Tài liệu Báo cáo khoa học: Insulin-dependent phosphorylation of DPP IV in liver Evidence for a role of compartmentalized c-Src ppt

DPP IV coimmunoprecipitated with the cellular tyrosine kinase Src c-Src with maximal association also observed after 2 min following insulin injection.. Following injection of the protei

Evidence for a role of compartmentalized c-Src

Nicolas Bilodeau1, Annie Fiset1, Guy G Poirier2, Suzanne Fortier1, Marie-Claude Gingras3,

Jose´e N Lavoie3and Robert L Faure1

1 Pediatric Research Unit, CRCHUL ⁄ CHUQ, Faculty of Medicine, Laval University, Que´bec, Canada

2 Quebec Proteomic Center, CRCHUL ⁄ CHUQ, Faculty of Medicine, Laval University, Que´bec, Canada

3 Cancer Research Center, CRHDQ ⁄ CHUQ, Faculty of Medicine, Laval University, Que´bec, Canada

Dipeptidyl peptidase IV (DPP IV, CD26, EC 3.4.14.5)

is a type II membrane glycoprotein that is expressed in

a variety of cell types [1] DPP IV belongs to a serine

class of proteases exhibiting a restricted substrate

spe-cificity which favours release of Xaa–Pro or Xaa–Ala

dipeptides from the N terminus of proteins [2,3]

Within a cell, DPP IV is transported with high

preci-sion [4] and is synthesized with an uncleaved signal

sequence that functions as a membrane-anchoring

domain [5] It has been shown that cysteine residues

and conformational changes are important

compo-nents that facilitate sorting [6] Glycosylation is crucial

[7,8] and recent data have highlighted the importance

of both glycosylation and the lipid microenvironment [9] Among the proteins DPP IV may bind are: adeno-sine deaminase [10], the kidney Na+⁄ H+ exchanger [11], the protein-tyrosine phosphatase (PTP) CD45 [12] and the tyrosine kinase of the cellular Src (c-Src) fam-ily p56lck[13] In hepatocarcinoma cells, kinase activity was detected in DPP IV immunoprecipitates [14]

In liver parenchyma, immunohistochemistry studies have shown that DPP IV is located mainly in the bile canalicular membrane [1] In the renal brush border, DPP IV is located in the microvilli and not in the

Keywords

c-Src; DPP IV; endosomes; tyrosine

phosphorylation, subcellular fractionation

Correspondence

R.L Faure, Pediatric Research Unit (Cell

Biology Laboratory), Room 9800, CHUL

Medical Research Center, 2705 Laurier

Boulevard, Que´bec, QC, G1V 4G2, Canada

Fax: +1 418 654 2753

Tel: +1 418 656 4141, extn 48263

E-mail: robert.faure@crchul.ulaval.ca

(Received 16 November 2005, revised 23

December 2005, accepted 3 January 2006)

doi:10.1111/j.1742-4658.2006.05125.x

Dipeptidyl peptidase IV (DPP IV, CD26, EC 3.4.14.5) serves as a model aimed at elucidating protein sorting signals We identify here, by MS, sev-eral tyrosine-phosphorylated proteins in a rat liver Golgi⁄ endosome (G ⁄ E) fraction including DPP IV We show that a pool of DPP IV is tyrosine-phosphorylated Maximal phosphorylation was observed after 2 min fol-lowing intravenous insulin injection DPP IV coimmunoprecipitated with the cellular tyrosine kinase Src (c-Src) with maximal association also observed after 2 min following insulin injection DPP IV was found phos-phorylated after incubation of nonsolubilized G⁄ E membranes with [c-32P]ATP The c-Src inhibitor PP2 inhibited DPP IV phosphorylation Oriented proteolysis experiments indicate that a large pool of c-Src is pro-tected in G⁄ E fractions Following injection of the protein-tyrosine phos-phatase inhibitor bpV(phen), DPP IV levels markedly decreased by 40% both in plasma membrane and G⁄ E fractions In the fraction designated

Lh, DPP IV levels decreased by 50% 15 min following insulin injection Therefore, a pool of DPP IV is tyrosine-phosphorylated in an insulin-dependent manner The results suggest the presence of a yet to be characterized signalling mechanism whereby DPP IV has access to c-Src-containing signalling platforms

Abbreviations

bpV(phen), bisperoxovanadium 1,10-phenanthroline; c-Src, cellular tyrosine kinase Src; Cyt, cytosol; DPP IV, dipeptidyl peptidase IV; ER, endoplasmic reticulum; G ⁄ E, Golgi ⁄ endosome; Gi and Gh, Golgi intermediate and heavy endosomes; GLP-1, glucagon-like peptide-1;

