Báo cáo khoa học: Dual expression of mouse and rat VRL-1 in the dorsal root ganglion derived cell line F-11 and biochemical analysis of VRL-1 after heterologous expression pptx

Dual expression of mouse and rat VRL-1 in the dorsal root ganglion derived cell line F-11 and biochemical analysis of VRL-1 after heterologous expression Ricarda Jahnel1,*, Olaf Bender1,

Dual expression of mouse and rat VRL-1 in the dorsal root ganglion derived cell line F-11 and biochemical analysis of VRL-1

after heterologous expression

Ricarda Jahnel1,*, Olaf Bender1,*, Lisa M Mu¨nter1, Mathias Dreger1, Clemens Gillen2and Ferdinand Hucho1

1

Arbeitsgruppe Neurochemie, Institut fu¨r Chemie-Biochemie, Freie Universita¨t Berlin, Germany;2Gru¨nenthal GmbH,

Aachen, Germany

The vanilloid-like TRP-channel VRL-1 (TRPV2) is a

non-selective cation channel expressed by primary sensory

neurons and non-neuronal tissues [Caterina, M.J., Rosen,

T.A., Tominaga, M., Brake, A.J and Julius, D (1999)

Nature 398, 436–441] It is one of the six members of the

vanilloid-like TRP-channel family which is now termed the

TRPV family [Montell, G., Birnbaumer, L., Flockerzi, V.,

Bindels, R.J., Brutford, E.A., Caterina, M.J., Clapham,

D.E., Harteneck, C., Heller, S., Julius, D., Kojima, I.,

Mori, Y., Penner, R., Prawitt, D., Scharenberg, A.M.,

Schultz, G., Shimizu, N and Zhu, M.X (2002) Mol Cell

2, 229–231] As it is a temperature-gated channel, VRL-1

appears to be functionally related to VR1 In contrast to

VR1, VRL-1 is activated at a higher temperature threshold

and it does not respond to capsaicin or protons Here we

describe the expression of VRL-1 in the rat dorsal root

ganglion-derived cell line F-11, a hybridoma of mouse

neuroblastoma (N18TG2) and rat dorsal root ganglion

cells We found by RT-PCR that F-11 cells express not

only the rat VRL-1, but also its mouse orthologue in a single cell The F-11 parental cell line N18TG2 also expressed murine VRL-1 Due to its neuronal character, the DRG-derived F-11 cell line provides an experimental system for the study of VRL-1 biochemistry However, one has to be aware that both the mouse and the rat protein are expressed simultaneously Furthermore we cloned VRL-1 from rat brain and analyzed its glycosylation and localization in comparison to the endogenously expressed protein in F-11 cells In contrast to the endogenous VRL-1 the overexpressed protein is glycosylated Similar to VR1 the glycosylation is N-linked as shown by an deglycosyla-tion assay Immunofluorescence analysis of the endo-genous VRL-1 in F-11 cells gives only weak signals in the cytoplasm whereas the overexpressed rat VRL-1 appears mainly at the plasma membrane

Keywords: TRPV2; F-11; glycosylation; localization; single cell RT-PCR

The vanilloid receptor 1 (VR1 or TRPV1) is a cation

channel predominantly expressed by primary sensory

neu-rons involved in nociception Caterina et al [1] isolated a

cDNA encoding the homologous VRL-1 by searching an

EST database for sequences related to VR1 According to

the new nomenclature, VRL-1 is now referred to as TRPV2

[2] The rat cDNA (Acc No AF129113) encodes a

761-amino acid VRL-1 protein, which is 82% identical to the

mouse protein of 756 amino acids (Acc No NM_011706),

and 78% identical to the human VRL-1 protein (Acc No

NM_016113) of 764 amino acids Computer analysis of the

sequence predicts six transmembrane sequences, a

pore-loop, a cytoplasmic N-terminal sequence with three anky-rin-repeat domains, and a cytoplasmic C-terminal sequence Functional analysis showed that VRL-1 does not respond

to capsaicin, low pH or moderate heat, but is activated at high temperatures, with a threshold at about 52
C[1] Immunocytochemical experiments revealed that VRL-1 is expressed in medium- to large-diameter dorsal root ganglion neurons and in the spinal cord, specifically in Lissauer’s tract and the dorsal horn [1] Ichikawa et al [3] detected VRL-1 immunoreactivity in 14% of the trigeminal ganglia cell bodies Furthermore Stenholm et al [4] found VRL-1 in the tooth pulp-innervating neurons and the gingival neurons Co-expression with VR1 was rarely observed Northern blot analysis revealed expression of an approxi-mately 2.5-kb VRL-1 transcript in rat sensory ganglia and spinal cord, as well as in lung, spleen, intestine, and multiple brain subregions [1] This led to the speculation that non-neuronal tissues expressing VRL-1 probably respond to stimuli other than heat An endogenous ligand for VRL-1 still has to be identified

