Tài liệu Báo cáo khoa học: Physico-chemical characterization and synthesis of neuronally active a-conotoxins docx

bovine chromaffin cells, Aplysia neurons; b, Discovered by peptide activity at nAChRs heterologously expressed in Xenopus oocytes; c, Discovered by peptide physico-chemical characteristics

M I N I R E V I E W

Physico-chemical characterization and synthesis of neuronally active a-conotoxins

Marion L Loughnan and Paul F Alewood

Institute for Molecular Bioscience, The University of Queensland, Brisbane, Australia

The high specificity of a-conotoxins for different neuronal

nicotinic acetylcholine receptors makes them important

probes for dissecting receptor subtype selectivity New

sequences continue to expand the diversity and utility of

the pool of available a-conotoxins Their identification

and characterization depend on a suite of techniques

with increasing emphasis on mass spectrometry and

micro-scale chromatography, which have benefited from recent

advances in resolution and capability Rigorous physico-chemical analysis together with synthetic peptide chemistry

is a prerequisite for detailed conformational analysis and to provide sufficient quantities of a-conotoxins for activity assessment and structure–activity relationship studies Keywords: a-conotoxins; Conus; peptide synthesis; post-translational modifications; sulfotyrosine

Classification, primary structure and biology

of a-conotoxins

Cone snails are a group of hunting gastropods that

incapacitate their prey, which consists of worms, molluscs

or fish, by envenomation Conotoxins from the venom of

cone snails are small disulfide-rich peptide toxins that act at

many voltage-gated and ligand-gated ion channels They

can be grouped according to their molecular form into

several superfamilies, each defined by characteristic

arrange-ments of cysteine residues (not necessarily a single pattern),

and characteristic highly conserved precursor signal

sequence similarities Individual conopeptide families

within a superfamily are denoted by Greek letters and

contain peptides that have a particular disulfide framework

and target homologous sites on a particular receptor [1]

Each of the characterized conopeptides is named using

a convention that indicates the activity (Greek letter), the

source species from which the peptide was first isolated

(Arabic letter(s)), the disulfide framework category (Roman

numeral) and the order of discovery within that category

(Arabic capital letter) [1] For example a-AuIB belongs to

the a-conotoxin family and was the second peptide, B, with

that framework, I, isolated and reported from Conus aulicus

[1,2] The names of some conotoxins deviate from this

nomenclature convention because their discovery preceded

its formulation Hence some a-conotoxin names do not conform to the alphabetical identifier system used to indicate order of discovery of peptides with a specified disulfide framework from the venom of any one species The framework identifiers I and II are both used in reference

to disulfide frameworks of the A superfamily without distinction

The A superfamily is so far comprised of the K+channel blocking jA familiy and the a and aA families, which together with the w family act at the nicotinic acetylcholine receptor (nAChR) No aA or w conopeptides have been reported to block neuronal nicotinic receptors with high affinity Rather, they are generally muscle-specific nicotinic receptor antagonists [1] The a-conotoxins fall into two categories depending on whether they act at muscle-type or neuronal-muscle-type receptors The neuronally active a-conotoxins are the focus of this minireview

The known a-conotoxins consist of 12–19 amino acids Most a-conopeptides have four cysteine residues and the general sequence GCCXmCXnC The disulfide connectivity

is between alternate cysteine residues (I-III, II-IV)

The numbers of amino acid residues encompassed by the second and third cysteine residues (m) and the third and fourth cysteine residues (n) are the basis for a further division into several structural subfamilies (a3/5, a4/3, a4/6 and a4/7) [1,3,4] For example a4/6-AuIB belongs to the 4/6 disulfide loop size subgroup of the a-conotoxin family The neuronally active a-conotoxins are typically from the a4/7, a4/6 and a4/3 subfamilies (Table 1) Peptides from the most abundant a4/7subfamily are typically 16 residues in length and range from  1600 to  1900 Da in mass However there have been recent additions to this subfamily in which

Correspondence to P F Alewood, Institute for Molecular Bioscience,

The University of Queensland, Brisbane, QLD 4072, Australia.

Fax: + 61 73346 2101, Tel.: + 61 73346 2982,

E-mail: P.Alewood@imb.uq.edu.au

Abbreviations: c-CRS, c-carboxylation recognition sequence;

nAChRs, nicotinic acetylcholine receptors; RT, retention time;

PTM, post-translational modification; TPST, tyrosyl-protein

sulfotransferase; TCEP, tris(2-carboxyethyl)phosphine; M-biotin,

maleimide-biotin; NEM, N-ethylmaleimide; IAM, iodoacetamide.

