Use of small animal models for screening immunoisolation approaches to cellular transplantation

Immortalized human myoblast cell lines for the delivery of therapeutic proteins using encapsulated cell technology

Despite many promising results obtained in previous preclinical studies, the clinical development of encapsulated cell technology (ECT) for the delivery of therapeutic proteins from macrocapsules is still limited, mainly due to the lack of an allogeneic cell line compatible with therapeutic application in humans. In our work, we generated an immortalized human myoblast cell line specifically tailored for macroencapsulation. In the present report, we characterized the immortalized myoblasts and described the engineering process required for the delivery of functional therapeutic proteins including a cytokine, monoclonal antibodies and a viral antigen. We observed that, when encapsulated, the novel myoblast cell line can be efficiently frozen, stored, and thawed, which limits the challenge imposed by the manufacture and supply of encapsulated cell-based therapeutic products. Our results suggest that this versatile allogeneic cell line represents the next step toward a broader development and therapeutic use of ECT.

Macroencapsulation protects against sensitization after allogeneic islet transplantation in rats

BACKGROUND

The aim of this study was to evaluate the risks of sensitization by islet grafts encapsulated in a bilaminar immunoprotective membrane.

METHODS

We studied five groups of Lewis rats: one control group (no islets), two groups that received free islets (200 or 1000 s.c.), and two groups that received encapsulated ones (200 or 1000 s.c.) from Dark Agouti (DA) rats. Four weeks later, abdominal heterotopic DA-heart transplantation was performed on the same recipients. The time-to-heart graft rejection was assessed by the cessation of heart contractions. Rejection was confirmed by histological examinations. Antidonor antibodies were determined by fluorescence activated cell sorter (FACS) analysis.

RESULTS

The control animals had a mean heart graft survival of 6.4 days. The free islet groups had significantly shorter heart graft survivals-i.e., 4.8 days (200 islets) and 1.0 day (1000 islets) (P < 0.001)-while those of the encapsulated islet groups were about the same as that of the control group-i.e., 6.4 days (200 islets) and 6.0 days (1000 islets). In the free islet groups, anti-DA antibodies developed in 7/10 (200 islets) and 8/8 (1000 islets) animals after the islet transplantation. In the encapsulated groups, 1/10 (200 islets) and 3/8 (1000 islets) animals developed anti-DA antibodies after these transplantations. All animals had anti-DA antibodies at the time of heart graft rejection. On histological examination all grafts showed various features of rejection.

CONCLUSIONS

The bilaminar membrane protects against sensitization and prevents accelerated rejection of a subsequent vascularized graft, at least during the first month after the islet transplantation.

Evidence that tilapia islets do not express alpha-(1,3)gal: implications for islet xenotransplantation

BACKGROUND

Cell therapy for diabetes using teleost fish islet tissue has emerged as an intriguing alternative to the use of islet tissue from mammalian pancreases. The islet tissue, called Brockman bodies (BBs), is anatomically distinct from the pancreatic exocrine tissue and can be easily identified and isolated. Islets harvested from Nile tilapia (Oreochromis niloticus), when transplanted into streptozotocin-diabetic nude mice, produce long-term normoglycemia and achieve mammalian-like glucose tolerance profiles. We asked whether tilapia express the alpha-(1,3)gal epitope, the immunodominant target of human xenogeneic responses.

METHODS AND RESULTS

Immunostaining with the alpha-(1,3)gal-specific IB4 lectin on tilapia BB, liver, heart, spleen, and head kidney was negative, as was staining with murine anti-alpha-gal-specific monoclonal antibodies. Absence of alpha-gal-specific binding of IB4 or murine anti-gal mAbs to dispersed BBs was confirmed by fluorescent-activated cell sorter analysis. Tilapia BB cell membranes failed to reduce binding of anti-alpha-(1,3)gal-specific mAb in an enzyme-linked immunosorbent assay (ELISA) inhibition assay, while porcine and murine tissue lysates did. Tilapia BB cell lysates were shown to be devoid of alpha-1,3 galactosyltransferase activity by ELISA. Transplantation of tilapia BBs into diabetic alpha-gal knockout (gal KO) mice was not associated with accelerated xenograft rejection when compared with wild type control recipients (mean survival time 6.5 days vs. 7.2 days). Tilapia BBs failed to induce a rise in anti-gal IgG and IgM titers in gal KO mice, while the transplant of wild type mouse islets into gal KO mice caused a significant rise in anti-gal IgG and IgM antibodies.

CONCLUSIONS

We conclude that tilapia BBs are devoid of alpha-gal expression, and may offer an alternative to swine as a donor species for islet xenotransplantation.

Prevention of the initial host immuno-inflammatory response determines the long-term survival of encapsulated myoblasts genetically engineered for erythropoietin delivery

The present study investigates the respective roles of both the host immune response and the metabolic requirements in determining the long-term survival of erythropoietin-secreting myoblasts within encapsulating polymer membranes. Hollow-fiber capsules loaded with a high density of erythropoietin-secreting C(2)C(12) myoblasts survived poorly in the subcutaneous tissue of syngeneic mice, inducing variable hematocrit responses. To determine the role and the nature of the host response, recipients were treated with anti-inflammatory (diclofenac) and immunosuppressive (dexamethasone, FK506) agents. Only immunosuppressive drugs led to improved graft survival after 5 weeks of implantation, indicating an immune process as the cause of cell death. Furthermore, transient blocking of this process allowed long-term preservation of the implanted cells (> 100 days). The formation of necrotic cell cores inside densely packed devices elicited a local chronic inflammatory reaction. Hence, implants were designed to limit early cell death by inserting a supporting matrix and decreasing the number of loaded cells. The most efficient erythropoietin delivery was obtained with matrix-containing capsules that had received the lowest myoblast density. These results highlight the critical role of initial engraftment in the long-term acceptance of encapsulated myoblasts and the need to limit early cell death in the device to prevent subsequent host immuno-inflammatory responses.

Immunoisolation techniques for islet cell transplantation

Diabetes remains a devastating disease, with tremendous cost in terms of human suffering and healthcare expenditures. The burden of diabetes is primarily related to the multiple complications, including retinopathy, nephropathy, neuropathy and cardiovascular disease that can develop as the disease progresses. It has been shown that these complications can be prevented, and in some cases, reversed by islet cell transplantation, which, until recently, had remained elusive as a viable routine treatment modality. In recent studies, islet cell transplantation has shown great promise as a viable alternative to solid pancreas transplantation. However, severe shortage of human pancreases and the need to use immunosuppressive drugs to prevent transplant rejection, remain major obstacles to routine use of islet cell transplants for the treatment of patients with Type 1 diabetes. In the attempt to overcome these barriers, many procedures have been designed to immunoisolate islet cells for transplantation. The ultimate goal in islet cell transplantation is the availability of unlimited supply of cells to be transplanted in a simple procedure performed with little or no use of immunosuppressive drugs. The development of reliable procedures to immunoisolate islets by microencapsulation prior to transplantation has a great deal of potential to accomplish this objective.