IR, insulin receptor; Li and Lh, light intermediate and heavy endosomes; PM, plasma membrane; PTP, protein-tyrosine phosphatase;

PY, phosphotyrosine; WGL, wheat germ lectin.

coated pit microdomain [15] In hepatocytes, DPP IV

is transported rapidly from the basolateral membrane

to the apical membrane by endocytosis [16] In

Madin–Darby canine kidney (MDCK) cells, a study of

chimeric forms of DPP IV has shown that the luminal

domain of DPP IV carries dominant apical sorting

information while the short cytoplasmic tail and the

transmembrane domain contain competing basolateral

sorting information [17] From one cell type to

another, DPP IV is sorted by different mechanisms

Hence in hepatocytes, DPP IV reaches the apical

mem-brane by transcytosis; while in MDCK cells, apical

and basolateral proteins are segregated from each

other in the trans-Golgi network [18]

DPP IV exopeptidase activity is involved in a variety

of regulatory processes including chemokine regulation

[19] and maintenance of physiological glucose

homeos-tasis [20] Knockout mice lacking the gene for DPP IV

show enhanced insulin secretion and accelerated

clear-ance of blood glucose coincident with increased

endo-genous levels of both glucagon-like peptide-1 (GLP-1)

and glucose-dependent insulinotropic polypeptide [21]

Pharmacological inhibition of DPP IV activity increases

insulin production and improves glucose control in

dia-betic animals [20,22–24] as well as in humans [25] Apart

from its proteolytic activity, DPP IV is also engaged in

multiple functions depending on its ability to bind to

extracellular matrix [26] Hence, DPP IV may be

involved in normal tissue architecture and growth

pat-terns [27] DPP IV binding to type 1 collagen and

fibro-nectin has been demonstrated [28,29] and DPP IV can

be considered as a cell surface adhesion receptor for

fibronectin [30] with possible implications in cell

migra-tion and metastasis [27,30,31] Also, DPP IV funcmigra-tions

in triggering the immune response [19,32]

Previously, we reported the presence of a series of tyrosine-phosphorylated proteins in a wheat germ lec-tin (WGL) subfraction prepared from a hepatic endo-somal fraction [33] Using MS, we identified the most abundant tyrosine-phosphorylated proteins first We show here that one of these proteins, DPP IV, is tyro-sine-phosphorylated in a ligand-dependent manner

Results

MS analysis of major proteins purified

by antiphosphotyrosine (PY) affinity column chromatography

We have reported previously the presence of several tyrosine-phosphorylated proteins in WGL affinity col-umn chromatography eluates prepared from a com-bined fraction of endosomes and Golgi elements (G⁄ E) isolated from liver parenchyma [33] Identification, by finger printing MS, of the nine major proteins purified

by anti-PY affinity column chromatography, stained with Coomassie blue, indicates that of these proteins, four [insulin receptor (IR), LAR, ER-60, SAPAP-3] are related to signalling events (Table 1) Identification

of the IR was expected, as it is readily concentrated by the WGL affinity column chromatography step [34] The PTP LAR is less well characterized However pre-viously, it was reported as being a regulator of the IR [35–37] The cysteine protease ER-60 was purified first from the endoplasmic reticulum (ER) of rat liver [38] ER-60 was found to be regulated by insulin and PTP-1B [39] SAPAP-3 is a signalling protein found associated with tyrosine phosphorylation events in membrane subdomains [40–43] The other major proteins identified were: the chaperone BIP, the

Table 1 MS analysis of major endosomal proteins purified by anti-PY affinity column chromatography Endosomal glycoproteins were eluted from anti-PY affinity column Major proteins of: 220, 180, 117, 110, 106, 79, 61, 60, 38 kDa stained with Coomassie blue were excised from gels after SDS ⁄ PAGE and subjected to proteolysis and MALDI-TOF analysis Data were analysed using MASCOT ; accession numbers for each scored protein in the NCBI nonredundant databank are listed; Sequence coverage indicates the percentage of the identified protein covered

by the sequences of identified peptides; m indicates the molecular mass of each protein predicted from the sequence (pred.) or experiment-ally observed in the gel (expt.)