One property of the murine VRL-1 which Kanzaki et al [5] had originally identified as a Ca2+-permeable channel (GRC) from mouse spleen is the regulation by insulin-like growth factor (IGF-1) IGF-1 causes the translocation of GRCto the plasma membrane where it forms a constitu-tively active channel at room temperature However, it still

Correspondence to F Hucho, Institut fu¨r Chemie-Biochemie,

Freie Universita¨t Berlin, Thielallee 63, 14195 Berlin, Germany.

Fax: + 49 0308385 3753, Tel.: + 49 0308385 5545,

E-mail: hucho@chemie.fu-berlin.de

Abbreviations: DAPI, 4¢-6-diamidino-2-phenylindole-2HCl; DRG,

dorsal root ganglion; GRC, growth-factor-regulated channel; TRP,

transient receptor potential; VR1, vanilloid receptor type 1 (TRPV1);

m/rVRL-1, mouse/rat vanilloid receptor-like protein 1 (TRPV2).

*Note: Both authors contributed equally to this work.

(Received 17 July 2003, revised 21 August 2003,

accepted 1 September 2003)

needs to be investigated how this relates to the rat and

human VRL-1

We previously investigated biochemical characteristics of

the capsaicin sensitive Vanilloid receptor VR1 transiently

transfected in the rat dorsal root ganglia derived cell line

F-11, a hybridoma of mouse neuroblastoma and rat dorsal

root ganglion cells [6] VR1 expressed in a neuronal cell

system should be more related to the in vivo situation than

fibroblast- or kidney-derived cell lines VR1 was not

endogenously expressed in F-11 cells These cells, formerly

generated and characterized by Platika et al [7] and Francel

et al [8], have been proven useful models for authentic

DRG cells They showed that several features of

differen-tiated DRG cells are present in F-11 cells, e.g release of

substance P, the presence of l- and d-opioid receptors,

receptors for prostaglandin and bradykinin and L-type

calcium channels Recently, Bender et al [9] isolated a rat

VRL-1 mRNA from F-11 cells identical to that observed in

dorsal root ganglia extracts They suggested, that the F-11

cells most likely are derived from medium-sized Ad-fibers

Here we show that the F-11 cells not only express the rat

VRL-1, but also the mouse VRL-1 and that the mouse

variant is derived from the F-11 parental cell line N18TG2

This finding is of interest when VRL-1 is functionally

studied in these cells Additionally in this study we cloned

VRL-1 from total RNA isolated from rat brain and

analyzed the glycosylation and localization of the

endo-genous VRL-1 in F-11 cells compared to VRL-1

over-expressed in the same cell line

Experimental procedures

Reverse transcription of rat brain, F-11 and N18TG2

total RNA

Total RNA of rat brain, F-11 and N18TG2 cells was

prepared using TRIzol Reagent (Invitrogen) according to

the instruction of the manufacturer 1 lg total RNA was

incubated for 10 min at 65
Cwith 500 ng

Oligo(dT)-Primer and chilled on ice First strand synthesis was

performed in a 20-lL reaction with 200 U Superscript II

reverse transcriptase in the presence of 40 U RNAse

Out, 500 lM each dNTP and 5 mM dithiothreitol (all

reagents from Invitrogen) at 42
Cfor 60 min followed

by an inactivation step at 70
C for 15 min As a control

each sample was additionally treated without reverse

transcriptase

VRL-1 specific PCR

To portray rat VRL-1 in overlapping PCR fragments in

F-11 cells PCR primers were designed according to the rat

VRL-1sequence (Acc No AF129113)

rVRL-1–34F: 5¢-CTGGAGACTTCCGATGGAGA-3¢

and rVRL-1–568R: 5¢-CATCCGCTCCATTCTCTACC-3¢

to obtain fragment A with 534 bp; rVRL-1–549F:

5¢-GGTAGAGAATGGAGCGGATG-3¢ and rVRL-1–

1205R: 5¢-ACCAAGTAGCAGGCGAAGTT-3¢ to obtain

fragment B with 656 bp; VRL-1/1061F: 5¢-ACTCGGTGC

TGGAGATCATC-3¢ and VRL-1/1897R: 5¢-TGAGAAG

GACGTAGGCCAAC-3¢ to obtain fragment C with

836 bp; rVRL-1–1618F: 5¢-TTCCTGCTGGTCTACCTG

GT-3¢ and rVRL-1–2251R: 5¢-CTTCCTCTGAGGCACT GTTC-3¢ to obtain fragment D with 633 bp

All primers were purchased from MWG Biotech AG PCR was performed with rat brain, N18TG2 and F-11 cDNA as template Two microlitres RT reaction was used

in 25 lL PCR amplifications using Taq-DNA-Polymerase (Invitrogen) after heating the sample to 95
Cfor 3 min PCR conditions were 94
C , 30 s; 57
C , 30 s; 72
C , 30 s for 35 cycle and an additional elongation step at 72
Cfor

7 min PCR was analyzed by electrophoresis in a 0.9% agarose gel

Single cell RT-PCR of F-11 cells F-11 cells were diluted in 5· RT first strand buffer to a concentration of 1 cell per 4 lL and checked under the microscope in a 96-well plate Only single cells were used for directly reverse transcription and PCR First strand synthe-sis was performed in a 20-lL reaction with 200 U Super-script II reverse tranSuper-scriptase in the presence of 40 U RNAse Out and 5 mM dithiothreitol (all reagents from Invitrogen) at 42
Cfor 60 min followed by an inactivation step at 70
Cfor 15 min As a control each sample was additionally treated without reverse transcriptase PCR was performed as described above for 40 instead of 35 cycles Non-denaturing PAGE

PCR products in a nondenaturing sample buffer were loaded on a 6% nondenaturing PAGE (buffered by tris-borate-EDTA) The gel was stained in an ethidiumbromide bath for 20 min and visualized under UV light Bands were eluted by the crush and soak method [10] and DNA purified

by Phenol/Chloroform extraction PCR fragments were ligated into the pCRII-TOPO vector (Invitrogen) and sequenced The accuracy of sequences from the open reading frame was checked by DNA sequencing of both strands The resulting sequences of specific bands were identical to GenBank sequence Acc No AF129113 or Acc

No NM_011706

Cloning of rVRL-1 Rat vanilloid receptor like-protein 1 (rVRL-1) was cloned from total rat brain cDNA Reverse-transcription poly-merase chain reaction (RT-PCR) was carried out with specific rVRL-1 forward and reverse primers designed using the GenBank sequence AF129113 Primers corresponding

to nucleotides 330–353 and 2587–2610 (rVRL-1_F: 5¢-AT GACTTCAGCCTCCAGCCCCCCA-3¢ and rVRL-1_R: 5¢-GGGACTGGAGGACCTGAAGGGGCA-3¢, respect-ively) were used to clone the open reading frame of rVRL-1

in frame with GFP into the pcDNA3.1/CT-GFP-TOPO vector (Invitrogen) A 2.5 lL RT reaction was used in

25 lL PCR amplifications containing 4% dimethylsulfox-ide using Pfu Polymerase (Life Technologies) After heating the sample to 95
Cfor 3 min PCR conditions were: 95
C,

30 s; 57
C , 30 s; 72
C, 5 min for 35 cycles and an additional elongation step at 72
Cfor 7 min To create 5¢A-overhang for TOPO cloning the reaction was incubated with Taq-DNA-Polymerase (Promega) for 20 min at 72
C PCR was analyzed by electrophoresis in a 1% agarose gel

