Báo cáo khoa học: Presence of melanocortin (MC4) receptor in spiny dogfish suggests an ancient vertebrate origin of central melanocortin system pot

When expressed and characterized by radioligand binding assay for the natural MSH melanocyte-stimulating hormone pep-tides a-, b-, and c-MSH, the SacMC4 receptor showed pharmacological p

Presence of melanocortin (MC4) receptor in spiny dogfish suggests

an ancient vertebrate origin of central melanocortin system

Aneta Ringholm1, Janis Klovins1, Robert Fredriksson1, Natalia Poliakova1, Earl T Larson1,

Jyrki P Kukkonen2, Dan Larhammar1and Helgi B Schio¨th1

Department of Neuroscience, Division of1Pharmacology and Division of2Physiology, Uppsala University, Uppsala, Sweden

We report the cloning, expression, pharmacological

char-acterization and tissue distribution of a melanocortin (MC)

receptor gene in a shark, the spiny dogfish (Squalus

acanth-ias) (Sac) Phylogenetic analysis showed that this receptor is

an ortholog of the MC4 subtype, sharing 71% overall amino

acid identity with the human (Hsa) MC4 receptor When

expressed and characterized by radioligand binding assay for

the natural MSH (melanocyte-stimulating hormone)

pep-tides a-, b-, and c-MSH, the SacMC4 receptor showed

pharmacological properties very similar to the HsaMC4

receptor Stimulation of SacMC4 receptor transfected cells

with a-MSH caused a dose-dependent increase in

intracel-lular cAMP levels The SacMC4 receptor has Ala in position

59 where all other cloned MC receptors have Glu We

con-firmed that this was not due to individual polymorphism and

subsequently mutated the residue
back to Glu but the mutation did not affect the pharmacological properties of the receptor SacMC4 receptor mRNA was detected by RT-PCR in the optic tectum, hypothalamus, brain stem, telen-cephalon and olfactory bulb but not in cerebellum or in peripheral tissues This study describes the first characteri-zation of an MC receptor in a cartilaginous fish, the most distant MC receptor gene cloned to date Conservation of gene structure, pharmacological properties and tissue dis-tribution suggests that this receptor may have similar roles in sharks as in mammals and that these were established more than 450 million years ago

Keywords: GPCR; melanocortin; melanocyte-stimulating hormone; receptor

The melanocortin (MC) receptor family consists of five

subtypes, termed MC1-MC5 in mammals The melanocortin

system is unique because in addition to possessing

endo-genous agonists, it also has an endoendo-genous antagonist, Agrp

The agonists are the pro-opiomelanocortin (POMC)

clea-vage products a-, b- and c-melanocyte-stimulating hormone

(MSH) and adrenocorticotrophic hormone (ACTH)

POMC has been used extensively as a model for studies of

the evolution of neuropeptides and it is well established that

the sequence of a-MSH is highly conserved between

mam-mals and fishes [1,2] The centrally expressed MC4 receptor

received great attention by many researchers within the field

of central regulation of food intake after it was
knocked-out

in mice [3], causing over-eating and obesity Centrally

administered MC4 receptor agonists have the ability of

reducing appetite [4,5], while MC4 receptor antagonists are

very effective in increasing food intake in rodents, both in

acute and long-term studies [6–8] These findings make the

MC4 receptor very interesting for pharmacological research

and drugs against this receptor may become helpful for people suffering from disorders like obesity and anorexia The MC3 receptor has been found exclusively in the brain and it is involved with regulation of the energy balance [9] The MC5 receptor is primarily expressed in a wide range of peripheral tissues and also in the mammalian brain [10] The MC2 receptor subtype mediates the function of ACTH but does not bind a-, b- or c-MSH This receptor has been found only in the adrenal gland The MC1 receptor has a role in pigmentation and it also mediates the anti-inflammatory action of MSH [11]

Our understanding of the mechanisms of appetite regu-lation and metabolism in mammals is increasing rapidly Many peptides such as neuropeptide Y, orexins, Agrp (agouti-related peptide), ghrelin and MSH are involved in the regulation of energy balance by binding to GPCRs in the central regions of the brain [12,13] However, in
lower vertebrates, the molecular mechanisms for appetite regula-tion of these peptide binding receptors are poorly known The spiny dogfish (Squalus acanthias) is a shark and a member of cartilaginous fishes (also called chondrichth-yans) Chondrichthyans are characterized by cartilaginous skeletons, placoid scales and pelvic claspers (in males) [14] They arose from the Agnatha, the jawless fishes, in the late Silurian period, approximately 420–430 million years ago The spiny dogfish became popular as a research model among chondrichthyans and it has been extensively studied due to its peculiar rectal gland, an organ that regulates the secretion of chloride [15] Cardiovascular control has also been widely studied in the spiny dogfish [16] Several peptides have been characterized in the dogfish, including

Correspondence to H B Schio¨th, Department of Neuroscience,

Biomedical Center, Box 593, 75 124 Uppsala, Sweden.