Protein

Sequence coverage (%) mpred.⁄ expt(Da) Accession no Name

NP_062122 Protein-tyrosine phosphatase, receptor-type, F: LAR 4 198 640 ⁄ 180 000 NP_058767 Insulin receptor (precursor) 19 159 420 ⁄ 220 700 NP_019369 Inter-alpha-inhibitor H4 heavy-chain 9 103 930 ⁄ 117 400

A39914 DPP IV, membrane-bound form precursor 21 91 650 ⁄ 106 400

protease inhibitor inter-alpha-inhibitor H4, the

trans-porter hemopexin and beta-1 adducin—a component

of the cytoskeleton

DPP IV phosphorylation in the G/E fraction

Assessment of DPP IV distribution in our hepatic

frac-tions, using anti-DPP IV (26C), showed that
80% of

the amount of DPP IV detected was located in the

G⁄ E fraction No DPP IV signal was observed in the

cytosol (Cyt) The remaining portion (
20%) was

present in the plasma membrane (PM) fraction

(Fig 1) We then verified DPP IV phosphorylation in

the G⁄ E fraction by use of an anti-PY IgG (4G10)

Following insulin injection (1.5 lgÆ100 g)1 body

weight), the IR was readily internalized as originally

described [44] (Fig 2A, upper panel) The IR tyrosine

phosphorylation and autophosphorylation activity

were both maximal before 15 min postinsulin injection

Under these circumstances, analysis of DPP IV

immuno-complexes revealed a signal detected by the

anti-PY IgG This signal increased after 2 min

post-injection (Fig 2A, lower panel) Sequence analysis

(LC-MS⁄ MS) of the excised immunoprecipitated

110-kDa band (SYPRO Ruby staining) confirmed unambiguously that this protein was DPP IV (Fig 2B) Previously, DPP IV was thought to be asso-ciated with c-Src-like kinases in lymphocytes [45] In addition, another study has shown that c-Src is present

in endosomes of fibroblasts [46] We detected c-Src in DPP IV immunocomplexes, with an increased signal observed 15 min following insulin injection (Fig 2A, lower panel)

We then verified DPP IV phosphorylation in vitro Following incubation of the nonsolubilized G⁄ E fraction in the presence of [c-32P]ATP, and immuno-precipitation with anti-DPP IV IgG, a phosphorylated protein of appropriate apparent molecular mass (110 kDa) was observed (Fig 3A) DPP IV 32P phosphorylation was alkali resistant Insulin injection (1.5 lgÆ100 g)1 body weight) also increased DPP IV phosphorylation by twofold above basal levels by

15 min When the PTP inhibitor bisperoxovanadium 1,10-phenanthroline [bpV(phen)] was added to the incubation medium, DPP IV phosphorylation was enhanced at 0 (control) and 2 min, but not at 15 min postinsulin injection (Fig 3A) In order to link this phosphorylation event with c-Src catalytic activity, samples were incubated either in the presence or absence of the c-Src inhibitor PP2 [47] prior to DPP IV immunoprecipitation The results show that DPP IV phosphorylation was readily abolished when PP2 was added to the incubation medium Also, we note the presence of an associated band around

56 kDa, presumably c-Src itself or a putative substrate (Fig 3B)

Localization of c-Src in G/E fractions

We assessed further c-Src localization in our fractions Permeabilization of the G⁄ E membranes with Triton X-100 resulted in loss of several proteins, most notably albumin (66 kDa), indicating that during permeabiliza-tion, soluble luminal proteins were washed out (Fig 4B) A number of proteins ‘disappeared’ fol-lowing treatment with proteinase K alone while the 66-kDa albumin was protected The 66-kDa albumin band almost completely disappeared when permeabi-lized membranes were treated with proteinase K along with other bands including the 110-kDa band (presum-ably DPP IV) (Fig 4B) The quality of the permeabili-zation step was also assessed by electron microscopy The G⁄ E fraction mainly contains typical lipoprotein-filled tubulovesicular elements as well as 70–400-nm diameter vesicles [48] (Fig 4C) The permeabilization step resulted in empty vesicular elements (Fig 4D) Therefore, while partial solubilization of membrane

Fig 1 Distribution of DPP IV in hepatic subcellular fractions The

Cyt, PM and G ⁄ E fractions were submitted directly to immunoblot

analysis (80 lg protein; 7.5% resolving gel) using the anti-DPP IV

(26C) IgG Results are also presented as a percentage of the total

amount of DPP IV detected, calculated from the yields measured

for each fraction (see Experimental procedures) This experiment

was repeated three times with similar results; mean ± SD are

shown.