for the presence of specific 2.3 kb rVRL-1 band The

band was excised from the gel and purified with UltraClean

DNA Purification Kit (MOBIO Laboratories, Inc.) using

the manufacturer’s instructions Four microlitres rVRL-1

cDNA was ligated into 1 lL pcDNA3.1/CT-GFP-TOPO

vector in the presence of 1 lL salt solution for 5 min at RT

The accuracy of the entire open reading frame was checked

by DNA sequencing of both strands

To obtain the full length rVRL-1 protein without GFP,

site-directed mutagenesis of pcDNA3.1/rVRL-1-CT-GFP

was performed using the QuikChangeTM Site-Directed

Mutagenesis Kit (Stratagene) Two primers were designed

to introduce the codon for P761 and a stop codon to prevent

GFP expression: mutVRL-1_F (5¢-TCAGGTCCTCCAG

TCCCCCTAAGGGCAATTCTGCAGAT-3¢) and

mut-VRL-1_R (5¢-ATCTGCAGAATTGCCCTTAGGGGGA

CTGGAGGACCTGA-3¢) The five introduced nucleotides

are shown in bold, they generate a new codon for P761 and

a stop codon The accuracy of the resulting new plasmid

pcDNA3.1/rVRL-1 was confirmed by DNA sequencing of

both strands

Cell culture and transfection of F-11 cells

F-11 cells (obtained from M.C Fishman, Cardiovascular

Research Center, Massachusetts General Hospital,

Charles-town, MA, USA) were cultured in Ham’s F-12 media with

Glutamax-I (Life Technologies), supplemented with 20%

fetal calf serum (GibcoBRL), 2% hypoxanthin/thymidine/

aminopterin supplement (Biochrom KG), 100 lgÆmL)1

streptomycin, and 100 lgÆmL)1 penicillin at 37
Cin a

humidified atmosphere with 5% CO2 on plastic tissue

culture grade flasks (Nunc)

N18TG2 cells (DSMZ ACC 103) were cultured in

Dulbecco’s MEM, supplemented with 10% fetal bovine

serum (GibcoBRL), 100 lM 6-thioguanine (Sigma),

100 lgÆmL)1 streptomycin, and 100 lgÆmL)1 penicillin at

37
Cin a humidified atmosphere with 5% CO2on plastic

tissue culture grade flasks (Nunc)

F-11 cells were transiently transfected with the

pcDNA3.1/rVRL-1 or pcDNA3.1/rVRL-1-CT-GFP

plas-mid using LipofectAMINE Plus (Life Technologies)

according to the procedure recommended by the

manufac-turer Plasmids were constructed as described above

Indirect immunofluorescence was performed as described

previously [6] For detection of VRL-1 anti-VRL-1

poly-clonal rabbit IgG (Oncogene, 1 : 100) was used as first and

Cy2-conjugated goat anti-(rabbit IgG) Ig (Jackson Immuno

research Laboratories) as second antibody Nuclei were

stained with 0.0004% 4¢-6-diamidino-2-phenylindole-2HCl

(DAPI) for 3 min before mounting Immunostaining was

visualized using fluorescence microscopy

Preparation of F-11 cell homogenate and particulate

Non-transfected or transfected cells from culture dishes

were washed once with cold NaCl/Pi and harvested in

NaCl/Pi The following steps were carried out at 4
C

The cells were gently centrifuged for 5 min at 500 g and

then resuspended in sucrose/Tris/MgSO4(0.25M sucrose,

50 mM Tris-Cl, pH 7.4, 5 mM MgSO4) containing one

protease inhibitor cocktail tablet for 50 mL buffer

(CompleteTM, Boehringer Mannheim) and 1 mM phenyl-methanesulfonyl fluoride Cells were homogenized in a glass homogenizer The homogenate was frozen in liquid nitrogen and stored at)70
Cuntil use For particulate preparation the homogenate was centrifuged for 20 min

at 40 000 g The resulting pellet was resuspended in 0.25M sucrose/Tris/MgSO4 and frozen as described above

Western blot analysis Aliquots (20 lg) of F-11 cell homogenate or particulate in loading buffer were subjected to SDS/PAGE (10%) Bands

of protein were electroblotted onto nitrocellulose mem-branes (Schleicher and Schuell) Memmem-branes were soaked for 2 h in TBST (20 mMTris buffer, pH 7.5, 150 mMNaCl, 0.1% Tween 20) with 5% nonfat dry milk and subsequently incubated for 1 h with anti-VRL-1 polyclonal rabbit IgG (Oncogene, 1 : 100) with and without 5 lgÆmL)1blocking peptide (KNSASEEDHLPLQVLQSP-COOH) in TBST with 5% nonfat dry milk After washing, blots were incubated for 1 h with a goat anti-(rabbit-IgG) Ig coupled

to horseradish-peroxidase (Dianova, 1 : 1000) For detec-tion of the VRL-1-GFP fusion protein anti-GFP polyclonal goat IgG (Abcam, 1 : 5000) was used as first and mouse anti-(goat-IgG) Ig coupled to horseradish-peroxidase (Pierce, 1 : 1000) as second antibody Immunoreactive bands were visualized by enhanced chemoluminescence detection methods (ECL Western Blotting Detection Reagents, Amersham Pharmacia Biotech)

