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Abstract

Schwann cells (SCs) play an important role in the pathogenesis of peripheral nerve diseases and represent a potential target for development of therapies. However, use of primary human SCs (hSCs) for in vitro models is limited because these cells are difficult to prepare and maintain in high yield and purity under common cell culture conditions. To circumvent this obstacle, we immortalized primary human fetal SCs using the SV40 large T-antigen and human telomerase reverse transcriptase expression vectors. After cloning, selection, and purification, we evaluated several immortalized SC lines for their ability to express extracellular matrix (ECM) molecules and myelinate embryonic rat sensory axons. In addition, we established a gene expression profile and explored their sensitivity to oxidative stress in a simple in vitro assay. Immortalized hSC clones expressed common glial markers and a broad variety of growth factors, receptors, and ECM molecules as determined by immunocytochemistry, microarray, and quantitative reverse transcription–polymerase chain reaction. In neuron-SC co-cultures, these cells were able to myelinate rat dorsal root ganglia neurons, although their effectiveness was lower in comparison to primary rat SCs. In toxicity assays, immortalized hSCs remain susceptible to oxidative stress induced by H₂O₂. This study shows that, using specific immortalization techniques, it is possible to establish hSC lines that retain characteristics of typical primary hSCs. These cells are particularly useful for drug screening and studies aimed at disease mechanisms involving SCs.

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References

Friedman

, Scherer

, Rudge

, Helgren

, Morrisey

, McClain

, Wang

, Wiegand

, Furth

, Lindsay

et al. 1992. Regulation of ciliary neurotrophic factor expression in myelin-related Schwann cells in vivo. Neuron, 9:295–305.

Acheson

, Barker

, Alderson

, Miller

, Murphy

. 1991. Detection of brain-derived neurotrophic factor-like activity in fibroblasts and Schwann cells: inhibition by antibodies to NGF. Neuron, 7:265–275.

Levi

, Bunge

. 1994. Studies of myelin formation after transplantation of human Schwann cells into the severe combined immunodeficient mouse. Exp Neurol, 130:41–52.

Heumann

, Korsching

, Bandtlow

, Thoenen

. 1987. Changes of nerve growth factor synthesis in nonneuronal cells in response to sciatic nerve transection. J Cell Biol, 104:1623–1631.

Court

, Wrabetz

, Feltri

. 2006. Basal lamina: Schwann cells wrap to the rhythm of space-time. Curr Opin Neurobiol, 16:501–507.

Keswani

, Buldanlioglu

, Fischer

, Reed

, Polley

, Liang

, Zhou

, Jack

, Leitz

, Hoke

. 2004. A novel endogenous erythropoietin mediated pathway prevents axonal degeneration. Ann Neurol, 56:815–826.

Jessen

, Mirsky

. 2008. Negative regulation of myelination: relevance for development, injury, and demyelinating disease. Glia, 56:1552–1565.

Weishaupt

, Bruck

, Hartung

, Toyka

, Gold

. 2001. Schwann cell apoptosis in experimental autoimmune neuritis of the Lewis rat and the functional role of tumor necrosis factor-alpha. Neurosci Lett, 306:77–80.

Lehmann

, Kohne

, Meyer zu Horste

, Dehmel

, Kiehl

, Hartung

, Kastenbauer

, Kieseier

. 2007. Role of nitric oxide as mediator of nerve injury in inflammatory neuropathies. J Neuropathol Exp Neurol, 66:305–312.

10.

Hafer-Macko

, Sheikh

, Li

, Ho

, Cornblath

, McKhann

, Asbury

, Griffin

. 1996. Immune attack on the Schwann cell surface in acute inflammatory demyelinating polyneuropathy. Ann Neurol, 39:625–635.

11.

Hoke

. 2006. Mechanisms of Disease: what factors limit the success of peripheral nerve regeneration in humans? Nat Clin Pract Neurol, 2:448–454.

12.

Chen

, Mi

, Haughey

, Oz

, Hoke

. 2007. Immortalization and characterization of a nociceptive dorsal root ganglion sensory neuronal line. J Peripher Nerv Syst, 12:121–130.

13.

Casella

, Bunge

, Wood

. 1996. Improved method for harvesting human Schwann cells from mature peripheral nerve and expansion in vitro. Glia, 17:327–338.

14.

Miller

, Rangwala

, Williams

, Ackerman

, Kong

, Jegga

, Kaiser

, Aronow

, Frahm

et al. 2006. Large-scale molecular comparison of human schwann cells to malignant peripheral nerve sheath tumor cell lines and tissues. Cancer Res, 66:2584–2591.

15.

Tapinos

, Rambukkana

. 2005. Insights into regulation of human Schwann cell proliferation by Erk1/2 via a MEK-independent and p56Lck-dependent pathway from leprosy bacilli. Proc Natl Acad Sci USA, 102:9188–9193.

16.

Rutkowski

, Kirk

, Lerner

, Tennekoon

. 1995. Purification and expansion of human Schwann cells in vitro. Nat Med, 1:80–83.

17.

Morrissey

, Kleitman

, Bunge

. 1995. Human Schwann cells in vitro. II. Myelination of sensory axons following extensive purification and heregulin-induced expansion. J Neurobiol, 28:190–201.

18.

Morrissey

, Bunge

, Kleitman

. 1995. Human Schwann cells in vitro. I. Failure to differentiate and support neuronal health under co-culture conditions that promote full function of rodent cells. J Neurobiol, 28:171–189.

19.