(Received 22 January 2004, revised 16 March 2004,

accepted 6 April 2004)

there have been extensions at the N-terminus or C-terminus

to a length of up to 19 residues and the mass range has been

extended to almost 2200 Da [5] For example, there are

three additional residues at the N-terminus in the case of

GID [5] Peptides from the a4/3 and a4/6 subfamilies are

typically 12 and 15 residues, respectively Unusually, EI has

the same disulfide framework as a4/7 conotoxins that target

neuronal nAChRs but has been reported to antagonize the

neuromuscular receptor as do the a3/5 and aA conotoxins

[1,6]

There is a conserved proline between the second and third

cysteine residues in almost all a-conotoxins except ImIIA

and ImII [7,8] However, the former has not been confirmed

to be a neuronally active a-conotoxin, despite its sequence

similarity with ImI and ImII There is also a conserved

serine residue between the second and third cysteine residues

in many a-conotoxins The residue N-terminal to the first

cysteine residue of the sequence is in most cases glycine,

although exceptions are the recently isolated peptides GID

and PIA that have c-carboxyglutamic acid and proline,

respectively, in that position (Table 1) [5,9] More generally,

the residues in the first loop tend to fit into defined

categories, whereas the second loop seems to have greater

heterogeneity of residues There appears to be a relationship between selected sequence motifs and receptor subtype specificity and these sequence patterns may be a basis for further defining subclasses within the neuronally active members of the a-conotoxin family [9a]

There are many interesting features of the biology of Conus species and the functional applications of the a-conotoxins in their venom It has been conjectured that

of the estimated 500 Conus species, each appears to make at least one nAChR antagonist [1] However, for some Conus species pharmacological screening of crude venom samples has not shown a-conotoxin activity (A Nicke &

M Loughnan, unpublished results) Nonetheless it has become apparent that in any one species there may be multiple peptides that target nAChRs [1], and it seems likely that the complement of neuronally acting a-conotoxins in one species may cover a range of subtype specificities There are examples of combinations of muscle-type and neuronal-type a-conotoxins in a single species, particularly in the case

of the fish-eating Conus species For example, C.geographus venom contains the muscle-acting a-conotoxins GI and GII together with the neuronally acting a-conotoxins GIC and GID [1,5,10] and C.magus venom contains the

Table 1 Comparison of selected known a-conotoxins from a4/7, a4/6 and a4/3 families, their selectivity for mammalian nAChR subtypes, size, route of discovery, method of synthesis and reference for synthesis Asterisks (*) indicate an amidated C-terminus The letters O and Y denote hydroxyproline and sulfotyrosine, respectively The letter Y

~~ denotes sulfotyrosine identified after original sequence was published The symbol c denotes c-carboxyglutamic acid Dashes indicate gaps in the sequence alignment Mass (monoisotopic) in daltons, given for disulfide-bonded form Conserved cysteine residues are shown in red and a highly conserved proline in the first loop is shown in green The peptides Vc1.1, GIC, ImII and ImIIA were identified by prediction from the nucleic acid sequence Other peptides were identified by isolation of the peptides from the venom ducts

in response to activity assays or by physico-chemical characteristics Im peptides are from C.imperialis, Au from C.aulicus, M from C.magus, Ep from C.episcopatus, Pn from C.pennaceus, P from C.purpurascens, G from C.geographus and E from C.ermineus Prey groups are denoted by p,

m, v for piscivores, molluscivores and vermivores, respectively Discovery and synthesis methods were as follows: a, Discovered by peptide activity

at nAChRs in native tissues (e.g bovine chromaffin cells, Aplysia neurons); b, Discovered by peptide activity at nAChRs heterologously expressed

in Xenopus oocytes; c, Discovered by peptide physico-chemical characteristics, and confirmed by synthesis and assay; d, Discovered by gene sequencing with peptide sequence deduced from cDNA library obtained by RT-PCR of cone snail mRNA; e, Synthesised by Fmoc assembly, trifluoroacetic acid cleavage and directed disulfide formation (off-resin); f, Synthesised by Fmoc assembly, modified trifluoroacetic acid cleavage and air oxidation in ammonium bicarbonate for disulfide formation; g, Synthesised by tBoc assembly, HF cleavage and air oxidation in ammonium bicarbonate for disulfide formation; N/A, not available.

ImI G CC SD P R C AWR C * v a7 1350.5 c,a,e [20]

ImII A CC SDRR C RWR C * v a7 1508.6 d,e [8] AuIB G CC SY P P C FATNPD- C * m a3/b4 1571.6 b,e [2] AuIA G CC SY P P C FATNSDY C * m (less active) 1724.6 b,e [2] AuIC G CC SY P P C FATNSGY C * m (less active) 1666.6 b,e [2] AnIA CC SH P A C AANNQDY C * v a3/b2, a7 1673.6 c,f [21] AnIB GG CC SH P A C AANNQDY C * v a3/b2, a7 1787.6 a,f [21] AnIC GG CC SH P A C FASNPDY C * v a3/b2, a7 1805.6 a,f [21] MII G CC SN P V C HLEHSNL C * p a3b2; a6b2b3 1709.7 b,e [13] EpI G CC SD P R C NMNNPDY C * m a3b2/a3b4; a7 1866.6 c,a,f [24] Vc1.1 G CC SD P R C NYDHPEI C * m a3a7b4/a3a5b4 1805.7 d,a,g [22] PnIA G CC SL P P C AANNPDY