Fax: + 46 18 51 15 40, E-mail: helgis@bmc.uu.se

Abbreviations: ACTH, adrenocorticotrophic hormone; GPCR,

G-protein coupled receptor; MC, melanocortin; MSH,

melanocyte-stimulating hormone; NDP-MSH, [Nle4, D -Phe7]a-MSH;

NTS, nucleus of the solitary tract; POMC,

pro-opiomelanocortin.

(Received 18 August 2002, revised 7 November 2002,

accepted 18 November 2002)

peptide PYY [17] and gastrin/cholecystokinin-like peptides

[18] but very few G-protein-coupled receptors (GPCRs)

have been cloned in this species Recently, we cloned one

MC4 receptor and two MC5 receptors in a teleost fish, the

zebrafish, Danio rerio [19] The results showed high

conser-vation in primary structure and pharmacology of these MC

receptors as compared with the mammalian ones The

teleosts belong to the bony fishes which arose later in the

evolution, after a split from cartilaginous fishes [20–22]

In this paper, we report the cloning, expression,

phar-macological characterization and tissue distribution of a

MC4 receptor in a cartilaginous fish, the spiny dogfish This

receptor is evolutionarily the most distant MC receptor

from mammals cloned so far

Materials and methods

Extraction of genomic DNA

Spiny dogfish genomic DNA was extracted from muscle

tissue of four different animals captured in the North Sea

(Hambergs Fisk, Uppsala, Sweden) The muscle tissue

(about 1 g) was homogenized in the lysis buffer [100 mM

EDTA (Titriplex, Merck, Stockholm, Sweden), 10 mM

Tris (VWR International, Stockholm, Sweden) and 1%

SDS (Scientific Imaging Systems, Eastman Kodak

Com-pany)] and centrifuged for 5 min at 11 500 g The

superna-tant was purified first with saturated phenol (BDH

Laboratory Supplies, Poole, UK), then with

phenol/chlo-roform/isoamyl alcohol (1 : 1 : 1) (BDH Laboratory

Sup-plies), and chloroform (KEBO Laboratory AB, Stockholm,

Sweden) The DNA was precipitated with propan-2-ol and

NH4Ac (2 : 1) and centrifuged for 30 min at 11 500 g

Finally the DNA was washed with 70% ethanol and

centrifuged again The DNA pellet was vacuum-dried and

re-suspended in water

Cloning

Degenerate primers based on conserved parts of the human,

rat, mouse and chicken MC receptors were used in different

pair-wise combinations One hundred nanograms of dogfish

genomic DNA was used as template in a low stringency

PCR, using the AmpliTaq DNA polymerase Stoffel

Frag-ment (Perkin Elmer, Roche, Langen, Germany) in a

reaction volume of 20 lL, containing 4 mM dNTP,

1· Stoffel buffer (Perkin Elmer), 60 mMMgCl2, 20 pmol

each primer and two units DNA polymerase, Stoffel

Fragment Touch-down PCR was performed, starting with

an initial 1 min 95C denaturation, followed by 22 cycles of

45 s at 94C, 45 s at 52 C to 42 C, 90 s at 72 C This was

followed by 25 cycles of 30 s at 94C, 40 s at 50 C, 1 min at

72C, with a final extension of 5 min at 72 C The PCR

gave a product of the expected size, 600 bp The 5¢ primer’s

sequence was CAY TCN CCN ATG TAY TTY TT and

the 3¢ primer ATN ACI GAR TTR CAC ATD AT Y

denotes C or T, R denotes A or G, D denotes, A, G or T, I

denotes inosine and N denotes any base The PCR product

was purified from a 1% agarose gel using Gel Extraction

Kit (Qiagen, Hilden, Germany) Re-amplification was

performed by denaturating for 1 min, followed by 45 s at

95C, 45 s at 50 C, 1 min at 72 C and 40 cycles with a

final extension of 72C for 5 min An aliquot of the re-amplified product was cloned into a Topo-vector and transformed into TOP10 cells (TOPO TA-cloning Kit, Invitrogen Corporation, Stockholm, Sweden) PCRs were performed on a GeneAmp PCR System 9700 (Perkin Elmer)