Deglycosylation with N-glycanase and endoglycosidase H Deglycosylation with PNGase F and endoglycosidase H (NEB) was performed in a volume of 50 lL with 100 lg of F-11 cell particulate according to the manufacturer’s instruc-tions Non transfected and rVRL-1 or rVRL-1-CT-GFP transfected F-11 cells were used 30 lg of a membrane preparation from the electric organ of Torpedo californica containing mainly nicotinic acetylcholine receptor (nAChR) was used as a positive control After incubation the probes were separated by electrophoresis on a 10% Laemmli-SDS gel Western blot analysis was performed as described above

Results

A construct coding for a VRL-1-GFP fusion protein was prepared by cloning the open reading frame of rVRL-1 from rat brain RNA without the last codon for amino acid P761 and the stop codon into pcDNA3.1/CT-GFP-TOPO vec-tor The resulting sequence was identical to GenBank sequence Acc No AF129113 with four single nucleotide exchanges in codons at amino acid 82 [573 AGTfi 573 AGG], amino acid 367 [1428 CCGfi CTG], amino acid

397 [1518 TTCfi TTT] and amino acid 462 [1713 TTTfi TTC] These differences lead to two changes in the amino-acid sequence in VRL-1, namely S82R and P367L The other two differences are silent To obtain the full length rVRL-1 protein without GFP site-directed mutagenesis of pcDNA3.1/rVRL-1-CT-GFP was per-formed in a way that the codon for P761 and a stop codon was introduced (pcDNA3.1/rVRL-1)

VRL-1 is expressed in F-11 cells

We probed an F-11 cell homogenate after SDS/PAGE and

electroblotting with a polyclonal rabbit antibody directed

against the C-terminus of rat VRL-1 It is important to

mention that this antibody also detects the mouse variant

[11] The anti-VRL-1 antibody specifically detected a

protein band at
80 kDa (Fig 1) This band was not

detected when 5 lgÆmL)1of the immunization peptide was

added to the primary antibody reaction to block the

VRL-1-antigen-specific antibody The anti-VRL-1 immunoreactive

protein band at
80 kDa is in agreement with the

calculated molecular mass of rat VRL-1

Mouse and Rat VRL-1 are both expressed in F-11 cells

To prove that the full length VRL-1 mRNA is present in

F-11 cells we examined the rat VRL-1 corresponding to

Acc No AF129113 in overlapping PCR fragments after

reverse transcription of F-11 total RNA (fragment A: 34–

568 bp¼ 534 bp, fragment B: 549–1205 bp ¼ 656 bp,

fragment C: 1061–1897 bp¼ 836 bp and fragment D:

1618–1897 bp¼ 633 bp) Even though there was only one

band visible in the agarose gel for each PCR product,

sequence analysis of different cloning experiments yielded

either the rat or sometimes the mouse VRL-1 sequence To

prove the possible expression of mouse VRL-1 in F-11 cells,

we tested the PCR products on a 6% nondenaturing

polyacrylamide gel and found that fragment A, B and D

clearly separated into two bands from which the upper band

always corresponded to a rat brain control (Fig 2)

Both bands from F-11 fragment B were cloned into

pCRII-Topo vector (Invitrogen) Sequence analysis

revealed that the upper band always corresponds to rat

VRL-1mRNA, whereas the lower band was identical with

the mouse VRL-1 mRNA (Acc No NM_011706) Graphi-cal alignment of the open reading frames of rat VRL-1 (Acc

No AF129113) and mouse VRL-1 (Acc No NM_011706) shows that rat and mouse VRL-1 share 92% sequence identity The ORF length of rat VRL-1 is 2286 bp whereas the mouse VRL-1 has 2271 bp This results in a protein of

761 amino acids for rVRL-1 and of 756 amino acids for mVRL-1 which cannot be separated by SDS/PAGE The primers we chose to examine rat VRL-1 in F-11 cells were also capable of amplifying the mouse orthologue (Fig 3) Consequently we examined the F-11 parental cell line N18TG2 and found mouse VRL-1 expression due to its origin (mouse neuroblastoma) (Fig 4) As controls, rat brain and F-11 cDNA were used On a 6% polyacrylamide gel fragments A, B and D of F-11 cells again separated into two bands The slower migrating band always corresponded

to the rat brain control, and the faster migrating band to the N18TG2 control (Fig 5)

The existence of both rat and mouse VRL-1 in the same cell was confirmed by F-11 single cell RT-PCR In all analyzed cells (n¼ 15) expression of both VRL-1 species was found Separation of the RT-PCR products of fragment D on a 6% nondenaturing polyacrylamide gel resulted in two bands for each single F-11 cell (Fig 6) and subsequent sequence analysis of the upper and lower fragment from one single cell confirmed the previous results