[A10L]PnIA G CC SL P P C ALNNPDY

PnIB G CC SL P P C ALSNPDY

GIC G CC SH P A C AGNNQHI C * p a3b2 1608.6 d,e [10] GID IRD c CC SN P A C RVNNOHV C # p a3b2 2184.6 b,g [5] PIA RDP CC SN P V C TVHNPQI C * p a6b2b3 1980.8 d,e [9]

EI RDO CC YH P T C NMSNPQI C * p (muscle-type) 2091.8 a [6] a

Synthesis method and activity refer to the unsulfated peptides.

muscle-acting a-conotoxin MI and the neuronally acting

a-conotoxin MII [11–13] A biological interpretation of this

emerging pattern of paired ligand types is that prey capture

might rely on the combination of muscle-acting antagonists

to cause paralysis and neuronally acting antagonists to

inhibit the flight-or-fight response [10,14] Although distinct

peptide complements have been attributed to individual

species [15], there are instances of a single a-conotoxin

sequence occurring in more than one species For example,

GID from C.geographus has also been isolated from

C.tulipavenom [5]

Conus venoms together provide an array of ligands

with selectivity for various neuronal nAChR subtypes

(Table 1, [9a]) Evolutionarily, this diversity of toxins has

been generated by a hypermutation process that allows

protection of conserved cysteine residues and high

substi-tution rates for the intervening residues in the mature

toxin peptides [3,16,17] Each venom peptide is processed

from a prepropeptide and the three defined regions of this

precursor (signal sequence, proregion, mature toxin) have

different rates of divergence [3,16] Proposed

diversifica-tion mechanisms include gene duplicadiversifica-tion and subsequent

diversifying selection, or targeted gene mutation with

some sophisticated molecular regulation, perhaps based

on repair processes or recombination processes acting in

discrete exon regions [16–19] Prey-driven diversifying

selection may be a factor for dominant expressed toxins,

given the feeding specificity of cone snail species [17] It

has been suggested that nicotinic ligands from fish-hunters

are more likely than those from snail and worm-hunters

to target vertebrate nAChRs with high affinity [1] Besides

the piscivores (fish-hunters) C.magus, C.geographus and

C.purpurascens, other species that have also yielded

neuronally active a-conotoxins include the vermivores

(worm-hunters) C.imperialis and C.anemone, and the

molluscivores (mollusc-hunters) C.aulicus, C.victoriae,

C.pennaceusand C.episcopatus (Table 1) [2,5,7–10,13,20–

24] Many more species are represented in a-conotoxin

sequence information contained in patent documents, for

example [25] However these are not within the scope of

this review because their activities have not been reported,

although the patent applications reflect the commercial

interest in this class of conopeptides as potential

candi-dates for drug development

Many of the neuronally active a-conotoxins show a

high conservation of the local backbone conformation

although the surfaces are unique [3,25a] The common

structural scaffold suggests that the hypervariability of the sidechain groups confers peptide specificity for different neuronal nAChR subtypes [3] Although the a-conotoxins are considered to have rigid structures, multiple inter-convertible isomers may exist in solution [1,3] (see also below) This potential heterogeneity is an important issue

in the isolation, analysis and chemical synthesis of these peptides

Post-translational modifications of neuronally active a-conotoxins

A feature of conotoxins in general is that they are relatively richly endowed with a wide spectrum of post-translational modifications (PTMs) and this aspect has been comprehen-sively reviewed elsewhere [14,15,26] The classical published a-conotoxin sequences contained comparatively few mod-ifications apart from disulfide bridges and C-terminal amidation However, more recently isolated peptides have expanded the list of modifications and they now seem comparable with the rest of the conotoxins in this respect (Table 2) A thorough exploration of the significance of these modifications for the function of a-conotoxins is yet to

be completed and reported

Disulfide bridge formation is a basic feature of the a-conotoxins with their defined cysteine spacing and disulfide connectivity Non-native disulfide-bonded cono-peptides are often considered to be inactive but this is not always the case Intriguing results have been obtained in structure-function studies of a synthetic variant of a-AuIB with non-native disulfide bond connectivity, where an enhancement of biological activity was observed [27] Hydroxylation of proline has been observed in several neuronally acting a-conotoxins but of these only GID has been described [5] Hydroxyproline also occurs elsewhere in the A superfamily: in the muscle-specific a-EI, in aA-EIVA, EIVB and PIVA and in w-PIIIE [1] The significance of this modification has not been determined Many other cono-toxins that contain multiple hydroxyproline residues also have naturally occurring under-hydroxylated variants such

as in the example of TVIIA [28] and perhaps the modifi-cation may not be critical However there was no evidence

of a variant of GID with proline in place of the single hydroxyproline residue [5]

Amidation of the C-terminus is a feature of most conotoxins and so far occurs in the majority of the a-conotoxins with the exceptions of GID and the

muscle-Table 2 Post-translational modifications (PTMs) in neuronal a-conotoxins.