Screening of a phage genomic library and isolation

of full-length gene The spiny dogfish phage-DNA library made in kGEM-11 (Promega, Falkenberg, Sweden) with Escherichia coli KW251-stem (Promega) as a host, was kindly supplied by Anders Johnsen, Rigshospitalet, Denmark [23] The inserts

in the phages were about 15–22 kb Approximately 50 000 phages were plated out on each of 12 different 15-cm Petri dishes (roughly three genome equivalents) and grown at

37C for 8 h Plaques were lifted over to the nylon transfer membrane (Amersham Biosciences, Uppsala, Sweden) and denatured for 1 min in Soak I solution (0.5MNaOH + 1.5

MNaCl), then neutralized for 5 min in Soak II solution [1M Tris/HCl (pH 8.0) + 1.5 NaCl] and equilibrated in 2· saline sodium citrate buffer (NaCl/Cit) The filters were dried and used for hybridization The MC receptor-like sequence PCR product was labeled with32P using Mega-prime Labeling System (Amersham Biosciences) and used

as a probe Hybridization was carried out at 65C in 25% formamide (Merck Eurolab AB, Stockholm, Sweden),

6· NaCl/Cit, 10% dextran sulfate (Amersham Biosci-ences), 5· Denhardt’s solution, and 0.1% SDS overnight The fi lters were washed fi ve times in 0.2· NaCl/ Cit + 0.1% SDS for 1 h at 65C After exposure to autoradiographic films, one positive signal was selected for further selection The procedure of selection and hybridiza-tion was repeated until a single phage was isolated (three times) The phage was grown according to the protocol and the phage DNA was isolated using k-purification kit (Qiagen, Hilden, Germany) The phage was confirmed to

be true positive and used as template for sequencing to obtain the full-length receptor We sequenced about 200–

300 bp both upstream and downstream of the coding region which did not include any introns

Sequencing Sequence determinations were performed using ABI PRISM Dye Terminator cycle sequencing kits according

to the manufacture’s recommendations (Applied Biosys-tems, Stockholm, Sweden) and analyzed on an ABI PRISM-310 Automated Sequencher (Applied Biosystems) Sequences were compiled and aligned in Sequencher (Gene Codes) Sequences were compared with National Center for Biotechnology Information (NCBI) database using BlastX Alignments and phylogenetic analysis

The full-length sequence of the SacMC4 receptor was aligned with other MC receptor sequences using ClustalW (1.7) software [24] and edited manually after visual inspec-tion The sequences (see Figs 1 and 2) were retrieved from GenBank and have accession codes as follows: Homo sapiens (Hsa) MC1 (NM_002386), MC2 (NM_000529),

