New Gene Therapy Technique On Induced Pluripotent Stem Cells Holds Promise In Treating Immune System Disease

Researchers have developed an effective technique that uses gene therapy on stem cells to correct chronic granulomatous disease (CGD) in cell culture, which could eventually serve as a treatment for this rare, inherited immune disorder, according to a study published in Blood, the Journal of the American Society of Hematology.

CGD prevents neutrophils, a type of white blood cell of the immune system, from making hydrogen peroxide, an essential defense against life-threatening bacterial and fungal infections. Most cases of CGD are a result of a mutation on the X chromosome, a type of CGD that is called "X-linked" (X-CGD).

While antibiotics can treat infections caused by X-CGD, they do not cure the disease itself. Patients with X-CGD can be cured with a hematopoietic stem cell (HSC) transplant from healthy bone marrow; however, finding a compatible donor is difficult. Even with a suitable donor, patients are at risk of developing graft-versus-host disease (GVHD), a serious and often deadly post-transplant complication that occurs when newly transplanted donor cells recognize a recipient's own cells as foreign and attack the patient's body.

Another treatment option under development for X-CGD is gene therapy, a technique for correcting defective genes responsible for disease development that involves manipulation of genetic material within an individual's blood-forming stem cells using genetically engineered viruses. However, this gene therapy has so far proved to be inefficient at correcting X-CGD. In addition, these engineered viruses insert new genetic material at random locations in the blood-forming stem cell genome, putting patients at significantly higher risk for developing genetic mutations that may eventually lead to serious blood disorders, including blood cancer.

In order to develop a more effective and safer gene therapy for X-CGD, researchers from the National Institute of Allergy and Infectious Disease (NIAID) at the National Institutes of Health (NIH) and The Johns Hopkins University School of Medicine embarked on a study using a more precise method for performing gene therapy that did not use viruses for the gene correction. Researchers removed adult stem cells from the bone marrow of a patient with X-CGD and genetically reprogrammed them to become induced pluripotent stem cells (iPS cells). Like embryonic stem cells, these patient-specific iPS cells can be grown and manipulated indefinitely in culture while retaining their capacity to differentiate into any cell type of the body, including HSCs.

"HSCs that are derived from gene corrected iPS cells are tissue-compatible with the patient and may create a way for the patient's own cells to be used in a transplant to cure the disease, removing the risk of GVHD or the need to find a compatible donor," said Harry L. Malech, MD, senior study author, Chief of the Laboratory of Host Defenses and Head of the Genetic Immunotherapy Section of NIAID at the NIH. "However, turning iPS cells into a large number of HSCs that are efficently transplantable remains technically difficult; therefore, our study aimed at demonstrating that it is possible to differentiate gene corrected iPS cells into a large number of corrected neutrophils. These corrected neutrophils, grown in culture, are tissue-compatible with the patient and may be used to manage the life-threatening infections that are caused by the disease."

Typically, iPS cells from a patient with an inherited disorder do not express disease traits, despite the fact that the iPS cell genome contains the expected mutation. The researchers were able to prove, in culture, that iPS cells from a patient with X-CGD could be differentiated into mature neutrophils that failed to produce hydrogen peroxide, thus expressing the disease trait. This is the first study in which the disease phenotype has been reproduced in neutrophils differentiated from X-CGD patient-specific iPS cells.

After discovering that the disease could be reproduced in cell culture, the researchers then sought to correct the disease and produce healthy neutrophils in culture. They used synthetic proteins called zinc finger nucleases (ZFNs) to target a corrective gene at a specifically defined location in the genome of the X-CGD iPS cells. The iPS cells were then carefully screened to identify those containing a single copy of the corrective gene properly inserted only at the safe site. The researchers observed that some of the gene-corrected iPS cells could differentiate into neutrophils that produced normal levels of hydrogen peroxide, effectively "correcting" the disease.

"This is the first study that uses ZFNs in specific targeting gene transfer to correct X-CGD," said Dr. Malech. "Demonstrating that this approach to gene therapy works with a single-gene disease such as X-CGD means that the results from our study offer not only a potential treatment for this disease, but more importantly, a technique by which other single-gene diseases can be corrected using specifically targeted gene therapy on iPS cells."

Source:
American Society of Hematology

Autologous Induced Pluripotent Stem Cells And Gene Repair Therapy For Treatment Of Familial Hypercholesterolemia

Study shows, for the first time, the successful reprogramming of diseased human hepatocytes into induced pluripotent stem cells (iPSC).1

Results also found differentiation into mature hepatocytes was more efficient than that with fibroblast-derived iPSCs.