elements by 0.1% Triton X-100 is possible, we were still

in a position to address the question of the orientation

of c-Src We used the endosomal fraction G⁄ E as well

as the Golgi intermediate and heavy endosomes

(Gi⁄ Gh) and the light intermediate and heavy

endo-somes (Li⁄ Lh) fractions [49] Li is a homogeneous

fraction containing late endosomes and a negligible

amount of the marker enzymes sialyl transferase and

galactosyl transferase The Gi fraction representing

early endosomes is contaminated (
50%) by Golgi

elements The other fractions (Lh, Gh) contain less

characterized endosomes and are rich (80%) in Golgi

elements As above, the fractions were subjected to

proteinase K digestion after a membrane

permeabiliza-tion step (Triton X-100 0.1%) In the G⁄ E, Lh and Gh

fractions, c-Src was detected easily in all conditions

(control, Triton 0.1%, proteinase K) except for the

per-meabilized membranes subjected to proteolysis (Triton

0.1% + proteinase K) (Fig 4A) In contrast, c-Src was

not protected from proteinase K degradation in the

PM fraction for both conditions (nonpermeabilized or

permeabilized) (Fig 4A) Using the same assay, we also

determined that DPP IV signal disappeared only when

permeabilized membranes (G⁄ E) were submitted to

proteolysis (Fig 4A) Therefore, the results indicate

that in endosomal fractions, c-Src is largely protected

from exogenously added proteinase K

DPP IV levels following stimulation with insulin and bpV(phen)

In order to examine changes in DPP IV levels follow-ing insulin stimulation, rats were injected with the PTP inhibitor bpV(phen) 16 h and 30 min prior to insulin injection and isolation of the G⁄ E and PM fractions

No effect on DPP IV level was detected following insulin injection However, DPP IV levels, as detected

by immunoblotting (26C), decreased by
40% when bpV(phen) was injected (Figs 5A and C) Such a

A

B

Fig 2 Insulin-dependent tyrosine phosphorylation of DPP IV and

its association with c-Src in the G ⁄ E fraction (A) Rats were injected

with insulin [1.5 lgÆ100 g)1 body weight (bw)] The G ⁄ E fraction

was isolated at the indicated times postinjection (Upper panels)

Proteins were separated by SDS ⁄ PAGE (80 lg, 7.5% resolving

gel); the IR was detected by using either the anti-IR b-subunit IgG

or the anti-PY IgG (4G10) Autophosphorylation of the IR (95 kDa

32 P panel) was achieved by incubating aliquots (30 lg protein) with

[c- 32 P]ATP Following centrifugation, the pellet was solubilized and

proteins immunoprecipitated using the anti-IR b-subunit IgG

Immu-noprecipitates were separated by SDS ⁄ PAGE and gels were

sub-jected to alkali treatment and autoradiography (Lower panels)

DPP IV immunoprecipitation: Aliquots of G ⁄ E fraction (200 lg

pro-tein) were immunoprecipitated using an anti-DPP IV IgG (MA-2607).

Immunoprecipitated proteins were separated by SDS ⁄ PAGE (10%

resolving gel) Membranes were incubated with anti-DPP IV (26C),

anti-PY (4G10) or anti-c-Src IgG (pieces of the same membrane).

The signals were submitted to densitometric analysis, and the

results were expressed as a percentage of the maximum signal.

Each value represents the mean ± SD of three independent

experi-ments (B) Amino acid sequence of rat DPP IV (NCBI accession

number NP_36921, Swiss-Prot P14740) The immunoprecipitated

110-kDa band, stained with SYPRO Ruby (left panel), was excised

and subjected to proteolysis Rat DPP IV peptide sequences that

were identified by LC-MS ⁄ MS are boxed Hashed boxes indicate

that a common sequence is present in two different peptides.

Results are representative of three independent experiments.

decrease was also observed for the PM fraction

(Figs 5B and C) In order to assess whether this effect

on DPP IV level was coincident with a

phosphoryla-tion event, we used an antibody which reconizes

residues phosphorylated by Src kinases (aPY-42

antibody) The results revealed the coincident

hyper-phosphorylation of a 100-kDa band This is consistent

with the view that a c-Src-dependent phosphorylation

event had occurred (Fig 5A)

Further fractionation was then used to refine our

assessment of DPP IV and c-Src distribution

Follow-ing insulin injection, IR accumulation and tyrosine

phosphorylation was observed for all examined

frac-tions, most evidently for the Lh, Gi and Gh fractions

(Fig 6A) The results show that both c-Src and

DPP IV are also located mainly in the Lh and Gh

fractions No changes in DPP IV levels are observed

following insulin injection, except at 15 min

postinjec-tion where the signal declines significantly by more

than 50% in the Lh fraction (n¼ 4; P < 0.001)

(Fig 6B) No significant changes in c-Src levels were

observed

Discussion

Previously, we have reported the presence of a series

of tyrosine-phosphorylated proteins partially purified

from hepatic endosomes [33] Following anti-PY

affin-ity column chromatography, a systematic identification

performed first on the more abundant protein species

reveals here that one of these is DPP IV (Table 1)

DPP IV is well represented in the G⁄ E fraction where

it is found even more abundantly than in the PM frac-tion (Fig 1) At the cell surface, DPP IV is located mainly in the bile canalicular domain This relative abundance in the G⁄ E fraction may be explained by the diverse representation of the three major domains (sinusoidal, lateral, bile canalicular) of the hepatocytes present in the PM fraction [50]