Brockes

, Fields

, Raff

. 1979. Studies on cultured rat Schwann cells. I. Establishment of purified populations from cultures of peripheral nerve. Brain Res, 165:105–118.

20.

van Gelder

, von Zastrow

, Yool

, Dement

, Barchas

, Eberwine

. 1990. Amplified RNA synthesized from limited quantities of heterogenous cDNA. Proc Natl Acad Sci USA, 87:1663–1667.

21.

Podratz

, Rodriguez

, Windebank

. 2001. Role of the extracellular matrix in myelination of peripheral nerve. Glia, 35:35–40.

22.

Lehmann

, Kohne

, Bernal

, Jangouk

, Meyer Zu Horste

, Dehmel

, Hartung

, Previtali

, Kieseier

. 2009. Matrix metalloproteinase-2 is involved in myelination of dorsal root ganglia neurons. Glia, 57:479–489.

23.

Schraufstatter

, Hinshaw

, Hyslop

, Spragg

, Cochrane

. 1986. Oxidant injury of cells. DNA strand-breaks activate polyadenosine diphosphate-ribose polymerase and lead to depletion of nicotinamide adenine dinucleotide. J Clin Invest, 77:1312–1320.

24.

Heine

, Ebnet

, Maysami

, Stangel

. 2006. Effects of interferon-beta on oligodendroglial cells. J Neuroimmunol, 177:173–180.

25.

Golden

, Pearse

, Blits

, Garg

, Oudega

, Wood

, Bunge

. 2007. Transduced Schwann cells promote axon growth and myelination after spinal cord injury. Exp Neurol, 207:203–217.

26.

Pearse

, Sanchez

, Pereira

, Andrade

, Puzis

, Pressman

, Golden

, Kitay

, Blits

, Wood

, Bunge

. 2007. Transplantation of Schwann cells and/or olfactory ensheathing glia into the contused spinal cord: Survival, migration, axon association, and functional recovery. Glia, 55:976–1000.

27.

Levi

, Guenard

, Aebischer

, Bunge

. 1994. The functional characteristics of Schwann cells cultured from human peripheral nerve after transplantation into a gap within the rat sciatic nerve. J Neurosci, 14:1309–1319.

28.

Guest

, Rao

, Olson

, Bunge

. 1997. The ability of human Schwann cell grafts to promote regeneration in the transected nude rat spinal cord. Exp Neurol, 148:502–522.

29.

Hill

, Moon

, Wood

, Bunge

. 2006. Labeled Schwann cell transplantation: cell loss, host Schwann cell replacement, and strategies to enhance survival. Glia, 53:338–343.

30.

Levi

, Evans

, Mackinnon

, Bunge

. 1994. Cold storage of peripheral nerves: an in vitro assay of cell viability and function. Glia, 10:121–131.

31.

Morrissey

, Levi

, Nuijens

, Sliwkowski

, Bunge

. 1995. Axon-induced mitogenesis of human Schwann cells involves heregulin and p185erbB2. Proc Natl Acad Sci USA, 92:1431–1435.

32.

Vroemen

, Weidner

. 2003. Purification of Schwann cells by selection of p75 low affinity nerve growth factor receptor expressing cells from adult peripheral nerve. J Neurosci Methods, 124:135–143.

33.

Crouch

, Kozlowski

, Slater

, Fletcher

. 1993. The use of ATP bioluminescence as a measure of cell proliferation and cytotoxicity. J Immunol Methods, 160:81–88.

34.

White

, Zheng

, Galatis

, Maher

, Hesse

, Multhaup

, Beyreuther

, Masters

, Cappai

. 1998. Survival of cultured neurons from amyloid precursor protein knock-out mice against Alzheimer's amyloid-beta toxicity and oxidative stress. J Neurosci, 18:6207–6217.

35.

Lezoualc'h

, Sagara

, Holsboer

, Behl

. 1998. High constitutive NF-kappaB activity mediates resistance to oxidative stress in neuronal cells. J Neurosci, 18:3224–3232.

36.

Desagher

, Glowinski

, Premont

. 1997. Pyruvate protects neurons against hydrogen peroxide-induced toxicity. J Neurosci, 17:9060–9067.

37.

Nicholls

. 2004. Mitochondrial dysfunction and glutamate excitotoxicity studied in primary neuronal cultures. Curr Mol Med, 4:149–177.

38.

Lee

, Chambers

, Tomishima

, Studer

. Derivation of neural crest cells from human pluripotent stem cells. Nat Protoc, 5:688–701.

39.

El Seady

, Huisman

, Lowik

, Frijns

. 2008. Uncomplicated differentiation of stem cells into bipolar neurons and myelinating glia. Biochem Biophys Res Commun, 376:358–362.

40.

Lee

, Kim

, Elkabetz

, Al Shamy

, Panagiotakos

, Barberi

, Tabar

, Studer

. 2007. Isolation and directed differentiation of neural crest stem cells derived from human embryonic stem cells. Nat Biotechnol, 25:1468–1475.

41.

, Say

, Zhou

. 2007. Isolation and characterization of neural crest progenitors from adult dorsal root ganglia. Stem Cells, 25:2053–2065.

42.

McKenzie

, Biernaskie

, Toma

, Midha

, Miller

. 2006. Skin-derived precursors generate myelinating Schwann cells for the injured and dysmyelinated nervous system. J Neurosci, 26:6651–6660.

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Human Schwann Cells Retain Essential Phenotype Characteristics After Immortalization

Abstract

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