MC3 (XM_009545), MC4 (NM_005912), MC5

(XM_008685), Mus musculus (Mmu) MC4 (AF201662),

MC5 (NM_013596), Gallus gallus (Gga) MC4 (AB012211),

MC5 (AB012868), Danio rerio (Dre) MC4 (AY078989),

MC5a (AY078990), MC5b (AY078991) receptors The

Squalus acanthias(Sac) MC4 receptor gained the accession

number AY169401 Its phylogenetic tree was generated by

using the MEGA v.2.1 software [25] applying maximum

parsimony methods Human cannabinoid 2 receptor

(hCB2) (accession code S36750) was used as an out-group

A bootstrap consensus tree assessing the robustness of the

nodes was made with 100 replicates

Cloning into expression vector

The entire coding region of the receptor sequence was

amplified with Pfu Turbo DNA polymerase (Stratagene,

AH Diagnostic, Stockholm, Sweden) Specific primers

containing HindIII and XhoI sites were used under the

following conditions: 60 s at 95C for one cycle, then 30 s at

95C, 30 s at 53 C and 70 s at 72 C for 35 cycles The

PCR fragments were purified by QIAquick PCR

Purifica-tion Kit (Qiagen) and digested by HindIII and XhoI The

full-length receptor sequence was re-purified and ligated

into a modified pCEP4 expression vector containing the

CMV promotor [26] The new construct was sequenced and

found to be identical to the genomic clone

Site-directed mutagenesis

The A59E mutation was introduced into the SacMC4

receptor coding sequence by PCR Two complementary

oligonucleotides were designed to contain the required

mutation The SacMC4-A59E primers were 5¢-CAG CCT

CTT GGA AAA TAT TTT GGT CAT TG and 3¢-GAC

CAA AAT ATT TTC CAA GAG GCT GAA GAT G

The primers were hybridized to opposite strands of the

receptor gene and the complete coding sequence was

amplified The end primer was complementary to 3¢ or 5¢

depending on which mutagenesis primer was used (forward

or reverse) The two products were used as templates and

linked together in a second PCR, in which only the

end-primers were used

Transfection

HEK 293-EBNA cells were transiently transfected with the

constructs using FuGENETMTransfection Reagent

(Boeh-ringer Mannheim, Roche, Stockholm, Sweden) diluted in

OptiMEM medium (Invitrogen Corporation) according to

the manufacturer’s recommendations The cells were grown

in DMEM/Nut Mix F-12 with 10% fetal bovine serum

(Invitrogen Corporation) containing 0.2 mM L-glutamate

(Invitrogen Corporation) and 250 lg/ml G-418 (Invitrogen

Corporation), 100 U penicillin and 100 lg

strepto-mycinÆmL)1(Invitrogen Corporation)

Radioligand binding

Intact transfected cells were re-suspended in 25 mMHepes

buffer (pH 7.4) containing 2.5 mM CaCl2, 1 mM MgCl2

and 2 gÆL)1 bacitracin Saturation experiments were

performed in a final volume of 100 lL for 3 h at 37C and carried out with serial dilutions of125I-labelled [Nle4,

D-Phe7]a-MSH (NDP-MSH) Non-specific binding was defined as the amount of radioactivity remaining bound to the cells after incubation in the presence of 2000 nM unlabelled NDP-MSH Competition experiments were performed in a final volume of 100 lL The cells were incubated in the well plates for 3 h at 37C with 0.05 ml binding buffer in each well containing a constant concentration of125I-labelled NDP-MSH and appropriate concentrations of competing unlabelled ligands NDP-, a-, b-, c-MSH or HS014 The incubations were terminated by filtration through Filtermat A, glass fiber filters (Wallac

Oy, Turku, Finland), which had been presoaked in 0.3% polyethylenimine, using a TOMTEC Mach III cell harvester (Orange, CT, USA) The filters were washed with 5.0 mL of 50 mM Tris/HCl (pH 7.4) at 4C and dried at 60C The dried filters were then treated with MeltiLex A (Perkin Elmer) melt-on scintillator sheets and counted with Wallac 1450 (Wizard automatic Microbeta counter) The results were analyzed with a software package suitable for radioligand binding data analysis (PRISM 3.0, Graphpad Software, San Diego, CA, USA) Data were analyzed by fitting to formulas derived from the law of mass action by the method generally referred to

as computer modeling The binding assays were per-formed in duplicate wells and repeated three times Nontransfected HEK293-EBNA cells did not show any specific binding for 125I-labelled NDP-MSH NDP-MSH was radio-iodinated by the chloramine T method and purified by HPLC NDP-, a-, b-, c-MSH or HS014 were purchased from Neosystem, France

cAMP assay The experiments were performed essentially as described in earlier [27] Briefly, the cells were incubated for 2 h with

5 lCiÆmL)1 [8-3H]adenine (Amersham Biosciences, Upp-sala, Sweden) and then washed and harvested in a medium composed of 137 mMNaCl, 5 mMKCl, 0.44 mMKH2PO4, 4.2 mM NaHCO3, 1.2 mM MgCl2, 20 mM Hepes, 1 mM CaCl2and 10 mMglucose, pH adjusted to 7.4 The pelleted cells were resuspended in the medium as above containing 0.5 mM isobutylmethylxantine (Sigma) and preincubated for 10 min at 37C before adding to appropriate concen-trations of the stimulant (a-MSH) in 96-well plates (Nunc, VWR International, Stockholm, Sweden) After an addi-tional 10 min of incubation in 37C with the hormone, the reactions were stopped by rapid centrifugation at 1000 g for 1 min, removal of supernatants, and addition of 200 lL ice-cold 0.33M perchloric acid per well The plates were frozen down to )20 C, thawed, and the cell debri were spun down (1000 g for 10 min) The extent of conversion of [3H]ATP to [3H]cAMP was determined by Dowex/alumina sequential chromatography [28] [14C]cAMP (Amersham Biosciences, Uppsala, Sweden) tracer in 0.75 mL 0.33 perchloric acid (about 1000 cpm) was added to each column together with the samples The ATP/ADP and cAMP fractions were dissolved in an appropriate volume of scintillation cocktail (Optiphase Hisafe 3, Wallac, Turku, Finland) and analyzed in a b-counter The conversion to [3H]cAMP was calculated as a percentage of total eluted

[3H]ATP and was normalized to the recovery of [14C]cAMP.

