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Abstract

Long-term survival of allo- and xenotransplanted immune-privileged Sertoli cells (SCs) is well documented suggesting that SCs can be used to deliver foreign proteins for cell-based gene therapy. The aim of this study was to use a lentivirus carrying proinsulin cDNA to achieve stable expression and lowering of blood glucose levels (BGLs). A SC line transduced with the lentivirus (MSC-LV-mI) maintained stable insulin expression in vitro. These MSC-LV-mI cells were transplanted and grafts were analyzed for cell survival, continued proinsulin mRNA, and insulin protein expression. All grafts contained MSC-LV-mI cells that expressed proinsulin mRNA and insulin protein. Transplantation of MSC-LV-mI cells into diabetic mice significantly lowered BGLs for 4 days after transplantation. Interestingly, in three transplanted SCID mice and one transplanted BALB/c mouse, the BGLs again significantly lowered by day 50 and 70, respectively. This is the first time SC transduced with a lentiviral vector was able to stably express insulin and lower BGLs. In conclusion, a SC line can be modified to stably express therapeutic proteins (e.g., insulin), thus taking us one step further in the use of SCs as an immune-privileged vehicle for cell-based gene therapy.

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References

Barry

S.C.

, Harder

, Brzezinski

, Flint

L.Y.

, Seppen

, and Osborne

W.R.

(2001). Lentivirus vectors encoding both central polypurine tract and posttranscriptional regulatory element provide enhanced transduction and transgene expression. Hum Gene Ther, 12, 1103–1108.

Christ

, Lusky

, Stoeckel

, Dreyer

, Dieterle

, Michou

A.I.

, et al. (1997). Gene therapy with recombinant adenovirus vectors: evaluation of the host immune response. Immunol Lett, 57, 19–25.

Dong

, Altomonte

, Morral

, Meseck

, Thung

S.N.

, and Woo

S.L.

(2002). Basal insulin gene expression significantly improves conventional insulin therapy in type 1 diabetic rats. Diabetes, 51, 130–138.

Dufour

J.M.

, Hemendinger

, Halberstadt

C.R.

, Gores

, Emerich

D.F.

, Korbutt

G.S.

, et al. (2004). Genetically engineered Sertoli cells are able to survive allogeneic transplantation. Gene Ther, 11, 694–700.

Dufour

J.M.

, Rajotte

R.V.

, Kin

, and Korbutt

G.S.

(2003). Immunoprotection of rat islet xenografts by cotransplantation with sertoli cells and a single injection of antilymphocyte serum. Transplantation, 75, 1594–1596.

Fallarino

, Luca

, Calvitti

, Mancuso

, Nastruzzi

, Fioretti

M.C.

, et al. (2009). Therapy of experimental type 1 diabetes by isolated Sertoli cell xenografts alone. J Exp Med, 206, 2511–2526.

Gores

P.F.

, Hayes

D.H.

, Copeland

M.J.

, Korbutt

G.S.

, Halberstadt

, Kirkpatrick

S.A.

, et al. (2003). Long-term survival of intratesticular porcine islets in nonimmunosuppressed beagles. Transplantation, 75, 613–618.

Grant

C.W.

, Duclos

S.K.

, Moran-Paul

C.M.

, Yahalom

, Tirabassi

R.S.

, Arreaza-Rubin

, et al. (2012). Development of standardized insulin treatment protocols for spontaneous rodent models of type 1 diabetes. Comp Med, 62, 381–390.

Halley

, Dyson

E.L.

, Kaur

, Mital

, Uong

P.M.

, Dass

, et al. (2010). Delivery of a therapeutic protein by immune-privileged Sertoli cells. Cell Transplant, 19, 1645–1657.

10.

Karaca

, Durel

, Languille

, Lamotte

, Tourrel-Cuzin

, Leroux

, et al. (2007). Transgenic expression of human INS gene in Ins1/Ins2 double knockout mice leads to insulin underproduction and diabetes in some male mice. Front Biosci, 12, 1586–1593.

11.

Kaur

, Long

C.R.

, and Dufour

J.M.

(2012). Genetically engineered immune privileged Sertoli cells: a new road to cell based gene therapy. Spermatogenesis, 2, 23–31.

12.

Kaur

, Thompson

L.A.

, and Dufour

J.M.

(2014a). Sertoli cells—immunological sentinels of spermatogenesis. Semin Cell Dev Biol, 30, 36–44.

13.

Kaur

, Thompson

L.A.

, Pasham

, Tessanne

, Long

C.R.

, and Dufour

J.M.

(2014b). Sustained expression of insulin by a genetically engineered sertoli cell line after allotransplantation in diabetic BALB/c mice. Biol Reprod 90, 109.

14.

Korbutt

G.S.

, Elliott

J.F.

, and Rajotte

R.V.

(1997). Cotransplantation of allogeneic islets with allogeneic testicular cell aggregates allows long-term graft survival without systemic immunosuppression. Diabetes, 46, 317–322.

15.

Kremer

K.L.

, Dunning

K.R.

, Parsons

D.W.