Localization of heterologously expressed vs endogenous VRL-1 in F-11

To assess the subcellular localization of the VRL-1 receptor,

we imaged rVRL-1 and rVRL-1-GFP heterologously expressed in F-11 cells in comparison with the endogenous protein by fluorescence microscopy Indirect immuno-fluorescence of the endogenous VRL-1 visualized with

Fig 1 VRL-1 Western blot of F-11 cell homogenate Anti-VRL-1

polyclonal rabbit IgG detected a band at
80 kDa in F-11 cell

homogenate This band was completely abolished with 5 lgÆmL)1

blocking peptide corresponding to the C-terminus of VRL-1

(KNSASEEDHLPLQVLQSP-COOH).

Fig 2 Non-denaturing PAGE of overlapping PCR products from F-11 and rat brain PCR from F-11 cDNA using rat VRL-1 specific primers result in two bands for fragments A, B and D, whereas PCR from rat brain cDNA only result in one band The slower migrating F-11 cDNA fragments (F11) always correspond to the rat brain (rb) cDNA control Both F-11 bands from fragment B were eluted from the gel and cloned into the pCRII-TOPO vector Sequence analysis clearly showed that the faster migrating band corresponded to mouse VRL-1 (Acc No NM_011706) whereas the slower migrating band corres-ponded to rat VRL-1 (Acc No AF129113).

Fig 3 Graphical alignment of the open reading frames of rat VRL-1 (Acc No AF129113) and mouse VRL-1 (Acc No NM_011706) Rat and mouse VRL-1 cDNA share a homology of 92% The ORF length of rat VRL-1 is 2286 bp whereas the mouse VRL-1 has 2271 bp This results in a 761 amino-acid protein for rVRL-1 and 756 amino-acid protein for mVRL-1 Colored arrows indicate primer sequences to amplify overlapping PCR fragments of rat VRL-1 (yellow to obtain fragment A with 534 bp, green for fragment B with 656 bp, orange for fragment Cwith 836 b and cyan for fragment D with 633 bp).

Fig 4 RT-PCR of fragment A RT-PCR with rat VRL-1 specific

primer for fragment A (34–568 bp ¼ 534 bp) yielded not only a

product from RNA of 11 (F11) and rat brain (rb) but also of the

F-11 parental cell line N18TG2 This product could only be derived from

the mouse variant +/–, with/without reverse transcriptase.

Fig 5 Non-denaturing PAGE of overlapping PCR products from F-11, rat brain and N18TG2 F-11 PCR products (F11) A, B and D separated into two bands, whereas PCR products from rat brain (rb) or N18TG2 cells (N) only result in one band The slower migrating of the two F-11 PCR bands always corresponded to the rat brain control, the faster migrating band to the N18TG2 control In case of Cthe PCR product from rat brain appeared lower than that of F-11 and N18TG2.

anti-VRL-1 polyclonal antibody gives only weak signals in

the cytoplasm of F-11 cells (Fig 7A,B) In contrast rVRL-1

transiently expressed in F-11 cells showed up predominantly

at the plasma membrane and neurite-like extensions

(Fig 7C,D) When rVRL-1-GFP of transiently transfected

F-11 cells was imaged by the GFP fluorescence, some of it

also localizes to the plasma membrane but most of the

fusion protein appeared on intracellular membranes (ER)

rVRL-1 is a glycoprotein

In lysates of pcDNA3.1/rVRL-1 transfected F-11 cells,

anti-VRL-1 immunoreactivity appeared as multiple bands which

is characteristic for glycoproteins To confirm this

post-translational modification of VRL-1, we incubated cell

lysates from transfected cells with glycosidases as described

previously [6] Deglycosylation of rVRL-1 was probed by anti-VRL-1 Western blotting Incubation with Endo H abolished the upper band of the anti-VRL-1 immunoreac-tivity doublet band at > 80/84 kDa The lower band of the doublet at 80 kDa increased proportionally in intensity, but the diffuse anti-VRL1 immunoreactivity at 97 kDa was unaffected (Fig 8A) Neither the 97 kDa nor the 84 kDa anti-VRL-1 immunoreactivity band were observed subse-quent to incubation of the rVRL-1-containing cell lysates with PNGase F; only the 80 kDa band could be observed Our data indicate that both high mannose-type glycosyla-tion and complex glycosylaglycosyla-tion of rVRL-1 occurs These findings are in agreement with previous investigations on rVR1 [6]