The cAMP assay was performed in triplicates and repeated

twice for each receptor

RT-PCR and Southern analysis

Fresh periphery tissues (muscle, heart, liver, kidney, rectal

gland, spiral valve, eye, colon) and several brain regions

(optic tectum, hypothalamus, brain stem, telencephalon,

cerebellum and olfactory bulb) were collected from spiny

dogfish The total RNA was isolated according to the

RNeasy Mini Kit (Qiagen) protocol The RNA

prepara-tions were then DNaseI treated for 20 min at room

temperature using the RNase-Free DNase Set protocol

(Qiagen) Absence of genomic DNA in all RNA

prepara-tions was confirmed in PCR reaction using 10–100 ng of

total RNA as a template Messenger RNA was reverse

transcribed using the 1st Strand cDNA Synthesis kit

(Amersham Pharmacia Biotech) with a reverse primer

specific to dogfish MC4 receptor The produced cDNA was

used as a template for PCR with the specific primers for the

receptor gene The conditions for PCR were: 1 min initial

denaturation, then 30 s at 95C, 40 s at 55 C, 60 s at 72 C

for 35 cycles and finished by 5 min at 72C, using Taq

polymerase (Invitrogen Corporation) The following

prim-ers were used: 5¢-AGG CAC TTA ACG GCC CCG GA-3¢

and 5¢-AGA GCG AGG CCA TGA GGG CG-3¢ giving

the expected size of the PCR product of around 300 bp The

PCR products were analyzed on a 1% agarose gel The

DNA products on the gel were transferred to nylon filters

over night using 0.4 M NaOH The filter was hybridized

with a random-primed 32P-labeled, species and receptor

specific probe (Megaprime kit, Amersham Biosciences) at

65C in 25% formamide, 6 · NaCl/Cit, 10% dextran

sulfate, 5· Denhardt’s solution and 0.1% SDS over night

The fi lter was then washed fi ve times in 0.2· NaCl/

Cit + 0.1% SDS for 1 h at 65C and exposed to

autoradiography film (Amersham Biosciences) Due to the

appearance of double bands (not shown), the PCR products

were denatured in 3% formaldehyde, 25% formamide

solution and separated on 1.4% agarose gel using Mops

buffer (20 mM Mops, 2 mM sodium acetate and 1 mM

EDTA) resulting in a single band The original double

band had different relative intensity in the ethidium bromide

staining and the hybridization signal It is thus likely that the

double band was caused by an extra signal of

single-stranded DNA As positive control for the Southern blot,

the genomic DNA was used in PCR reaction Sequence

analysis of this PCR product confirmed the presence of

SacMC4 receptor sequence Water was used as negative

control The RT-PCR reactions and Southern blotting were

performed three times

Results

Several 600-bp PCR products were cloned and about 25

clones were sequenced of which two identical clones showed

high identity to the MC receptors After library screening, a

single phage was confirmed to contain a MC receptor-like

protein of 331 amino acids Among the mammalian and

chicken MC receptor subtypes, our clone had highest

identity to the MC4 receptors (69–71%) and was designated

as the SacMC4 receptor The protein sequence of the spiny dogfish receptor are shown in Fig 1, aligned with the human MC receptors, the GgaMC4 and GgaMC5 recep-tors, the MmuMC4 receptor and the recently cloned DreMC4, DreMC5a and DreMC5b receptors [19] The SacMC4 receptor has 71% identity to the HsaMC4, 69% to the GgaMC4 and 75.8% to the DreMC4 receptor Phylogenetic analysis was performed using the maximum parsimony method (MP) (Fig 2) The MC3, MC4 and MC5 receptors are more similar to each other in amino acid sequence comparison, than the MC2 and MC1 receptors are (see also previous analysis in [19]) The Hsa and MmuMC4 receptors are most similar to each other, followed by the Gga- and DreMC4 receptors As expected the SacMC4 branched out at basal to the DreMC4 receptor