, and Anson

D.S.

(2007). Gene delivery to airway epithelial cells in vivo: a direct comparison of apical and basolateral transduction strategies using pseudotyped lentivirus vectors. J Gene Med, 9, 362–368.

16.

Limberis

M.P.

, Bell

C.L.

, Heath

, and Wilson

J.M.

(2010). Activation of transgene-specific T cells following lentivirus-mediated gene delivery to mouse lung. Mol Ther, 18, 143–150.

17.

Mann

N.P.

, Johnston

D.I.

, Reeves

W.G.

, and Murphy

M.A.

(1983). Human insulin and porcine insulin in the treatment of diabetic children: comparison of metabolic control and insulin antibody production. Br Med J (Clin Res Ed), 287, 1580–1582.

18.

Mital

, Hinton

B.T.

, and Dufour

J.M.

(2011). The blood-testis and blood-epididymis barriers are more than just their tight junctions. Biol Reprod, 84, 851–858.

19.

Mital

, Kaur

, Bowlin

, Paniagua

N.J.

, Korbutt

G.S.

, and Dufour

J.M.

(2014). Nondividing, postpubertal rat sertoli cells resumed proliferation after transplantation. Biol Reprod 90, 13.

20.

Mital

, Kaur

, and Dufour

J.M.

(2010). Immunoprotective sertoli cells: making allogeneic and xenogeneic transplantation feasible. Reproduction, 139, 495–504.

21.

Montini

, Cesana

, Schmidt

, Sanvito

, Ponzoni

, Bartholomae

, et al. (2006). Hematopoietic stem cell gene transfer in a tumor-prone mouse model uncovers low genotoxicity of lentiviral vector integration. Nat Biotechnol, 24, 687–696.

22.

Nayak

, and Herzog

R.W.

(2010). Progress and prospects: immune responses to viral vectors. Gene Ther, 17, 295–304.

23.

O'Rand

M.G.

, and Romrell

L.J.

(1977). Appearance of cell surface auto- and isoantigens during spermatogenesis in the rabbit. Dev Biol, 55, 347–358.

24.

Park

, and Kay

M.A.

(2001). Modified HIV-1 based lentiviral vectors have an effect on viral transduction efficiency and gene expression in vitro and in vivo. Mol Ther, 4, 164–173.

25.

Pepper

A.R.

, Gall

, Mazzuca

D.M.

, Melling

C.W.

, and White

D.J.

(2009). Diabetic rats and mice are resistant to porcine and human insulin: flawed experimental models for testing islet xenografts. Xenotransplantation, 16, 502–510.

26.

Powell

S.K.

, Rivera-Soto

, and Gray

S.J.

(2015). Viral expression cassette elements to enhance transgene target specificity and expression in gene therapy. Discov Med, 19, 49–57.

27.

Raper

S.E.

, Chirmule

, Lee

F.S.

, Wivel

N.A.

, Bagg

, Gao

G.P.

, et al. (2003). Fatal systemic inflammatory response syndrome in a ornithine transcarbamylase deficient patient following adenoviral gene transfer. Mol Genet Metab, 80, 148–158.

28.

Suarez-Pinzon

, Korbutt

G.S.

, Power

, Hooton

, Rajotte

R.V.

, and Rabinovitch

(2000). Testicular sertoli cells protect islet beta-cells from autoimmune destruction in NOD mice by a transforming growth factor-beta1-dependent mechanism. Diabetes, 49, 1810–1818.

29.

Thomas

C.E.

, Ehrhardt

, and Kay

M.A.

(2003). Progress and problems with the use of viral vectors for gene therapy. Nat Rev Genet, 4, 346–358.

30.

Trivedi

A.A.

, Igarashi

, Compagnone

, Fan

, Hsu

J.Y.

, Hall

D.E.

, et al. (2006). Suitability of allogeneic sertoli cells for ex vivo gene delivery in the injured spinal cord. Exp Neurol, 198, 88–100.

31.

Wang

G.P.

, Levine

B.L.

, Binder

G.K.

, Berry

C.C.

, Malani

, McGarrity

, et al. (2009). Analysis of lentiviral vector integration in HIV+ study subjects receiving autologous infusions of gene modified CD4+ T cells. Mol Ther, 17, 844–850.

32.

Williams

D.A.

(2009). Gene therapy continues to mature and to face challenges. Mol Ther, 17, 1305–1306.

33.

Wright

, Dziuk

, Mital

, Kaur

, and Dufour

J.M.

(2016). Xenotransplanted pig Sertoli cells inhibit both the alternative and classical pathways of complement-mediated cell lysis while pig islets are killed. Cell Transplant, 25, 2027–2040.

34.

Yule

T.D.

, Montoya

G.D.

, Russell

L.D.

, Williams

T.M.

, and Tung

K.S.

(1988). Autoantigenic germ cells exist outside the blood testis barrier. J Immunol, 141, 1161–1167.

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Sertoli Cells Engineered to Express Insulin to Lower Blood Glucose in Diabetic Mice

Abstract

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Supplementary Material