The generation of diseased hepatocyte-derived human iPSC lines provides a good basis for the study of liver disease pathogenesis.

Such technology could give a potentially unlimited reservoir of cells for the treatment of human liver diseases: generating genetically corrected liver cells via auto-transplantation of genetically modified hepatocytes, thus avoiding liver transplant and lifelong immunosuppression.

References:
1 Bosman, A. et al. Progress toward the clinical application of autologus induced pluripotent stem cells and gene repair therapy for treatment of familial hypercholesterolemia. Abstract presented at The International Liver CongressTM 2011.

Source:
Travis Taylor
European Association for the Study of the Liver

Study Of Umbilical Cord Blood-Derived Stem Cells For Lupus Therapy

Main Category: Lupus
Also Included In: Stem Cell Research
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Human umbilical cord blood-derived mensenchymal stem cells (uMSCs) have been found to offer benefits for treating lupus nephritis (LN) when transplanted into mouse models of systemic lupus erythematosus (SLE). SLE is an autoimmune disease with "myriad immune system aberrations" characterized by diverse clinical conditions, including LN, a leading cause of morbidity and mortality for patients with SLE.

The beneficial results were reported in a study by Taiwanese researchers published in the current issue of Cell Transplantation (20:2), freely available on-line here.

According to corresponding author Dr. Oscar K. Lee of the National Yang-Ming University School of Medicine, MSCs have been shown to possess immune-modulatory capabilities and can alleviate immune responses by inhibiting inflammation as well as the function of mature and immature immune system T cells. Seeking to explore the therapeutic effects of uMSCs in treating LN, their study transplanted umbilical cord blood-derived stem cells into mice modeled with systemic immune diseases closely resembling SLE in humans.

"We found that uMSC transplantation markedly delayed the deterioration of renal function, reduced certain antibody levels, alleviated changes in renal pathology and the development of proteinuria - the presence of excess protein serum in the urine and a sign of renal damage," said Dr. Lee.

The positive difference in survival rate for mice treated at two months of age compared with mice treated at six months of age, led the researchers to conclude that early uMSC transplantation may be most efficacious. The researchers also deduced that their findings favored the use of allogenic (other-donated) rather than autologous (self-donated) MSCs for SLE treatment, which would make sense with an autoimmune disorder.

"The therapeutic effects demonstrated in this pre-clinical study support further exploration of the possibility of using uMSCs from mismatched donors in LN treatment," concluded Dr. Lee.

"The ability of uMSCs to reduce inflammation means that they are likely to be of use in the treatment of autoimmune disorders and this study supports that reasoning and, in this case, also advocates the use of non-self cells," said Dr. David Eve, associate editor of Cell Transplantation and an instructor at the University of South Florida Center of Excellence for Aging and Brain Repair.

Citation:
Chang, J-W.; Hung , S-P.; Wu, H-H.; Wu, W-M.; Yang, A-H.; Tsai, H-L.; Yang, L-Y.; Lee, O. K. Therapeutic Effects of Umbilical Cord Blood-Derived Mesenchymal Stem Cell Transplantation in Experimental Lupus Nephritis. Cell Transplant. 20(2):245-257; 2011.

Source:
David Eve
Cell Transplantation Center of Excellence for Aging and Brain Repair

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Potential Stem Cell Therapy For Age-Related Macular Degeneration

The notion of transplanting adult stem cells to treat or even cure age-related macular degeneration has taken a significant step toward becoming a reality. In a study published today in Stem Cells, Georgetown University Medical Center researchers have demonstrated, for the first time, the ability to create retinal cells derived from human-induced pluripotent stem cells that mimic the eye cells that die and cause loss of sight.

Age-related macular degeneration (AMD) is a leading cause of visual impairment and blindness in older Americans and worldwide. AMD gradually destroys sharp, central vision needed for seeing objects clearly and for common daily tasks such as reading and driving. AMD progresses with death of retinal pigment epithelium (RPE), a dark color layer of cells which nourishes the visual cells in the retina.

While some treatments can help slow its progression, there is no cure. The discovery of human induced pluripotent stem (hiPS) cells has opened a new avenue for the treatment of degenerative diseases, like AMD, by using a patient's own stem cells to generate tissues and cells for transplantation.

For transplantation to be viable in age-related macular degeneration, researchers have to first figure out how to program the naïve hiPS cells to function and possess the characteristics of the native retinal pigment epithelium, RPE, the cells that die off and lead to AMD.

The research conducted by the Georgetown scientists shows that this critical step in regenerative medicine for AMD has greatly progressed.