As an out-group, we used the human cannabinoid 2 (hCB2) receptor

The SacMC4 receptor had an unusual amino acid in a very conserved region (TM1) All previously cloned MC receptors regardless of subtype, share the acidic amino acid Glu in position 59 in transmembrane (TM) region 1, whereas the new SacMC4 receptor surprisingly had Ala in this position (see Fig 1) In order to investigate if this was a single amino acid polymorphism, we prepared genomic DNA from three additional individuals, ran PCR to generate an  490 bp fragment containing position 59, cloned it and sequenced All the individuals had identical sequence in this region including the Ala in position 59 Subsequently we inserted Glu into position 59 by site-directed mutagenesis in order to enable pharmacological characterization (see below)

The coding sequence of the genomic clone SacMC4 and mutant SacMC4-A59E receptors were transferred to the expression vector and control sequenced The constructs were transiently expressed in mammalian cells and the receptors were tested in radioligand binding assay on intact cells using radioligand-binding assay Figure 3 shows saturation and competition curves for these dogfish recep-tors Table 1 shows the Kdand the Kivalues obtained from saturation and competition analysis, respectively Our results suggest that125I-labelled NDP-MSH bound to the SacMC4 receptor with indistinguishable affinity as com-pared with the Hsa- and DreMC4 receptors Both the wild-type SacMC4 receptor and the SacMC4-A59E mutant receptor had also the same affinities for the endogenous peptides a-MSH, and the high potency synthetic ligand NDP-MSH, as compared to the Hsa- and DreMC4 receptors c1-MSH had also the same affinity to the Hsa-and SacMC4 receptors The SacMC4 receptor had how-ever, slightly lower affinity for b-MSH, as compared with the Hsa- and DreMC4 receptors The synthetic compound HS014 had the same affinity for the Dre- and SacMC4 receptors, while it had 90-fold lower affinity for the HsaMC4 receptor The binding profile for the mutant A59E receptor was not determined for the low affinity ligands b-, c1-MSH and HS014

In order to investigate if the SacMC4 and SacMC4-A59E receptors were able to influence intracellular cAMP after stimulation of a-MSH, we tested both receptors in a cAMP assay The results are shown in Fig 4 We found that both SacMC4 and SacMC4-A59E receptors responded to the stimulation by a-MSH with the same potency These results

are in line with that which we have observed for the

HsaMC4 receptor in response to a-MSH [11]

Non-transfected HEK293-EBNA cells, which showed no

response to the a-MSH, were used as controls

Tissue distribution was determined by RT-PCR The

results of the RT-PCR are shown in Fig 5 The SacMC4

receptor was expressed in five brain regions (Fig 6) but not

in any of the peripheral tissues There were strong signals in the brain stem and the hypothalamus and slightly weaker signals in the optic tectum, olfactory bulb and telencepha-lon However, it should be noted that the PCR assay was not designed for quantification The experiments were performed three times and there were no qualitative differences between the runs The integrity of the mRNAs was tested by using zebrafish and fugu based actin primers for RT-PCRs We received a distinct product of the expected length for the cDNA from all the different tissues This PCR product was confirmed to be dogfish actin by sequencing

Discussion

We describe here the cloning of the first MC receptor in spiny dogfish The phylogenetic analysis indicates that the new receptor is an ortholog of the MC4 receptor and we use thus the nomenclature SacMC4 receptor and the gene is entered in the gene database under this name The SacMC4 receptor appears basal in the MC4 receptor phylogenetic cluster (see Fig 2) The spiny dogfish belongs to the chondrichthyans, the cartilaginous fishes, which diverged prior to the split leading to ray-finned and lobe finned fishes The sharks are thus more distant from mammals than the bony fishes, including zebrafish which we cloned earlier [19] The phylogenetic positioning of the SacMC4 receptor is

Fig 1 Amino acid sequence alignment made using CLUSTALW (1.7) software and edited by manual inspection The SacMC4 receptor served as a master for the HsaMC1-5, MmuMC4, GgaMC4, GgaMC5, DreMC4, DreMC5a and DreMC5b sequences The lines mark putative trans-membrane (TM) regions (according to [34]) The accession numbers are listed in Material and methods.