Disulfide bridge formation Yes all

Sulfation of tyrosine Yes EpI, PnIA, PnIB, AnIA, AnIB, AnIC [24,31,21]

Cyclization of N-terminal Gln No

Bromination of tryptophan No

Isomerization of tryptophan No

Epimerization of other residues (L fi D) No

acting SII [1,5] The functional significance of the nature of

the C-terminus in neuronal-type a-conotoxins has not been

established However a recent study of the effects of an

amidated or free carboxyl C-terminus on activity of a

synthetic a-conotoxin (AnIB) at nAChR subtypes expressed

in oocytes showed subtype specific differences in activity [21]

Carboxylation of glutamic acid to c-carboxyglutamic

acid has been reported in GID [5] It has been estimated that

10% of conopeptides contain c-carboxyglutamic acid and

the conantokins (NMDA receptor antagonists) have

mul-tiple c-carboxyglutamic acid residues that are important

for maintaining their three dimensional structure [15,29]

The existence of c-carboxylation recognition sequences

(c-CRSs) in conopeptide precursors from some Conus

species has been established and an enzyme responsible for

glutamic acid carboxylation in conantokin G has been

described [30] The c-CRS regions in conantokin G and

bromosleeper peptides [30] are highly dissimilar suggesting

thatthissequenceinformationcannotnecessarilybeextended

to other conopeptide families c-CRSs in a-conotoxin

precursors have not been described

Sulfation of tyrosine has been observed in EpI, PnIA,

PnIB, AnIA, AnIB and AnIC [21,24,31] The mechanism of

sulfation of tyrosine by an enzyme, tyrosyl-protein

sulfo-transferase (TPST), has not been elucidated It may involve

a recognition sequence in the peptide precursor [15] or a

consensus sequence in the mature peptide [32]

Alternat-ively, secondary structure may be the major determinant of

sulfation and the TPST might broadly recognize any

sufficiently exposed tyrosine residue [33,34] The

sulfotyro-sine-containing a-conotoxins have not previously been

reported to have substantially different activity from the

unmodified variants [15,24] Recent comparisons of EpI

with [Y15]EpI, and AnIB with [Y16]AnIB found about

three-fold and ten-fold reduced activities, respectively, of the

unsulfated forms relative to the sulfated peptides [21,35] In

the case of AnIB, tyrosine sulfation selectively influenced the

binding to the mammalian a7 but not the a3b2 subtype [21]

The effects of substitution of phosphotyrosine for

sulpho-tyrosine in a-conotoxins have not been investigated

Post-translational modifications such as O-glycosylation

of serine or threonine residues, bromination of tryptophan,

isomerization of tryptophan or Lfi D epimerization of

other residues have been observed in conotoxins from other

families [1,15] but not reported for a-conotoxins However,

characterizations of a-conotoxins have not routinely

inclu-ded tests for isomerization and epimerization modifications

Aspects of the biosynthesis of conotoxins in the cone snail

and the mechanisms for incorporation of PTMs have

garnered considerable interest [15] Hypermutation of

amino acid residues is a feature of the mature toxins but

in contrast the prepropeptide precursor sequence,

partic-ularly the signal sequence, seems to be highly conserved for

each family of conotoxins [3,16] Precursor sequences are

available for conotoxins from most families but there have

been relatively few precursors published in journals for the

a-conotoxins (Table 3) Nevertheless it is interesting to

examine the available prepropeptide sequence information

for ImIIA and Vc1.1, ImII, GIC and PIA, each of which

was identified by prediction from a genomic DNA clone

[7–10,22] Comparison of the peptide sequences GID, EI,

ImIIA, GIC and PIA suggests that there are anomalies in Tab

relation to GID, EI and PIA, which each have an

N-terminal sequence motif RDX It is tempting to speculate

about the relationship of this motif to the potential dibasic

cleavage sites for generation of the mature peptides from the

prepropeptides, particularly in those cases where the residue

at position X becomes post-translationally modified in the

mature peptide However there are also many other

sequences reported in patent documents that have not been

considered here and for many of those the deduced cleavage

site does not have a dibasic motif [25] There has been

increasing utility of molecular biology techniques for

identification of new a-conotoxin sequences Reliance on

the gene sequence of a conopeptide alone without

verifica-tion from the peptide sequence might miss PTM sites, or

misidentify the cleavage site for generation of the mature

peptide Much further work is necessary to elucidate the

mechanisms of incorporation of PTMs in the biosynthesis

of conopeptides Appropriate methods of analysis need

to be addressed to ensure recognition of these PTMs,

if present, in the course of characterization of native

a-conotoxins

Analysis of neuronally active a-conotoxins

using HPLC and MS, including identification

of post-translational modifications

Isolation and identification

Standard procedures for identification and isolation of

a-conotoxins generally incorporate separations using

reversed-phase HPLC, size exclusion or ion exchange

chromatography in combination with mass-based screening

and functional screening Most of the a-conotoxins

identi-fied so far are relatively hydrophilic and hence tractable

Mass-based screening entails searching by LC/MS or MS

alone for components with a mass in the defined range for

a-conotoxins and two disulfide bonds (identified by partial

reduction and alkylation studies and MS/MS) It may also

include diagnostic LC/MS for recognition of some

post-translational modifications and possibly MS/MS for

recog-nition of conserved sequence motifs The small size range

of a-conotoxins would seem ideal for MS-based sequence

determination However, complete de novo sequencing of

conopeptides by MS/MS is still considered experimental,

and primary sequence information is usually obtained by

Edman degradation sequencing, interpreted in conjunction

with MS data for the intact molecule Efficient sequence

analysis usually requires that the peptides are reduced and

the cysteine residues alkylated in order to verify their

identification Although there are standard procedures for

reduction and alkylation, their application to conopeptide

analysis and characterization is by no means trivial, and

often optimization on a case-by-case basis is required [14]