To the best of our knowledge, tyrosine phosphoryla-tion of DPP IV has not been reported before In addi-tion, the results show that DPP IV phosphorylation is regulated, thus defining a new insulin-dependent effect The observation that maximal DPP IV phosphoryla-tion (after 2 min postinsulin injecphosphoryla-tion) does not corres-pond with maximal IR tyrosine phosphorylation is consistent with the fact that DPP IV is not phosphor-ylated by the IR

Previous studies performed with immune cells have shown that DPP IV is associated with the c-Src related tyrosine kinase p56lck [13], despite a short (6 residues) cytoplasmic tail Investigation here for a role of c-Src

in DPP IV phosphorylation indeed reveals that not only is c-Src associated with DPP IV, but its associ-ation is dependent of insulin with maximal associassoci-ation coincident with maximal tyrosine phosphorylation of DPP IV in vivo (Fig 2) Insulin-dependent DPP IV phosphorylation is also readily detected in vitro and is furthermore inhibited by the c-Src inhibitor PP2 This confirms that DPP IV is tyrosine-phosphorylated and further supports the idea that c-Src is involved in DPP IV phosphorylation

A

B

Fig 3 In vitro phosphorylation of DPP IV (A) Rats were injected with insulin (1.5 lgÆ100 g)1body weight) The G ⁄ E frac-tion was isolated at the indicated times postinjection and aliquots (100 lg protein) were incubated with [c- 32 P]ATP in the pres-ence or abspres-ence of 100 l M bpV(phen) They were solubilized and proteins immunoprecip-itated using the anti-DPP IV IgG (MA-2607) The immunoprecipitates were separated by SDS ⁄ PAGE (10% resolving gel) and gels were subjected to autoradiography before and after alkali treatment (B) The G ⁄ E fraction was isolated 15 min following insulin injection and was subjected to phosphorylation, in the presence or absence

of the c-Src inhibitor PP2 (10 l M ), and then immunoprecipitated as above Results are representative of three independent experiments.

A B

D C

Fig 4 Oriented proteolysis: The tyrosine kinase c-Src is protected from exogenously added protease in endosomal fractions (A, upper pan-els) The G ⁄ E, Lh, Gh and PM fractions (100 lg protein) were incubated in the presence or absence of Triton X-100 and proteinase K before immunoblotting with the anti-c-Src IgG The same experiment (lower panel) was performed using the G ⁄ E fraction and the anti-DPP IV (26C) IgG Results shown are typical of three independent experiments (B) The G ⁄ E fraction (100 lg protein) was incubated in the presence or absence of Triton X-100 (0.1%) and proteinase K before staining with SYPRO Ruby The 66-kDa (albumin) and 110-kDa bands are shown with arrows (C) Electron microscopy of the G ⁄ E fraction that was purified and processed as described in Experimental procedures Note the presence of typical tubulovesicular structures as well as lipoprotein-filled vesicles (70–400 nm) (Scale bar ¼ 200 nm) (D) Electron micros-copy of the G ⁄ E fraction treated with 0.1% Triton X-100 as described in Experimental procedures Note the absence of typical lipoprotein-filled (dark) vesicles (Scale bar ¼ 200 nm).

c-Src is known to be located in endosomes [46] and

Golgi elements [51] where it is thought to regulate

retrograde transport [52] In lipid raft compartments,

c-Src plays a role in signalling events [53] It is also

clear, either by immunofluorescence microscopy of

endogenous or transfected c-Src (data not shown) or

by immunoblotting of endosomal fractions (G⁄ E, Lh,

Gh and Gi, Li) (Figs 2, 4 and 6), that c-Src is

distri-buted in the vacuolar system Our results also provide

the first evidence that c-Src has access to the lumen

Indeed, oriented proteolysis indicates that a pool of

c-Src is protected from exogenous proteolysis There are no known translocation motifs in c-Src, and the mechanism of c-Src translocation is yet to be charac-terized However, the dynamic role of the translocons [54,55] and membrane restructuring enzymes [56] in protein targeting is beginning to be perceived For instance, one striking example of c-Src location inside one organelle has been reported for the inner mem-brane of mitochondria of osteoclasts [57] Moreover, there are 50 tyrosine residues in the sequence of rat DPP IV, all of which are located in the lumen

A

B

C

Fig 5 Effect of the PTP inhibitor bpV(phen) on DPP IV levels in

G ⁄ E and PM fractions (A) bpV(phen) was injected (0.3 mgÆ100 g)1

body weight) 16 h and 30 min before the injection of insulin

(1.5 lgÆ100 g)1body weight) Endosomes (G ⁄ E) were isolated at

the noted times and were submitted directly to immunoblot

analy-sis (100 lg protein; 7.5% resolving gel) using the anti-DPP IV (26C)

IgG or the aPY-42 antibody (B) bpV(phen) was injected into rats

16 h and 30 min before liver excision The PM fraction was

pre-pared as described and immunoblotted as in (A) (C) DPP IV signals

obtained in (A) and (B) were submitted to densitometric analysis,

and the results were expressed as a percentage of the maximum

signal, respectively Means ± SD are shown (n ¼ 11 in G ⁄ E

frac-tion, n ¼ 4 in PM fraction).