Identical observations were made with pcDNA3.1/ rVRL-1-CT-GFP transfected F-11 cells Anti-GFP (Fig 8B) and anti-VRL-1 (Fig 8C) Western blots of F-11 cells show an analogous pattern of the rVRL-1 glycopro-tein, when the
30 kDa molecular weight of GFP is taken into account The main rVRL-1-GFP band appeared at

110 kDa, the upper band at 114 kDa and the diffuse band at 128 kDa The endogenous VRL-1 can also be observed at
80 kDa in the anti-VRL-1 Western blot and does not appear to be glycosylated Lower bands are due to unspecific reaction of the anti-VRL-1 antibody

Discussion

F-11 cells were first generated by Platika et al [7] as a model

to analyze the properties of single neurons Four cell lines (F-11 A–D) showed properties characteristic of DRG neurons, such as action potentials, extensive neurite-like processes and expression of neuronal gangliosides Even

Fig 6 Non-denaturing PAGE of single cell RT-PCR fragment D.

Single F-11 cells (sc1–5) show the two band pattern for fragment D.

The upper correspond to the rat brain (rb) cDNA control, the lower

band to the N18TG2 (N) cDNA control Both fragments from a single

F-11 cell (sc1) were cloned and sequenced.

Fig 7 Fluorescent images of VRL-1 and VRL-1-GFP in F-11 cells Indirect immunofluorescence with anti-VRL-1 polyclonal antibody (A–D) Endogenous VRL-1 in F-11 cells only gives week signals in the cytoplasm (A,B) whereas VRL-1 in transfected F-11 cells (C,D) shows predomi-nantly plasma membrane localization GFP fluorescence of VRL-1-GFP transfected F-11 cells (E,F) Here VRL-1-GFP is located at the plasma-membrane but part of the protein remains at intracellular plasma-membranes (ER) Overlay images with DAPI-stain for nuclei are shown.

though F-11 cells have varying numbers of mouse and rat

chromosomes, they show a remarkable homogeneity of

neuronal features Three rat and mouse isoenzymes

[nucleo-side phosphorylase (NP), peptidase B (PB), mannose

phosphate isomerase (MPI)] were shown to be expressed

in all four stable F-11 cell lines A–D Unique expression of

mouse PB and MPI was observed in line C[7] As shown by

Mevel-Ninio and Weiss [12] it cannot be excluded that some

gene expression might be due to selective activation of a

previously silent gene from the neuroblastoma cell line by

the DRG They observed this phenomenon in other cell

fusion experiments

Depending on growth conditions these fusion cells alter

their morphology to a neuronal phenotype, exhibiting many

long neurite-like extensions There are several differential

features of DRG cells present in F-11 cells such as l- and

d-opioid receptors, receptors for prostaglandin and

brady-kinin, and voltage-sensitive calcium channels Also F-11

cells synthesize and release substance P [8] Here we show

that F-11 cells express another receptor expected in DRG

neurons They express the vanilloid-like TRP channel

VRL-1 as shown by Western blot analysis Bender et al

[9] isolated a rat VRL-1 mRNA from F-11 cells identical to

that observed in dorsal root ganglion extracts and suggested

that the F-11 cells most likely are derived from

medium-sized Ad-fibers Surprisingly when performing PCR with rat

VRL-1specific primers we detected two products instead of

one, from which the slower migrating band corresponded to

a rat brain control Sequence analysis of both bands clearly

showed that the faster migrating band corresponds to

mouse VRL-1 (Acc No NM_011706) whereas the slower

migrating band corresponds to rat VRL-1 (Acc No

AF129113) Our findings that the mouse and rat VRL-1

are both expressed in individual F-11 cells fits well with this

result In F-11 parental cell line N18TG2 we detected the

expression of mouse VRL-1 due to its murine origin Therefore we propose that in the F-11 fusion cell no selective activation of a previously silent gene from the neuroblastoma cell line by the DRG cell occurs

Rat and mouse VRL-1 cDNA are 92% identical On protein level five amino acids located near the N-terminus are missing in the rat VRL-1 as compared to its mouse orthologue Unfortunately it is not possible to distinguish between the two on the protein level using commercially available antibodies Due to the expression of the endo-genous protein, the N18TG2 cells are appropriate for functional investigations of the mouse VRL-1 The DRG-derived F-11 cell line provides an additional powerful experimental system for functional studies of VRL-1 However, one has to be aware that both the mouse and the rat protein are expressed