Sample amounts may be limiting even with the enhanced

sensitivity of current automated sequence analysis

instru-ments

Chromatography and structural heterogeneity

Several a-conotoxins have a characteristic asymmetric peak

under standard reversed-phase HPLC elution conditions

[5,36] The anomalous chromatographic behaviour is seen

particularly with a-CnIA, a-MI, a-GI and a-GID for both native and synthetic forms and persists even after repeated refractionation [5,36,37] The asymmetry may be more pronounced under isocratic elution conditions It presum-ably reflects structural heterogeneity and can be interpreted

as a slow interconversion between two conformers; this conclusion has been supported by the results of structure studies NMR studies have shown the existence of two distinct interconvertible conformers for GI and multiple conformers of CnIA [36,37] This heterogeneity may yet prove to be an important feature of some a-conotoxins in the understanding of structure-function relationships and the interaction of these ligands with the nAChR

Identification of PTMs Methods for the characterization of PTMs in conotoxins have been reviewed elsewhere, with particular emphasis

on the utility of MS [14], but specific aspects relevant to a-conotoxins (identification of C-terminal amidation, sulfotyrosine, hydroxyproline and c-carboxyglutamic acid) are revisited here The identification of the PTM is usually confirmed by synthesis of the modified a-conotoxin and comparison with the natural peptide

Identification of the nature of the C-terminus The identification of C-terminal amidation or a free carboxyl terminus in an a-conotoxin is usually straightforward with the one mass unit difference between the two forms readily apparent from the monoisotopic mass determined by high resolution mass spectrometry There may be difficulties in interpretation of MS data when there are ambiguities arising from, for example, asparagine to aspartic acid, or glutamine to glutamic acid changes [14] The a-conotoxins EpI, PnIA, GIC, GID, AnIA and AnIB contain pairs of asparagine residues [5,10,21,23,24] (Table 1), and deamida-tion may confound MS data for these peptides

Determination of sulfotyrosine Identification of sulfo-tyrosine in peptides is usually by mass spectrometry and the lability of the sulfogroup in mass spectrometry analysis allows recognition of the modification, and differentiation of sulfotyrosine and phosphotyrosine [38] Characterization of the sulfotyrosine-containing a-cono-toxin EpI was undertaken by a combination of mass spectrometry and modified amino acid analysis [24] The conotoxins a-PnIA and a-PnIB from C.pennaceus were initially identified and reported as unmodified sequences although an unidentified mass discrepancy had been recognized [23] The verification of tyrosine sulfation in a-PnIA and a-PnIB and revision of those sequences were made in an investigation of labile sulfo- and phospho-peptides by electrospray MALDI and atmospheric pressure MALDI mass spectrometry [31] The sulfation

of three conotoxins from C.anemone was identified on the basis of LC/MS under different conditions together with the difference between the observed mass and that predicted from primary Edman sequence data [21] The presence of either sulfation or phosphorylation may

be indicated when liquid chromatography/electrospray ionization mass spectrometry shows doubly protonated species of the modified a-conotoxins with additional related

ions at +40 m/z (+80 Da) Further examination by

MALDI MS or ESI MS in both positive and negative ion

modes, at high and low energy, or MALDI high-energy

collision-induced dissociation, can be undertaken to confirm

tyrosine sulfation by distinguishing features of ionization

and fragmentation [31,38,39]

Determination of hydroxyproline and c-carboxyglutamic

acid The presence of these modified residues in

a-conotoxins is generally determined by a combination

of mass spectrometry, Edman N-terminal sequencing and

amino acid analysis [14] Hydroxyproline residues can be

reliably identified in the course of N-terminal Edman

sequencing of peptides [14] Mass spectrometry has also

been used for the analysis of peptides containing

hydroxy-proline and bromotryptophan, by resolution,

high-accuracy precursor ion scanning utilizing fragment ions

with mass-deficient mass tags [40] c-Carboxyglutamic acid

residues are readily recognized in electrospray mass

spectrometry under standard conditions because of the

lability of the extra carboxyl group ()44 Da) ([5,41] and as

shown in Fig 1) This residue can not be reliably identified

by standard N-terminal Edman sequencing procedures

because inefficient extraction of the polar derivative

generates a largely blank cycle [14,42], although there

may be residual amounts of glutamic acid Modified

Edman sequencing procedures, modified amino acid

analysis or colorimetric c-carboxyglutamic acid assays

can also be used to confirm this residue

Disulfide linkage determination Identification of closely spaced cystine residues in peptides with complex disulfide linkage patterns is still considered a significant analytical challenge and determination of disul-fide linkages in even the relatively simple a-conotoxins can still pose difficulties There have been several studies on characterization of closely spaced, complex disulfide bond patterns in peptides, usually based on stepwise reduction and differential alkylation of cysteine residues in a sequen-tial manner (Fig 2), although there may be complications because of disulfide shuffling via the thiol-disulfide exchange reaction These studies are of relevance to the characteriza-tion of neuronal a-conotoxins although many of the studies have been validated with other well-characterized peptides (some of them including a-conotoxin SI) and proteins One