A

B

Fig 6 DPP IV level is decreased by insulin in the Lh subfraction (A) Following insulin injection (1.5 lgÆ100 g)1 body weight), frac-tions (Li, Lh, Gi and Gh) were isolated at the indicated times Aliqu-ots were immunoblotted (40 lg protein; 7.5% resolving gel) using

an anti-IR b-subunit IgG (95 kDa, b-subunit panel) or an anti-PY IgG (95 kDa aPY panel) (B) Immunoblot analysis of c-Src and DPP IV (80 lg protein; 7.5% resolving gel) using anti-c-Src and anti-DPP IV (26C) IgG (pieces of the same membrane) DPP IV signals are expressed as a percentage of the maximal value; means ± SD are shown (DPP IV: *Lh: P < 0.01, 0 min vs 15 min, n ¼ 4; Student’s t-test).

The results show also that DPP IV levels are

affec-ted following stimulation with a potent PTP inhibitor

[bpV(phen)] The observation that this effect coincides

with the hyperphosphorylation of a 110-kDa band

revealed by the aPY-42 antibody, supports the idea

that DPP IV tyrosine phosphorylation is related to

DPP IV levels (Fig 5) Hence, in the presence of

bpV(phen) a relatively small pool of DPP IV can be

continuously diverted towards lysosomal

compart-ments for degradation Alternatively, a soluble form of

DPP IV can be released from the cell surface In this

regard, an increased circulating concentration of the

soluble form of DPP IV may result in an increased

proteolysis of GLP-1 peptides and thus decreased

insu-lin secretion [20] The insuinsu-lin-dependent

phosphoryla-tion of DPP IV observed here may thus provide a

regulatory loop among a target organ (liver) and the

insulin secreting cells Deregulation of this DPP IV

phosphorylation mechanism may have implications for

the homeostasis of circulating GLP-1 levels and

diabe-tes However, we did not detect significant changes in

circulating DPP IV activity, using

Gly-Pro-p-nitro-anilide as a substrate in our acute conditions of

sti-mulation (insulin dose: 15 lgÆ100 g)1, control: 0.122 ±

0.013 UÆmL)1, n¼ 25; bpV(phen): 0.124 ± 0.0045

UÆmL)1, n¼ 27; U ¼ amount of enzyme which

hydrolyses 1 lmol substrateÆmin)1) It remains possible

that more chronic alteration of circulating insulin

results in significant changes of circulating DPP IV

Indeed, further fractionation demonstrated the

pres-ence of a significant decrease in DPP IV levels in the

Lh fraction thus revealing that DPP IV is subject to

ligand control in a precise microenvironment This is

also consistent with the fact that the IR, DPP IV and

c-Src are present mainly in the same fractions (Lh and

Gh) This therefore points to the importance of

sub-jecting these fractions to further purification and

bio-chemical characterization in order to gain a more

detailed understanding of this process

In conclusion, the results presented here demonstrate

that DPP IV is tyrosine-phosphorylated in an

insulin-dependent manner in hepatic endosomal fractions The

possible involvement of luminal c-Src in this process

suggests the presence of a mechanism whereby DPP IV

en route along with the endocytosed IR can reach

compartments where c-Src is present

Experimental procedures

Reagents and antibodies

Porcine insulin was from Sigma (St Louis, MO) The

anti-body directed against the b-subunit of the IR was from BD

Transduction Laboratories (rabbit polyclonal, 188430) The hybridoma (26C, clone 287) expressing the monoclonal antibody against DPP IV was kindly provided by M.G Farquhar (University of California, San Diego, CA) and was used for immunoblotting experiments The anti-DPP IV used for immunoprecipitation experiments was from Endogen (Woburn, MA) A mixture of antibodies against c-Src 1 : 1 (N-16, sc-19 and SRC2, sc-18, Santa Cruz Biotechnologies, Inc., Santa Cruz, CA) was used for immunoblots The monoclonal anti-PY IgG (4G10) used to detect IR b-subunit phosphorylation was purchased from Upstate (Lake Placid, NY) The antiphospho-E4orf4 (Y42) 42-2 was produced by injecting rabbits with a chemically synthesized peptide comprising phosphorylated Tyr42 (HEGVY[PO3H2]IEPEARGRLC) coupled to mcKLH (Imject Mariculture Keyhole Limpet Hemocyanin, Pierce Biotechnology Inc., Rockford, IL), following recommenda-tions of the manufacturer This phosphosite is the major residue phosphorylated by Src kinases on the adenoviral protein E4orf4 [58,59] The serum was absorbed on immo-bilized phosphorylated peptide using a SulfoLink Kit (Bio-Lynx, Brockville, ON) and blocked against an excess of nonphosphorylated peptide during immune detection The specificity of the purified 42-2 antibody was tested by west-ern blot analysis of E4orf4 immune complexes and total cell lysates from cells transfected with wild type Flag-E4orf4 as compared to mutant Flag-E4orf4 (Y42F) alone, or together with c-Src or v-Src to induce maximum tyrosine phos-phorylation of Ad2 E4orf4 and of Src substrates as well The antibody reacted specifically with wild-type Ad2 E4orf4 but not with mutant E4orf4 (Y42F) and the signal was proportional to the level of tyrosine phosphorylation This antibody does not react with the tyrosine-phosphoryl-ated IR but it does react against other PY proteins that are selectively modulated by E4orf4 and whose phosphoryla-tion is modulated by Src (data not shown) E4orf4 is itself

a Src substrate, which acts as a modifier of Src-dependent phosphorylation [59,60] For western blot studies we used the enhanced chemiluminescence kit Western Plus (Perkin Elmer Life Sciences Inc., Boston, MA) and Immobilon-P transfer membrane (Millipore, Bedford, MA) [c-32P]ATP (1000–3000 CiÆmmol)1) was from New England Nuclear Radiochemicals (Lachine, QC) The c-Src inhibitor PP2 was from EMD Biosciences (La Jolla, CA) Reagents for SDS⁄ PAGE were obtained from Bio-Rad (Mississauga, ON) bpV(phen) was synthesized as described [61] All other chemicals were of analytical grade and were pur-chased from either Fisher (Sainte-Foy, QC) or Roche Laboratories (Laval, QC)

Subcellular fractionation Sprague–Dawley rats (female, 140–150 g body weight) were purchased from Charles River Ltd (St Constant, QC) Work was conducted with the approval of the Laval

University Animal Care committee Rats were fasted

over-night, anesthetized with Nembutal (6.7 mgÆ100 g)1 body

weight) and injected with insulin via the left jugular vein

(1.5 lgÆ100 g)1body weight) When bpV(phen) was used in

vivo, a peritoneal injection (0.3 mgÆ100 g)1 body weight)

was made 16 h and 30 min before insulin injection Livers

were excised rapidly at the noted times postinjection and

minced in ice-cold homogenization buffer (250 mm sucrose,

50 mm Hepes pH 7.4, 40 mm sodium fluoride, 1 mm

MgCl2, 1 mm benzamidine, 1 mm phenlymethylsulphonyl

fluoride) The G⁄ E fraction was prepared immediately as

described previously [44] This fraction has been

character-ized by transmission electron microscopy, enzyme markers,

silver staining and receptor-mediated endocytosis SYPRO

Ruby (Eugene, OR) staining of SDS⁄ PAGE 1-D gels is

also shown here (Fig 4B) The endosomal fractions

previ-ously designated Li⁄ Lh and Gi ⁄ Gh were prepared from the

parent light mitochondrial (L) and microsomal (P)

frac-tions, respectively, by a flotation method as originally

des-cribed elsewhere [62] The yield of the G⁄ E fraction was

0.38 ± 0.015 mg proteinÆg)1 liver weight (n¼ 36) The

yields from the other fractions were: Li, 0.18 ± 0.036 mg

proteinÆg)1 liver weight; Lh, 0.09 ± 0.01 mg proteinÆg)1

liver weight; Gi, 0.015 ± 0.004 mg proteinÆg)1liver weight;

Gh, 0.034 ± 0.005 mg proteinÆg)1 liver weight, n¼ 36

The PM fraction was prepared according to the method

of Hubbard with modifications [44] and used directly A

yield of 1.18 ± 0.61 mg proteinÆg)1 liver weight (n¼ 22)

was obtained The Cyt fraction was generated by

centrifu-ging the homogenate at 100 000 g for 1 h and the

supernatant was collected Protein content of fractions

was determined by a modification of the Bradford method

using BSA as a standard Statistical analysis was

performed with statview (Abacus Concepts Inc.,

Berkeley, CA)