Fig 2 Phylogenetic analysis of the MC-receptor family using the

full-length amino acid sequences The tree was generated by maximum

parsimony analysis ( PAUP 4.0) The human cannabinoid 2 receptor

(hCB2) sequence was used to root the tree The numbers above the

nodes indicate percentage of bootstrap replicates The accession

numbers are listed in Material and methods.

thus in agreement with that of the cartilaginous fishes This

shows that the MC4 receptor originated before the radiation

of gnathostomes

It is interesting that despite the fact that cartilaginous

fishes diverged from the lineage leading to mammals

over 450 million years ago, the SacMC4 receptor shows

very similar pharmacological properties as the HsaMC4

receptor The characteristics of the HsaMC4 receptor, such

as relatively low affinity for c-MSH and a slightly higher affinity for b-MSH as compared with a-MSH, seem to be conserved The ligand b-MSH, whose physiological roles are still obscure, also has a higher affinity for the SacMC4 receptor than a-MSH, which is in line with our previous results for the human and rat MC4 receptors [29,30] This

Fig 3 Saturation binding with Scatchard plots (left) and competition curves for the SacMC4 and SacMC4-A59E receptors expressed in intact transfected cells The figure shows competition curves (right) for125I-labelled NDP-MSH (m), a-MSH (j), c-MSH (h) and HS014 (d) to the SacMC4 receptors, and the two first mentioned for the SacMC4-A59E receptor The binding curves were obtained by using a fixed concentration of

2 n M125I-labelled NDP-MSH and varying concentrations of the nonlabeled competing peptide Lines represent the computer-modeled best fit of the data assuming that ligands bound to one-site.

Table 1 K i and K d values (mean±SEM) obtained from competition and saturation curves, respectively, for melanocortin peptides analogs on SacMC4, SacMC4-A59E, DreMC4, HsaMC4 receptor transfected EBNA cells.

Ligand

SacMC4 (nmolÆL)1)

SacMC4-A59E (nmolÆL)1)

DreMC4 a (nmolÆL)1)

HsaMC4 a (nmolÆL)1)

125 I-labelled NDP- MSH 1.21 ± 0.44 1.93 ± 0.30 2.39 ± 0.96 2.35 ± 1.18

a Data taken from Ringholm et al [19] ND, not done.

feature was also conserved in the zebrafish receptors (see

Table 1) and our new results thus provide additional

evidence for our speculation that b-MSH may have a

specific and also an evolutionarily conserved role for this receptor subtype HS014, an antagonistic substance, is a synthetic cyclic peptide and was developed to be selective for the human MC4 receptor [31] This substance is the only one that has lower affinity for the SacMC4 receptor as compared with the human ones It could be speculated that even though the ability of the receptors to bind the natural peptides is highly conserved, the 3D binding cavity of the SacMC4 receptor may not be as well conserved to fit this synthetic ligand Moreover, our results also show that the SacMC4 receptor is a functional receptor and able to activate the Gs pathway when stimulated with a-MSH, in agreement with the other MC receptors from mammals and zebrafish

The SacMC4 receptor exhibits high sequence identity with the mammalian orthologs It also displays several of the structural characteristics typical for the mammalian MC receptors such as conserved Cys in the first extra-cellular loop, lack of Pro in TM5, short extra-cellular and intracel-lular loops, and short divergent C- and N-terminals (see Fig 1) This is in line with what we found for the DreMC receptors The SacMC4 receptor sequence had however, Ala in position 59 in TM1 We found this remarkable as all the five MC receptor subtypes in all the species cloned so far have Glu in this position TM1 is believed to contribute to the main binding region in MC receptors [32,33] Some earlier studies suggested that this acidic and hydrophilic Glu may play an important role in the ligand binding [34] while other studies have indicated that this residue may not be participating in the ligand binding [35] for the mammalian receptors It was possible that this was a mutation that was only found in the genome of the individual we cloned We investigated if this residue was conserved in the SacMC4 receptor gene by sequencing additional three individuals The results show that the missing Glu was not due to polymorphism The putative importance of the unique amino acid exchange in the SacMC4 receptor was investi-gated by mutating the Ala
back to Glu We investiinvesti-gated the mutant receptor both regarding binding of NDP-MSH and a-MSH, and the ability to increase production of adenylate cyclase when stimulated with a-MSH The SacMC4 and the SacMC4-A59E had indistinguishable Kd, Ki and

EC50-values, suggesting that this exchange is not important for the pharmacological profile of the receptor It is difficult

to speculate why this Glu59 has been replaced in the SacMC4 receptor but cloning of other MC4 receptors from other distant species as well as other MC receptors from

Fig 4 Generation of cAMP in response toa-MSH forSacMC4 (h) and

SacMC4-A59E (j) receptors in intact transfected cells Each point

represents the mean ± SEM Untransfected HEK293-EBNA (m) cells

showed no adenylate cyclase-activity in response to a-MSH The cAMP

assay was performed in triplicates and repeated twice for each receptor.