of the original comprehensive studies of disulfide bond linkage relevant to conotoxins involved analysis of differ-entially alkylated products by Edman N-terminal sequen-cing and MS [43] A subsequent study specific for conopeptide analysis described differential alkylation fol-lowed by tandem mass spectrometry to determine disulfide bond connectivity, and indicated that reduction and alky-lation under acidic conditions is preferred to avoid condi-tions that promote scrambling of disulfide bonds [44] A further modification has been the use of iodination labelling

of the peptide to obtain better separation of intermediates

in partial reduction and alkylation studies [45] Disulfide

Fig 2 Scheme of disulfide determination Diagram of the general strategy for determination of disulfide linkage of conotoxins by dif-ferential reduction and alkylation of cystine residues and subsequent analysis by LC/ESI MS/MS or by Edman sequencing [43,44,46] (A) Partial reduction of peptide containing disulfide bonds by incubation with a low concentration of tris(2-carboxyethyl)phosphine (TCEP) (0.1–0.5 m M ) at 65 C for 10–15 min, generating partially reduced peptides that were immediately alkylated by N-ethylmaleimide (NEM) (two to five-fold molar excess over the Cys residues of the analyte) present in the TCEP solution (B) Complete reduction with dithio-threitol and alkylation by iodoacetamide (IAM) to label the Cys residues of the peptide that were not reduced by TCEP (C) Analysis of the resulting peptides differentially alkylated with NEM and IAM to identify the disulfide linkages.

Fig 1 LC/MS analysis of crude venom from C geographus Example

of experiment approach using LC/ES MS of crude extract of

C.geographus showing complexity of crude venom and showing the

identification of a modified peptide, GID (2184.9 Da) [5] Total ion

chromatogram from positive ion analysis using LC/ES QqTOF mass

spectrometry over a range m/z 500–2000 Chromatography was on a

Zorbax 300SB C3, 2.1 · 150 mm, 5 lm column run at 300 llÆmin)1

with a gradient from 0 to 60% solvent B over 60 min Solvent A was

0.1% formic acid in water and solvent B was 90% acetonitrile, 0.09%

(v/v) formic acid in water Location of the selected component has

been indicated Inset: Electrospray reconstructed mass spectrum of

selected component from main figure revealing the presence of two

components 44 Da apart, indicating the presence of a

c-carboxyglut-amic acid residue Doubly and triply charged ions were observed (data

not shown).

linkage determination in peptides and proteins by LC/

electrospray ionization tandem mass spectrometry (LC/ESI

MS/MS) in combination with partial reduction by tris

(2-carboxyethyl)phosphine (TCEP) has been described

recently [46] The general procedure in these studies has been that peptides were treated with TCEP in the presence of an alkylation reagent such as maleimide-biotin (M-maleimide-biotin) or N-ethylmaleimide (NEM), followed

by complete reduction with dithiothreitol and alkylation

by iodoacetamide (IAM) Subsequently, peptides that contained alkylated cysteine were analyzed by capillary LC/ESI MS/MS or other means to determine which cysteine residues were modified with M-biotin/NEM or IAM The presence of the alkylating reagent (M-biotin or NEM) during TCEP reduction was found to minimize the occurrence of the thiol-disulfide exchange reaction [46] In the determination of disulfide connectivity, it is advisable to undertake directed synthesis of mispaired as well as correctly disulfide-bonded conopeptides (as described below), and to compare their elution with the naturally occurring conopep-tide in chromatography studies This is particularly applic-able for a-conotoxins because there are a manageapplic-able number of potential disulfide isomer variants Authenticity

is indicated by chromatography coelution of natural and synthetic peptides after coinjection Ideally, disulfide con-nectivity would be further confirmed by assessing the structure of the naturally occurring peptide However, the limitation of scarcity of most conopeptides usually precludes this The possibility of activity of non-native disulfide-bonded isomers of a-conotoxins [27] precludes reliance on activity for identification of the correctly disulfide-bonded synthetic isomer

Peptide synthesis

Chemical synthesis strategies The small size (10–25 amino acids) of a-conotoxins has made chemical synthesis the preferred route of synthetic access with both Boc and Fmoc chemistry widely employed The incorporation of most post-translationally modified residues such as hydroxyproline, c-carboxyglut-amic acid or pyroglutc-carboxyglut-amic acid into synthetic a-conotox-ins is relatively straightforward through incorporation of the suitably protected amino acid in the chain assembly step By contrast, two areas of a-conopeptide synthesis can pose challenges and deserve particular attention: sulfotyrosine incorporation and disulfide bond formation together with selection of the desired disulfide bond isomer

