linked to genetic research have raised as much controversial debate as the use of somatic cell nuclear transfer technology to create embryos specifically for stem cell research. Whereas European countries unanimously agree that reproductive cloning should be prohibited there is no agreement to be found on whether or not research into therapeutic cloning should be permitted. Since the UK took the lead and voted in favour of regulations allowing therapeutic cloning the public debate has intensified on the Continent. This debate reflects the wide spectrum of diverse religious and secular moralities that are prevalent in modern multicultural European democratic societies. Arguments range from putting forward strictly utilitarian views that weight the moral issues involved against the potential benefits that embryonic stem cell research may harbour to considering the embryo as a human being, endowed with human dignity and human rights from the moment of its creation, concluding that its use for research is unethical and should be strictly prohibited. Given the current state of dissension among the various European states, it is difficult to predict whether 'non-harmonisation' will prevail or whether in the long run 'harmonisation' of legislation that will allow stem cell research will evolve in the EU.

Ethical guidance on human embryonic and fetal tissue transplantation: a European overview.

This article presents an overview of regulations, guidelines and societal debates in eight member states of the EC about a) embryonic and fetal tissue transplantation (EFTT), and b) the use of human embryonic stem cells (hES cells) for research into cell therapy, including 'therapeutic' cloning. There appears to be a broad acceptance of EFTT in these countries. In most countries guidance has been developed. There is a 'strong' consensus about some of the central conditions for 'good clinical practice' regarding EFTT. International differences concern, amongst others, some of the informed consent issues involved, and the questions whether an intermediary organisation is necessary, whether the methods of abortion may be influenced by the possible use of EFT, and whether EFTT should only be used for the experimental treatment of rare disorders. The potential use of hES cells for research into cell therapy has given a new impetus to the debate about (human) embryo research. The therapeutic prospects with regard to the retrieval and research use of hES cells appear to function as a catalyst for the introduction of less restrictive regulations concerning research with spare embryos, at least in some European countries. It remains to be seen whether the prospect of treating patients suffering from serious disorders with transplants produced by therapeutic cloning will decrease the societal and moral resistance to allowing the generation of embryos for 'instrumental' use.

Allogenic fetal liver cells have a distinct competitive engraftment advantage over adult bone marrow cells when infused into fetal as compared with adult severe combined immunodeficient recipients.

In utero transplantation (IUT) is becoming a viable option for the treatment of various immune and metabolic disorders diagnosed early in gestation. In this study, donor fetal liver cells had a 10-fold competitive engraftment advantage relative to adult bone marrow in allogeneic fetal severe combined immunodeficient (SCID) recipients compared with adult recipients. In contrast, adult bone marrow cells engrafted slightly better than fetal liver cells in allogeneic adult SCID transplant recipients. By using different ratios of fetal and adult cell mixtures, fetal liver cells repopulated 8.2 times better than adult bone marrow cells in fetal recipients, but only 0.8 times as well in adult recipients. Fetal SCID recipients were more permissive to an allogeneic donor graft than adult recipients. These data indicate that the recipient microenvironment may regulate the engraftment efficiency of a given stem cell source and suggest that the use of cord blood should be tested in clinical IUT.

In utero transplantation of fetal liver cells in the mucopolysaccharidosis type VII mouse results in low-level chimerism, but overexpression of beta-glucuronidase can delay onset of clinical signs.

Mice with the lysosomal storage disease mucopolysaccharidosis (MPS) VII, caused by a deficiency of beta-glucuronidase (GUSB), have signs of disease present at birth. Bone marrow transplantation (BMT) or retroviral vector-mediated gene transfer into hematopoietic stem cells can partially correct the disease in adult mice, and BMT performed at birth results in a better clinical outcome. Thus, treatment in utero may result in further improvement. However, this must be done without cyto-ablation, and the donor cells do not have a competitive repopulating advantage over host cells. Transplantation in utero of either syngeneic fetal liver hematopoietic stem cells marked with a retroviral vector, or allogeneic donor cells that constitutively express high levels of human GUSB from a transgene, resulted in only about 0.1% engraftment in the adult. Immuno-affinity enrichment of stem and progenitor cells of 5- to 10-fold resulted in significantly higher GUSB activities at 2 months of age, but by 6 months engraftment was about 0.1%. Attempts to further increase the number of stem and progenitor cells were deleterious to the recipients. Nevertheless, GUSB expressed during the first 2 months of life in MPS VII fetuses could delay the onset of overt signs of disease. This suggests that the expression of some normal enzyme activity beginning in fetal life may offer the possibility of slowing the progression of the disease until more definitive postnatal transplantation or gene transfer to stem cells could be accomplished.

Fetal porcine ventral mesencephalon graft. Determination of the optimal gestational age for implantation in parkinsonian patients.

Human fetal ventral mesencephalon tissue has been used as dopaminergic striatal implants in Parkinsonian patients, so far with variable effects. Fetuses from animals that breed in large litters, e.g., pigs, have been considered as alternative donors of dopaminergic tissue. The optimal gestational age of the porcine fetal donors has not been studied systematically. We collected ventral mesencephalic (VM) tissue from fetal pigs, embryonal ages E21, E28, E42, and E70, and examined the viability of the fetal VM cells after dissociation, the expression of tyrosine hydroxylase (TH) in culture, the presence of catecholamines, and the cellular survival and outgrowth up to 10 months after intrastriatal implantation in rats. The highest viability was found in suspensions prepared from E28 fetuses. The highest number of TH-positive cells was found in cell cultures prepared from E28 VM tissue. Explants with a gestational age of 28 and 42 days contained the largest amount of dopamine. Only E28-derived grafts showed TH-cell survival after implantation in rat striatum. Our results show that a gestational age of 28 days must be considered to be the optimal age for dopaminergic tissue derived from pig fetuses for therapeutic use as intrastriatal grafts in Parkinsonian patients.