In a comparative study we here show that in F-11 cells the heterologously expressed rVRL-1 is located at the plasma membrane and in neurite-like structures whereas the endogenous protein appears only in the cytoplasm, prob-ably at intracellular membranes When GFP is fused to the C-terminus of rVRL-1 a portion is observed at the plasma membrane, but is associated with intracellular membranes, likely the endoplasmic reticulum Another notable differ-ence could be observed when we looked at the glycosylation status of VRL-1 Surprisingly we observed no evidence of glycosylation of the endogenous VRL-1 at
80 kDa in the anti-VRL-1 Western blot, whereas the overexpressed rVRL-1 was shown to be glycosylated in the same cells Obviously, we only observe an endogenous VRL-1 variant in F-11 cells, which for unknown reasons is retained

in intracellular compartments in an unglycosylated state Because in Western blot and immunofluorescence experi-ments the amount of VRL-1 is very low, this might represent an immature protein One way to prove whether

Fig 8 Deglycosylation with N-glycanase and endoglycosidase H of VRL-1 and VRL-1-GFP transfected F-11 cells (A) Anti-VRL-1 Westernblot (WB) of VRL-1 transfected F-11 cells Anti-VRL-1 immunoreactivity appeared as multiple bands in lysates of transfected F-11 cells which is characteristic for a glycoprotein Incubation of cell lysates with Endo H abolished the upper band of the anti-VRL-1 immunoreactivity doublet band at
80/84 kDa, the diffuse anti-VR1 immunoreactivity at
97 kDa was unaffected After incubation with N-Gly, neither the
97 kDa nor the
84 kDa anti-VRL-1 immunoreactivity band were observed, only the 80 kDa band showed up with strong intensity (B) and (C) Anti-GFP and anti-VRL-1 Western blot of F-11 cells expression VRL-1-GFP The same band pattern of the VRL-1 glycoprotein as in (A) is observed, with the difference that GFP shifts the molecular weight
30 kDa higher The endogenous VRL-1 can be observed at
80 kDa in (C) and is not glycosylated Lower bands are unspecific reaction of the anti-VRL-1 antibody.

the m-VRL-1 and/or r-VRL-1 protein is expressed

signifi-cantly by untransfected F-11 cells would be to overexpress

the mVRL-1 and look for glycosylation, but at present the

mouse clone is not available to us Whether the

glycosyla-tion is responsible for membrane targeting of VRL-1 and

can be induced by signaling molecules which activate

endogenous VRL-1 in F-11 cells still needs to be

investi-gated

Our data indicate that both N-linked high mannose-type

glycosylation and complex glycosylation, i.e

endoglycosi-dase H-resistant glycosylation of rVRL-1 occur These

findings are similar to previous investigations on rVR1,

where the same glycosylation pattern was found [6] In order

to determine the glycosylation sites of rVRL-1 and mVRL-1

we used the PROSITE prediction tool (http://www.exp

asy.org/tools/scanprosite; Gattika et al [13]) for the

detec-tion of Asn-X-Ser/Thr Asn-glycosyladetec-tion consensus motif

within the VRL-1 primary structure Three potential

Asn-glycosylation sites were detected for rVRL-1, namely 63–66

NTSA, 571–574 NNST and 572–575 NSTV With respect to

the membrane topology predicted by the programTMHMM

(http://www.cbs.dtu.dk/services/TMHMM-2.0; [14]) only

N571 and/or N572 are located extracellularly and can be

glycosylated An alignment of rVR1 and rVRL-1 shows

that these Asn-glycosylation sites are located in an

analog-ous position to the Asn-glycosylation site in rVR1, between

the fifth transmembrane sequence and the pore loop Only

one potential Asn-glycosylation site was detected for

mVRL-1, namely 567–570 NTTV, which also is located

extracellularly We were previously able to confirm N604 as

the only glycosylation site in rVR1 by site-directed

muta-genesis [6]

Acknowledgements

We would like to thank Dr Erik Wade (Gru¨nenthal GmbH) and

Dr Chris Weise for critical reading of the manuscript Many thanks to

Doris Kru¨ck for her technical assistance with cell culture This work

was supported by the Bundesministerium fu¨r Bildung und Forschung

(BMB + F; 01 GG 9818/0), Deutsche Forschungsgemeinschaft

(DFG; SFB 515) and Fonds der Deutschen Chemischen Industrie.

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