Disulfide bond formation Synthetic strategies for the preparation of a-conotoxins vary between laboratories and often reflect different scientific

Fig 3 Schemes of directed disulfide bond formation Schemes showing orthogonal strategies for selective disulfide bond formation in synthesis

of a-conotoxins (A) One-step directed disulfide formation [52] (B) Two-step standard directed disulfide formation from Olivera and coworkers [2,8,10,13,20,50,51] (C) Two-step directed disulfide formation, illustrated with discrete mispaired isomer with small disulfide loop closed first [54] (D) Two-step directed disulfide forma-tion, in solution or resin-bound, with small disulfide loop closed first [55] (E) Three possible disulfide isomers of a-conotoxins [4,53].

needs or preferences The choice of simultaneous

(non-selective) or selective oxidation (Fig 3) for disulfide bond

formation is a major point of difference Information

described in the following sections concerning detailed

studies of selective disulfide formation with the

muscle-specific a-conotoxin SI can be extended to the neuronal

a-conotoxins

Nonselective disulfide bond formation Several research

groups have taken advantage of the fact that the native form

(I-III, II-IV C-C connectivity) of the a-conotoxins is the

predominant form accessible under simple oxidative

condi-tions from the tetrathiol (i.e fully reduced) peptide

Appropriate solvent conditions may influence the efficiency

of the process and either standard Fmoc or Boc chemistry

may be employed to generate the fully reduced conopeptide

[47,48] Disulfide bond formation is performed via a

one-step procedure usually with 0.02–0.1Maqueous ammonium

bicarbonate, pH 6.7–10, or with minor variations such as

the inclusion of 10–30% (v/v) of isopropanol, acetonitrile or

dimethylsulfoxide where required An exception to the

generally used chain assembly and deprotection procedures

employs a two-step deprotection and cleavage from

methylbenzhydrylamine resin using trifluoroacetic acid

and hydrogen fluoride, prior to nonselective disulfide

formation and a shorter oxidation at higher pH (pH 10)

[49]

Selective disulfide bond formation: off-resin

approa-ches Fmoc methodology for chain assembly together with

trifluoroacetic acid-based deprotection and cleavage of

peptide from resin is the most commonly used Typical

approaches have employed orthogonal cysteine

protec-tion (Trityl, Acetamidomethyl) for a two-step disulfide

bond formation, using reagents such as Tris buffer,

20 mM potassium ferricyanide with 0.1M Tris, pH 7.5,

or 10% dimethylsulfoxide in 0.02M ammonium

bicar-bonate, pH 6.7, for formation of the first disulfide bond,

and iodine for the second disulfide bond (Fig 3B)

[2,8,10,13,20,50,51]

A novel approach by Cuthbertson & Indrevoll employed a

one-pot regioselective formation of the two disulfide bonds

of a-conotoxin SI [52] (Fig 3A) By selecting

temperature-sensitive orthogonal cysteine protecting groups, t-butyl and

4-methylbenzyl, the target molecule was efficiently obtained

Thus the first disulfide bridge was formed directly from the

crude material by simultaneous cleavage and oxidation of

the t-butyl groups in trifluoroacetic acid/dimethylsulfoxide/

anisole (97.9 : 2 : 0.1, v/v/v) at room temperature The

subsequent heating of this solution resulted in the cleavage of

the 4-methylbenzyl groups with simultaneous oxidation

yielding the desired bicyclic product [52]

Selective disulfide bond formation: on-resin

approa-ches Two detailed studies of selective disulfide formation

in the muscle-specific a-conotoxin SI (Fig 3) [49,53],

employed both off and on-resin approaches Syntheses of

all three possible disulfide regioisomers, natural and

disulfide-mispaired, with the sequence of a-conotoxin SI

were described [53] (Disulfide isomers: natural I-III, II-IV;

mispaired nested I-IV, II-III and mispaired discrete I-II,

III-IV, Fig 3E) It was possible to achieve the desired

alignments with either order of loop formation (smaller loop before larger, or vice versa) The highest overall yields were obtained when both disulfides were formed in solution, while experiments where either the first or both bridges were formed while the peptide was on the solid support revealed lower overall yields and poorer selectivities towards the desired isomers This and further studies with a-conotoxin

SI illustrated novel protection schemes and oxidation strategies ([53–55] Fig 3C,D)