Electron microscopy

The G⁄ E fraction was immediately fixed with 2.5%

glutar-aldehyde, and 100 mm sodium cacodylate pH 7.4 Samples

were rinsed and postfixed in 1% ferrocyanide osmium

tetr-oxide, dehydrated in a graded series of ethanol and then

processed for embedding in EPON Ultrathin sections of

each block were cut and placed on copper grids, stained

with uranyl acetate and lead citrate [48] Sections were

examined with a Philips EM 301 electron microscope

(Phi-lips, Eindhoven, the Netherlands)

MS

Tyrosine-phosphorylated proteins were recovered from the

WGL subfraction of the G⁄ E fraction prepared as

des-cribed previously [33] The WGL subfraction was applied

to an anti-PY affinity column (PY-20-agarose) and

phos-phoproteins were eluted by re-suspension of each column

in 40 mm para-nitrophenylphosphate (pNPP) for 120 min

at room temperature The columns were spun to yield the eluates and protein contents in the fractions were deter-mined as above Eluates were then separated by SDS⁄ PAGE and the major bands, stained with Coomassie blue, were excised and subjected to alkylation and diges-tion procedures using lysyl endopeptidase C [63] Digesdiges-tion products were spotted on a stainless steel MALDI plate (Applied Biosystems, Foster City, CA) Analyses utilized

an automated acquisition procedure on a Voyager-DE PRO MALDI-TOF mass spectrometer (Applied Biosys-tems) operated in a delayed extraction mode mascot (Matrix Science Inc., Boston, MA) [64] was used for searches in the nonredundant NCBI database For identifi-cation of the immunoprecipitated DPP IV, a 110-kDa band, stained with SYPRO Ruby, was excised from the gel and subjected to trypsin digestion [63] The resulting pep-tides were separated by a capillary HPLC reverse phase C18 column (Picofrit BioBasic, 10 cm length, 0.075 mm internal diameter New Objective, Woburn, MA) and ana-lysed by tandem MS using a LC-MS⁄ MS quadrupole ion trap mass spectrometer (Finnigan LCQ Deca XP, Thermo Electro Corporation, San Jose, CA) mascot was used for searches in the nonredundant NCBI database [64]

Phosphorylation and immunoprecipitation assays

IR autophosphorylation and KOH treatment (hydrolysis of phosphorylated serine and threonine residues) of gels were conducted as reported previously [65] with minor modifica-tions Aliquots of intact endosomes (G⁄ E fraction) were incubated at 37
C for 15 min in the kinase buffer (50 mm Hepes pH 7.4, 3 mm benzamidine, 40 mm MgCl2, 1 mm MnCl2, 0.05% Triton X-100), in the presence of [c-32P]ATP (25 lm, 3000 CiÆmmol)1) When indicated, an inhibitor [100 lm bpV(phen) or 10 lm PP2] was added Samples were then solubilized in 1% Triton X-100 for 60 min and centrifuged at 250 000 g for 30 min The resulting superna-tants were immunoprecipitated for IR (1 lg affinity purified antibodyÆml)1; 100 lg protein) or DPP IV (5 lg affinity purified antibodyÆml)1; 500 lg protein) The resulting immuno-complexes were separated by SDS⁄ PAGE (7.5% resolving gel) and gels were subjected to autoradiography Unlabelled DPP IV immuno-complexes were analysed directly by immunoblotting using DPP IV (26C),

anti-PY or anti-c-Src IgG

Oriented proteolysis Oriented proteolysis experiments were performed essen-tially as described [33] Endosomes (G⁄ E, Lh and Gh fractions) or PM fraction were incubated in 50 mm Hepes

pH 7.4, at 4
C for 30 min in the presence or absence of 0.1% Triton X-100 and proteinase K (60 ngÆ100 lg)1 pro-tein of fractions) The membranes were then diluted

(1 : 10) in ice-cold buffer without Triton X-100 and

proteinase K and centrifuged for 30 min at 250 000 g

(TL-100, Beckman Coulter, Fullerton, CA) The resulting

pellet was analysed by transmission electron microscopy

or re-suspended in Laemmli sample buffer and subjected

to SDS⁄ PAGE (10 lg protein) Gels were stained with

SYPRO Ruby for examination or immunoblotted with

anti-c-Src and anti-DPP IV (26C) IgG

Acknowledgements

This work is supported by the Natural Sciences and

Engineering Research Council (NSERC) of Canada

(RF: OGPO157551), by the Canadian Diabetes

Associ-ation (CDA) and a grant from the FondAssoci-ation pour la

Recherche sur les Maladies Infantiles (FRMI) JL is a

chercheur-boursier(Junior 2, FRSQ), NB and AF were

supported by Canadian Institutes of Health Research

(CIHR) scholarships Dr Paul Khan (Laval University)

is greatly acknowledged for comments

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