Fig 5 Expression of SacMC4 receptor mRNA as determined by

RT-PCR on total RNA preparations from spiny dogfish tissues The tissues

and the controls are denoted at the top of the figure The figure shows

4-h exposure on an X-ray film after hybridization with the SacMC4

receptor probe The size (bp) of the ladder is shown on the right The

PCR reactions and the hybridization were performed three times with

qualitatively similar results.

Fig 6 Side view of spiny dogfish (Squalus acanthias) brain Shaded sections represent regions expressing the SacMC4 receptor Dashed lines indicate incisions made to divide brain regions for collecting tis-sues for RT-PCR OB, olfactory bulb; Tel, telencephalon; OT, optic tectum; Hyp, hypothalamus; Cb, cerebellum; BS, brain stem.

dogfish may provide additional information about this

unusual replacement

The results show that the SacMC4 receptor was expressed

in olfactory bulb, telencephalon, optic tectum,

hypothala-mus, and brain stem but not in cerebellum (Fig 6) The

presence of MC4 in the hypothalamus is not surprising This

receptor is expressed in hypothalamus in all species

inves-tigated and is important in the regulation of appetite In the

telencephalon, especially the limbic system, the MC4

receptor is possibly playing a role in the communication

between the melanocortin system and the serotonergic

system and stress effects on appetite [36] The presence of

SacMC4 receptor in the olfactory bulb may suggest a role in

chemosensory mechanisms, possibly those associated with

feeding [37,38] In the brainstem, the SacMC4 receptor

could be involved in visceral afferent signals from the gut via

the nucleus of the solitary tract (NTS) The NTS could be

sending signals to the hypothalamus from the gut to

regulate energy balance [39] a-MSH immunoreactivity has

been found in the spotted dogfish (Scyliorhinus canicula)

[40], showing that perikarya were largely located in the

hypothalamus with projections running to various places

in the diencephalon The SacMC4 receptor was found

both in the hypothalamus and diencephalon, indicating that

this receptor is expressed in brain regions of sharks where

a-MSH can be found

The SacMC4 receptor was expressed only in the brain but

not in peripheral tissues This is in agreement with the

mammalian MC4 receptors that have only been found in

brain tissue [8,41] The DreMC4 receptor was also found in

the brain but rather surprisingly also in the eye,

gastro-intestinal tract and ovaries In chicken, the MC4 receptor is

expressed in a wide variety of peripheral tissues, including

the heart, adrenal glands, ovaries, testes, spleen, adipose

tissues and eye, as well as the brain [42,43] In our previous

report, we speculated that the expression pattern of the MC4

receptor in mammals had become more confined to central

regions, as compared with zebrafish and chicken [19] Our

new results from the dogfish indicate rather that the MC4

receptor had a predominant and important function in the

CNS very early in vertebrate evolution and later became

more widely expressed in zebrafish and chicken

In conclusion, our data show that the MC4 receptor had

already arisen before the radiation of gnathostomes The

spiny dogfish receptor clone will facilitate cloning in

cyclostomes and amphioxus as well as additional

gnathos-tomes Our results provide an understanding of the

evolutionary origin of the MC receptor system and enhance

further studies on their many important physiological roles

The high degree of conservation of MC receptors in teleosts

and cartilaginous fish may indicate that the MC receptors

arose even before the appearance of vertebrates The

conservation of the pharmacological properties and tissue

distribution pattern could demonstrate an early

develop-ment of a mechanism where a peptide binds to a GPCR for

central regulation of the energy balance

Acknowledgments

We thank Flemming Cornelius, University of Aarhus, Denmark for

providing dogfish tissues and Anders Johnsen, Rigshospitalet,

Den-mark for providing a dogfish phage library The studies were supported

by the Swedish Research Council (VR, medicin), the Swedish Society for Medical Research (SSMF), A˚ke Wibergs Stiftelse, Svenska La¨karesa¨llskapet, Petrus och Augusta Hedlunds Stiftelse, Go¨ran Gustavsson and Lars Hierta foundations and Melacure Therapeutics

AB, Uppsala, Sweden.

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