Synthesis of sulfated a-conotoxins Sulfopeptides can be prepared by chemical assembly with the incorporation of sulfated residues or less commonly

by global modification of the completed peptide using enzymic or chemical methods of sulfation The chemical synthesis of peptides containing O-sulfated hydroxy amino acids is still considered a difficult, delicate and laborious task for peptide chemists because of the intrinsic acid-lability of the sulfate moiety [50,56,57] An efficient cleavage/deprotection procedure without loss of the sulfate remains to be elucidated for Fmoc-based solid-phase synthesis of sulfopeptides [24,50,57] There have been a few reports of the solid phase synthesis of sulfotyrosine-containing a-conotoxins including EpI, PnIA, PnIB, AnIA, AnIB and AnIC and some ana-logues [21,24,56] Most of the reported syntheses of PnIA, PnIB and the [A10L]PnIA analogue have been of the unsulfated forms [51,58–61] A modified trifluoro-acetic acid-based protocol including low temperature steps and exclusion of thiol-containing scavengers, for example 95% (v/v) trifluoroacetic acid/triisopropylsilane

or 90% (v/v) aqueous trifluoroacetic acid (0C, 8 h), is generally used for cleavage of sulfopeptides assembled with Fmoc chemistry [24,56] Desulfation rate is strongly temperature-dependent whereas sidechain deprotections are less temperature-dependent and effective deprotection protocols can be developed accordingly The use of tetrabutylammonium salts (rather than sodium or barium salts) of O-sulfated hydroxy amino acids minimized desulfation during Fmoc-based assembly, room tempera-ture trifluoroacetic acid cleavage and reversed-phase HPLC purification in applications for synthesis of cholecystokinin-12 and bradykinin containing tyrosine sulfate [57], and could perhaps be applicable to synthesis

of a-conopeptides

Synthesis of variants of a-conotoxins: alanine scans and loop replacements

In addition to replication of natural conotoxins, the standard synthesis procedures described above have been applied for strategies requiring synthesis of specific variants of conotoxins The synthesis of alanine scan peptide variants containing systematic alanine replace-ments of the amino acids [62], and assessment in structure

or function screening procedures, may reveal crucial amino acids or regions that are essential binding and structural determinants A parallel of the alanine scan approach is the synthesis of a-conotoxin variants or

chimeras in which whole loop regions have been swapped with those from other a-conotoxins with different

attrib-utes in an attempt to confer a different specificity or

conformation [1,48,63]

Strategies for synthesis of multiple conotoxins in parallel

Synthesis and evaluation of many different peptide

mole-cules may be required for structure-function studies of

a-conotoxins in the search for optimum synthetic variants

The rate-limiting step in these studies is often the time and

effort required for peptide synthesis Options for synthesis

of multiple peptides in parallel have included synthesis on

polyethylene pins, in tea bags and on chip or memb rane

supports such as in the spot synthesis technique [64–66] A

study of [A10L]PnIA variants synthesized in parallel in a 96

well plate has been described [67] However there have been

few other references to the application of these techniques to

the synthesis of a-conotoxins and their analogues, and

quantities may be insufficient for conventional

structure-function studies There may be increasing scope for

applications of parallel synthesis, particularly

membrane-anchored synthetic peptide libraries, for structure-function

analysis by in situ screening using binding assays or

antibody recognition

Concluding remarks

Comprehensive characterization of novel natural

a-cono-toxin peptides has relied on a combination of analyses

These have included Edman N-terminal sequencing, MS

and tandem MS for determination of the primary

sequence, determination of disulfide linkages after

differ-ential reduction and alkylation, and confirmation of the

primary structure Amino acid analysis in conjunction

with Edman sequence analysis and diagnostic ion MS has

been used to assess the possibility of other PTMs

Characterization would ideally include NMR analysis

for proof of structure although this has often been

precluded by scarcity of material It may be the only

means to assure certainty in determination of novel

disulfide linkages The primary structure of the peptide

and the identified PTMs have usually been verified by

subsequent synthetic chemistry and comparison with the

natural peptide The synthesized disulfide-bonded peptide,

with minimum purity of 95–98% determined by

reversed-phase HPLC, has been compared with the natural

peptide, if available, by coinjection of the synthesized

peptide and the naturally occurring peptide, and

authen-ticity has been indicated by chromatography coelution

The correctness of the disulfide linkage has usually been

confirmed by NMR spectroscopy Newly identified

pep-tides that clearly fit previously defined categories are often

not subjected to such rigorous analysis For variants such

as residue replacement peptides and chimeras, where there is

no corresponding natural peptide available for comparison,

verification of authenticity, particularly correct disulfide

linkage, has been reliant on NMR structure analysis Many

nonselective syntheses of a-conotoxins yield a single

pre-dominant disulfide-bonded isomer, although in cases where

multiple isomers are generated in substantial amounts,

further characterization may be warranted Thorough

assessment of novel a-conotoxin folds may generate

import-ant structure-function information

In conclusion, the physico-chemical characterization of the native peptides and chemical synthesis of neuronal a-conotoxins provide an important basis for the pharma-cology, structure and modelling studies that are the subject

of further minireviews in this series

After this manuscript had been submitted for publication

a newly published paper reported 16 conotoxin precursors

of the A superfamily, from six Conus species, defining the A conotoxin gene superfamily [68]

Acknowledgements

We thank Annette Nicke, David Craik, Gene Hopping, Alun Jones and Richard Lewis for their input The LC/MS analysis shown in Fig 1 was run b y Alun Jones.

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