"This is the first time that hiPS-RPE cells have been produced with the characteristics and functioning of the RPE cells in the eye. That makes these cells promising candidates for retinal regeneration therapies in age-related macular degeneration," says the study's lead author Nady Golestaneh, Ph.D., assistant professor in GUMC's Department of Biochemistry and Molecular & Cellular Biology.

Using an established laboratory stem cell line, Golestaneh and her colleagues show that RPE generated from hiPS cells under defined conditions exhibit ion transport, membrane potential, polarized VEGF secretion and gene expression profile similar to those of a normal eye's RPE.

"This isn't ready for prime time though. We also identified some issues that need to be worked out before these cells are ready for transplantation but overall, this is a tremendous step forward in regenerative medicine," Golestaneh adds.

She explains that the hiPS-derived RPE cells show rapid telomere shortening, DNA chromosomal damage and increased p21 expression that cause cell growth arrest. This might be due to the random integration of viruses in the genome of skin fibroblasts during the reprogramming of iPS cells. Therefore, generation of viral-free iPS cells and their differentiation into RPE will be a necessary step towards implementation of these cells in clinical application, Golestaneh says.

"The next step in this research is to focus on a generation of 'safe' as well as viable hiPS-derived somatic cells," Golestaneh concludes.

Notes:

Other authors on the paper include first author Maria Kokkinaki, Ph.D., Department of Biochemistry and Molecular &Cellular Biology, and Niaz Sahibzada, Ph.D., Department of Pharmacology at GUMC.

This work was funded by the National Institutes of Health. The authors report no personal financial interests related to this study.

Source:
Karen Mallet
Georgetown University Medical Center

 

Clinical Trial Success For Crohn's Disease Cell Therapy

Speaking at the UK National Stem Cell Network annual science meeting, Professor Miguel Forte described research into a new cell therapy for chronic inflammatory conditions such as Crohn's disease. Patient's own blood cells are used to produce a type of cell - Type 1 T regulatory lymphocyte - that can reduce the extent of the disease.

Professor Forte said "T regulatory lymphocytes are amazing cells - they secrete proteins - cytokines - that dampen down the over active immune response that causes the terrible symptoms of chronic inflammatory diseases such as Crohn's. We know that treatments based on these cells can work but the challenge is to develop them in the clinic so as to maximise the benefits and minimise the risk. We must show that these cells are well tolerated and do a good job to treat the disease."

Professor Forte and his colleagues at TxCell in Valbonne, France, have used patient's own immune system cells derived from PBMCs - a type of blood cell - to treat patients with chronic inflammatory diseases like Crohn's disease. They used these cells, from patients with Crohn's, who had previously been treated with drugs and/or surgery but still had significant symptoms due to treatment resistance to make Type 1 regulatory T lymphocytes, which were then given back to the patients. The purpose of the study was to assess how well patients react in general to the treatment and also to check the efficacy of these cells for treating Crohn's disease. The preliminary results presented today show a good tolerability and, when given the correct dose, patients with severe Crohn's disease that do not respond to other treatments have an improvement in their condition.

Cell therapy approaches, like this one and also MSCs, aim at using living cells as innovative new treatments to address unmet medical needs.

Professor Forte continued "It's still early days but the preliminary results are really good. The treatment didn't make the patients ill in any way and there is an early indication that their Crohn's disease has improved. The next step will be to do what we call a "phase 2b" clinical trial to find out if the treatment definitely works, what types of chronic inflammatory disease it works for, more about any potential side effects and how to manage them, and to confirm our results on the best dose used."

Source:
Mike Davies
Biotechnology and Biological Sciences Research Council

 

Autologous Induced Pluripotent Stem Cells And Gene Repair Therapy For Treatment Of Familial Hypercholesterolemia

Study shows, for the first time, the successful reprogramming of diseased human hepatocytes into induced pluripotent stem cells (iPSC).1

Results also found differentiation into mature hepatocytes was more efficient than that with fibroblast-derived iPSCs.

The generation of diseased hepatocyte-derived human iPSC lines provides a good basis for the study of liver disease pathogenesis.

Such technology could give a potentially unlimited reservoir of cells for the treatment of human liver diseases: generating genetically corrected liver cells via auto-transplantation of genetically modified hepatocytes, thus avoiding liver transplant and lifelong immunosuppression.

References:
1 Bosman, A. et al. Progress toward the clinical application of autologus induced pluripotent stem cells and gene repair therapy for treatment of familial hypercholesterolemia. Abstract presented at The International Liver CongressTM 2011.

Source:
Travis Taylor
European Association for the Study of the Liver